Calculators Created by Urvi Rathod

Vishwakarma Government Engineering College (VGEC), Ahmedabad
https://www.linkedin.com/in/urvi-rathod-a3b634177
1539
Formulas Created
1942
Formulas Verified
466
Across Categories

List of Calculators by Urvi Rathod

Following is a combined list of all the calculators that have been created and verified by Urvi Rathod. Urvi Rathod has created 1539 and verified 1942 calculators across 466 different categories till date.
Verified Coefficient of Friction of Power Screw given Effort in Lowering Load with Acme Threaded Screw
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Verified Coefficient of Friction of Power Screw given Effort in Moving Load with Acme Threaded Screw
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Verified Coefficient of Friction of Power Screw given Torque Required in Lifting Load with Acme Thread
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Verified Coefficient of Friction of Power Screw given Torque Required in Lowering Load with Acme Thread
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Verified Efficiency of Acme Threaded Power Screw
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Verified Effort Required in Lifting Load with Acme Threaded Screw
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Verified Effort Required in Lowering Load with Acme Threaded Screw
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Verified Helix Angle of Power Screw given Effort Required in Lifting Load with Acme Threaded Screw
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Verified Helix Angle of Power Screw given Load and Coefficient of Friction
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Verified Helix Angle of Power Screw given Torque Required in Lifting Load with Acme Threaded Screw
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Verified Helix Angle of Power Screw given Torque Required in Lowering Load with Acme Threaded Screw
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Verified Load on Power Screw given Effort Required in Lifting Load with Acme Threaded Screw
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Verified Load on Power Screw given Effort Required in Lowering Load with Acme Threaded Screw
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Verified Load on Power Screw given Torque Required in Lifting Load with Acme Threaded Screw
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Verified Load on Power Screw given Torque Required in Lowering Load with Acme Threaded Screw
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Verified Mean Diameter of Power Screw given Torque Required in Lowering Load with Acme Threaded Screw
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Verified Torque Required in Lowering Load with Acme Threaded Power Screw
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1 More Acme Thread Calculators
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Verified Black Bodies Heat Exchange by Radiation
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Verified Heat Exchange by Radiation due to Geometric Arrangement
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Verified Non Ideal Body Surface Emittance
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10 More Conduction, Convection and Radiation Calculators
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Verified Diameter of Spring Wire given Mean Stress in Spring
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Verified Diameter of Spring Wire given Torsional Stress Amplitude
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Verified Force Amplitude of Spring
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Verified Force Amplitude on Spring given Torsional Stress Amplitude
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Verified Maximum Force on Spring given Force Amplitude
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Verified Maximum Force on Spring given Mean Force
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Verified Mean Coil Diameter of Spring given Torsional Stress Amplitude
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Verified Mean Diameter of Spring coil given Mean Stress on Spring
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Verified Mean Force on spring
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Verified Mean Force on Spring given Mean Stress
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Verified Mean Stress on Spring
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Verified Minimum Force on Spring given Force Amplitude
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Verified Minimum Force on Spring given Mean Force
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Verified Shear Stress Correction Factor for Spring given Mean Stress
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Verified Shear Stress Factor for Spring given Torsional stress amplitude
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Verified Shear Yield Strength of Oil-hardened Tempered Steel Wires
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Verified Shear Yield Strength of Patented and Cold-drawn Steel Wires
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Verified Spring Index given Mean Stress on spring
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Verified Spring Index given Torsional Stress Amplitude
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Verified Torsional Stress Amplitude in Spring
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Verified Ultimate Tensile Stress of Ol hardened tempered Steel wires
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Verified Ultimate Tensile Stress of Patented and Cold drawn Steel wires
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Verified Force applied at end of Spring given Bending Stress on Graduated length leaves
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Verified Force Applied at End of Spring given Force Taken by Graduated length Leaves
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Verified Force taken by Extra Full length leaves given Number of leaves
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Verified Force Taken by Full Length Leaves given Bending Stress in Plate Extra Full Length
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Verified Force Taken by Full length Leaves given Force at end of Spring
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Verified Force taken by Graduated length leaves given Bending Stress in Plate
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Verified Force Taken by Graduated length leaves given Deflection at Load Point
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Verified Force taken by graduated length leaves given force applied at end of spring
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3 More Force Taken By Leaves Calculators
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Verified Diameter of Spring Wire from Load Stress Equation
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Verified Diameter of Spring Wire given Spring Index
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Verified Inside Diameter of Spring Coil given Mean Coil Diameter
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Verified Mean Coil Diameter given Spring Index
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Verified Mean Coil Diameter of Spring
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Verified Outside Diameter of Spring given Mean Coil Diameter
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Verified Spring Index
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Verified Spring Index given Shear stress in Spring
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Verified Total Number of Coils given Solid Length of Spring
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Verified Length of Cantilever given Bending Stress in Plate
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Verified Length of Cantilever given Bending Stress in Plate of Extra Full Length
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Verified Length of Cantilever given Bending Stress on Graduated Length Leaves
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Verified Length of Cantilever given Deflection at Load Point of Graduated length leaves
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Verified Shear Yield Strength by Maximum Shear Stress Theory
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2 More Maximum Shear Stress Theory Calculators
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Verified Combined Stiffness of 2 Springs when Connected in Parallel
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Verified Combined Stiffness of 3 Springs when Connected in Parallel
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Verified Combined Stiffness of Three Springs Connected in Series
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Verified Combined Stiffness of Two Springs Connected in Series
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Verified Coefficient of Friction of Screw Thread given Load
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Verified Effort Required in Lowering Load
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Verified Helix Angle of Power Screw given Effort Required in Lowering Load
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Verified Load on power Screw given Effort Required in Lowering Load
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Verified Load on power Screw given Torque Required in Lowering Load
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Verified Torque Required in Lowering Load on Power Screw
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3 More Torque Requirement in Lowering Load using Square threaded Screws Calculators
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Created Length using Volume of Conductor Material (DC 2-Wire OS)
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Created Line Losses using Volume of Conductor Material (DC 2-Wire OS)
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Created Load Current using Line Losses(DC Two-Wire OS)
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Created Maximum Voltage using Area of X-Section(DC Two-Wire OS)
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Created Resistance(2-Wire DC OS)
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Created Line to Neutral Current using Reactive Power
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Created Line to Neutral Current using Real Power
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43 More AC Circuit Design Calculators
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Verified In-Phase Potentiometer Reading
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Verified Potentiometer Voltage
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Verified Quadrature Potentiometer Reading
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4 More AC Circuits Calculators
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Created Complex Power
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Created Complex Power given Power Factor
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Created Power in Single-Phase AC Circuits
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Created Power in Single-Phase AC Circuits using Current
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Created Power in Single-Phase AC Circuits using Voltage
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Created Power in Three-Phase AC Circuits using Phase Current
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Created Reactive Power
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Created Reactive Power using Line-to-Neutral Current
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Created Reactive Power using RMS Voltage and Current
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Created Real Power in AC Circuit
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Created Real Power using Line-to-Neutral Voltage
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Created Real Power using RMS Voltage and Current
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Verified Average Meter Current
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Verified Current at Full-scale reading
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Verified Microammeter Current
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Verified Peak Meter Current
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6 More Ammeter Calculators
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Verified Common-Base Current Gain
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Verified Common-Emitter Current Gain using Common-Base Current Gain
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Verified Forced Common-Emitter Current Gain
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Verified Intrinsic Gain of BJT
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Verified Overall Voltage Gain given Load Resistance of BJT
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Verified Overall Voltage Gain of Amplifier when Load Resistance is Connected to Output
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Verified Overall Voltage Gain of Buffer Amplifier given Load Resistance
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Verified Voltage Gain given all Voltages
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Verified Voltage Gain given Collector Current
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7 More Amplification Factor or Gain Calculators
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Verified Maximum Voltage Gain at Bias Point
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Verified Maximum Voltage Gain given all Voltages
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Verified Voltage Gain given Drain Voltage
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Verified Voltage Gain given Load Resistance of MOSFET
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2 More Amplification Factor or Gain Calculators
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Verified Saturation Current
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Verified Voltage Gain given Load Resistance
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19 More Amplifier Characteristics Calculators
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Verified Drain Voltage
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Verified Gate to Base Capacitance
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Verified Gate to Channel Voltage
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Verified Gate to Collector Potential
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Verified Gate to Drain Capacitance
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Verified Gate to Drain Potential
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Verified Gate to Source Capacitance
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Verified Gate to Source Potential
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Verified High Noise Margin
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Verified Low Noise Margin
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Verified Maximum Low Input Voltage
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Verified Maximum Low Output Voltage
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Verified Minimum High Input Voltage
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Verified Minimum High Output Voltage
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Verified Potential between Source to Body
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Verified Potential from Drain to Source
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Verified Antenna Gain
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Verified Average Radiation Intensity
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Verified Directivity of Antenna
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Verified Radiation Intensity
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20 More Antenna Theory Parameters Calculators
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Verified Distance between Plates given Dynamic Viscosity of Fluid
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Verified Friction Factor given Frictional Velocity
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Verified Shear Stress using Dynamic Viscosity of Fluid
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Verified Total Surface Area of Object Submerged in Liquid
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5 More Applications of Fluid Force Calculators
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Verified Bending Moment on Arm of Belt Driven Pulley
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Verified Bending Moment on Arm of Belt Driven Pulley given Bending Stress in Arm
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Verified Bending Moment on Arm of Belt Driven Pulley given Torque Transmitted by Pulley
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Verified Bending Stress in Arm of Belt Driven Pulley
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Verified Bending Stress in Arm of Belt Driven Pulley given Torque Transmitted by Pulley
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Verified Major Axis of Elliptical Cross-Section of Pulley's Arm given Moment of Inertia of Arm
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Verified Minor Axis of Elliptical Cross-Section of Arm given Moment of Inertia of Arm
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Verified Minor Axis of Elliptical Cross-Section of Pulley's Arm given Bending Stress in Arm
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Verified Minor Axis of Elliptical Cross-Section of Pulley's Arm given Moment of Inertia of Arm
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Verified Minor Axis of Elliptical Cross-Section of Pulley's Arm given Torque and Bending Stress
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Verified Moment of Inertia of Pulley's Arm
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Verified Moment of Inertia of Pulley's Arm given Bending Stress in Arm
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Verified Moment of Inertia of Pulley's Arm given Minor Axis of Elliptical Section Arm
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Verified Number of Arms of Pulley given Bending Moment on Arm
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Verified Number of Arms of Pulley given Bending Stress in Arm
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Verified Number of Arms of Pulley given Torque Transmitted by Pulley
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Verified Radius of Rim of Pulley given Bending Moment Acting on Arm
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Verified Radius of Rim of Pulley given Torque Transmitted by Pulley
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Verified Tangential Force at End of Each Arm of Pulley given Bending Moment on Arm
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Verified Tangential Force at End of Each Arm of Pulley given Torque Transmitted by Pulley
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Verified Torque Transmitted by Pulley
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Verified Torque Transmitted by Pulley given Bending Moment on Arm
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Verified Torque Transmitted by Pulley given Bending Stress in Arm
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Verified Area of Memory Cell
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Verified Area of Memory Containing N Bits
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Verified Array Efficiency
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Verified Bit Capacitance
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Verified Carry-Increamentor Adder Delay
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Verified Carry-Looker Adder Delay
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Verified Carry-Ripple Adder Critical Path Delay
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Verified Carry-Skip Adder Delay
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Verified Cell Capacitance
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Verified Critical Delay in Gates
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Verified Ground Capacitance
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Verified Group Propagation Delay
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Verified K-Input 'And' Gate
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Verified Multiplexer Delay
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Verified N-Bit Carry-Skip Adder
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Verified N-Input 'And' Gate
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Verified Tree Adder Delay
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Verified Voltage Swing On Bitline
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Verified 'XOR' Delay
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Verified Diameter of Shaft given Principle Shear Stress
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Verified Equivalent Bending Moment when Shaft is Subjected to Fluctuating Loads
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Verified Equivalent Torsional Moment when Shaft is Subjected to Fluctuating Loads
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Verified Principle Shear Stress Maximum Shear Stress Theory of Failure
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1 More ASME Code for Shaft Desgin Calculators
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Verified Angle of Wrap given Tension on Loose Side of Band
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Verified Coefficient of Friction between Friction Lining and Brake Drum
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Verified Radius of Brake Drum given Torque Absorbed by Brake
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Verified Tension of Tight Side of Band
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Verified Tension on Loose Side of Band
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Verified Tension on Loose Side of Band given Torque Absorbed by Brake
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Verified Tension on Tight Side of Band given Torque Absorbed by Brake
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Verified Torque Absorbed by Brake
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Verified Base Current 1 of BJT
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Verified Base Current 2 of BJT
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Verified Base Current of PNP Transistor given Emitter Current
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Verified Base Current of PNP Transistor using Collector Current
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Verified Base Current of PNP Transistor using Common-Base Current Gain
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Verified Base Current of PNP Transistor using Saturation Current
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Verified Base Current using Saturation Current in DC
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Verified Drain Current given Device Parameter
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Verified Reference Current of BJT Mirror
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Verified Reference Current of BJT Mirror given Collector Current
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Verified Saturation Current using Doping Concentration
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Verified Total Base Current
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2 More Base Current Calculators
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Verified Amount of Feedback Given Loop Gain
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3 More Basic Characteristics Calculators
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Verified Class Width of Data
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Verified F Value of Two Samples
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Verified F Value of Two Samples given Sample Standard Deviations
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Verified Number of Classes given Class Width
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Verified Number of Individual Values given Residual Standard Error
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Verified P Value of Sample
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Verified Sample Size given P Value
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11 More Basic Formulas in Statistics Calculators
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Verified Degree of Freedom given Equipartition Energy
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15 More Basic Formulas of Thermodynamics Calculators
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Verified Drift Speed
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Verified Drift Speed given Cross-Sectional Area
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7 More Basics of Current Electricity Calculators
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Verified Current Value for Alternating Current
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Created EMF Induced in Rotating Coil
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Verified Power Factor
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Verified Resonant Frequency for LCR Circuit
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Created Total Flux in Mutual Inductance
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10 More Basics of Electromagentic Induction Calculators
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Verified Digital Image Column
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Verified Digital Image Row
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Verified Number of Bits
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Verified Number of Grey Level
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13 More Basics of Image Processing Calculators
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Verified Carrier Frequency in Spectral Line
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Verified Plasma Frequency
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Verified Power Generated in Anode Circuit
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Verified Power Obtained from DC Power Supply
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Verified Rectangular Microwave Pulse Peak Power
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Verified Reduced Plasma Frequency
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Verified Repeller Voltage
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Verified Return Loss
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Verified Skin Depth
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14 More Beam Tube Calculators
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Verified Bending Moment due to Force
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Verified Bending Moment due to Force given Angle of Rotation of Arbor with Respect to Drum
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Verified Bending Moment due to Force given Bending Stress induced in Spring
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Verified Bending Moment due to Force given Deflection of one End of Spring
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Verified Bending Moment given Strain Energy Stored in Spring
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Verified Deflection of one End of Spring with Respect to Other End
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Verified Distance of centre of Gravity of Spiral from outer end given Bending Moment due to Force
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Verified Distance of centre of Gravity of Spiral from outer end given Deflection of one End of Spring
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Verified Base Collector Delay Time
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Verified Base Resistance
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Verified Base Transit Time
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Verified Collector Base Capacitance
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Verified Collector Charging Time
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Verified Cut-off Frequency of Microwave
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Verified Emitter Base Charging Time
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Verified Emitter to Collector Delay Time
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Verified Emitter to Collector Distance
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Verified Maximum Frequency of Oscillations
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Verified Saturation Drift Velocity
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4 More BJT Microwave Devices Calculators
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Verified Actual Coefficient of Friction given Equivalent Coefficient of Friction
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Verified Braking Torque when Brakes are Applied
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Verified Coefficient of Friction given Braking Torque
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Verified Distance from Center of Drum to Pivoted Shoe
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Verified Equivalent Coefficient of Friction in Block Brake with Long Shoe
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Verified Length of Block given Normal Reaction
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Verified Normal Reaction Force
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Verified Normal Reaction Force given Braking Torque
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Verified Permissible Pressure between Block and Brake Drum given Normal Reaction
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Verified Radius of Drum Brake given Braking Torque
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Verified Radius of Drum given Distance from Center of Drum to Pivoted Shoe
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Verified Width of Block given Normal Reaction Force
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Verified Core Diameter of Bolt given Maximum Tensile Stress in Bolt
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Verified Core Diameter of Bolt given Tensile Force on Bolt in Tension
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Verified Nominal Diameter of Bolt given Diameter of Hole inside Bolt
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5 More Bolt Dimensions Calculators
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Verified Buffer Capacity
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Verified Maximum pH of Basic Buffer
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Verified Maximum pOH of Acidic Buffer
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8 More Buffer Solution Calculators
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Verified Inner Diameter of Boiler given Thickness of Welded Boiler Shell
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Verified Internal Pressure in Boiler given Thickness of Welded Boiler Shell
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Verified Tensile Stress in Boiler Butt Weld given Thickness of Boiler Shell
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Verified Thickness of Welded Boiler Shell given Stress in Weld
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12 More Butt Welds Calculators
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Verified Gain at Mid and High Frequencies
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Verified Upper 3-DB Frequency of Feedback Amplifier
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3 More BW Extension and Signal Interference Calculators
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Created Capacitance for Parallel RLC Circuit using Q Factor
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Created Capacitance for Series RLC Circuit given Q Factor
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Created Capacitance given Cut off Frequency
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Created Capacitance using Time Constant
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Verified Capacitance for Parallel Plate Capacitors with Dielectric between them
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Verified Capacitor with Dielectric
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10 More Capacitance Calculators
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Verified Drain Resistance of Cascode Amplifier
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Verified Output voltage gain of MOS Cascode Amplifier
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3 More Cascode Ampifier Calculators
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Verified Cross-sectional Area of Rod given Strain Energy stored in Rod
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Verified Force Applied on Rod given Strain Energy Stored in Tension Rod
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Verified Length of Rod given Strain Energy Stored
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Verified Length of Shaft given Strain Energy Stored in Shaft Subjected to Bending Moment
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Verified Length of Shaft when Strain Energy in Shaft Subjected to External Torque
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Verified Modulus of Elasticity given Strain Energy Stored in Shaft Subjected to Bending Moment
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Verified Modulus of Elasticity of Rod given Strain Energy Stored
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Verified Modulus of Rigidity of Rod given Strain Energy in Rod
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Verified Moment of Inertia of Shaft when Strain Energy Stored in Shaft Subjected to Bending Moment
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Verified Polar Moment of Inertia of Rod given Strain Energy in Rod
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Verified Strain Energy in Rod when it is Subjected to External Torque
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Verified Strain Energy Stored in Rod Subjected to Bending Moment
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Verified Strain Energy Stored in Tension Rod
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Verified Torque given Strain Energy in Rod Subjected to External Torque
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Verified Concentration of Hydronium Ion in Salt of Weak Acid and Strong Base
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Verified Concentration of Hydronium ion in Weak Base and Strong Acid
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Verified Degree of Hydrolysis in Salt of Weak Acid and Strong Base
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Verified Hydrolysis Constant in Strong Acid and Weak Base
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Verified Hydrolysis Constant in Weak Acid and Strong Base
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8 More Cationic and Anionic Salt Hydrolysis Calculators
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Verified Average Calling Time
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Verified Cell Radius
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Verified Co-Channel Interference
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Verified Frequency Reuse Distance
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Verified Hamming Distance
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Verified Maximum Calls per Hour per Cell
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Verified New Cell Area
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Verified New Cell Radius
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Verified New Traffic Load
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Verified Offered Load
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Verified Old Cell Area
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Verified Old Cell Radius
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Verified Traffic Load
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3 More Cellular Concepts Calculators
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Verified Electrostatic Deflection Sensitivity of CRT
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Verified Force on Current Element in Magnetic Field
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Verified Holes Diffusion Constant
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Verified Intrinsic Concentration
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Verified Thermal Voltage using Einstein's Equation
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11 More Charge Carrier Characteristics Calculators
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Verified Circumference of Circle given Diameter
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4 More Circumference of Circle Calculators
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Verified Area of Source Diffusion
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Verified CMOS Critical Voltage
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Verified CMOS Mean Free Path
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Verified Critical Electric Field
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Verified Depletion Region Width
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Verified Effective Capacitance in CMOS
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Verified Effective Channel Length
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Verified Oxide Layer Thickness
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Verified Permittivity of Oxide Layer
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Verified PN Junction Length
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Verified Sidewall Perimeter of Source Diffusion
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Verified Transition Width of CMOS
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Verified Voltage at Minimum EDP
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Verified Width of Gate
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Verified Width of Source Diffusion
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Verified Delay of 1-Bit Propagate Gates
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Verified Delay of AND-OR Gate in Gray Cell
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Verified Delay Rise
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Verified Edge Rate
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Verified Fall Time
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Verified Normalized Delay
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Verified Propagation Delay
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Verified Propagation Delay without Parasitic Capacitance
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Verified Rise Time
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Verified Small Deviation Delay
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Verified VCDL Gain
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Verified Voltage-Controlled Delay Line
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1 More CMOS Delay Characteristics Calculators
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Verified Adjacent Capacitance
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Verified Agression Driver
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Verified Agression Time Constant
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Verified Agressor Voltage
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Verified Branching Effort
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Verified Built-in Potential
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Verified Capacitance Offpath
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Verified Capacitance Onpath
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Verified Change in Frequency Clock
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Verified Ground to Agression Capacitance
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Verified Lock Voltage
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Verified Off-Path Capacitance of CMOS
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Verified Output Clock Phase
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Verified Static Current
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Verified Static Power Dissipation
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Verified Thermal Voltage of CMOS
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Verified Time Constant Ratio of Agression to Victim
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Verified Total Capacitance Seen by Stage
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Verified VCO Control Voltage
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Verified VCO Offset Voltage
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Verified VCO Single Gain Factor
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Verified Victim Driver
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Verified Victim Time Constant
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Verified Victim Voltage
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Verified Activity Factor
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Verified Contention Current in Ratioed Circuits
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Verified Dynamic Power in CMOS
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Verified Gate Leakage through Gate Dielectric
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Verified Gates on Critical Path
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Verified Leakage Energy in CMOS
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Verified Output Switching at Load Power Consumption
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Verified Short-Circuit Power in CMOS
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Verified Static Power in CMOS
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Verified Subthreshold Leakage through OFF Transistors
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Verified Switching Energy in CMOS
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Verified Switching Power
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Verified Switching Power in CMOS
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Verified Total Energy in CMOS
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Verified Total Power in CMOS
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2 More CMOS Power Metrics Calculators
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Verified Capacitance of External Load
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Verified Change in Frequency of Clock
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Verified Change in Phase of Clock
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Verified Delay for Two Inverters in Series
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Verified Fanout of Gate
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Verified Feedback Clock PLL
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Verified Gate Delay
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Verified Input Clock Phase PLL
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Verified Invertor Electric Effort 1
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Verified Invertor Electric Effort 2
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Verified Invertor Power
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Verified Output Clock Phase PLL
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Verified PLL Phase Detector Error
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Verified Power Consumption of Chip
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Verified Series Resistance from Die to Package
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Verified Series Resistance from Package to Air
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Verified Stage Effort
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Verified Temperature Difference between Transistors
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Verified Thermal Resistance between Junction and Ambient
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Verified Transfer Function of PLL
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Verified Acceptable MTBF
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Verified Aperture Time for Falling Input
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Verified Aperture Time for Rising Input
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Verified Hold Time at High logic
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Verified Hold Time at Low logic
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Verified Initial Voltage of Node A
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Verified Metastable Voltage
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Verified Phase Detector Average Voltage
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Verified Probability of Synchronizer Failure
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Verified Setup Time at High Logic
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Verified Setup Time at Low Logic
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Verified Small Signal Offset Voltage
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Verified XOR Phase Detector Current
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Verified XOR Phase Detector Phase
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Verified XOR Phase Detector Phase with reference to Detector Current
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Verified XOR Phase Detector Voltage
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1 More CMOS Time Characteristics Calculators
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Verified Coefficient of Variation Ratio
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6 More Coefficients Calculators
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Verified Collector Current given Early Voltage for PNP Transistor
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Verified Collector Current of BJT
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Verified Collector Current of PNP Transistor
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Verified Collector Current of PNP Transistor when Common-Emitter Current Gain
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Verified Collector Current using Early Voltage for NPN Transistor
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Verified Collector Current using Emitter Current
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Verified Collector Current using Leakage Current
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Verified Collector Current using Saturation Current
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Verified Collector Current when Saturation Current due to DC Voltage
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1 More Collector Current Calculators
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Verified Common Base Current Gain
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Verified Emitter Current of Common-Base Amplifier
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Verified Input Impedance of Common-Base Amplifier
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Verified Input Resistance of Common-Base Circuit
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Verified Negative Voltage Gain from Base to Collector
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Verified Resistance of Emitter in Common-Base Amplifier
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Verified Voltage Gain of Common-Base Amplifier
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1 More Common Base Amplifier Calculators
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Verified Fundamental Voltage in Common-Emitter Amplifier
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Verified Input Resistance of Common Emitter Amplifier
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Verified Input Resistance of Common Emitter Amplifier given Small-Signal Input Resistance
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Verified Input Resistance of Common-Emitter Amplifier given Emitter Resistance
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Verified Overall Feedback Voltage Gain of Common-Collector Amplifier
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Verified Overall Feedback Voltage Gain of Common-Emitter Amplifier
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Verified Overall Voltage Gain of Common-Emitter Amplifier
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1 More Common Emitter Amplifier Calculators
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Verified Common-Mode Input Signal of MOSFET
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Verified Common-Mode Rejection Ratio of MOS Controlled Source Transistor
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Verified Common-Mode Rejection Ratio of MOS with Current-Mirror Load
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Verified Common-Mode Rejection Ratio of MOS with Current-Mirror Load when Resistance at Drains are Equal
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Verified Common-Mode Rejection Ratio of MOSFET
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Verified Common-Mode Rejection Ratio of MOSFET given Resistance
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Verified Common-Mode Rejection Ratio of MOSFET in Decibels
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Verified Common-Mode Rejection Ratio of MOSFET when Transconductance Mismatches
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Verified Common-Mode Signal of MOSFET given Output Voltage at Drain Q2
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1 More Common Mode Rejection Ratio (CMRR) Calculators
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Verified Emitter Voltage with respect to Voltage Gain
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Verified Load Voltage of CS Amplifier
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Verified Open-Circuit Voltage Gain of CS Amplifier
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Verified Overall Feedback Voltage Gain of Common-Source Amplifier
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Verified Overall Voltage Gain of Source Follower
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6 More Common Source Amplifier Calculators
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Verified Molarity
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Verified Molarity using Molality
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Verified Molarity using Mole Fraction
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Verified Mole Fraction of Solute
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Verified Mole Fraction of Solvent
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Verified Mole Fraction using Molality
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Verified Mole Fraction using Molarity
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Verified Number of Moles of Solute using Molarity
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14 More Concentration Terms Calculators
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Verified Axial Force transmitted by Outer Spring
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Verified Cross-Sectional Area of Inner Spring given Axial force transmitted
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Verified Cross-sectional Area of Inner Spring Wire
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Verified Cross-sectional Area of Outer Spring given Axial force transmitted
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Verified Cross-sectional Area of Outer Spring Wire
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Verified Radial Clearance between Concentric Springs
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Verified Wire Diameter of Inner Spring given Axial Force transmitted by Outer Spring
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Verified Wire Diameter of Inner Spring given Radial Clearance between Springs
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Verified Wire Diameter of Outer Spring given Axial Force transmitted by Outer Spring
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Verified Wire Diameter of Outer Spring given Radial Clearance between Springs
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1 More Concentric Springs Calculators
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Verified Duty Cycle for Buck Regulator (CCM)
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Verified Input Voltage for Buck Regulator (CCM)
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Verified Output Voltage for Buck Regulator (CCM)
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Verified Duty Cycle for Boost Regulator (CCM)
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Verified Input Voltage for Boost Regulator (CCM)
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Verified Output Voltage for Boost Regulator (CCM)
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Verified Duty Cycle for Buck-Boost Regulator (CCM)
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Verified Input Voltage for Buck-Boost Regulator (CCM)
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Verified Output Voltage for Buck-Boost Regulator (CCM)
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Verified Actual Number of Teeth on Gear given Virtual Number of Teeth
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Verified Addendum Circle Diameter of Gear
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Verified Addendum Circle Diameter of Gear given Pitch Circle Diameter
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Verified Addendum of Gear given Addendum Circle Diameter
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Verified Angular Velocity of Gear given Speed Ratio
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Verified Angular Velocity of Pinion given Speed Ratio
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Verified Center to Center distance between Two Gears
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Verified Dedendum Circle Diameter of Gear given Pitch Circle Diameter
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Verified Normal Module of Helical Gear
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Verified Normal Module of Helical Gear given Addendum Circle Diameter
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Verified Normal Module of Helical Gear given Center to Center Distance between Two Gears
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Verified Normal Module of Helical Gear given Pitch Circle Diameter
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Verified Normal Module of Helical Gear given Virtual Number of Teeth
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Verified Number of Teeth on First Gear given Center to Center Distance between Two Gears
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Verified Number of Teeth on Gear given Addendum Circle Diameter
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Verified Number of Teeth on Gear given Pitch Circle Diameter
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Verified Number of Teeth on Helical Gear given Speed Ratio for Helical Gears
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Verified Number of Teeth on Pinion given Speed Ratio
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Verified Number of Teeth on Second Helical Gear given Center to Center Distance between Two Gears
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Verified Pitch Circle Diameter of Gear given Addendum Circle Diameter
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Verified Pitch Circle Diameter of Gear given Dedendum Circle Diameter
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Verified Pitch Circle Diameter of Gear given Radius of Curvature at Point
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Verified Pitch Circle Diameter of Helical Gear
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Verified Speed Ratio for Helical Gears
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Verified Transverse Module of Helical Gear given Normal Module
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Verified Transverse Module of Helical Gear given Transverse Diametrical Pitch
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Verified Virtual Number of Teeth on Helical Gear
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Verified Virtual Number of Teeth on Helical Gear given Actual Number of Teeth
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Verified Belt Length for Cross Belt Drive
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Verified Center Distance given Wrap Angle for Small Pulley of Cross Belt Drive
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Verified Diameter of Big Pulley given Wrap Angle for Small Pulley of Cross Belt Drive
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Verified Diameter of Small Pulley given Wrap Angle for Small Pulley of Cross Belt Drive
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Verified Wrap Angle for Small Pulley of Cross Belt Drive
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Verified Duty Cycle for Cuk Regulator
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Verified Input Voltage for Cuk Regulator
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Verified Output Voltage for Cuk Regulator
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Created Armature Current of Shunt DC Motor given Input Power
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Created Armature Current of Shunt DC Motor given Torque
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Created Armature Current of Shunt DC Motor given Voltage
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Created Field Current of DC Shunt Motor
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Created Armature Current for DC Shunt Generator
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Created Field Current of DC Shunt Generator
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Created Field Current of DC Shunt Generator given Load Current
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Created Current using Complex Power
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Created Current using Power Factor
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Created Electric Current using Reactive Power
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Created Electric Current using Real Power
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Created RMS Current using Reactive Power
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Created RMS Current using Real Power
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Created Armature Current given Power in Induction Motor
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Created Field Current using Load Current in Induction Motor
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Created Load Current in Induction Motor
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Created Rotor Current in Induction Motor
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1 More Current Calculators
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Created Primary Current given Primary Leakage Reactance
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Created Primary Current given Voltage Transformation Ratio
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Created Primary Current using Primary Parameters
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Created Secondary Current given Secondary Leakage Reactance
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Created Secondary Current given Voltage Transformation Ratio
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Created Secondary Current using Secondary Parameters
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Created Armature Current of Series DC Generator given Output Power
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Created Armature Current of Series DC Generator given Torque
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Created Armature Current of Series DC Generator using Terminal Voltage
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Created Load Current of Series DC Generator given Load Power
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Created Load Current of Series DC Generator given Output Power
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Created Armature Current of Series DC Motor
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Created Armature Current of Series DC Motor given Input Power
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Created Armature Current of Series DC Motor given Speed
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Created Armature Current of Series DC Motor using Voltage
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Created Armature Current of Synchronous Motor given 3 Phase Mechanical Power
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Created Armature Current of Synchronous Motor given Input Power
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Created Armature Current of Synchronous Motor given Mechanical Power
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Created Load Current of Synchronous Motor given 3 Phase Mechanical Power
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Created Load Current of Synchronous Motor using 3 Phase Input Power
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Verified Drain Current in Load Line
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Verified Drain Current without Channel-Length Modulation of MOSFET
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Verified Drain Saturation Current of MOSFET
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Verified First Drain Current of MOSFET on Large-Signal Operation
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Verified First Drain Current of MOSFET on Large-Signal Operation given Overdrive Voltage
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Verified Second Drain Current of MOSFET on Large-Signal Operation
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6 More Current Calculators
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Current (14)
Created A-Phase Current using A-Phase Voltage(LGF)
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Created A-Phase Current using Negative Sequence Current (LGF)
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Created A-Phase Current using Positive Sequence Current (LGF)
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Created A-Phase Current using Zero Sequence Current (LGF)
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Created Negative Sequence Current for L-G-F
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Created Negative Sequence Current using A-Phase Current (LGF)
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Created Negative Sequence Current using A-Phase EMF (LGF)
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Created Positive Sequence Current for L-G-F
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Created Positive Sequence Current using A-Phase Current (LGF)
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Created Positive Sequence Current using A-Phase EMF (LGF)
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Created Positive Sequence Current using Fault Impedance(LGF)
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Created Zero Sequence Current for L-G-F
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Created Zero Sequence Current using A-Phase Current (LGF)
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Created Zero Sequence Current using A-Phase EMF (LGF)
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5 More Current Calculators
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Created B-Phase Current (LLF)
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Created B-Phase Current using Fault Impedance (LLF)
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Created C-Phase Current using Fault Impedance (LLF)
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Created C-Phase Current(LLF)
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Created Negative Sequence Current(LLF)
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Created Positive Sequence Current (LLF)
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4 More Current Calculators
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Current (10)
Created B-Phase Current (LLGF)
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Created C-Phase Current (LLGF)
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Created Fault Current (LLGF)
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Created Fault Current using B-Phase Voltage (LLGF)
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Created Fault Current using C-Phase Voltage (LLGF)
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Created Negative Sequence Current using Negative Sequence Voltage (LLGF)
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Created Positive Sequence Current using Positive Sequence Voltage (LLGF)
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Created Zero Sequence Current using B-Phase Voltage (LLGF)
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Created Zero Sequence Current using C-Phase Voltage (LLGF)
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Created Zero Sequence Current using Zero Sequence Voltage (LLGF)
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6 More Current Calculators
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Created Receiving End Current using Impedance (STL)
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Created Receiving End Current using Losses (STL)
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Created Receiving End Current using Receiving End Power (STL)
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Created Receiving End Current using Sending End Angle (STL)
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Created Receiving End Current using Transmission Efficiency (STL)
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Created Sending End Current using Losses (STL)
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Created Sending End Current using Sending End Power (STL)
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Created Sending End Current using Transmission Efficiency (STL)
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Created Transmitted Current (SC Line)
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Created Load Current(Two-Wire One Conductor Earthed)
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Created Maximum Voltage using K(Two-Wire One Conductor Earthed)
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Created Maximum Voltage using Line Losses(Two-Wire One Conductor Earthed)
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Created Maximum Voltage using Load Current(Two-Wire One Conductor Earthed)
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Created Maximum Voltage using Volume(Two-Wire One Conductor Earthed)
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Created Load Current using Line Losses(Two-Wire Mid-Point Earthed)
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Created Load Current(Two-Wire Mid-Point Earthed)
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Created Maximum Voltage (Two-Wire Mid-Point Earthed)
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Created Maximum Voltage using Line Losses(Two-Wire Mid-Point Earthed)
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Created Maximum Voltage using Load Current(Two-Wire Mid-Point Earthed)
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Created Maximum Voltage using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
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Created Load Current using Area of X-Section(DC 3-Wire)
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Created Load Current using Line Losses(DC 3-Wire)
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Created Load Current(DC 3-Wire)
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Created Maximum Power using Constant(DC 3-Wire)
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Created Maximum Power using Load Current(DC 3-Wire)
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Created Maximum Voltage using Area of X-Section(DC 3-Wire)
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Created Maximum Voltage using Line Losses(DC 3-Wire)
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Created Maximum Voltage using Volume of Conductor Material (DC 3-Wire)
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Created Load Current using Area of X-Section(Single Phase Two Wire OS)
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Created Load Current using Line Losses (Single Phase Two Wire OS)
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Created Load Current(Single Phase Two Wire OS)
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Created Maximum Voltage using Area of X-Section(Single Phase Two Wire OS)
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Created Maximum Voltage using Load Current (Single Phase Two Wire OS)
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Created RMS Voltage using Area of X-Section(Single Phase Two Wire OS)
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Created RMS Voltage using Load Current (Single Phase Two Wire OS)
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Created Load Current(Single-Phase Two-Wire Mid-Point Earthed)
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Created Maximum Voltage using Area of X-section(Single-Phase Two-Wire Mid-Point Earthed OS)
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Created Maximum Voltage using Line Losses (Single-Phase Two-Wire Mid-Point OS)
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Created Maximum Voltage using Load Current (Single-Phase Two-Wire Mid-Point OS)
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Created Maximum Voltage(Single-Phase Two-Wire Mid-Point Earthed)
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Created RMS Voltage using Area of X-Section(Single-Phase Two-Wire Mid-Point Earthed OS)
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Created RMS Voltage using Line Losses (Single-Phase Two-Wire Mid-Point OS)
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Created RMS Voltage using Load Current (Single-Phase Two-Wire Mid-Point OS)
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Created Load Current using Area of X-Section(Single-Phase Three-Wire OS)
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Created Load Current using Line Losses (Single-Phase Three-Wire OS)
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Created Load Current(Single-Phase Three-Wire OS)
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Created Maximum Voltage using Area of X-Section(Single-Phase Three-Wire OS)
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Created Maximum Voltage using Line Losses (Single-Phase Three-Wire OS)
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Created Maximum Voltage using Load Current (Single-Phase Three-Wire OS)
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Created Maximum Voltage using Volume of Conductor Material (Single-Phase Three-Wire OS)
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Created Maximum Voltage(Single-Phase Three-Wire OS)
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Created RMS Voltage using Area of X-Section(Single-Phase Three-Wire OS)
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Created RMS Voltage using Line Losses (Single-Phase Three-Wire OS)
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Created RMS Voltage using Load Current (Single-Phase Three-Wire OS)
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Created Load Current using Area of X-Section(2-Phase 4-Wire OS)
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Created Load Current using Line Losses (2-Phase 4-Wire OS)
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Created Load Current(2-Phase 4-Wire OS)
Go
Created Maximum Voltage using Area of X-Section(2-Phase 4-Wire OS)
Go
Created Maximum Voltage using Line Losses (2-Phase 4-Wire OS)
Go
Created Maximum Voltage using Load Current (2-Phase 4-Wire OS)
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Created Maximum Voltage(2-Phase 4-Wire OS)
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Created RMS Voltage using Area of X-Section(2-Phase 4-Wire OS)
Go
Created RMS Voltage using Line Losses (2-Phase 4-Wire OS)
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Created RMS Voltage using Load Current (2-Phase 4-Wire OS)
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Created Load Current(3-Phase 3-Wire OS)
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Created Maximum Voltage using Area of X-Section(3-Phase 3-Wire OS)
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Created Maximum Voltage using Load Current(3-Phase 3-Wire OS)
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Created Maximum Voltage(3-Phase 3-Wire OS)
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Created Resistance(3-Phase 3-Wire OS)
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Created Resistivity using Area of X-Section(3-Phase 3-Wire OS)
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Created RMS Voltage using Area of X-Section(3-Phase 3-Wire OS)
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Created RMS Voltage using Load Current(3-Phase 3-Wire OS)
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Created Load Current(3-Phase 4-Wire OS)
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Created Maximum Voltage using Area of X-Section(3-Phase 4-Wire OS)
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Created Maximum Voltage using Load Current (3-Phase 4-Wire OS)
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Created Maximum Voltage using Volume of Conductor Material (3-Phase 4-Wire OS)
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Created Maximum Voltage(3-Phase 4-Wire OS)
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Created RMS Voltage using Area of X-Section(3-Phase 4-Wire OS)
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Created RMS Voltage using Load Current (3-Phase 4-Wire OS)
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Created Load Current in Each Outer (Two-Phase Three-Wire OS)
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Created Load Current of Neutral Wire (Two-Phase Three-Wire OS)
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Created Load Current using Area of X-Section(Two-Phase Three-Wire OS)
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Created Load Current(Two-Phase Three-Wire OS)
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Created Maximum Voltage using Area of X-Section(Two-Phase Three-Wire OS)
Go
Created Maximum Voltage using Line Losses (Two-Phase Three-Wire OS)
Go
Created Maximum Voltage using Load Current (Two-Phase Three-Wire OS)
Go
Created Maximum Voltage using Volume of Conductor Material (Two-Phase Three-Wire OS)
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Created Maximum Voltage(Two-Phase Three-Wire OS)
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Created RMS Voltage using Area of X-Section(Two-Phase Three-Wire OS)
Go
Created RMS Voltage using Line Losses (Two-Phase Three-Wire OS)
Go
Created RMS Voltage using Load Current (Two-Phase Three-Wire OS)
Go
Created Load Current (1-Phase 2-Wire US)
Go
Created Load Current using Constant (1-Phase 2-Wire US)
Go
Created Load Current using Line Losses (1-Phase 2-Wire US)
Go
Created Load Current using Resistance (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Area of X-Section (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Constant (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Line Losses (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Load Current (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Resistance (1-Phase 2-Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created RMS Voltage using Area of X-Section (1-Phase 2-Wire US)
Go
Created RMS Voltage using Constant (1-Phase 2-Wire US)
Go
Created RMS Voltage using Line Losses (1-Phase 2-Wire US)
Go
Created RMS Voltage using Load Current (1-Phase 2-Wire US)
Go
Created RMS Voltage using Resistance (1-Phase 2-Wire US)
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Created RMS Voltage using Volume of Conductor Material (1-Phase 2-Wire US)
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Created RMS Voltage(1-Phase 2-Wire US)
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Verified Emitter Current of BJT Differential Amplifier
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10 More Current and Voltage Calculators
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Created Receiving End Current using Sending End Current (LTL)
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Created Receiving End Current using Sending End Voltage (LTL)
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Created Receiving End Voltage using Sending End Current (LTL)
Go
Created Sending End Current (LTL)
Go
Created Sending End Voltage (LTL)
Go
Created Load Current (3 Phase 4 Wire US)
Go
Created Load Current using Line Losses (3 Phase 4 Wire US)
Go
Created Load Current using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Maximum Voltage using Area of X-Section (3 Phase 4 Wire US)
Go
Created Maximum Voltage using Line Losses (3 Phase 4 Wire US)
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Created Maximum Voltage using Load Current (3 Phase 4 Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Current using Line Losses (3-Phase 3-Wire US)
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Created Load Current Per Phase (3-Phase 3-Wire US)
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Created Load Current using Line Losses (DC Three-Wire US)
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Created Maximum Voltage between Each Phase and Neutral (3-Phase 3-Wire US)
Go
Created Maximum Voltage using Area of X-Section (3-Phase 3-Wire US)
Go
Created Maximum Voltage using Area of X-Section (DC Three-Wire US)
Go
Created Maximum Voltage using Line Losses (DC Three-Wire US)
Go
Created Maximum Voltage using Load Current Per Phase (3-Phase 3-Wire US)
Go
Created Maximum Voltage using RMS Voltage Per Phase (3-Phase 3-Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material (3-Phase 3-Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material(DC Three-Wire US)
Go
Created RMS Voltage Per Phase (3-Phase 3-Wire US)
Go
Created RMS Voltage using Area of X-Section (3-Phase 3-Wire US)
Go
Created RMS Voltage using Load Current Per Phase (3-Phase 3-Wire US)
Go
Created Current in Each Outer (2-Phase 3-Wire US)
Go
Created Current in Each Outer using Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created Current in Neutral Wire using Current in Each Outer (2-Phase 3-Wire US)
Go
Created Maximum Phase Voltage between Outer and Neutral Wire (2-Phase 3-Wire US)
Go
Created Maximum Voltage using Current in Each Outer (2-Phase 3-Wire US)
Go
Created Maximum Voltage using Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created Maximum Voltage using Line Losses (2-Phase 3-Wire US)
Go
Created Maximum Voltage using RMS Voltage between Outer and Neutral Wire (2-Phase 3-Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material (2-phase 3-wire US)
Go
Created RMS Voltage between Outer and Neutral Wire (2-Phase 3-Wire US)
Go
Created RMS Voltage using Current in Each Outer (2-Phase 3-Wire US)
Go
Created RMS Voltage using Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created RMS Voltage using Line Losses (2-Phase 3-Wire US)
Go
Created Load Current using Area of X-section (1 Phase 3 Wire US)
Go
Created Load Current using Line Losses (1 Phase 3 Wire US)
Go
Created Maximum Voltage using Area of X-section (1 Phase 3 Wire US)
Go
Created Maximum Voltage using Line Losses (1 Phase 3 Wire US)
Go
Created Maximum Voltage using Load Current (1 Phase 3 Wire US)
Go
Created Maximum Voltage using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created RMS Voltage using Area of X-section (1 Phase 3 Wire US)
Go
Created RMS Voltage using Line Losses (1 Phase 3 Wire US)
Go
Created RMS Voltage using Load Current (1 Phase 3 Wire US)
Go
Created RMS Voltage using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Load Current using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Maximum Voltage using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Maximum Voltage using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Maximum Voltage using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created RMS Voltage using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created RMS Voltage using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created RMS Voltage using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Load Current (2 Phase 4 Wire US)
Go
Created Load Current using Area of X-Section (2 Phase 4 Wire US)
Go
Created Load Current using Line Losses (2 Phase 4 Wire US)
Go
Created Load Current using Volume of Conductor Material (2 Phase 4 Wire US)
Go
Created Maximum Voltage using Area of X-Section (2 Phase 4 Wire US)
Go
Created Maximum Voltage using Line Losses (2 Phase 4 Wire US)
Go
Created Maximum Voltage using Load Current (2 Phase 4 Wire US)
Go
Created RMS Voltage using Area of X-Section (2 Phase 4 Wire US)
Go
Created RMS Voltage using Line Losses (2 Phase 4 Wire US)
Go
Created RMS Voltage using Load Current (2 Phase 4 Wire US)
Go
Created Load Current (2-Wire Mid-Point DC US)
Go
Created Maximum Voltage using Area of X-Section (2-Wire Mid-Point Earthed DC US)
Go
Created Maximum Voltage using Load Current (2-Wire Mid-Point DC US)
Go
Created Maximum Voltage using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created RMS Voltage using Area of X-Section (2-Wire Mid-Point Earthed DC US)
Go
Created Load Current using Line Losses (DC Two-Wire US)
Go
Created Maximum Voltage using Area of X-Section (DC Two-Wire US)
Go
Created Maximum Voltage using Line Losses (DC Two-Wire US)
Go
Verified Input Resistance with Feedback Current Amplifier
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Verified Output Resistance with Feedback Current Amplifier
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Verified Actual S by N Ratio at Output
Go
Verified Average Duration of Fade
Go
Verified Capability of Error Correction Bits
Go
Verified Coding Noise
Go
Verified Expected Number of Transmission
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Verified Expected One Transmission(E1)
Go
Verified Header Bits
Go
Verified Information Bits
Go
Verified Input Waveform
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Verified Number of Bits Per Word
Go
Verified Success Probability
Go
Verified Undetected Error Probability per Single-Word Message
Go
Verified Undetected Probability per Word
Go
Verified Unsuccess Probability
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Verified Word Error Rate
Go
Created Voltage in DC Circuit
Go
16 More DC Circuits Calculators
Go
Verified Line Voltage
Go
Verified Voltage Division Ratio
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4 More DC Circuits Calculators
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Created Armature Current of DC Generator given Power
Go
Created Armature Power in DC Generator
Go
Created Armature Resistance of DC Generator using Output Voltage
Go
Created Back EMF of DC Generator given Flux
Go
Created Converted Power in DC Generator
Go
Created Core Losses of DC Generator given Converted Power
Go
Created EMF for DC Generator for Wave Winding
Go
Created Field Copper Loss in DC Generator
Go
Created Induced Armature Voltage of DC Generator given Converted Power
Go
Created Mechanical Efficiency of DC Generator using Armature Voltage
Go
Created Output Voltage in DC Generator using Converted Power
Go
Created Power Drop in Brush DC Generator
Go
Created Stray Losses of DC Generator given Converted Power
Go
4 More DC Generator Characteristics Calculators
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Created Angular Speed of DC Machine using Kf
Go
Created Armature Induced Voltage of DC Machine given Kf
Go
Created Back EMF of DC Generator
Go
Created Back Pitch for DC Machine
Go
Verified Back Pitch for DC Machine given Coil Span
Go
Verified Coil Span of DC Motor
Go
Created Design Constant of DC Machine
Go
Created Electrical Efficiency of DC Machine
Go
Created EMF Generated in DC Machine with Lap Winding
Go
Created Front Pitch for DC Machine
Go
Created Input Power of DC Motor
Go
Created Magnetic Flux of DC Machine given Torque
Go
Created Output Power of DC Machine
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3 More DC Machine Characterstics Calculators
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Created Angular Speed given Electrical Efficiency of DC Motor
Go
Created Armature Current given Electrical Efficiency of DC Motor
Go
Created Armature Current of DC Motor
Go
Created Armature Torque given Electrical Efficiency of DC Motor
Go
Created Armature Torque given Mechanical Efficiency of DC Motor
Go
Created Constant Losses given Mechanical Loss
Go
Created Converted Power given Electrical Efficiency of DC Motor
Go
Created Core Loss given Mechanical Loss of DC Motor
Go
Created DC Motor Frequency given Speed
Go
Created Electrical Efficiency of DC Motor
Go
Created Input Power given Electrical Efficiency of DC Motor
Go
Created Magnetic Flux of DC Motor
Go
Created Mechanical Efficiency of DC Motor
Go
Created Mechanical Power Developed in DC Motor given Input Power
Go
Created Motor Speed of DC Motor given Flux
Go
Created Motor Torque given Mechanical Efficiency of DC Motor
Go
Created Motor Torque of Series DC Motor given Machine Constant
Go
Created Output Power given Overall Efficiency of DC Motor
Go
Created Overall Efficiency of DC Motor
Go
Created Overall Efficiency of DC Motor given Input Power
Go
Created Supply Voltage given Electrical Efficiency of DC Motor
Go
Created Supply Voltage given Overall Efficiency of DC Motor
Go
Created Total Power Loss given Overall Efficiency of DC Motor
Go
3 More DC Motor Characteristics Calculators
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Verified Input Offset Voltage of BJT Differential Amplifier
Go
3 More DC Offset Calculators
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Verified De Brogile Wavelength
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15 More De Broglie Hypothesis Calculators
Go
Verified Mass of Gas using Vapor Density
Go
Verified Specific Gravity
Go
Verified Vapour Density of Gas using Mass
Go
14 More Density for Gases Calculators
Go
Verified Angle of Twist of Hollow Shaft on Basis of Torsional Rigidity
Go
Verified Axial Tensile Force given Tensile Stress in Hollow Shaft
Go
Verified Inner Diameter of Hollow Shaft given Ratio of Diameters
Go
Verified Length of Shaft given Angle of Twist of Hollow Shaft on Basis of Torsional Rigidity
Go
Verified Modulus of Rigidity given Angle of Twist of Hollow Shaft on basis of Torsional Rigidity
Go
Verified Outer Diameter given Ratio of Diameters
Go
Verified Outer Diameter of Hollow Shaft given Angle of Twist Torsional Rigidity
Go
Verified Outer Diameter of Hollow Shaft given Principle Stress
Go
Verified Outer Diameter of Shaft given Torsional Shear Stress
Go
Verified Principle Stress Maximum Principle Stress Theory
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Verified Ratio of Diameter given Torsional Shear Stress in Hollow Shaft
Go
Verified Ratio of Diameters given Angle of Twist of Hollow Shaft and Torsional Rigidity
Go
Verified Ratio of Diameters given Bending Stress of Hollow Shaft
Go
Verified Ratio of Diameters given Principle Stress
Go
Verified Ratio of Diameters given Tensile Stress in Hollow Shaft
Go
Verified Ratio of Inner Diameter to Outer Diameter
Go
Verified Torsional Moment given Angle of Twist on Basis of Torsional Rigidity
Go
Verified Torsional Moment given Torsional Shear Stress in Hollow Shaft
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6 More Design of Hollow Shaft Calculators
Go
Verified Compressive Stress in Kennedy Key
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Verified Diameter of Shaft given Compressive Stress in Kennedy Key
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Verified Diameter of Shaft given Shear Stress in Kennedy Key
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Verified Length of Kennedy Key given Compressive Stress in Key
Go
Verified Length of Kennedy Key given Shear Stress in Key
Go
Verified Shear Stress in Kennedy Key
Go
Verified Torque Transmitted by Kennedy Key given Compressive Stress in Key
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Verified Torque Transmitted by Kennedy Key given Shear Stress in Key
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Verified Width of Key given Compressive Stress in Key
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Verified Core Diameter of Power Screw
Go
Verified Helix Angle of Thread
Go
Verified Mean Diameter of Power Screw
Go
Verified Nominal Diameter of Power Screw
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Verified Pitch of Power Screw
Go
Verified Pitch of Screw given Mean Diameter
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27 More Design of Screw and Nut Calculators
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Verified Polar Moment of Inertia of Solid Circular Shaft
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Verified Major Diameter of Spline given Mean Radius
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Verified Mean Radius of Splines
Go
Verified Mean Radius of Splines given Torque Transmitting Capacity
Go
Verified Minor Diameter of Spline given Mean Radius
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Verified Permissible Pressure on Splines given Torque Transmitting Capacity
Go
Verified Torque Transmitting Capacity of Splines
Go
Verified Torque Transmitting Capacity of Splines given Diameter of Splines
Go
Verified Total Area of Splines
Go
Verified Total Area of Splines given Torque Transmitting Capacity
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Verified Compressive Stress in Key
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Verified Compressive Stress in Square Key due to Transmitted Torque
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Verified Force on Key
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Verified Height of Key given Compressive Stress in Key
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Verified Length of Key given Compressive Stress in Key
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Verified Length of Key given Shear Stress
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Verified Shaft Diameter given Compressive Stress in Key
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Verified Shaft Diameter given Force on Key
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Verified Shear Stress in given Force on Key
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Verified Shear Stress in Key given Torque Transmitted
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Verified Torque Transmitted by Keyed Shaft given Force on Keys
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Verified Torque Transmitted by Keyed Shaft given Stress in Key
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Verified Width of Key given Shear Stress in Key
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1 More Design of Square and Flat Keys Calculators
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Verified Factor of Safety for Bi-Axial State of Stress
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Verified Factor of Safety for Tri-axial State of Stress
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8 More Design Parameters Calculators
Go
Verified Apex Angle
Go
Verified Current Due to Optically Generated Carrier
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Verified Diffusion Length of Transition Region
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11 More Devices with Optical Components Calculators
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Verified Input Offset Voltage of MOS Differential Amplifier given Saturation Current
Go
Verified Input Voltage of MOS Differential Amplifier on Small-Signal Operation
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Verified Maximum Input Common-Mode Range of MOS Differential Amplifier
Go
Verified Minimum Input Common-Mode Range of MOS Differential Amplifier
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Verified Total Input Offset Voltage of MOS Differential Amplifier given Saturation Current
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Verified Transconductance of MOS Differential Amplifier on Small-Signal Operation
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3 More Differential Configuration Calculators
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Verified Average Switching Time per Stage
Go
Verified Equipment Utilization Factor
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Verified Instantaneous Resistance of Microphone
Go
Verified Maximum Variation Resistance by Carbon Granules
Go
Verified Number of SE in Equivalent Multistage
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Verified Number of SE in Single Switch
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Verified Number of SE when SC Fully Utilised
Go
Verified Number of Switching Elements
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Verified Number of Switching Stage
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Verified Power Ratio
Go
Verified Quiescent Resistance of Microphone
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Verified Sinusoidal Input
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Verified Switching Element Advantage Factor
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Verified Theoretical Maximum Load
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Verified Total Number of SE in System
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Verified Cut-off Frequency of Varactor Diode
Go
Verified Diode Equation for Germanium at Room Temperature
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Verified Ideal Diode Equation
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Verified Maximum Wavelight
Go
Verified Non-Ideal Diode Equation
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Verified Quality Factor of Varactor Diode
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Verified Self-Resonance Frequency of Varactor Diode
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Verified Thermal Voltage of Diode Equation
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8 More Diode Characteristics Calculators
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Verified Inductor Value for Buck Regulator (DCM)
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Verified Output Current for Buck Regulator (DCM)
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Verified Output Voltage for Buck Regulator (DCM)
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Verified Commutation Period for Boost Regulator (DCM)
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Verified Duty Cycle for Boost Regulator (DCM)
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Verified Inductor Value for Boost Regulator (DCM)
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Verified Output Current for Boost Regulator (DCM)
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Verified Output Voltage for Boost Regulator (DCM)
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Verified Inductor Value for Buck-Boost Regulator (DCM)
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Verified Output Current for Buck-Boost Regulator (DCM)
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Verified Output Voltage for Buck-Boost Regulator (DCM)
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Verified Actuating Force
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Verified Actuating Force given Torque Capacity of Disk Brake
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Verified Angular Dimension of Pad given Area of Brake Pad
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Verified Area of Brake Pad
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Verified Area of Pad given Actuating Force
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Verified Average Pressure given Actuating Force
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Verified Coefficient of Friction given Torque Capacity of Disk Brake
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Verified Friction Radius given Torque Capacity of Disk Brake
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Verified Friction Radius of Disk Brake
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Verified Inner Radius of Brake Pad given Area of Brake Pad
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Verified Outer Radius of Brake Pad given Area of Brake Pad
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Verified Torque Capacity of Disk Brake
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Verified Shear Yield Strength by Maximum Distortion Energy Theory
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12 More Distortion Energy Theory Calculators
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Verified Axial Thrust Load on Bearing given Equivalent Dynamic Load
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Verified Equivalent Dynamic Load for Back to Back Bearings when subjected to Pure Radial Load
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Verified Equivalent Dynamic Load for Back to Back Bearings when subjected to Pure Thrust Load
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Verified Race Rotation Factor for Bearing given Radial Factor
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Verified Radial Factor of Bearing given Equivalent Dynamic Load
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Verified Radial Load of Bearing given Radial Factor
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Verified Thrust Factor on Bearing given Equivalent Dynamic Load
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8 More Dynamic and Equivalent Load Calculators
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Verified Couple on Weld given Torsional Shear Stress in Throat Area of Weld
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Verified Distance of point in Weld from Center of Gravity given Torsional Shear Stress
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Verified Length of Weld given Polar Moment of Inertia of Weld about its Center of Gravity
Go
Verified Load acting on Weld given Primary Stress
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Verified Polar Moment of Inertia of Weld about Center of Gravity
Go
Verified Polar Moment of Inertia of Weld about Center of Gravity given Torsional Shear Stress
Go
Verified Primary Shear Stress in Weld
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Verified Throat Area of Weld given Polar Moment of Inertia of Weld about Center
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Verified Throat Area of Weld given Primary Shear Stress
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Verified Torsional Shear Stress in Throat Area of Weld
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Verified Energy Density in Electric Field given Free Space Permittivity
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4 More Electric Potential and Energy Density Calculators
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Verified Concentration of Hydronium ion using pH
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Verified Concentration of Hydronium Ion using pOH
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Verified Ionic Product of Water
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Verified pH of Salt of Weak Acid and Strong Base
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Verified pH of Salt of Weak Base and Strong Base
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Verified pH Value of Ionic Product of Water
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Verified pOH of Salt of Weak Base and Strong Base
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Verified pOH of Strong acid and Strong base
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Verified Relation between pH and pOH
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16 More Electrolytes and Ions Calculators
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Verified AC Conductance
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Verified Difference in Electron Concentration
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Verified Electron Component
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Verified Electron Current Density
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Verified Electron Flux Density
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Verified Electron in Region
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Verified Electron Multiplication
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Verified Electron Out of Region
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Verified Hole Component
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Verified Hole Current Density
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Verified Mean Free Path
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Verified Mean Time Spend by Hole
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Verified Phi-dependent Wave Function
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Verified Quantum State
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Verified Radius of Nth Orbit of Electron
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Verified Total Carrier Current Density
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Verified Wave Function Amplitude
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1 More Electrons and Holes Calculators
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Verified Change in Wave Number of Moving Particle
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Verified Change in Wavelength of Moving Particle
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Verified Total Energy of Electron
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13 More Electrons and Orbits Calculators
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Verified Angular Speed of Particle in Magnetic Field
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13 More Electrostatic Parameters Calculators
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Verified Emitter Current given Base Current
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Verified Emitter Current given Collector Current
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Verified Emitter Current given Saturation Current
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Verified Emitter Current of BJT
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Verified Emitter Current through Minority Carrier Concentration
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Verified Emitter Current using Collector Current and Current Gain
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Verified Emitter Current using Common Emitter Current Gain
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Verified Emitter Current using Transistor Constant
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1 More Emitter Current Calculators
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Verified Base Resistance across Emitter follower Junction
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Verified Collector Current of Emitter Follower Transistor
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Verified Input Resistance of Emitter Follower
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Verified Input Resistance of Transistor Amplifier
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Verified Input Voltage of Emitter Follower
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Verified Output Resistance of Emitter Follower
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Verified Output Resistance of Transistor at Intrinsic Gain
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Verified Saturation Current of Emitter Follower
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Verified Total Emitter Resistance of Emitter Follower
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1 More Emitter Follower Calculators
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Created Admittance using A Parameter in End Condenser Method
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Created Capacitive Current in End Condenser Method
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Created Impedance using A Parameter in End Condenser Method
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Created Impedance(ECM)
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Created Line Losses in End Condenser Method
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Created Medium Line A Parameter (LEC)
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Created Receiving End Angle using Sending End Power in End Condenser Method
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Created Receiving End Current in End Condenser Method
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Created Receiving End Voltage in End Condenser Method
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Created Resistance using Losses in End Condenser Method
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Created Sending End Current in End Condenser Method
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Created Sending End Current using Impedance in End Condenser Method
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Created Sending End Current using Losses in End Condenser Method
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Created Sending End Power in End Condenser Method
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Created Sending End Voltage in End Condenser Method
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Created Transmission Efficiency in End Condenser Method
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Created Voltage Regulation in End Condenser Method
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Verified Brake Drum Rotational Angle given Work Done by Brake
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Verified Braking Torque given Work Done by Brake
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Verified Final Angular Velocity of Body given Kinetic Energy of Rotating Body
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Verified Final Velocity given Kinetic Energy Absorbed by Brakes
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Verified Initial Angular Velocity of Body given Kinetic Energy of Rotating Body
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Verified Initial Velocity of System given Kinetic Energy Absorbed by Brakes
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Verified Kinetic Energy Absorbed by Brake
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Verified Kinetic energy of Rotating Body
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Verified Mass of Brake Drum Assembly given Temperature Rise of Brake Drum Assembly
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Verified Mass of System given Kinetic Energy Absorbed by Brakes
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Verified Mass of System given Kinetic Energy of Rotating Body
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Verified Mass of System given Potential Energy Absorbed during Braking Period
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Verified Moment of Inertia of System given Kinetic Energy of Rotating Body
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Verified Potential Energy Absorbed during Braking Period
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Verified Radius of Gyration given Kinetic Energy of Rotating Body
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Verified Specific Heat of Brake Drum Material given Temperature Rise of Brake Drum Assembly
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Verified Temperature Rise of Brake Drum Assembly
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Verified Total Energy Absorbed by Brake
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Verified Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly
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Verified Carrier Lifetime
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Verified Concentration in Conduction Band
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Verified Concentration of Holes in Valence Band
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Verified Conduction Band Energy
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Verified Distribution Coefficient
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Verified Effective Density of State
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Verified Effective Density State in Valence Band
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Verified Energy Gap
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Verified Excess Carrier Concentration
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Verified Fermi Function
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Verified Intrinsic Carrier Concentration
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Verified Liquid Concentration
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Verified Net Rate of Change in Conduction Band
Go
Verified Optical Generation Rate
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Verified Photoelectron Energy
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Verified Recombination Lifetime
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Verified Steady State Electron Concentration
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Verified Valence Band Energy
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2 More Energy Band and Charge Carrier Calculators
Go
Verified Average Load of Meter
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Verified Average Monthly Load Factor
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Verified Energy Recorded
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Verified Maximum Demand
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Verified Number of Revolution made
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Verified Revolution in KWh
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Verified Entropy using Helmholtz Free Energy
Go
Verified Internal Energy using Helmholtz Free Energy
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Verified Temperature using Helmholtz Free Energy
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13 More Entropy Generation Calculators
Go
Verified Relative Atomic Mass
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14 More Equivalent Weight Calculators
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Errors (2)
Verified Residual Standard Error of Data given Degrees of Freedom
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Verified Standard Error of Data given Variance
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5 More Errors Calculators
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Verified Bending Stress in extra full length leaves
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Verified Bending Stress in Plate Extra Full Length
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Verified Bending Stress in Plate Graduated Length Leaves
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Verified Deflection at Load Point Graduated Length Leaves
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Verified Deflection of leaf Spring at load point
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Verified Force applied at end of Spring given Bending Stress in extra full length leaves
Go
Verified Force applied at end of Spring given Deflection at end of Spring
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Verified Force applied at end of Spring given Force taken by extra full length leaves
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Verified Length of Cantilever given Bending Stress in extra full length leaves
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Verified Length of Cantilever given Deflection at end of Spring
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Verified Length of Cantilever given Deflection of Spring at load point
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Verified Modulus of Elasticity of leaf given Deflection at Load Point Graduated Length Leaves
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Verified Modulus of Elasticity of leaf of leaf spring given Deflection of Spring at load point
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Verified Modulus of Elasticity of Spring given Deflection at end of Spring
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Verified Number of extra full length leaves given Bending Stress in extra full length leaves
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Verified Number of extra full length leaves given Deflection at end of Spring
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Verified Number of extra full length leaves given Deflection of Spring at load point
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Verified Number of Graduated length leaves given Bending Stress in extra full length leaves
Go
Verified Number of Graduated length leaves given Deflection at End of Spring
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Verified Number of Graduated length leaves given Force taken by extra full length leaves
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Verified Portion of Force taken by extra full length leaf given deflection of Spring at load point
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Verified Thickness of each leaf given Bending Stress in extra full length leaves
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Verified Thickness of each leaf given Deflection at end of Spring
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Verified Width of each leaf given Bending Stress in extra full length leaves
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Verified Width of each leaf of leaf Spring given Deflection of Spring at load point
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Verified Width of Leaf given Deflection at end of Spring
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3 More Extra Full Length Leaves Calculators
Go
Verified Molar Mass of Gas given Average Speed of Gas
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Verified Molar Mass of Gas given Most Probable Speed of Gas
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Verified Molar Mass of Gas given RMS Velocity of Gas
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10 More Factors of Thermodynamics Calculators
Go
Verified Graded Index Length of Fiber
Go
Verified Group Delay
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Verified Normalized Frequency
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Verified Numerical Aperture
Go
Verified Optical Pulse Duration
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Verified Plane Wave Velocity
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Verified Ray Optics Critical Angle
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Verified Refractive Index of Cladding
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Verified Refractive Index of Fiber Core
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3 More Fiber Design Characteristics Calculators
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Verified Diameter of Fiber
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Verified Fiber Attenuation Coefficient
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Verified Fiber Length
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Verified Gaussian Pulse
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Verified Number of Modes using Normalized Frequency
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Verified Optical Dispersion
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Verified Power Loss in Fiber
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12 More Fiber Modelling Parameters Calculators
Go
Verified Absolute Viscosity
Go
Verified Average Velocity of Fluid
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Verified Density of Liquid
Go
Verified Drag Coefficient of Pipe
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Verified Flow Rate
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Verified Head Loss
Go
Verified Head Loss Due to Fitting
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Verified Length of Pipe
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Verified Length of weighing platform
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Verified Loss Coefficient for Various Fitting
Go
Verified Mass Flow Rate
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Verified Pipe Diameter
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Verified Reynolds number of fluid flowing in Pipe
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Verified Speed of Conveyor Belt
Go
Verified Volume Flow Rate
Go
Verified Weight of Material on Length of Weighing Platform
Go
Verified Rate of Flow given Head loss in Laminar Flow
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Verified Rate of Flow given Hydraulic Transmission Power
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6 More Flow Rate Calculators
Go
Flux (2)
Created Magnetic Flux of DC Shunt Motor given Kf
Go
Created Magnetic Flux of DC Shunt Motor given Torque
Go
Created Frequency given Number of Poles in Induction Motor
Go
2 More Frequency Calculators
Go
Created Cut Off Frequency for RC circuit
Go
Created Frequency using Time Period
Go
1 More Frequency Calculators
Go
Created Frequency given EMF Induced in Primary Winding
Go
Created Frequency given EMF Induced in Secondary Winding
Go
Verified Absolute Frequency
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Verified Relative Frequency
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Verified Total Frequency
Go
Verified Coherence Bandwidth for Random Phases of Two Received Signals
Go
Verified Coherence Bandwidth for Two Fading Amplitudes of Two Received Signals
Go
Verified Delay Spread
Go
Verified Forward Frame
Go
Verified M-Ary PAM
Go
Verified M-Ary QAM
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Verified Reverse Frame
Go
Verified Symbol Time Period
Go
Verified Time Slots
Go
7 More Frequency Reuse Concept Calculators
Go
Verified Depth of Permanent Magnet
Go
Verified Maximum Resistance Deviation in Ohmmeter
Go
Verified Multiplier Resistance in Ohmmeter
Go
Verified Percent Linearity in Ohmmeter
Go
Verified Resistance of Meter
Go
Verified Resistance of Path of Eddy Current
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Verified Resistivity of Material Disc
Go
Verified Thickness of Metal Disc
Go
Verified Volume Resistance of Insulation
Go
Verified Closed Loop Negative Feedback Gain
Go
Verified Gain-Bandwidth Product
Go
17 More Fundamental Parameters Calculators
Go
Verified Horizontal Frequency
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Verified One Horizontal Line
Go
Verified One Horizontal Line Scan
Go
Verified One Horizontal Line Tracing
Go
Verified One Horizontal Time
Go
Verified Video Bandwidth
Go
Verified Video Bandwidth Signal
Go
Created Current-1 (G-Parameter)
Go
Created Current-1 given G11 Parameter (G-Parameter)
Go
Created Current-2 given Voltage-2 (G-Parameter)
Go
Created Delta-G given A' Parameter
Go
Created G11 Parameter (G-Parameter)
Go
Created G11 Parameter given Current-1 (G-Parameter)
Go
Created G11 Parameter in Terms of T Parameters
Go
Created G11 Parameter in Terms of Y Parameters
Go
Created G12 Parameter (G-Parameter)
Go
Created G12 Parameter given Current-1 (G-Parameter)
Go
Created G21 Parameter (G-Parameter)
Go
Created G21 Parameter in Terms of T Parameters
Go
Created G21 Parameter in Terms of Y Parameters
Go
Created G21 Parameter in Terms of Z Parameters
Go
Created G22 Parameter in Terms of Y Parameters
Go
Created G22 Parameter in Terms of Z Parameters
Go
Gain (1)
Verified Common-Mode Current Gain of Controlled Source Transistor
Go
1 More Gain Calculators
Go
Verified Area of Secondary Coil
Go
Verified Ballistic Sensitivity
Go
Verified Ballistic Sensitivity using Flux Linkage Sensitivity
Go
Verified Charge passing through Galvanometer
Go
Verified Constant of Galvanometer
Go
Verified Length of Solenoid
Go
Verified Throw of Galvanometer
Go
10 More Galvanometer Calculators
Go
Verified Average Chain Velocity given Number of Teeth on Sprocket
Go
Verified Average Velocity of Chain
Go
Verified Chain Pitch given Minimum Tooth Height above Pitch Polygon
Go
Verified Length of Chain
Go
Verified Number of Links in Chain
Go
Verified Number of Links in Chain given Length of Chain
Go
Verified Number of Teeth on Driven Sprocket given Velocity of Chain Drives
Go
Verified Number of Teeth on Driving and Driven Sprockets given Average Chain Velocity
Go
Verified Number of Teeth on Driving Sprocket given Velocity of Chain Drives
Go
Verified Number of Teeth on Sprocket given Pitch Circle Diameter
Go
Verified Pitch of chain given Average Chain Velocity
Go
Verified Pitch of chain given Length of Chain
Go
Verified Pitch of chain given Pitch Circle Diameter
Go
Verified Roller Radius given Maximum Tooth Height above Pitch Polygon
Go
Verified Roller Radius given Minimum Roller Seating Radius
Go
Verified Roller Radius given Minimum Tooth Flank Radius
Go
Verified Roller Radius given Minimum Tooth Height above Pitch Polygon
Go
Verified Roller Radius given Tooth Flank Radius
Go
Verified Roller Radius given Top Diameter of Sprocket Wheel
Go
Verified Speed of Rotation of Driven Shaft given Velocity Ratio of Chain Drives
Go
Verified Speed of Rotation of Driving Shaft given Velocity Ratio of Chain Drives
Go
Verified Speed of Rotations of Driving and Driven Shafts given Average Chain Velocity
Go
Verified Velocity Ratio of Chain Drives
Go
Verified Acute Value
Go
Verified Angle of Elevation
Go
Verified Angle of Tilt
Go
Verified Azimuth Angle
Go
Verified Earth Station Latitude
Go
Verified Geostationary Height
Go
Verified Geostationary Radius
Go
Verified Satellite Geostationary Radius
Go
Verified Time of Perigee Passage
Go
5 More Geostationary Orbit Calculators
Go
Created Current-1 given Current-2 (H-Parameter)
Go
Created Current-1 given H11 Parameter (H-Parameter)
Go
Created Current-1 given H21 Parameter (H-Parameter)
Go
Created Current-1 given Voltage-1 (H-Parameter)
Go
Created Current-2 (H-Parameter)
Go
Created Current-2 given H21 Parameter (H-Parameter)
Go
Created Current-2 given H22 Parameter (H-Parameter)
Go
Created H11 Parameter (H-Parameter)
Go
Created H11 Parameter in Terms of T' Parameters
Go
Created H11 Parameter in Terms of Y Parameters
Go
Created H11 Parameter in Terms of Z Parameters
Go
Created H12 Parameter (H-Parameter)
Go
Created H12 Parameter given Voltage-1 (H-Parameter)
Go
Created H12 Parameter in Terms of G Parameters
Go
Created H12 Parameter in Terms of Z Parameters
Go
Created H21 Parameter (H-Parameter)
Go
Created H21 Parameter in Terms of G Parameters
Go
Created H21 Parameter in Terms of Y Parameters
Go
Created H21 Parameter in Terms of Z Parameters
Go
Created H22 Parameter (H-Parameter)
Go
Created H22 Parameter given Current-2 (H-Parameter)
Go
Created H22 Parameter in Terms of Y Parameters
Go
Created H22 Parameter in Terms of Z Parameters
Go
Created Voltage-1 given H11 Parameter (H-Parameter)
Go
Created Voltage-1 given H12 Parameter (H-Parameter)
Go
Created Voltage-2 given H22 Parameter (H-Parameter)
Go
Verified Bending Moment applied on Spring given Bending Stress
Go
Verified Bending Stress in Spring
Go
Verified Diameter of Spring Wire given Bending Stress in Spring
Go
Verified Diameter of Spring Wire given Stiffness
Go
Verified Mean Coil Diameter of Spring given Stiffness
Go
Verified Modulus of Elasticity of Spring given Stiffness
Go
Verified Number of Coils of Spring given Stiffness of Helical Torsion Spring
Go
Verified Stiffness of Helical Torsion Spring
Go
Verified Stress Concentration Factor given Bending Stress in Spring
Go
Verified Axial Pitch of Helical Gear given Helix Angle
Go
Verified Helix Angle of Helical Gear given Actual and Virtual Number of Teeth
Go
Verified Helix Angle of Helical Gear given Addendum Circle Diameter
Go
Verified Helix Angle of Helical Gear given Axial Pitch
Go
Verified Helix Angle of Helical Gear given Center to Center Distance between Two Gears
Go
Verified Helix Angle of Helical Gear given Normal Circular Pitch
Go
Verified Helix Angle of Helical Gear given Normal Module
Go
Verified Helix Angle of Helical Gear given Pitch Circle Diameter
Go
Verified Helix Angle of Helical Gear given Pressure Angle
Go
Verified Helix Angle of Helical Gear given Radius of Curvature at Point
Go
Verified Helix Angle of Helical Gear given Virtual Number of Teeth
Go
Verified Normal Circular Pitch of Helical Gear
Go
Verified Normal Circular Pitch of Helical Gear given Virtual Number of Teeth
Go
Verified Normal Pressure Angle of Helical Gear given Helix Angle
Go
Verified Pitch Circular Diameter of Gear given Radius of Curvature
Go
Verified Pitch Circular Diameter of Gear given Virtual Gear
Go
Verified Pitch Circular Diameter of Gear given Virtual Number of Teeth
Go
Verified Pitch of Helical Gear given Axial Pitch
Go
Verified Pitch of Helical Gear given Normal Circular Pitch
Go
Verified Radius of Curvature at Point on Helical Gear
Go
Verified Radius of Curvature at Point on Virtual Gear
Go
Verified Radius of Curvature of Virtual Gear given Pitch Circular Diameter
Go
Verified Radius of Curvature of Virtual Gear given Virtual Number of Teeth
Go
Verified Semi Major Axis of Elliptical Profile given Radius of Curvature at Point
Go
Verified Semi Minor Axis of Elliptical Profile given Radius of Curvature at Point
Go
Verified Transverse Diametrical Pitch of Helical Gear given Transverse Module
Go
Verified Transverse Pressure Angle of Helical Gear given Helix Angle
Go
Verified DC Voltage
Go
Verified Gate Length
Go
Verified Insertion Loss
Go
Verified Mismatched Loss
Go
Verified Phase Velocity
Go
Verified Pitch Angle
Go
Verified Power Standing Wave Ratio
Go
Verified Ratio of Voltage Wave
Go
Verified Reflection Coefficient
Go
Verified Round Trip DC Transit Time
Go
Verified Saturation Drift Voltage
Go
Verified Voltage Standing Wave Ratio
Go
1 More Helix Tube Calculators
Go
Verified Actual Humidity
Go
Verified Humidity ratio
Go
Verified Mass of Dry Air or Gas in Mixture
Go
Verified Mass of Water Vapor in Mixture
Go
Verified Saturated Humidity
Go
Verified Metacentric Height given Time Period of Rolling
Go
Verified Reynolds Number given Frictional Factor of Laminar Flow
Go
7 More Hydrodynamics Basics Calculators
Go
Verified Number of Spectral Lines
Go
20 More Hydrogen Spectrum Calculators
Go
Verified Acid Ionization Constant of Weak Acid
Go
Verified Basic Ionization Constant of Weak Base
Go
Verified Concentration of Hydronium ion in Salt of Weak Acid and Weak Base
Go
Verified Degree of Hydrolysis in Salt of Weak Acid and Weak Base
Go
Verified Hydrolysis Constant in Weak Acid and Weak Base
Go
Verified pH of Salt of Weak Acid and Weak base
Go
Verified pOH of Salt of Weak Acid and Weak Base
Go
6 More Hydrolysis for Weak Acid and Weak Base Calculators
Go
Verified Distance between Buoyancy Point and Center of Gravity given Metacenter Height
Go
Verified Moment of Inertia of Waterline Area using Metacentric Height
Go
Verified Radius of Gyration given Time Period of Rolling
Go
Verified Surface Area given Surface Tension
Go
Verified Surface Energy given Surface Tension
Go
Verified Volume of Liquid Displaced given Metacentric Height
Go
Verified Volume of Submerged Object given Buoyancy Force
Go
13 More Hydrostatic Fluid Calculators
Go
Verified Emitter Resistance in Widlar Current Source
Go
Verified Output Resistance of Wilson MOS Mirror
Go
Verified Reference Current of IC Amplifier
Go
Verified Reference Current of Wilson Current Mirror
Go
6 More IC Amplifiers Calculators
Go
Verified Degree of Freedom given Molar Internal Energy of Ideal Gas
Go
Verified Isothermal Compression of Ideal Gas
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Verified Number of Moles given Internal Energy of Ideal Gas
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Verified Temperature of Ideal Gas given its Internal Energy
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4 More Ideal Gas Calculators
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Created Impedance given Complex Power and Current
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Created Impedance given Complex Power and Voltage
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Created Impedance using Power Factor
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Created Resistance for Parallel RLC Circuit using Q Factor
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Created Resistance for Series RLC Circuit given Q Factor
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Created Resistance using Power Factor
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Created Resistance using Time Constant
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Created Reactance given Slip at Maximum Torque
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Created Resistance given Slip at Maximum Torque
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2 More Impedance Calculators
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Verified Impedance for LCR Circuit
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Verified Impedance for LR Circuit
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Verified Impedance for RC Circuit
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1 More Impedance Calculators
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Created Equivalent Impedance of Transformer from Primary Side
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Created Equivalent Impedance of Transformer from Secondary Side
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Created Impedance of Primary Winding
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Created Impedance of Primary Winding given Primary Parameters
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Created Impedance of Secondary Winding
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Created Impedance of Secondary Winding given Secondary Parameters
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Created Armature Resistance of Synchronous Motor given 3 Phase Mechanical Power
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Created Armature Resistance of Synchronous Motor given Input Power
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Created Fault Impedance using A-Phase Voltage(LGF)
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Created Negative Sequence Impedance for L-G-F
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Created Negative Sequence Impedance using A-Phase EMF (LGF)
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Created Positive Sequence Impedance for L-G-F
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Created Positive Sequence Impedance using A-Phase EMF (LGF)
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Created Zero Sequence Impedance for L-G-F
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Created Zero Sequence Impedance using A-Phase EMF (LGF)
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3 More Impedance Calculators
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Created Fault Impedance using Positive Sequence Current (LLF)
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3 More Impedance Calculators
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Created Fault Impedance using B-Phase Voltage (LLGF)
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Created Fault Impedance using C-Phase Voltage (LLGF)
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4 More Impedance Calculators
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Created Impedance-1 for Transmitted Coefficient of Current-2 (Line PL)
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Created Impedance-1 for Transmitted Coefficient of Current-3 (Line PL)
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Created Impedance-1 using Incident Current and Voltage (Line PL)
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Created Impedance-1 using Reflected Coefficient of Current (Line PL)
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Created Impedance-1 using Transmitted Coefficient of Current-2 (Line PL)
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Created Impedance-1 using Transmitted Coefficient of Current-3 (Line PL)
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Created Impedance-1 using Transmitted Voltage (Line PL)
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Created Impedance-2 for Transmitted Coefficient of Current-2 (Line PL)
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Created Impedance-2 using Reflected Coefficient of Current (Line PL)
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Created Impedance-2 using Reflected Coefficient of Voltage (Line PL)
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Created Impedance-2 using Transmitted Coefficient of Current-2 (Line PL)
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Created Impedance-2 using Transmitted Coefficient of Voltage (Line PL)
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Created Impedance-2 using Transmitted Current-2 (Line PL)
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Created Impedance-2 using Transmitted Voltage (Line PL)
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Created Impedance-3 for Transmitted Coefficient of Current-3 (Line PL)
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Created Impedance-3 using Reflected Coefficient of Current (Line PL)
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Created Impedance-3 using Reflected Coefficient of Voltage (Line PL)
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Created Impedance-3 using Transmitted Coefficient of Current-3 (Line PL)
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Created Impedance-3 using Transmitted Coefficient of Voltage (Line PL)
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Created Impedance-3 using Transmitted Voltage (Line PL)
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Created Admittance using Characteristic Impedance (LTL)
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Created Admittance using Propagation Constant (LTL)
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Created Capacitance using Surge Impedance (LTL)
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Created Characteristic Impedance (LTL)
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Created Characteristic Impedance using B Parameter (LTL)
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Created Characteristic Impedance using C Parameter (LTL)
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Created Characteristic Impedance using Sending End Current (LTL)
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Created Characteristic Impedance using Sending End Voltage (LTL)
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Created Impedance using Characteristic Impedance (LTL)
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Created Impedance using Propagation Constant (LTL)
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Created Inductance using Surge Impedance (LTL)
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Created Surge Impedance (LTL)
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Created Characteristic Impedance for Incident Waves
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Created Inductance for Parallel RLC Circuit using Q Factor
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Created Inductance for Series RLC Circuit given Q Factor
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Created Inductance using Time Constant
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Verified Angular Deflection of Spring
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Verified Angular Speed of Disc
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Verified Angular Speed of Former
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Verified Damping Constant
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Verified Damping Torque
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Verified EMF generated in Former
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Verified EMF induced in portion below magnetic Field
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Verified Flat Spiral Spring Controlling Torque
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Verified Full-Scale Resistance Deviation
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Verified Full-Scale Voltage Reading
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Verified Instrumentation Span
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Verified Inverse Sensitivity or Scale Factor
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Verified Largest Reading(Xmax)
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Verified Linear velocity of Former
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Verified Magnitude of Input
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Verified Magnitude of Output Response
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Verified Maximum Displacement Deviation
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Verified Maximum Fiber Stress in Flat Spring
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Verified Power Consumed at Full-Scale Reading
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Verified Sensitivity
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Verified Smallest reading(Xmin)
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Verified Strength of Magnetic Field
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Verified Youngs Modulus of Flat Spring
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2 More Instrument Characteristics Calculators
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Verified Area of Capillary Tube
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Verified Breadth of Former
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Verified Coefficient of volumetric Expansion
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Verified Length of Capillary Tube
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Verified Length of Former
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Verified Length of Spring
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Verified Sharpness of Curve
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Verified Standard Deviation for Normal Curve
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Verified Thickness of Spring
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Verified Volume of Bulb in Capillary Tube
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Verified Width of Spring
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Verified Absolute Static Error of Quantity
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Verified Average Deviation
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Verified Erroneous Quantity
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Verified Location of Point
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Verified Measured Value of quantity
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Verified Nominal Value
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Verified Percentage Error
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Verified Relative Limiting Error
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Verified Relative Static Error
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Verified True Quantity
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Verified True Value of Quantity
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Verified Flux Linkage Sensitivity
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Verified Primary Phasor
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Verified Secondary Phasor
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Verified Transformer Ratio
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2 More Instrument Transformer Calculators
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Verified Common Mode Rejection Ratio of Difference Amplifiers
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7 More Integrator and Difference Calculators
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Verified Conductance of Channel of MOSFETs
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Verified Magnitude of Electron Charge in Channel of MOSFET
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Verified Total Capacitance between Gate and Channel of MOSFETs
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12 More Internal Capacitive Effects and High Frequency Model Calculators
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Verified Base-Emitter Junction Capacitance
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Verified Collector-Base Junction Capacitance
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Verified Concentration of Electrons Injected from Emitter to Base
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Verified Small-Signal Diffusion Capacitance
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Verified Small-Signal Diffusion Capacitance of BJT
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Verified Stored Electron Charge in Base of BJT
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Verified Thermal Equilibrium Concentration of Minority Charge Carrier
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4 More Internal Capacitive Effects and High Frequency Model Calculators
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Verified Angle of Wrap given Belt Tension in Tight Side
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Verified Belt Tension in Loose Side of Belt given Tension in Tight Side
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Verified Belt Tension in Tight Side
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Verified Center Distance from Small Pulley to Big Pulley given Wrap Angle of Big Pulley
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Verified Center Distance from Small Pulley to Big Pulley given Wrap Angle of Small Pulley
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Verified Coefficient of Friction in between Surfaces given Belt Tension in Tight Side
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Verified Diameter of Big Pulley given Wrap Angle for Big Pulley
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Verified Diameter of Big Pulley given Wrap Angle of Small Pulley
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Verified Diameter of Small Pulley given Wrap Angle of Big Pulley
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Verified Diameter of Small Pulley given Wrap Angle of Small Pulley
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Verified Length of Belt
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Verified Mass per unit length of belt
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Verified Velocity of Belt given Tension of Belt in Tight Side
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Verified Wrap Angle for Big Pulley
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Verified Wrap Angle for Small Pulley
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Verified Factor of Safety given Tensile Force on Bolt in Tension
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Verified Maximum Tensile Stress in Bolt
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Verified Yield Strength of Bolt in Tension given Tensile Force on Bolt in Tension
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5 More Joint Analysis Calculators
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Verified Thickness of Cotter Joint
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26 More Joint Geometry and Dimensions Calculators
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Verified Anode Voltage
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Verified Beam Loading Conductance
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Verified Cavity Conductance
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Verified Copper Loss of Cavity
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Verified DC Power Supply
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Verified DC Transit Time
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Verified Klystron Efficiency
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Verified Mutual Conductance of Klystron Amplifier
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Verified Power Loss in Anode Circuit
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Verified Resonant Frequency of Cavity
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3 More Klystron Calculators
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Verified Average Distance between Cavities
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Verified Buncher Cavity Gap
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Verified Conductance of Resonator
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Verified Induced Current in Catcher Cavity
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Verified Induced Current in Walls of Catcher Cavity
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Verified Number of Resonant Cavities
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Verified Phase Constant of Fundamental Mode Field
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7 More Klystron Cavity Calculators
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Lasers (3)
Verified Plane of Polarizer
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Verified Plane of Transmission of Analyzer
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Verified Single Pinhole
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9 More Lasers Calculators
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Verified Buoyancy
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Verified Buoyancy Force on Cylindrical Displacer
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Verified Capacitance with No Liquid
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Verified Cross-Sectional Area of Object
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Verified Depth of Fluid
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Verified Float diameter
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Verified Height of plates
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Verified Immersed Depth
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Verified Length of displacer submerged in liquid
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Verified Liquid Level
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Verified Magnetic Permeability of Liquid
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Verified Non-Conductive Liquid Capacitance
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Verified Volume of Material in Container
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Verified Weight of Air
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Verified Weight of Body in Liquid
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Verified Weight of Displacer
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Verified Weight of Material in Container
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Verified Weight on Force Sensor
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Verified Area affected by Light Incident
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Verified Area Projected at solid angle
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Verified Flux at Solid Angle
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Verified Illuminance
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Verified Incident Luminous Flux
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Verified Intensity on Solid Angle
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Verified Irradiation
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Verified Light flux
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Verified Light Power
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Verified Luminous Flux incident upon Object
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Verified Luminous Flux Transmitted by Object
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Verified Luminous Intensity in Direction at Angle
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Verified Luminous Intensity in Direction Normal to Surface
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Verified Photoelectric Current
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Verified Photoelectric Sensitivity
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Verified Reflected Luminous Flux
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Verified Reflection Factor
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Verified Transmission Factor
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Created Incident Current using Transmitted Current (Line OC)
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Created Incident Voltage using Reflected Voltage (Line OC)
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Created Transmitted Current (Line OC)
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Created Incident Current using Reflected Current (Line SC)
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Created Incident Voltage using Transmitted Voltage (Line SC)
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Created Reflected Current (Line SC)
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Created Transmitted Voltage (Line SC)
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Created Impedance (STL)
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Created Losses using Transmission Efficiency (STL)
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Created Resistance using Losses (STL)
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Created Transmission Efficiency (STL)
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Created Voltage Regulation in Transmission Line
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Created Line Losses (1-phase 2-wire Mid-point Earthed)
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Created Line Losses (1-Phase 2-Wire US)
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Created Line Losses using Area of X-Section (1-Phase 2-Wire US)
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Created Line Losses using Constant (1-Phase 2-Wire US)
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Created Line Losses using Load Current (1-Phase 2-Wire US)
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Created Line Losses using Resistance (1-Phase 2-Wire US)
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Created Line Losses using Volume of Conductor Material (1-Phase 2-Wire US)
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Created Length using A Parameter (LTL)
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Created Length using B Parameter (LTL)
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Created Length using C Parameter (LTL)
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Created Length using D Parameter (LTL)
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Created Propagation Constant (LTL)
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Created Propagation Constant using A Parameter (LTL)
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Created Propagation Constant using B Parameter (LTL)
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Created Propagation Constant using C Parameter (LTL)
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Created Propagation Constant using D Parameter (LTL)
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Created B-Parameter using Receiving End Reactive Power Component
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Created B-Parameter using Receiving End Real Power Component
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Created Complex Power given Current
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Created Receiving End Real Power Component
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Created Skin Depth in Conductor
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10 More Line Performance Characteristics Calculators
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Created Fault Impedance using A-Phase Current
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Created Fault Impedance using Positive Sequence Current
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Created Negative Sequence Impedance for Delta Connected Load
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Created Positive Sequence Impedance for Delta Connected Load
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Created Sequence Impedance
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Created Zero Sequence Impedance for Delta Connected Load
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Created Zero Sequence Impedance for Star Connected Load
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Created Incident Current using Impedance-1 (Line PL)
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Created Incident Current using Transmitted Coefficient of Current-2 (Line PL)
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Created Incident Current using Transmitted Coefficient of Current-3 (Line PL)
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Created Incident Current using Transmitted Current-3 and 2 (Line PL)
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Created Incident Voltage using Impedance-1 (Line PL)
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Created Incident Voltage using Transmitted Coefficient of Current-3 (Line PL)
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Created Incident Voltage using Transmitted Voltage (Line PL)
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Created Reflected Coefficient of Current (Line PL)
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Created Reflected Current using Impedance-1 (Line PL)
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Created Reflected Current using Transmitted Current-3 and 2 (Line PL)
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Created Reflected Voltage using Impedance-1 (Line PL)
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Created Transmitted Coefficient of Voltage (Line PL)
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Created Transmitted Coefficient of Voltage using Transmitted Coefficient of Current-2 (Line PL)
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Created Transmitted Coefficient of Voltage using Transmitted Coefficient of Current-3 (Line PL)
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Created Transmitted Coefficient of Voltage using Transmitted Voltage (Line PL)
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Created Transmitted Voltage using Incident Voltage (Line PL)
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Created Transmitted Voltage using Transmitted Coefficient of Current-2 (Line PL)
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Created Transmitted Voltage using Transmitted Coefficient of Current-3 (Line PL)
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Created Transmitted Voltage using Transmitted Coefficient of Voltage(Line PL)
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Created Transmitted Voltage using Transmitted Current-2 (Line PL)
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Created Transmitted Voltage using Transmitted Current-3 (Line PL)
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Verified Input Voltage of Shunt Regulator
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Verified Load Current in Shunt Regulator
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Verified Output Voltage of Shunt Regulator
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Verified Shunt Current in Shunt Regulator
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Verified Shunt Resistance in Shunt Regulator
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Verified Angle of Jet given Maximum Vertical Elevation
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Verified Angle of Jet given Time of Flight of Liquid Jet
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Verified Angle of Jet given Time to Reach Highest Point
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Verified Initial Velocity given Time of Flight of Liquid Jet
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Verified Initial Velocity given Time to Reach Highest Point of Liquid
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Verified Initial Velocity of Liquid Jet given Maximum Vertical Elevation
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Verified Mean Velocity given Frictional Velocity
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5 More Liquid Jet Calculators
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Verified Angle of Inclined Manometer
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8 More Liquid Properties Measuring Equipments Calculators
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Verified Tensile Force on Bolt given Maximum Tensile Stress in Bolt
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Verified Tensile Force on Bolt in Tension
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11 More Load and Strength Characteristics Calculators
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Created Incident Current using Reflected Current (Load OC)
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Created Reflected Current (Load OC)
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Created Transmitted Current (Load OC)
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Created Transmitted Voltage (Load OC)
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Created Incident Current using Transmitted Current (Load SC)
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Created Incident Voltage using Reflected Voltage (Load SC)
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Created Transmitted Current (Load SC)
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Created Transmitted Voltage (Load SC)
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Verified Isotropic Radiation Intensity for Loop Antenna
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7 More Loop Antennas Calculators
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Losses (2)
Created Armature Copper Loss for DC Shunt Generator
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Created Shunt Field Copper Loss for DC Shunt Generator
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2 More Losses Calculators
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Losses (2)
Created Mechanical Losses of Series DC Generator given Converted Power
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Created Series Field Copper Loss in DC Generator
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Created Maximum Flux Density given Primary Winding
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Created Maximum Flux Density using Secondary Winding
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3 More Magnetic Flux Calculators
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Verified Armature Flux per pole
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Verified Field Strength at Center
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Verified Flux Density at Center of Solenoid
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Verified Flux Density of Field Traverse to Strip
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Verified Flux in Magnetic Circuit
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Verified Flux Linkage of Search Coil
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Verified Flux linkages of Secondary Coil
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Verified Leakage Factor
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Verified Maximum Flux Density
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Verified Total Flux per pole
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Verified Actual length of Specimen
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Verified Apparent Magnetic Force at length l
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Verified Area of Cross-section of Specimen
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Verified Area of hysteresis loop
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Verified Extention of Specimen
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Verified Hall Coefficient
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Verified Hysteresis Coefficient
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Verified Hysteresis loss per unit volume
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Verified Magnetic Field of Solenoid
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Verified Magneto Motive Force(MMF)
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Verified Number of Turns in Solenoid
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Verified Number of turns per unit length of magnetic coil
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Verified Reluctance of Joints
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Verified Reluctance of Magnetic Circuit
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Verified Reluctance of Yoke's
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Verified Specimen Extension Factor
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Verified Thickness of Strip
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Verified True Magnetizing Force
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Verified Anode Current
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Verified Characteristic Admittance
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Verified Circuit Efficiency in Magnetron
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Verified Cyclotron Angular Frequency
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Verified Distance between Anode and Cathode
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Verified Electron Uniform Velocity
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Verified Electronic Efficiency
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Verified Hull Cutoff Magnetic Flux Density
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Verified Hull Cut-off Voltage
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Verified Magnetron Phase Shift
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Verified Modulation Linearity
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Verified Noise Ratio
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Verified Receiver Sensitivity
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Verified Repetition Frequency of Pulse
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Verified RF Pulse Width
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Verified Spectral Line Frequency
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1 More Magnetron Oscillator Calculators
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Verified Maximum Value of Data given Class Width
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Verified Maximum Value of Data given Mid Range
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Verified Maximum Value of Data given Range
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Verified Mid Range of Data
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Verified Minimum Value of Data given Class Width
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Verified Minimum Value of Data given Mid Range
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Verified Minimum Value of Data given Range
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Verified Actual Power Transmitted given Power Transmitted by Flat for Design Purpose
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Verified Belt Tension in Loose Side of Belt given Initial Tension in Belt
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Verified Belt Tension in Tight Side of Belt given Initial Tension in Belt
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Verified Belt Tension in Tight Side of Belt given Tension due to Centrifugal Force
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Verified Belt Velocity given Tension in Belt Due to Centrifugal Force
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Verified Initial Tension in Belt Drive
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Verified Initial Tension in Belt given Velocity of Belt for Maximum Power Transmission
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Verified Load Correction Factor given Power Transmitted by Flat Belt for Design Purpose
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Verified Mass of One Meter Length of Belt given Maximum Permissible Tensile Stress of Belt
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Verified Mass of One Meter Length of Belt given Tension in Belt Due to Centrifugal Force
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Verified Mass of One Meter Length of Belt given Velocity for Maximum Power Transmission
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Verified Maximum Belt Tension
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Verified Maximum Belt Tension given Tension Due to Centrifugal Force
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Verified Maximum Permissible Tensile Stress of Belt Material
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Verified Optimum Velocity of Belt for Maximum Power Transmission
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Verified Power Transmitted by Flat Belt for Design Purpose
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Verified Tension in Belt Due to Centrifugal Force
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Verified Tension in Belt Due to Centrifugal Force given Permissible Tensile Stress of Belt Material
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Verified Thickness of Belt given Maximum Belt Tension
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Verified Velocity of Belt for Maximum Power Transmission given Maximum Permissible Tensile Stress
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Verified Width of Belt given Maximum Belt Tension
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Verified Diameter of Shaft given Permissible Value of Maximum Principle Stress
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Verified Equivalent Bending Moment given Torsional Moment
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Verified Factor of Safety given Permissible Value of Maximum Principle Stress
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Verified Factor of Safety given Permissible Value of Maximum Shear Stress
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Verified Maximum Shear Stress in Shafts
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Verified Permissible Value of Maximum Principle Stress
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Verified Permissible Value of Maximum Principle Stress using Factor of Safety
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Verified Permissible Value of Maximum Shear Stress
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Verified Torsional Moment given Equivalent Bending Moment
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Verified Yield Strength in Shear Maximum Shear Stress Theory
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Verified Yield Stress in Shear given Permissible Value of Maximum Principle Stress
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6 More Maximum Shear Stress and Principal Stress Theory Calculators
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Verified Iron Loss in Maxwell Bridge
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3 More Maxwell Bridge Calculators
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Mean (3)
Verified Mean of Data given Coefficient of Variation
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Verified Mean of Data given Median and Mode
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Verified Mean of Data given Standard Deviation
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4 More Mean Calculators
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Created Armature Winding Constant of Synchronous Motor
Go
Created Magnetic Flux of Synchronous Motor given Back EMF
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Created Number of Poles given Synchronous Speed in Synchronous Motor
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2 More Mechanical Specification Calculators
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Created Force by Linear Induction Motor
Go
Created Thrust in Linear Induction Motor
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1 More Mechanical Specifications Calculators
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Created Number of Turns in Primary Winding given Transformation Ratio
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Created Number of Turns in Secondary Winding given Transformation Ratio
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6 More Mechanical Specifications Calculators
Go
Created Angular Speed of Series DC Generator given Torque
Go
Created Torque of Series DC Generator given Angular Speed and Armature Current
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1 More Mechanical Specifications Calculators
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Created Machine Constant of DC Shunt Motor given Torque
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Created Machine Construction Constant of DC Shunt Motor given Angular Speed
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Created Machine Construction Constant of Shunt DC Motor
Go
Created Machine Construction Constant using Speed of Shunt DC Motor
Go
Created Number of Armature Conductors of DC Shunt Motor using K
Go
Created Number of Parallel Paths of Shunt DC Motor
Go
Created Number of Poles of Shunt DC Motor
Go
Created Machine Construction Constant of Series DC Motor using Armature Induced Voltage
Go
Created Machine Construction Constant of Series DC Motor using Speed
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Created Magnetic Flux of Series DC Motor given Speed
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Median (1)
Verified Median of Data given Mean and Mode
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1 More Median Calculators
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Verified Cut-off Frequency
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Verified Drain Resistance of MESFET
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Verified Gate Length of MESFET
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Verified Gate Metallization Resistance
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Verified Gate Source Capacitance
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Verified Input Resistance
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Verified Maximum Frequency of Oscillations in MESFET
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Verified Source Resistance
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Verified Transconductance in MESFET
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4 More MESFET Characteristics Calculators
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Verified Change in Drain Current
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Verified Miller Capacitance
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4 More Miller’s Theorem Calculators
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Verified Block of N Serial Source
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Verified Cumulative Distribution Function
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Verified Long Term Fading
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Verified Maximum Possible S by N Ratio
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Verified Mobile Radio Distance
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Verified Mobile Radio Signal
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Verified Mobile Reciever Carrier Power
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Verified Multipath Fading
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Verified Noise Figure
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Verified Path Loss Coefficient
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Verified Selective Retransmission
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Verified Serial to Parallel Modulation Time Period
Go
Verified Short Term Fading
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Verified Stop-and-Wait ARQ Technique
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Verified Symbol Duration
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1 More Mobile Radio Propogation Calculators
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Verified Molality using Molarity
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Verified Molality using Mole Fraction
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3 More Molality Calculators
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MOSFET (1)
Verified Transistor Aspect Ratio
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8 More MOSFET Calculators
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Verified Body Effect in NMOS
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Verified Current Entering Drain Source at Boundary of Saturation and Triode Region of NMOS
Go
Verified Current Entering Drain Terminal of NMOS
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Verified Current Entering Drain Terminal of NMOS given Gate Source Voltage
Go
Verified Current Entering Drain-Source at Saturation Region of NMOS
Go
Verified Current Entering Drain-Source at Saturation Region of NMOS given Effective Voltage
Go
Verified Current Entering Drain-Source in Triode Region of NMOS
Go
Verified Drain Current given NMOS Operates as Voltage-Controlled Current Source
Go
Verified Drain Current when NMOS Operates as Voltage-Controlled Current Source
Go
Verified Electron Drift Velocity of Channel in NMOS Transistor
Go
Verified Fabrication Process Parameter of NMOS
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Verified NMOS as Linear Resistance
Go
Verified Output Resistance of Current Source NMOS given Drain Current
Go
Verified Oxide Capacitance of NMOS
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Verified Positive Voltage given Channel Length in NMOS
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Verified Total Power Dissipated in NMOS
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1 More N Channel Enhancement Calculators
Go
Created Negative Sequence Current using Negative Sequence Impedance (One Conductor Open)
Go
Created Negative Sequence Voltage using Negative Sequence Impedance (One Conductor Open)
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1 More Negative Sequence Calculators
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Created Negative Sequence Current using A-Phase Current(Two Conductor Open)
Go
Created Negative Sequence Current using Negative Sequence Voltage (Two Conductor Open)
Go
Created Negative Sequence Potential Difference (Two Conductor Open)
Go
Created Negative Sequence Voltage using Negative Sequence Current (Two Conductor Open)
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1 More Negative Sequence Calculators
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Verified Force Applied at End of Spring
Go
Verified Force Applied at End of Spring given Pre-Load Required to Close Gap
Go
Verified Initial Nip in Leaf Spring
Go
Verified Initial Pre-Load Required to Close Gap
Go
Verified Length of Cantilever given Initial Nip of Leaf Spring
Go
Verified Modulus of Elasticity given Initial Nip of Spring
Go
Verified Number of Full Length Leaves given Initial Pre-load Required to Close Gap
Go
Verified Number of Graduated length leaves given Initial Pre-Load required to close gap
Go
Verified Thickness of Each Leaf given Initial Nip of Leaf Spring
Go
Verified Total Number of Leaves given Initial Nip of Leaf Spring
Go
Verified Total Number of Leaves given Pre-Load Required to Close Gap
Go
Verified Width of Each Leaf given Initial Nip of Leaf Spring
Go
Created A-Parameter in Nominal Pi Method
Go
Created B Parameter for Reciprocal Network in Nominal Pi Method
Go
Created C Parameter in Nominal Pi Method
Go
Created D Parameter in Nominal Pi Method
Go
Created Impedance using A Parameter in Nominal Pi Method
Go
Created Load Current using Losses in Nominal Pi Method
Go
Created Load Current using Transmission Efficiency in Nominal Pi Method
Go
Created Losses in Nominal Pi Method
Go
Created Losses using Transmission Efficiency in Nominal Pi Method
Go
Created Receiving End Angle using Transmission Efficiency in Nominal Pi Method
Go
Created Receiving End Current using Transmission Efficiency in Nominal Pi Method
Go
Created Receiving End Voltage using Sending End Power in Nominal Pi Method
Go
Created Receiving End Voltage using Voltage Regulation in Nominal Pi Method
Go
Created Resistance using Losses in Nominal Pi Method
Go
Created Sending End Current using Transmission Efficiency in Nominal Pi Method
Go
Created Sending End Power using Transmission Efficiency in Nominal Pi Method
Go
Created Sending End Voltage using Transmission Efficiency in Nominal Pi Method
Go
Created Sending End Voltage using Voltage Regulation in Nominal Pi Method
Go
Created Transmission Efficiency (Nominal Pi Method)
Go
Created Voltage Regulation (Nominal Pi Method)
Go
Created Admittance using A Parameter in Nominal T Method
Go
Created Admittance using D Parameter in Nominal T Method
Go
Created A-Parameter for Reciprocal Network in Nominal T Method
Go
Created A-Parameter in Nominal T Method
Go
Created B Parameter in Nominal T Method
Go
Created Capacitive Current in Nominal T Method
Go
Created Capacitive Voltage in Nominal T Method
Go
Created Capacitive Voltage using Sending End Voltage in Nominal T Method
Go
Created Impedance using Capacitive Voltage in Nominal T Method
Go
Created Impedance using D Parameter in Nominal T Method
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Created Losses in Nominal T Method
Go
Created Receiving End Angle using Sending End Power in Nominal T Method
Go
Created Receiving End Voltage using Capacitive Voltage in Nominal T Method
Go
Created Sending End Current in Nominal T Method
Go
Created Sending End Current using Losses in Nominal T Method
Go
Created Sending End Voltage using Capacitive Voltage in Nominal T Method
Go
Created Sending End Voltage using Voltage Regulation in Nominal T Method
Go
Created Transmission Efficiency in Nominal T Method
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Created Voltage Regulation using Nominal T Method
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Verified Amplifier Gain of Tunnel Diode
Go
Verified Average Diode Temperature using Single Side Band Noise
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Verified Bandwidth using Dynamic Quality Factor
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Verified Dynamic Q Factor
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Verified Magnitude of Negative Resistance
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Verified Maximum Applied Current across Diode
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Verified Maximum Applied Voltage across Diode
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Verified Negative Conductance of Tunnel Diode
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Verified Noise Figure of Double Side Band
Go
Verified Noise Figure of Single Side Band
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Verified Power Gain of Tunnel Diode
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Verified Ratio Negative Resistance to Series Resistance
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Verified Reactive Impedence
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Verified Room Temperature
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Verified Tunnel Diode Output Power
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Verified Voltage Reflection Coefficient of Tunnel Diode
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Verified Equivalent Stress by Distortion Energy Theory
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Verified Stress Amplitude
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6 More Normal Stress Calculators
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Verified Number of Extra Full length leaves given Bending Stress on Graduated length leaves
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Verified Number of Extra Full Length Leaves given Force Taken by Graduated Length Leaves
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Verified Number of Full Length Leaves given Bending Stress in Plate Extra Full Length
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Verified Number of Graduated length leaves given Bending Stress in Plate
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Verified Number of Graduated length leaves given Bending Stress on Graduated length leaves
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Verified Number of Graduated length leaves given Deflection at Load Point Graduated-Length Leaves
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Verified Number of Graduated length leaves given Force taken by Graduated length leaves
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1 More Number of leaves Calculators
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Verified Diameter of Hole Inside Bolt
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4 More Nut Dimensions Calculators
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Created A-Phase EMF using Zero Sequence Impedance (One Conductor Open)
Go
Created B-Phase Current (One Conductor Open)
Go
Created C-Phase Current (One Conductor Open)
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Created Potential Difference between A-Phase using Zero Sequence Potential Difference (One Conductor Open)
Go
2 More One Conductor Open Calculators
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Verified Deflection Factor
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Verified Deflection on Screen
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Verified Deflection Sensitivity
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Verified Degree Per Division
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Verified Display Rise Time of Oscilloscope
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Verified Horizontal Division Per Cycle
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Verified Length of Oscilloscope
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Verified Modulus Number of Counter
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Verified Number of Gaps in Circle
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Verified Number of Positive Peak
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Verified Number of Right Hand Side Peak
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Verified Oscillation Time Period
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Verified Output Time Period
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Verified Peak to Peak Voltage of Waveform
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Verified Phase Difference between Two Sine Wave
Go
Verified Phase Difference in Division
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Verified Potential between Deflection Plate
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Verified Pulse Width of Oscilloscope
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Verified Ratio of Modulating Frequency to Deflecting Plate
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Verified Rise Time Imposed by Oscilloscope
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Verified Rise Time of Oscilloscope
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Verified Time Constant of Oscilloscope
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Verified Time Per Division of Oscilloscope
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Verified Time Period of Waveform
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Verified Vertical Frequency
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Verified Vertical Peak to Peak Division
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1 More Oscilloscope Calculators
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Verified Maximum Efficiency of Steam Engine
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20 More Others and Extra Calculators
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Verified Body Effect in PMOS
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Verified Drain Current in Saturation Region of PMOS Transistor
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Verified Drain Current in Saturation Region of PMOS Transistor given Vov
Go
Verified Drain Current in Triode Region of PMOS Transistor
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Verified Drain Current in Triode Region of PMOS Transistor given Vsd
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Verified Overall Drain Current of PMOS Transistor
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Verified Overdrive Voltage of PMOS
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Verified Process Transconductance Parameter of PMOS
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7 More P Channel Enhancement Calculators
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Verified Obtuse Angle between Pair of Lines
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2 More Pair of Lines Calculators
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Verified Width of Plane in Double Parallel Fillet Weld
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14 More Parallel Fillet Welds Calculators
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Verified Bandwidth of Negative Resistance Parametric Amplifier (NRPA)
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Verified Bandwidth of Parametric Up-Converter
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Verified Gain-Degradation Factor
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Verified Idler Frequency using Pumping Frequency
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Verified Noise Figure of Parametric Up-Converter
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Verified Output Frequency in Up-Convertor
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Verified Output Resistance of Signal Generator
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Verified Power Gain for Parametric Up-Converter
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Verified Power Gain of Demodulator
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Verified Power Gain of Down-Converter
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Verified Power Gain of Modulator
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Verified Pumping Frequency using Demodulator Gain
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Verified Signal frequency
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Verified Hardness of Water
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Verified Percentage of Chlorine in Bleaching Powder
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9 More Percentage Concentration Terms Calculators
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Verified Power Transmitted
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4 More Performance Factors Calculators
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Verified Acceleration Execution Time
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Verified Baudrate
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Verified Compilation
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Verified CPU Time for Useful Work
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Verified CPU Utilization
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Verified Cyclomatic Complexity
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Verified Execution Time
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Verified Number of Component in Graph
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Verified Optimization
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Verified Read Time
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Verified Total Available CPU Time
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Verified Translation
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Verified Write Time
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2 More Performance Metrics Calculators
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Verified Wavelength of Radiation in Vaccum
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12 More Photonics Devices Calculators
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Pipes (5)
Verified Depth of Centroid given Total Hydrostatic Force
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Verified Diameter of Pipe given Head Loss due to Laminar Flow
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Verified Head Loss using Efficiency of Hydraulic Transmission
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Verified Length of Pipe given Head loss
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Verified Viscous Force using Head loss Due to Laminar Flow
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7 More Pipes Calculators
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Verified Energy of Moving Particle given Frequency
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Verified Energy of Moving Particle given Wave Number
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Verified Energy of Moving Particle given Wavelength
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Verified Frequency of Moving Particle
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2 More Planck Quantum Theory Calculators
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Verified Diameter of Pitch Circle of Sprocket given Minimum Linear Velocity of Sprocket
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Verified Linear Velocity of Sprocket
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Verified Minimum Linear Velocity of Sprocket
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Verified Pitch Circle Diameter of Sprocket given Linear Velocity of Sprocket
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Verified Speed of Rotation of Shaft given Linear Velocity of Sprocket
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Verified Speed of Rotation of Shaft given Minimum Linear Velocity of Sprocket
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Created Positive Sequence Current using Positive Sequence Voltage (One Conductor Open)
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Created Positive Sequence Current using Zero Sequence Impedance (One Conductor Open)
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Created Positive Sequence Impedance using Positive Sequence Voltage (One Conductor Open)
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Created Positive Sequence Potential Difference using A-Phase Potential Difference (One Conductor Open)
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Created Positive Sequence Voltage using Positive Sequence Impedance (One Conductor Open)
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Created Positive Sequence Current (Two Conductor Open)
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Created Positive Sequence Current using A-Phase EMF (Two Conductor Open)
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Created Positive Sequence Current using Positive Sequence Voltage (Two Conductor Open)
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Created Positive Sequence Impedance using A-Phase EMF (Two Conductor Open)
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Created Positive Sequence Impedance using Positive Sequence Voltage (Two Conductor Open)
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Created Positive Sequence Potential Difference (Two Conductor Open)
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Created Positive Sequence Voltage using Positive Sequence Current (Two Conductor Open)
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Power (1)
Created Power Converted in Induction Motor
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4 More Power Calculators
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Power (1)
Created Power Generated given Armature Current in DC Shunt Generator
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1 More Power Calculators
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Power (2)
Created Converted Power of Series DC Generator given Input Power
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Created Converted Power of Series DC Generator given Output Power
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Power (7)
Created 3 Phase Input Power of Synchronous Motor
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Created 3 Phase Mechanical Power of Synchronous Motor
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Created Input Power of Synchronous Motor
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Created Mechanical Power of Synchronous Motor
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Created Mechanical Power of Synchronous Motor given Gross Torque
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Created Mechanical Power of Synchronous Motor given Input Power
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Created Output Power for Synchronous Motor
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1 More Power Calculators
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Created Receiving End Angle using Losses (STL)
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Created Receiving End Angle using Receiving End Power (STL)
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Created Receiving End Angle using Transmission Efficiency (STL)
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Created Receiving End Power (STL)
Go
Created Sending End Angle using Receiving End Parameters (STL)
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Created Sending End Angle using Sending End Power (STL)
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Created Sending End Power (STL)
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1 More Power and Phase Difference Calculators
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Created Power Transmitted using K(Two-Wire One Conductor Earthed)
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Created Transmitted Power using Area of X-Section(Two-Wire One Conductor Earthed)
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Created Transmitted Power using Line Losses(Two-Wire One Conductor Earthed)
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Created Transmitted Power using Load Current(Two-Wire One Conductor Earthed)
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Created Transmitted Power using Volume(Two-Wire One Conductor Earthed)
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Created Power Transmitted using Line Losses(Two-Wire Mid-Point Earthed)
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Created Power Transmitted using Load Current(Two-Wire Mid-Point Earthed)
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Created Power Transmitted using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
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Created Power Transmitted per Phase (DC 3-Wire)
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Created Power Transmitted using Area of X-Section(DC 3-Wire)
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Created Power Transmitted using Constant(DC 3-Wire)
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Created Power Transmitted using Line Losses(DC 3-Wire)
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Created Power Transmitted using Load Current(DC 3-Wire)
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Created Power Transmitted using Volume of Conductor Material (DC 3-Wire)
Go
Created Power Factor using Area of X-Section(2-Phase 4-Wire OS)
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Created Power Factor using Line Losses (2-Phase 4-Wire OS)
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Created Power Factor using Load Current (2-Phase 4-Wire OS)
Go
Created Power Transmitted using Area of X-Section(2-Phase 4-Wire OS)
Go
Created Power Transmitted using Line Losses (2-Phase 4-Wire OS)
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Created Power Transmitted using Load Current (2-Phase 4-Wire OS)
Go
Created Power Transmitted(2-Phase 4-Wire OS)
Go
Created Angle of PF using Area of X-Section(3-Phase 4-Wire OS)
Go
Created Angle of PF using Load Current (3-Phase 4-Wire OS)
Go
Created Angle of PF using Volume of Conductor Material (3-Phase 4-Wire OS)
Go
Created Power Factor using Area of X-Section(3-Phase 4-Wire OS)
Go
Created Power Factor using Load Current (3-Phase 4-Wire OS)
Go
Created Power Factor using Volume of Conductor Material (3-Phase 4-Wire OS)
Go
Created Power Transmitted using Area of X-Section(3-Phase 4-Wire OS)
Go
Created Power Transmitted using Load Current (3-Phase 4-Wire OS)
Go
Created Power Transmitted using Volume of Conductor Material (3-Phase 4-Wire OS)
Go
Created Power Transmitted(3-Phase 4-Wire OS)
Go
Created Angle of PF using Area of X-Section(3-Phase 3-Wire OS)
Go
Created Angle of PF using Load Current(3-Phase 3-Wire OS)
Go
Created Power Factor using Area of X-Section(3-Phase 3-Wire OS)
Go
Created Power Factor using Load Current(3-Phase 3-Wire OS)
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Created Power Transmitted using Area of X-Section(3-Phase 3-Wire OS)
Go
Created Power Transmitted(3-Phase 3-Wire OS)
Go
Created Transmitted Power using Load Current(3-Phase 3-Wire OS)
Go
Created Angle of PF using Line Losses (Two-Phase Three-Wire OS)
Go
Created Angle of PF using Volume of Conductor Material (Two-Phase Three-Wire OS)
Go
Created Power Factor using Area of X-section(Two-Phase Three-Wire OS)
Go
Created Power Factor using Line Losses (Two-Phase Three-Wire OS)
Go
Created Power Factor using Volume of Conductor Material (Two-Phase Three-Wire OS)
Go
Created Power Transmitted using Area of X-Section(Two-Phase Three-Wire OS)
Go
Created Power Transmitted using Load Current (Two-Phase Three-Wire OS)
Go
Created Power Transmitted using Volume of Conductor Material (Two-Phase Three-Wire OS)
Go
Created Power Transmitted(Two-Phase Three-Wire OS)
Go
Created Transmitted Power using Line Losses (Two-Phase Three-Wire OS)
Go
Created Power Factor using Area of X-Section(Single-Phase Three-Wire OS)
Go
Created Power Factor using Line Losses (Single-Phase Three-Wire OS)
Go
Created Power Factor using Load Current (Single-Phase Three-Wire OS)
Go
Created Power Factor using Volume of Conductor Material (Single-Phase Three-Wire OS)
Go
Created Power Transmitted using Area of X-Section(Single-Phase Three-Wire OS)
Go
Created Power Transmitted using Line Losses (Single-Phase Three-Wire OS)
Go
Created Power Transmitted using Load Current (Single-Phase Three-Wire OS)
Go
Created Power Transmitted using Volume of Conductor Material (Single-Phase Three-Wire OS)
Go
Created Power Factor using Area of X-Section(Single phase Two Wire OS)
Go
Created Power Factor using Load Current (Single Phase Two Wire OS)
Go
Created Power Transmitted using Area of X-Section(Single Phase Two Wire OS)
Go
Created Power Transmitted using Load Current (Single Phase Two Wire OS)
Go
Created Power Factor using Area of X-Section(Single-Phase Two-Wire Mid-Point Earthed OS)
Go
Created Power Factor using Line Losses (Single-Phase Two-Wire Mid-Point OS)
Go
Created Power Factor using Load Current (Single-Phase Two-Wire Mid-Point OS)
Go
Created Power Transmitted using Area of X-Section(Single-Phase Two-Wire Mid-Point Earthed OS)
Go
Created Power Transmitted using Line Losses (Single-Phase Two-Wire Mid-Point OS)
Go
Created Power Transmitted using Load Current (Single-Phase Two-Wire Mid-Point OS)
Go
Created Power Factor using Area of X-Section (1-Phase 2-Wire US)
Go
Created Power Factor using Constant (1-Phase 2-Wire US)
Go
Created Power Factor using Line Losses (1-Phase 2-Wire US)
Go
Created Power Factor using Load Current (1-Phase 2-Wire US)
Go
Created Power Factor using Resistance (1-Phase 2-Wire US)
Go
Created Power Factor using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created Power Transmitted using Area of X-Section (1-Phase 2-Wire US)
Go
Created Power Transmitted using Constant (1-Phase 2-Wire US)
Go
Created Power Transmitted using Line Losses (1-Phase 2-Wire US)
Go
Created Power Transmitted using Load Current (1-Phase 2-Wire US)
Go
Created Power Transmitted using Resistance (1-Phase 2-Wire US)
Go
Created Power Transmitted using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created Angle of PF using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Power Factor using Area of X-Section (3 Phase 4 Wire US)
Go
Created Power Factor using Line Losses (3 Phase 4 Wire US)
Go
Created Power Factor using Load Current (3 Phase 4 Wire US)
Go
Created Power Factor using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Power Transmitted using Area of X-Section (3 Phase 4 Wire US)
Go
Created Power Transmitted using Line Losses (3 Phase 4 Wire US)
Go
Created Power Transmitted using Load Current (3 Phase 4 Wire US)
Go
Created Power Transmitted using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created RMS Voltage using Area of X-Section (3 Phase 4 Wire US)
Go
Created RMS Voltage using Line Losses (3 Phase 4 Wire US)
Go
Created RMS Voltage using Load Current (3 Phase 4 Wire US)
Go
Created RMS Voltage using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Power Factor Angle for 3 Phase 3 Wire System
Go
Created Power Factor using Area of X-Section (3 Phase 3 Wire US)
Go
Created Power Factor using Load Current Per Phase (3 Phase 3 Wire US)
Go
Created Power Factor using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Power Transmitted Per Phase (3 Phase 3 Wire US)
Go
Created Power Transmitted using Area of X-Section (3 Phase 3 Wire US)
Go
Created Power Transmitted using Load Current Per Phase (3 Phase 3 Wire US)
Go
Created Power Transmitted using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Power Factor using Current in Each Outer (2-Phase 3-Wire US)
Go
Created Power Factor using Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created Power Factor using Line Losses (2-Phase 3-Wire US)
Go
Created Power Factor using Volume of Conductor Material (2 Phase 3 Wire US)
Go
Created Power Transmitted using Current in Each Outer (2-Phase 3-Wire US)
Go
Created Power Transmitted using Current in Neutral Wire (2-Phase 3-Wire US)
Go
Created Power Transmitted using Volume of Conductor Material (2 Phase 3 Wire US)
Go
Created Transmitted Power using Line Losses (2-Phase 3-Wire US)
Go
Created Power Factor Angle for Single Phase 3 Wire System
Go
Created Power Factor using Area of X Section (1 Phase 3 Wire US)
Go
Created Power Factor using Line Losses (1 Phase 3 Wire US)
Go
Created Power Factor using Load Current (1 Phase 3 Wire US)
Go
Created Power Factor using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Power Transmitted using Area of X Section (1 Phase 3 Wire US)
Go
Created Power Transmitted using Line Losses (1 Phase 3 Wire US)
Go
Created Transmitted Power using Load Current (1 Phase 3 Wire US)
Go
Created Transmitted Power using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Power Factor using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Power Factor using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Power Factor using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Power Transmitted using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Power Transmitted using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Power Transmitted using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Angle using Load Current (2 Phase 4 Wire US)
Go
Created Power Factor using Area of X-Section (2 Phase 4 Wire US)
Go
Created Power Factor using Line Losses (2 Phase 4 Wire US)
Go
Created Power Factor using Load Current (2 Phase 4 Wire US)
Go
Created Power Transmitted using Area of X-Section (2 Phase 4 Wire US)
Go
Created Power Transmitted using Line Losses (2 Phase 4 Wire US)
Go
Created Power Transmitted using Load Current (2 Phase 4 Wire US)
Go
Created Power Transmitted using Area of X-Section (DC Two-Wire US)
Go
Created Power Transmitted using Line Losses (DC Two-Wire US)
Go
Created Resistance using Line Losses (DC Two-Wire US)
Go
Created Resistivity using Area of X-Section (DC Two-Wire US)
Go
Created Resistivity using Line Losses (DC Two-Wire US)
Go
Created Power Transmitted using Area of X-Section (2-Wire Mid-Point Earthed DC US)
Go
Created Power Transmitted using Load Current (2-Wire Mid-Point DC US)
Go
Created Power Transmitted using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Resistivity using Area of X-Section (2-wire Mid-point earthed DC US)
Go
Created Resistivity using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Phase Angle between Load Voltage and Current given 3 Phase Input Power
Go
Created Phase Angle between Voltage and Armature Current given 3 Phase Mechanical Power
Go
Created Phase Angle between Voltage and Armature Current given Input Power
Go
Created Power Factor of Synchronous Motor given 3 Phase Mechanical Power
Go
Created Power Factor of Synchronous Motor given Input Power
Go
Created Power Factor of Synchronous Motor using 3 Phase Input Power
Go
Created Power Factor given Impedance
Go
Created Power Factor given Power
Go
Created Power Factor given Power Factor Angle
Go
Created Q Factor for Parallel RLC Circuit
Go
Created Q Factor for Series RLC Circuit
Go
Created Average Load for Load Curve
Go
Created Unit Generated per Annum
Go
13 More Power Plant Operational Factors Calculators
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Verified Allowable Tension in Chain given Power Transmitted by Roller Chain
Go
Verified Average Velocity of Chain given Power Transmitted by Roller Chain
Go
Verified Multiple Strand Factor given Power Rating of Chain
Go
Verified Power Rating of Chain
Go
Verified Power to be Transmitted given Power Rating of Chain
Go
Verified Power Transmitted by Roller Chain
Go
Verified Service Factor given Power Rating of Chain
Go
Verified Tooth Correction Factor given Power Rating of Chain
Go
Verified Belt Tension in Loose Side of V-Belt given Power Transmitted
Go
Verified Belt Tension in Tight Side of Belt given Power Transmitted using V-Belt
Go
Verified Belt Velocity given Power Transmitted using V-Belt
Go
Verified Drive Power to be Transmitted given Number of Belts Required
Go
Verified Power Rating of Single V-Belt given Number of Belts Required
Go
Verified Power Transmitted using V Belt
Go
Verified Change in Pressure
Go
Verified Height of liquid in column
Go
Verified Pressure Difference in Manometer
Go
Verified Pressure Difference in U-tube Manometer
Go
Verified Pressure on Left of Manometer
Go
Verified Pressure on right of Manometer
Go
Verified Shear Stress in Fluid
Go
1 More Pressure Measurement Calculators
Go
Verified Absolute Pressure at Height h
Go
Verified Angle of Inclined Manometer given Pressure at Point
Go
Verified Area of Surface Wetted given Center of Pressure
Go
Verified Bulk Modulus given Velocity of Pressure Wave
Go
Verified Density of Liquid given Dynamic Pressure
Go
Verified Depth of Centroid given Center of Pressure
Go
Verified Diameter of Droplet given Change in Pressure
Go
Verified Diameter of Soap Bubble
Go
Verified Height of Fluid 1 given Differential Pressure between Two Points
Go
Verified Height of Fluid 2 given Differential Pressure between Two Points
Go
Verified Height of Liquid given its Absolute Pressure
Go
Verified Length of Inclined Manometer
Go
Verified Mass Density given Velocity of Pressure Wave
Go
Verified Moment of Inertia of Centroid given Center of Pressure
Go
Verified Pressure using Inclined Manometer
Go
Verified Pressure Wave Velocity in Fluids
Go
Verified Surface Tension of Liquid Drop given Change in Pressure
Go
Verified Surface Tension of Soap Bubble
Go
Verified Velocity of Fluid given Dynamic Pressure
Go
11 More Pressure Relations Calculators
Go
Verified Thermal Expansion
Go
12 More Production of Power from Heat Calculators
Go
Verified Population Proportion
Go
2 More Proportion Calculators
Go
Verified Chain Pitch given Maximum Tooth Height above Pitch Polygon
Go
Verified Maximum Roller Seating Angle
Go
Verified Maximum Tooth Height above Pitch Polygon
Go
Verified Minimum Roller Seating Angle
Go
Verified Minimum Roller Seating Radius
Go
Verified Minimum Tooth Flank Radius
Go
Verified Minimum Tooth Height above Pitch Polygon
Go
Verified Number of Teeth given Maximum Roller Seating Angle
Go
Verified Number of Teeth given Maximum Tooth Height above Pitch Polygon
Go
Verified Number of Teeth given Minimum Roller Seating Angle
Go
Verified Number of Teeth given Minimum Tooth Flank Radius
Go
Verified Number of Teeth on Sprocket given Pitch Angle of Sprocket
Go
Verified Pitch Angle of Sprocket
Go
Verified Pitch Circle Diameter given Average Velocity of Chain
Go
Verified Pitch Circle Diameter given Pitch
Go
Verified Pitch Circle Diameter given Root Diameter of Sprocket Wheel
Go
Verified Pitch Circle Diameter given Top Diameter of Sprocket Wheel
Go
Verified Roller Seating Radius given Roller Radius
Go
Verified Roller Seating Radius given Root Diameter of Sprocket Wheel
Go
Verified Root Diameter of Sprocket Wheel
Go
Verified Tooth Flank Radius
Go
Verified Top Diameter of Sprocket Wheel
Go
Verified External Q-Factor
Go
Verified Q-Factor of Beam Loading
Go
Verified Q-Factor of Catcher Wall
Go
Verified Q-Factor of External Load
Go
Verified Q-Factor of Loaded Catcher Cavity
Go
Verified Q-Factor of Loaded Resonator Circuit
Go
Verified Quality Factor of Cavity Resonator
Go
Verified Unloaded Q-factor
Go
6 More Q Factor Calculators
Go
Verified Quartile Deviation given Coefficient of Quartile Deviation
Go
1 More Quartile Deviation Calculators
Go
Verified Antenna Aperture Efficiency
Go
Verified Antenna Area
Go
Verified Cumulative Probability of Detection
Go
Verified Doppler Angular Frequency
Go
Verified Doppler Frequency
Go
Verified Effective Area of Receiving Antenna
Go
Verified Maximum Gain of Antenna
Go
Verified Maximum Power Density Radiated by Antenna
Go
Verified Maximum Range of Radar
Go
Verified Maximum Unambiguous Range
Go
Verified Measured Runtime
Go
Verified Minimum Detectable Signal
Go
Verified N Scans
Go
Verified Power Density Radiated by Lossless Antenna
Go
Verified Probability of Detection
Go
Verified Pulse Repetition Frequency
Go
Verified Pulse Repetition Time
Go
Verified Radar Antenna Height
Go
Verified Radial Velocity
Go
Verified Range of Target
Go
Verified Target Height
Go
Verified Target Velocity
Go
Verified Transmitted Frequency
Go
Verified Transmitted Gain
Go
Verified Earth Station Altitude
Go
Verified Effective Path Length
Go
Verified Effective Path Length using Reduction Factor
Go
Verified Rain Height
Go
Verified Reduction Factor using Slant Length
Go
Verified Slant Length
Go
Verified Specific Attenuation
Go
Verified Total Attenuation
Go
6 More Radio Wave Propagation Calculators
Go
Verified Angular Momentum using Radius of Orbit
Go
Verified Bohr's Radius
Go
Verified Frequency using Energy
Go
Verified Radius of Orbit
Go
4 More Radius of Bohr's Orbit Calculators
Go
Created Equivalent Reactance from Primary Side given Equivalent Impedance
Go
Created Equivalent Reactance from Secondary Side given Equivalent Impedance
Go
Created Equivalent Reactance of Transformer from Primary Side
Go
Created Equivalent Reactance of Transformer from Secondary Side
Go
Created Primary Leakage Reactance
Go
Created Primary Leakage Reactance given Equivalent Reactance from Secondary Side
Go
Created Primary Leakage Reactance given Impedance of Primary Winding
Go
Created Primary Leakage Reactance using Equivalent Reactance from Primary Side
Go
Created Reactance of Primary in Secondary using Equivalent Reactance from Secondary Side
Go
Created Reactance of Primary Winding in Secondary
Go
Created Reactance of Secondary in Primary using Equivalent Reactance from Primary Side
Go
Created Reactance of Secondary Winding in Primary
Go
Created Secondary Leakage Reactance
Go
Created Secondary Leakage Reactance given Equivalent Reactance from Primary Side
Go
Created Secondary Leakage Reactance given Equivalent Reactance from Secondary Side
Go
Created Secondary Leakage Reactance given Impedance of Secondary Winding
Go
Created Characteristic Impedance using Transmitted Coefficient of Current
Go
Created Load Impedance using Transmitted Coefficient of Current
Go
Created Load Impedance using Transmitted Coefficient of Voltage
Go
Created Characteristic Impedance for Reflected Waves
Go
Created Characteristic Impedance using Reflected Current
Go
Created Characteristic Impedance using Reflected Voltage
Go
Created Incident Voltage using Reflected Current
Go
Created Load Impedance using Reflected Voltage
Go
Created Reflected Current using Incident and Transmitted Current
Go
Created Reflected Current using Load Impedance
Go
Created Incident Current using Reflection Coefficient of Current
Go
Created Incident Voltage using Reflection Coefficient of Voltage
Go
Created Reflection Coefficient of Current using Reflection Coefficient of Voltage
Go
Created Characteristic Impedance using Transmitted Coefficients
Go
Created Load Impedance using Transmitted Coefficients
Go
Created Reflected Coefficient of Current using Reflected Coefficient of Voltage
Go
Created Reflected Coefficient of Current using Transmitted Coefficient of Current
Go
Created Reflected Coefficient of Voltage using Reflected Coefficient of Current
Go
Created Reflected Coefficient of Voltage using Transmitted Coefficient of Voltage
Go
Created Transmitted Coefficient of Current using Reflected Coefficient of Current
Go
Created Transmitted Coefficient of Current using Transmitted Coefficient of Voltage
Go
Created Transmitted Coefficient of Voltage using Reflected Coefficient of Voltage
Go
Created Transmitted Coefficient of Voltage using Transmitted Coefficient of Current
Go
Verified Resistance of Wire
Go
Verified Temperature Dependence of Resistance
Go
6 More Resistance Calculators
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Created Equivalent Resistance from Primary Side
Go
Created Equivalent Resistance from Primary Side using Equivalent Impedance from Primary Side
Go
Created Equivalent Resistance from Secondary Side
Go
Created Equivalent Resistance from Secondary Side using Equivalent Impedance from Secondary Side
Go
Created Equivalent Resistance of Transformer from Primary Side
Go
Created Equivalent Resistance of Transformer from Secondary Side
Go
Created Primary Winding Resistance
Go
Created Primary Winding Resistance given Impedance of Primary Winding
Go
Created Primary Winding Resistance given Secondary Winding Resistance
Go
Created Resistance of Primary in Secondary using Equivalent Resistance from Secondary Side
Go
Created Resistance of Primary Winding in Secondary
Go
Created Resistance of Secondary in Primary using Equivalent Resistance from Primary Side
Go
Created Resistance of Secondary Winding in Primary
Go
Created Secondary Winding Resistance
Go
Created Secondary Winding Resistance given Equivalent Resistance from Primary Side
Go
Created Secondary Winding Resistance given Impedance of Secondary Winding
Go
Created Secondary Winding Resistance given Primary Winding Resistance
Go
1 More Resistance Calculators
Go
Created Armature Resistance of Series DC Generator given Output Power
Go
Created Armature Resistance of Series DC Generator using Terminal Voltage
Go
Created Series Field Resistance of Series DC Generator using Terminal Voltage
Go
Created Armature Resistance of Shunt DC Motor given Voltage
Go
Created Shunt Field Resistance of Shunt DC Motor given Shunt Field Current
Go
Created Armature Resistance of Series DC Motor given Voltage
Go
Created Series Field Resistance of Series DC Motor given Speed
Go
Created Series Field Resistance of Series DC Motor given Voltage
Go
Verified Drain Output Resistance
Go
Verified Electron Mean Free Path
Go
Verified MOSFET as Linear Resistance
Go
Verified MOSFET as Linear Resistance given Aspect Ratio
Go
Verified Output Resistance of Differential Amplifier
Go
9 More Resistance Calculators
Go
Verified Emitter Resistance given Threshold Voltage
Go
Verified Emitter Resistance of BJT
Go
Verified Output Resistance of BJT
Go
Verified Output Resistance of Current Source given Device Parameter
Go
Verified Output Resistance of Transistor when Base Current is Constant
Go
Verified Small-Signal Input Resistance between Base and Emitter
Go
Verified Small-Signal Input Resistance between Base and Emitter using Base Current
Go
Verified Small-Signal Input Resistance between Base and Emitter using Transconductance
Go
Verified Small-Signal Input Resistance given Emitter Current
Go
6 More Resistance Calculators
Go
Verified Differential Input Resistance of BJT Amplifier
Go
Verified Differential Input Resistance of BJT Amplifier given Common-Emitter Current Gain
Go
Verified Differential Input Resistance of BJT Amplifier given Small-Signal Input Resistance
Go
1 More Resistance Calculators
Go
Created Resistance using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Resistivity using Area of X-Section(Two-Wire One Conductor Earthed)
Go
Created Resistivity using K(Two-Wire One Conductor Earthed)
Go
Created Resistivity using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Resistivity using Resistance(Two-Wire One Conductor Earthed)
Go
Created Resistivity using Volume(Two-Wire One Conductor Earthed)
Go
Created Resistance using Line Losses(Two-Wire Mid-Point Earthed)
Go
Created Resistance(Two-Wire Mid-Point Earthed)
Go
Created Resistivity using Line Losses(Two-Wire Mid-Point Earthed)
Go
Created Resistivity using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
Go
Created Resistance using Line Losses(DC 3-Wire)
Go
Created Resistance(DC 3-Wire)
Go
Created Resistivity using Area of X-Section(DC 3-Wire)
Go
Created Resistivity using Constant(DC 3-Wire)
Go
Created Resistivity using Line Losses(DC 3-Wire)
Go
Created Resistivity using Volume of Conductor Material (DC 3-Wire)
Go
Created Resistance using Line Losses (Single Phase Two Wire OS)
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Created Resistance using Load Current (Single Phase Two Wire OS)
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Created Resistance(Single-Phase Two-Wire OS)
Go
Created Resistivity using Area of X-Section(Single-Phase Two-Wire OS)
Go
Created Resistivity using Line Losses (Single-Phase Two-Wire OS)
Go
Created Resistivity using Load Current (Single-Phase Two-Wire OS)
Go
Created Resistance using Line Losses (Single-Phase Two-Wire Mid-Point OS)
Go
Created Resistance using Load Current (Single-Phase Two-Wire Mid-Point OS)
Go
Created Resistance(Single-Phase Two-Wire Mid-Point Earthed OS)
Go
Created Resistivity using Area of X-Section(Single-Phase Two-Wire Mid-Point Earthed OS)
Go
Created Resistivity using Load Current (Single-Phase Two-Wire Mid-Point OS)
Go
Created Resistance using Line Losses (Single-Phase Three-Wire OS)
Go
Created Resistance using Load Current (Single-Phase Three-Wire OS)
Go
Created Resistance(Single-Phase Three-Wire OS)
Go
Created Resistivity using Area of X-section(Single-Phase Three-Wire OS)
Go
Created Resistivity using Line Losses (Single-Phase Three-Wire OS)
Go
Created Resistivity using Load Current (Single-Phase Three-Wire OS)
Go
Created Resistivity using Volume of Conductor Material (Single-Phase Three-Wire OS)
Go
Created Resistance using Line Losses (2-Phase 4-Wire OS)
Go
Created Resistance using Load Current (2-Phase 4-Wire OS)
Go
Created Resistance(2-Phase 4-Wire OS)
Go
Created Resistivity using Area of X-Section(2-Phase 4-Wire OS)
Go
Created Resistivity using Line Losses (2-Phase 4-Wire OS)
Go
Created Resistivity using Load Current (2-Phase 4-Wire OS)
Go
Created Resistance of Neutral Wire (Two-Phase Three-Wire OS)
Go
Created Resistance using Line Losses (Two-Phase Three-Wire OS)
Go
Created Resistance(Two-Phase Three-Wire OS)
Go
Created Resistivity using Area of X-Section(Two-Phase Three-Wire OS)
Go
Created Resistivity using Line Losses (Two-Phase Three-Wire OS)
Go
Created Resistivity using Resistance (Two-Phase Three-Wire OS)
Go
Created Resistivity using Volume of Conductor Material (Two-Phase Three-Wire OS)
Go
Created Resistance(3-Phase 4-Wire OS)
Go
Created Resistivity using Area of X-Section(3-Phase 4-Wire OS)
Go
Created Resistivity using Resistance (3-Phase 4-Wire OS)
Go
Created Resistivity using Volume of Conductor Material (3-Phase 4-Wire OS)
Go
Created Resistance (1-Phase 2-Wire US)
Go
Created Resistance using Constant (1-Phase 2-Wire US)
Go
Created Resistance using Line Losses (1-Phase 2-Wire US)
Go
Created Resistance using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created Resistivity using Area of X-Section (1-Phase 2-Wire US)
Go
Created Resistivity using Constant (1-Phase 2-Wire US)
Go
Created Resistivity using Line Losses (1-Phase 2-Wire US)
Go
Created Resistivity using Load Current (1-Phase 2-Wire US)
Go
Created Resistivity using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created Resistance using Line Losses (3 Phase 4 Wire US)
Go
Created Resistance using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Resistivity using Area of X-Section (3 Phase 4 Wire US)
Go
Created Resistivity using Line Losses (3 Phase 4 Wire US)
Go
Created Resistivity using Load Current (3 Phase 4 Wire US)
Go
Created Resistivity using Volume of Conductor Material (3 Phase 4 Wire US)
Go
Created Angle of PF using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Angle using Area of X-Section (3 Phase 3 Wire US)
Go
Created Resistance using Line Losses (3 Phase 3 Wire US)
Go
Created Resistivity using Area of X-Section (3 Phase 3 Wire US)
Go
Created Resistivity using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Resistance of Neutral Wire (2-Phase 3-Wire US)
Go
Created Resistance using Line Losses (2-Phase 3-Wire US)
Go
Created Resistivity using Line Losses (2-Phase 3-Wire US)
Go
Created Resistivity using Resistance of Natural Wire (2-Phase 3-Wire US)
Go
Created Resistivity using Volume of Conductor Material (2 Phase 3 Wire US)
Go
Created Resistance using Line Losses (1 Phase 3 Wire US)
Go
Created Resistivity using Area of X Section (1 Phase 3 Wire US)
Go
Created Resistivity using Line Losses (1 Phase 3 Wire US)
Go
Created Resistivity using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Resistance using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Resistivity using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Resistivity using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Resistance using Line Losses (2 Phase 4 Wire US)
Go
Created Resistivity using Area of X-Section (2 Phase 4 Wire US)
Go
Created Resistivity using Line Losses (2 Phase 4 Wire US)
Go
Created Resistivity using Load Current (2 Phase 4 Wire US)
Go
Created Resistivity using Volume of Conductor Material (2 Phase 4 Wire US)
Go
Created Power Transmitted using Area of X-Section (DC Three-Wire US)
Go
Created Power Transmitted using Line Losses (DC Three-Wire US)
Go
Created Resistance using Line Losses (DC Three-Wire US)
Go
Created Resistivity using Area of X-Section (DC Three-Wire US)
Go
Created Resistivity using Line Losses (DC Three-Wire US)
Go
Created Resistivity using Volume of Conductor Material(DC Three-Wire US)
Go
Created Transmitted Power using Volume of Conductor Material(DC Three-Wire US)
Go
Verified Aspect Ratio
Go
Verified Height of Rectangle Picture Frame
Go
Verified Horizontal Resolution
Go
Verified Kell Factor or Resolution Factor
Go
Verified Number of Frames Per Sec
Go
Verified Number of Horizontal Lines Lost during Vertical Retrace
Go
Verified Number of Lines in Frame
Go
Verified Vertical Resolution (VR)
Go
Verified Vertical Retrace Time
Go
Verified Width of Rectangle Picture
Go
Verified 3-DB Frequency in Design Insight and Trade-Off
Go
Verified Amplifier Gain given Function of Complex Frequency Variable
Go
Verified Drain Resistance in Cascode Amplifier
Go
2 More Response of Cascode Amplifier Calculators
Go
Verified Collector Base Junction Resistance of CE Amplifier
Go
Verified High-Frequency Gain of CE Amplifier
Go
Verified Input Capacitance in High-Frequency Gain of CE Amplifier
Go
5 More Response of CE Amplifier Calculators
Go
Verified Resistance due to Capacitor CC1 using Method Short-Circuit Time Constants
Go
Verified Time Constant Associated with Cc1 using Method Short-Circuit Time Constants
Go
Verified Time Constant of CE Amplifier
Go
Verified Load Resistance of CG Amplifier
Go
Verified Second Pole-Frequency of CG Amplifier
Go
4 More Response of CG Amplifier Calculators
Go
Verified Dominant Pole-Frequency of Source-Follower
Go
Verified Transition Frequency of Source-Follower Transfer Function
Go
5 More Response of Source and Emitter Follower Calculators
Go
Verified Diameter of Rivet given Margin of Rivet
Go
Verified Margin of Rivet
Go
Verified Number of Rivets Per Pitch given Crushing Resistance of Plates
Go
Verified Pitch of Rivet
Go
Verified Pitch of Rivets given Tensile Resistance of Plate between two Rivets
Go
Verified Transverse Pitch for Zig-Zag riveting
Go
Verified Transverse Pitch of Rivet Chain Riveting
Go
9 More Rivet Dimensions Calculators
Go
Verified Length of Rivet Shank
Go
Verified Length of Shank Portion necessary to form Closing Head
Go
Verified Shank Diameter of Rivet given Crushing Resistance of Plates
Go
Verified Shank Diameter of Rivet given Pitch of Rivet
Go
Verified Shank diameter of Rivet subjected to double shear given Shear resistance of Rivet per Pitch
Go
Verified Local Sidereal Time
Go
Verified Mean Anomaly
Go
Verified Range Vector
Go
Verified True Anomaly
Go
12 More Satellite Orbital Characteristics Calculators
Go
Verified Capacitance due to Space between Specimen and Dielectric
Go
Verified Capacitance of Specimen
Go
Verified Capacitance with Specimen as Dielectric
Go
Verified Effective Area of Electrode in Schering Bridge
Go
Verified Effective Capacitance in Schering Bridge
Go
Verified Relative Permittivity
Go
Verified Spacing between Electrodes in Schering Bridge
Go
3 More Schering Bridge Calculators
Go
Verified Angular Momentum using Quantum Number
Go
Verified Magnetic Moment
Go
Verified Number of Spherical Nodes
Go
Verified Orbital Angular Momentum
Go
Verified Spin Angular Momentum
Go
Verified Total Number of Nodes
Go
16 More Schrodinger Wave Equation Calculators
Go
Verified Correction Factor for Industrial Service given Design Power
Go
Verified Design Power for V Belt
Go
Verified Pitch diameter of big pulley of V Belt drive
Go
Verified Pitch diameter of smaller pulley given pitch diameter of big pulley
Go
Verified Speed of bigger pulley given speed of smaller pulley
Go
Verified Speed of smaller pulley given pitch diameter of both pulleys
Go
Verified Transmitted Power given Design Power
Go
Verified Conductivity of Extrinsic Semiconductor for P-Type
Go
Verified Drift Current Density
Go
Verified Electric Field due to Hall Voltage
Go
Verified Majority Carrier Concentration in Semiconductor
Go
9 More Semiconductor Characteristics Calculators
Go
Created Negative Phase Current for Delta Connected Load
Go
Created Negative Sequence Current for Star Connected Load
Go
Created Negative Sequence Voltage for Delta Connected Load
Go
Created Negative Sequence Voltage for Star Connected Load
Go
Created Positive Sequence Current for Delta Connected Load
Go
Created Positive Sequence Current for Star Connected Load
Go
Created Positive Sequence Voltage for Delta Connected Load
Go
Created Positive Sequence Voltage for Star Connected Load
Go
Created Symmetric Component Current using Sequence Impedance
Go
Created Symmetric Component Voltage using Sequence Impedance
Go
Created Zero Sequence Current for Star Connected Load
Go
Created Zero Sequence Voltage for Star Connected Load
Go
Verified Open Loop Gain of Feedback Transconductance Amplifier
Go
Verified Output Resistance with Feedback of Feedback Transconductance Amplifier
Go
1 More Series Feedback Amplifiers Calculators
Go
Verified Axial Force given Tensile Stress in Shaft
Go
Verified Bending Moment given Bending Stress Pure Bending
Go
Verified Bending Stress in Shaft Pure Bending Moment
Go
Verified Diameter of Shaft given Bending Stress Pure Bending
Go
Verified Diameter of Shaft given Tensile Stress in Shaft
Go
Verified Diameter of Shaft given Torsional Shear Stress in Shaft Pure Torsion
Go
Verified Normal Stress given Both Bending and Torsional act on Shaft
Go
Verified Tensile Stress given Normal Stress
Go
Verified Torsional Moment given Torsional Shear Stress in Shaft Pure Torsion
Go
Verified Torsional Shear Stress in Shaft Pure Torsion
Go
6 More Shaft Design on Strength Basis Calculators
Go
Verified Open Loop Gain of Feedback Transresistance Amplifier (Shunt-Shunt)
Go
2 More Shunt Feedback Amplifiers Calculators
Go
Verified Voltage Gain of Amplifier with Current-Source Load
Go
6 More Signal Amplifier Calculators
Go
Verified Error Signal
Go
Verified Loop Gain of Feedback Amplifier
Go
3 More Signal Analysis Calculators
Go
Slip (5)
Created Breakdown Slip of Induction Motor
Go
Created Slip at Pull Out Torque
Go
Created Slip given Efficiency in Induction Motor
Go
Created Slip given Frequency in Induction Motor
Go
Created Slip of Motor in Induction Motor
Go
Verified Slope of Line given Numerical Coefficients
Go
3 More Slope of Line Calculators
Go
Verified Slope of Perpendicular of Line given Two Points on Line
Go
3 More Slope of Perpendicular of Line Calculators
Go
Verified Amplification Factor for Small Signal MOSFET Model
Go
Verified Drain Current of MOSFET Small Signal
Go
13 More Small Signal Analysis Calculators
Go
Verified Amplitude of Reference Signal
Go
Verified Amplitude of Signal Received from Target at Range
Go
Verified CFA DC Power Input
Go
Verified CFA RF Drive Power
Go
Verified CFA RF Power Output
Go
Verified Distance from Antenna 1 to Target in Monopulse Radar
Go
Verified Distance from Antenna 2 to Target in Monopulse Radar
Go
Verified Doppler Frequency Shift
Go
Verified Echo Signal Voltage
Go
Verified Efficiency of Cross Field Amplifier(CFA)
Go
Verified Measured Position at Nth Scan
Go
Verified Peak Quantization Lobe
Go
Verified Phase Difference between Echo Signals in Monopulse Radar
Go
Verified Position Smoothing Parameter
Go
Verified Predicted Position of Target
Go
Verified Range Resolution
Go
Verified Reference Voltage of CW Oscillator
Go
Verified Smoothed Position
Go
Verified Smoothed Velocity
Go
Verified Time between Observations
Go
Verified Velocity Smoothing Parameter
Go
Verified Specific Weight of Fluid 1 given Differential Pressure between Two Points
Go
Verified Specific Weight of Fluid 2 given Differential Pressure between Two Points
Go
Verified Specific Weight of Inclined Manometer Liquid
Go
Verified Specific Weight of Liquid given Buoyancy Force
Go
Verified Specific Weight of Liquid given Head loss Due to Laminar Flow
Go
Verified Specific Weight of Liquid given Hydraulic Transmission Power
Go
Verified Specific Weight of Liquid given its Absolute Pressure at Height
Go
Verified Specific Weight of Liquid given Total Hydrostatic Force
Go
2 More Specific Weight Calculators
Go
Speed (6)
Created Motor Speed given Efficiency in Induction Motor
Go
Created Motor Speed given Synchronous Speed
Go
Created Motor Speed in Induction Motor
Go
Created Synchronous Speed given Mechanical Power
Go
Created Synchronous Speed given Motor Speed
Go
Created Synchronous Speed of Induction Motor given Efficiency
Go
2 More Speed Calculators
Go
Speed (6)
Created Angular Speed of DC Shunt Motor given Kf
Go
Created Angular Speed of DC Shunt Motor given Output Power
Go
Created Full Load Speed of Shunt DC Motor
Go
Created No Load Speed of Shunt DC Motor
Go
Created Speed Regulation of Shunt DC Motor
Go
Created Torque of DC Motor given Output Power
Go
Speed (2)
Created Angular Speed of DC Motor given Output Power
Go
Created Speed of Series DC Motor
Go
Speed (2)
Created Synchronous Speed of Synchronous Motor
Go
Created Synchronous Speed of Synchronous Motor given Mechanical Power
Go
Verified Angle of Rotation of Arbor with Respect to Drum
Go
Verified Force given Bending Moment Due to that Force
Go
Verified Length of Strip from Outer end to inner End given Angle of Rotation of Arbor
Go
Verified Length of Strip from Outer end to inner End given Deflection of one End of Spring
Go
Verified Length of Strip from Outer end to Inner End given Strain Energy Stored in Spring
Go
Verified Maximum Bending Stress induced at outer end of Spring
Go
Verified Modulus of Elasticity given Angle of Rotation of Arbor
Go
Verified Modulus of Elasticity given Deflection of one End of Spring with Respect to Other End
Go
Verified Modulus of Elasticity of Spring Wire given Strain Energy Stored in Spring
Go
Verified Strain Energy Stored in Spiral Spring
Go
Verified Acceptor Concentration
Go
Verified Cross-Sectional Area of Junction
Go
Verified Donor Concentration
Go
Verified Junction Capacitance
Go
Verified Junction Transition Width
Go
Verified Junction Voltage
Go
Verified Length of P-Side Junction
Go
Verified Net Distribution of Charge
Go
Verified N-Type Width
Go
Verified P-N Junction Length
Go
Verified Quantum Number
Go
Verified Series Resistance in N-type
Go
Verified Series Resistance in P-type
Go
Verified Total Acceptor Charge
Go
2 More SSD Junction Calculators
Go
Verified Compressive Stress of Spigot
Go
Verified Permissible Shear Stress for Cotter
Go
Verified Permissible Shear Stress for Spigot
Go
Verified Tensile Stress in Spigot
Go
9 More Strength and Stress Calculators
Go
Stress (1)
Verified Stress developed in wire due to fluid pressure given strain in wire
Go
20 More Stress Calculators
Go
Verified Deflection of Spring
Go
Verified Deflection of Spring given Strain Energy Stored
Go
Verified Diameter of Spring Wire given Deflection in Spring
Go
Verified Diameter of Spring Wire given Rate of Spring
Go
Verified Diameter of Spring Wire given Resultant Stress in Spring
Go
Verified Diameter of Spring Wire given Shear Stress Correction Factor
Go
Verified Force acting on Spring given Resultant Stress
Go
Verified Force Applied on Spring given Deflection in Spring
Go
Verified Force Applied on Spring given Strain Energy Stored in Spring
Go
Verified Mean Coil Diameter given Deflection in Spring
Go
Verified Mean Coil Diameter given Rate of Spring
Go
Verified Mean Coil Diameter given Resultant Stress in Spring
Go
Verified Mean Coil diameter given Shear Stress Correction Factor
Go
Verified Modulus of Rigidity given Deflection in Spring
Go
Verified Modulus of Rigidity given Rate of Spring
Go
Verified Number of Active Coils given Deflection in Spring
Go
Verified Rate of Spring
Go
Verified Rate of Spring given Deflection
Go
Verified Resultant Stress in Spring
Go
Verified Shear Stress Correction Factor
Go
Verified Shear Stress Correction Factor given Diameter of Spring Wire
Go
Verified Spring Index given Shear Stress Correction Factor
Go
Verified Strain Energy Stored in Spring
Go
Verified Stress Factor of Spring
Go
Verified Normal Stress 2
Go
19 More Stress and Strain Calculators
Go
Verified Crushing Resistance of Plates per Pitch Length
Go
Verified Permissible Compressive Stress of Plate Material given Crushing Resistance of Plates
Go
Verified Permissible Shear Stress for Rivet for Single Shear
Go
Verified Permissible Shear Stress for Rivet given Shear Resistance of Rivet Per Pitch Length
Go
Verified Shear Resistance of Rivet per Pitch Length
Go
Verified Shear Resistance of Rivet Per Pitch Length for Double Shear
Go
Verified Shear Resistance of Rivet Per Pitch Length for Single Shear
Go
Verified Tensile Resistance of Plate between two Rivets
Go
1 More Stresses and Resistances Calculators
Go
Verified Angle between adjacent Balls of Ball Bearing
Go
Verified Diameter of Ball of Bearing from Stribeck's Equation
Go
Verified Diameter of Ball of Bearing given Force required to produce Permanent Deformation in Ball
Go
Verified Force required to produce Permanent Deformation of Balls of Ball Bearing
Go
Verified Force required to produce Permanent Deformation of Balls of Ball Bearing given Static Load
Go
Verified K Factor for Ball Bearing from Stribeck's Equation
Go
Verified K Factor for Ball Bearing given Force required to produce Permanent Deformation of Balls
Go
Verified Number of Balls of Ball Bearing from Stribeck's Equation
Go
Verified Number of Balls of Ball Bearing given Angle between Balls
Go
Verified Number of Balls of Ball Bearing given Static Load
Go
Verified Static Load on Ball of Ball Bearing from Stribeck's Equation
Go
Verified Static Load on Ball of Ball Bearing given Primary force
Go
Verified Energy in Electron Volts
Go
Verified Energy of Electron
Go
Verified Kinetic Energy in Electron Volts
Go
Verified Kinetic Energy of Electron
Go
Verified Total Energy in Electron Volts
Go
Verified Velocity of Particle
Go
Verified Wave Number of Moving Particle
Go
Verified Wavelength of Moving Particle
Go
Verified Wavelength using Energy
Go
21 More Structure of Atom Calculators
Go
Verified Residual Sum of Squares
Go
Verified Residual Sum of Squares given Residual Standard Error
Go
Verified Sum of Squares
Go
Verified Angular Frequency of Spring
Go
Verified Axial Deflection of Spring due to Axial load given Stiffness of Spring
Go
Verified Axial Spring Force given Stiffness of Spring
Go
Verified Mass of Spring
Go
Verified Mass of Spring given Natural angular frequency of Spring
Go
Verified Mass of Spring given Natural angular frequency of Spring whose one end is free
Go
Verified Natural angular frequency of Spring whose one end is free
Go
Verified Shear stress in spring
Go
Verified Solid Length of Spring
Go
Verified Stiffness of Spring given Natural angular frequency of Spring
Go
Verified Stiffness of Spring given Natural angular frequency of Spring whose one end is free
Go
1 More Surge in Springs Calculators
Go
Verified Number of Edges in Control Complexity
Go
3 More System Design Calculators
Go
Created A Parameter In Terms Of G Parameters
Go
Created A Parameter In Terms Of T' Parameters
Go
Created A-Inverse Parameter (A'B'C'D'-Parameter)
Go
Created A-Parameter (ABCD Parameter)
Go
Created A-Parameter in Terms of Voltage 1 (ABCD Parameter)
Go
Created B Inverse Parameter (A'B'C'D'-Parameter)
Go
Created B Parameter (ABCD Parameter)
Go
Created B Parameter given Voltage 1 (ABCD Parameter)
Go
Created B Parameter in Terms of G Parameters
Go
Created B Parameter in Terms of Z Parameters
Go
Created C Parameter (ABCD Parameter)
Go
Created C Parameter in Terms of Y Parameters
Go
Created C Parameter in Terms of Z Parameters
Go
Created Current 1 (ABCD Parameter)
Go
Created Current 2 given Voltage 1 (ABCD Parameter)
Go
Created Voltage 1 (ABCD Parameter)
Go
Created Voltage 1 given A Parameter (ABCD Parameter)
Go
Created Voltage 2 given Current 1 (ABCD Parameter)
Go
Created Voltage-1 given A' Parameter (A'B'C'D'-Parameter)
Go
Verified Availability
Go
Verified Average Holding Time
Go
Verified Average Number of Call
Go
Verified Average Occupancy
Go
Verified Average Poisson Call Arrival Rate
Go
Verified Call Setup Time
Go
Verified Cost Capacity Index
Go
Verified Cost of Common Hardware
Go
Verified Cost of Switching System
Go
Verified Cost per Subscriber
Go
Verified Downtime
Go
Verified Grade of Service
Go
Verified Number of Lost Call
Go
Verified Poisson Arrival
Go
Verified Quantization Error
Go
Verified Switching Capacity
Go
Verified Time Required for Functions other than Switching
Go
Verified Total Number of Offered Calls
Go
Verified Traffic Handling Capability
Go
Verified Trunk Occupancy
Go
Verified Unavailability of System
Go
Verified Uptime
Go
Verified Temperature of Gas given Average Speed of Gas
Go
Verified Temperature of Gas given Equipartition energy
Go
Verified Temperature of Gas given Most Probable Speed of Gas
Go
Verified Temperature of Gas given RMS Velocity of Gas
Go
Verified Temperature of Gas using Equipartition Energy for Molecule
Go
6 More Temperature Calculators
Go
Verified Area of thermal contact
Go
Verified Heat Transfer Coefficient
Go
Verified Thermal time constant
Go
Verified Maximum temperature in secondary deformation zone
Go
19 More Temperature Rise Calculators
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Verified Stefan Boltzmann Law
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16 More Thermal Parameters Calculators
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Verified Thickness of each Leaf given Bending Stress in Plate
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Verified Thickness of each Leaf given Bending Stress in Plate Extra Full Length
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Verified Thickness of Each Leaf given Bending Stress on Graduated Length Leaves
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Verified Thickness of Each Leaf given Deflection
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Verified Thickness of each Leaf given Deflection at Load Point for Graduated length leaves
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Verified Thickness of plate 1 given Length of Rivet Shank
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Verified Thickness of Plate 2 given Length of Rivet Shank
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Verified Thickness of Plate given Tensile Resistance of Plate between two Rivets
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Verified Thickness of Plates given Crushing Resistance
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2 More Thickness of Plates Calculators
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Verified Thickness of Strip given Bending Stress induced at outer end of Spring
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Verified Thickness of Strip given Deflection of one end of Spring with respect to other end
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Verified Thickness of Strip given Strain Energy Stored in Strip
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Verified Thickness of Strip when Angle of Rotation of Arbor with Respect to Drum
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Created Potential Difference between A-Phase (Three Conductor Open)
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Created Potential Difference between B-Phase (Three Conductor Open)
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Created Potential Difference between C-Phase (Three Conductor Open)
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Created Zero Sequence Potential Differences (Three Conductor Open)
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Verified RMS Output Voltage for Resistive Load
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4 More Three Phase Half Wave Converters Calculators
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Created Time Constant for RC Circuit
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Created Time Constant for RL Circuit
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1 More Time Constant Calculators
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Verified Titration of Sodium Carbonate with Sodium Bicarbonate after first end point for Methyl Orange
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Verified Titration of Sodium Carbonate with Sodium Bicarbonate after First End Point phenolphthalein
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Verified Titration of Sodium Carbonate with Sodium Bicarbonate after Second End Point for Methyl Orange
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Verified Titration of Sodium Carbonate with Sodium Bicarbonate after Second End Point phenolphthalein
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Verified Titration of Sodium Hydroxide and Sodium Carbonate Methyl Orange
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Verified Titration of Sodium Hydroxide and Sodium Carbonate Phenolphthalein
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Verified Titration of Sodium Hydroxide with Sodium Bicarbonate after First End Point Methyl Orange
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Verified Titration of Sodium Hydroxide with Sodium Carbonate after Second End Point Methyl Orange
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Verified Titration of Sodium Hydroxide with Sodium Carbonate after Second End Point using Phenolphthalein
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Created Gross Torque Developed per Phase
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Created Maximum Running Torque
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Created Starting Torque of Induction Motor
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Created Torque of Induction Motor under Running Condition
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2 More Torque and Efficiency Calculators
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Verified Coefficient of Friction for Screw Thread given Efficiency of Square Threaded Screw
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Verified Coefficient of Friction of Power Screw given Torque Required to Lift Load
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Verified Effort Required in Lifting load using Power Screw
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Verified Effort Required to Lift Load given Torque Required to Lift Load
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Verified Load on Power Screw given Effort Required to Lift Load
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Verified Load on Power Screw given Torque Required to Lift Load
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Verified Torque Required to Lift Load given Effort
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9 More Torque Requirement in Lifting Load using Square Threaded Screw Calculators
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Verified Angle of Twist of Shaft
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Verified Length of Shaft Subjected to Torsional Moment given Angle of Twist
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Verified Modulus of Rigidity given Angle of Twist
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Verified Torsional Moment given Angle of Twist in Shaft
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1 More Torsional Rigidity Calculators
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Verified Body Effect on Transconductance
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Verified Drain Current using Transconductance
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Verified MOSFET Transconductance Parameter using Process Transconductance
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Verified Process Transconductance Parameter of MOSFET
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Verified Transconductance in MOSFET
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11 More Transconductance Calculators
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Verified Body Transconductance
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Verified Transconductance using Collector Current
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2 More Transconductance Calculators
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Verified Area of Detector
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Verified Capacitance of Amplifier
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Verified Capacitance of Cable
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Verified Capacitance of Transducer
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Verified Change in Irradiation
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Verified Change in Resistance
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Verified Current Generator Capacitance
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Verified Detectivity
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Verified Detectivity of Transducer
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Verified Efficiency of transducer
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Verified Input Signal of Transducer
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Verified Noise Equivalent of Bandwidth
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Verified Normalized Detectivity
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Verified Output Signal of Transducer
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Verified Responsivity of Detector
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Verified Responsivity of Transducer
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Verified Rise in Temperature
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Verified RMS Incident Power of Detector
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Verified RMS Noise Voltage of Cell
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Verified RMS output Voltage Detector
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Verified Sensitivity of LVDT
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Verified Sensitivity of Photoresistive Transducer
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Verified Size of Output Signal
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Verified Temperature Difference
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Created Transformation Ratio given Equivalent Reactance from Primary Side
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Created Transformation Ratio given Equivalent Reactance from Secondary Side
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Created Transformation Ratio given Equivalent Resistance from Primary Side
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Created Transformation Ratio given Equivalent Resistance from Secondary Side
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Created Transformation Ratio given Primary and Secondary Current
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Created Transformation Ratio given Primary and Secondary Induced Voltage
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Created Transformation Ratio given Primary and Secondary Number of Turns
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Created Transformation Ratio given Primary and Secondary Voltage
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Created Transformation Ratio given Primary Leakage Reactance
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Created Transformation Ratio given Secondary Leakage Reactance
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Created Area of Core given EMF Induced in Primary Winding
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Created Area of Core given EMF Induced in Secondary Winding
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Created Maximum Flux in Core using Primary Winding
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Created Maximum Flux in Core using Secondary Winding
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Created Number of Turns in Primary Winding
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Created Number of Turns in Secondary Winding
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13 More Transformer Design Calculators
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Created Delta Impedance using Star Impedance
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Created Leakage Impedance for Transformer given Positive Sequence Voltage
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Created Leakage Impedance for Transformer given Zero Sequence Current
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Created Negative Sequence Impedance for Transformer
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Created Neutral Impedance for Star Connected Load using Zero Sequence Voltage
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Created Positive Sequence Impedance for Transformer
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Created Star Impedance using Delta Impedance
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Created Zero Sequence Impedance for Transformer
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Created Characteristic Impedance (Line SC)
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Created Characteristic Impedance using Reflected Coefficient of Current
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Created Characteristic Impedance using Reflected Coefficient of Voltage
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Created Characteristic Impedance using Transmitted Coefficient of Voltage
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Created Characteristic Impedance using Transmitted Current
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Created Characteristic Impedance using Transmitted Voltage
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Created Impedance-3 using Transmitted Current-3 (Line PL)
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Created Incident Current for Incident Wave
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Created Incident Current using Reflected and Transmitted Current
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Created Incident Voltage of Incident Wave
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Created Incident Voltage using Reflected and Transmitted Voltage
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Created Incident Voltage using Reflected Voltage
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Created Incident Voltage using Transmitted Coefficient of Current-2 (Line PL)
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Created Incident Voltage using Transmitted Voltage (Load OC)
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Created Load Impedance for Transmitted Waves
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Created Load Impedance using Reflected Coefficient of Current
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Created Load Impedance using Reflected Coefficient of Voltage
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Created Load Impedance using Reflected Current
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Created Load Impedance using Transmitted Voltage
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Created Reflected Coefficient of Voltage (Line PL)
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Created Reflected Current for Refracted Wave
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Created Reflected Current using Reflection Coefficient of Current
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Created Reflected Voltage (Line OC)
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Created Reflected Voltage (Load SC)
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Created Reflected Voltage for Refracted Wave
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Created Reflected Voltage using Incident and Transmitted Voltage
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Created Reflected Voltage using Load Impedance
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Created Reflected Voltage using Reflection Coefficient of Voltage
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Created Reflection Coefficient for Current
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Created Reflection Coefficient for Voltage
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Created Reflection Coefficient of Voltage using Reflection Coefficient of Current
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Created Transmission Coefficient for Current
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Created Transmission Coefficient for Voltage
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Created Transmitted Current Transmitted Wave
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Created Transmitted Current using Transmission Coefficient of Current
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Created Transmitted Voltage using Incident and Reflected Voltage
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3 More Transient Calculators
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Verified Amplifier Input of Transistor Amplifier
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Verified Current Entering Drain Terminal of MOSFET at Saturation
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Verified Current Flowing through Induced Channel in Transistor given Oxide Voltage
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Verified DC Current Gain of Amplifier
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Verified Drain Current of Transistor
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Verified Input Resistance of Common-Collector Amplifier
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Verified Input Resistance of Common-Gate Circuit
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Verified Overall Effective Voltage of MOSFET Transconductance
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Verified Test Current of Transistor Amplifier
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Verified Transconductance Parameter of MOS Transistor
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8 More Transistor Amplifier Characteristics Calculators
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Verified Collector Current
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Verified Common Emitter Current Gain
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Verified Transistor Base Current
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Created Alpha Parameter of Transistor
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Created Alpha Parameter of Transistor given Beta
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Created Base Current of Transistor given Beta
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Created Beta Parameter of Transistor
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Created Beta Parameter of Transistor given Base Current
Go
Created Collector Current of Transistor using Alpha
Go
Created Collector Current of Transistor using Beta
Go
Created Current in Transistor
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Created Emitter Current of Transistor using Alpha
Go
Created Transconductance
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Created Incident Current using Transmission Coefficient of Current
Go
Created Incident Voltage using Transmission Coefficient of Voltage
Go
Created Transmitted Voltage using Transmission Coefficient of Voltage
Go
Created Transmitted Coefficient of Current-2 (Line PL)
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Created Transmitted Coefficient of Current-2 using Impedance-1 and 2 (Line PL)
Go
Created Transmitted Coefficient of Current-2 using Transmitted Coefficient of Voltage (Line PL)
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Created Transmitted Coefficient of Current-2 using Transmitted Voltage (Line PL)
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Created Transmitted Coefficient of Current-3 (Line PL)
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Created Transmitted Coefficient of Current-3 using Impedance-1 and 3 (Line PL)
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Created Transmitted Coefficient of Current-3 using Transmitted Coefficient of Voltage (Line PL)
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Created Transmitted Coefficient of Current-3 using Transmitted Voltage (Line PL)
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Created Transmitted Current-1 (Line PL)
Go
Created Transmitted Current-2 (Line PL)
Go
Created Transmitted Current-2 using Reflected Current (Line PL)
Go
Created Transmitted Current-2 using Transmitted Coefficient of Current-2 (Line PL)
Go
Created Transmitted Current-2 using Transmitted Voltage (Line PL)
Go
Created Transmitted Current-3 (Line PL)
Go
Created Transmitted Current-3 using Reflected Current (Line PL)
Go
Created Transmitted Current-3 using Transmitted Coefficient of Current-3 (Line PL)
Go
Created Transmitted Current-3 using Transmitted Voltage (Line PL)
Go
Created Incident Current using Transmitted Current
Go
Created Incident Voltage using Transmitted Voltage
Go
Created Load Impedance using Transmitted Current
Go
Created Transmitted Current using Incident and Reflected Current
Go
Created Transmitted Current using Incident Current
Go
Created Transmitted Voltage Transmitted Wave
Go
Created Transmitted Voltage using Incident Current
Go
Verified Allowable Load per mm Length of Transverse Fillet Weld
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Verified Force Acting given Shear Stress-induced in Plane that is Inclined at angle theta
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Verified Leg of Weld given Maximum Shear Stress-induced in Plane
Go
Verified Leg of Weld given Shear Stress-induced in Plane
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Verified Length of Weld given Maximum Shear Stress-induced in Plane
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Verified Length of Weld given Shear Stress-induced in Plane that is inclined at Angle theta
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Verified Maximum Shear Stress-induced in Plane that is Inclined at Angle theta
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Verified Shear Stress-Induced in Plane that is inclined at Angle theta to Horizontal
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8 More Transverse Fillet Weld Calculators
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Verified Coefficient of Friction of Power Screw given Efficiency of Trapezoidal Threaded Screw
Go
Verified Coefficient of Friction of Screw given Efficiency of Trapezoidal Threaded Screw
Go
Verified Coefficient of Friction of Screw given Effort in Lowering Load
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Verified Coefficient of Friction of Screw given Torque Required in Lifting Load with Trapezoidal Thread
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Verified Coefficient of Friction of Screw given Torque Required in Lowering Load with Trapezoidal Thread
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Verified Efficiency of Trapezoidal Threaded Screw
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Verified Effort Required in Lowering Load with Trapezoidal Threaded Screw
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Verified Helix Angle of Screw given Effort Required in Lowering Load with Trapezoidal Threaded Screw
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Verified Helix Angle of Screw given Torque Required in Lifting Load with Trapezoidal Threaded Screw
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Verified Helix Angle of Screw given Torque Required in Lowering Load with Trapezoidal Threaded Screw
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Verified Load on Screw given helix Angle
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Verified Load on Screw given Torque Required in Lifting Load with Trapezoidal Threaded Screw
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Verified Load on Screw given Torque Required in Lowering Load with Trapezoidal Threaded Screw
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Verified Mean Diameter of Screw given Torque in Lifting Load with Trapezoidal Threaded Screw
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Verified Mean Diameter of Screw given Torque in Lowering Load with Trapezoidal Threaded Screw
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Verified Torque Required in Lowering Load with Trapezoidal Threaded Screw
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5 More Trapezoidal Thread Calculators
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Created A-Phase Current (Two Conductor Open)
Go
Created A-Phase EMF using Positive Sequence Current (Two Conductor Open)
Go
Created A-Phase EMF using Positive Sequence Voltage (Two Conductor Open)
Go
Created Potential Difference between B-Phase (Two Conductor Open)
Go
Created Potential Difference between C-Phase (Two Conductor Open)
Go
1 More Two Conductor Open Calculators
Go
Verified Variance in Uniform Distribution
Go
2 More Uniform Distribution Calculators
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Verified Angle of Wrap of V-Belt given Belt Tension in Loose Side of Belt
Go
Verified Belt Tension in Loose Side of V-Belt
Go
Verified Belt Tension in Tight Side of V-Belt
Go
Verified Belt Velocity of V-Belt given Belt Tension in Loose Side
Go
Verified Coefficient of Friction in V-Belt given Belt Tension in Loose Side of Belt
Go
Verified Correcting Factor for Belt Length given Number of Belts Required
Go
Verified Correction Factor for Arc of Contact given Number of Belts Required
Go
Verified Correction Factor for Industrial Services given Number of Belts Required
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Verified Effective Pull in V-Belt
Go
Verified Mass of One Meter Length of V-Belt given Belt Tension in Loose Side
Go
Verified Number of V Belts Required for Given Applications
Go
Verified Variance given Standard Deviation
Go
Verified Variance of Scalar Multiple of Random Variable
Go
3 More Variance Calculators
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Verified Boundary area being moved
Go
Verified Distance between boundaries
Go
Verified Dynamic viscosity
Go
Verified Resisting Motion in fluid
Go
Verified Shear Stress in Viscosity
Go
Verified Velocity of Moving Boundaries
Go
Verified Body Effect Coefficient
Go
Verified Channel Charge
Go
Verified Critical Voltage
Go
Verified DIBL Coefficient
Go
Verified Gate Capacitance
Go
Verified Gate Length using Gate Oxide Capacitance
Go
Verified Gate Oxide Capacitance
Go
Verified Intrinsic Gate Capacitance
Go
Verified Junction Current
Go
Verified K-Prime
Go
Verified Mobility in Mosfet
Go
Verified Subthreshold Slope
Go
Verified Surface Potential
Go
Verified Threshold Voltage
Go
Verified Threshold Voltage when Source is at Body Potential
Go
Verified Total Source Parasitic Capacitance
Go
23 More VLSI Material Optimization Calculators
Go
Created Line to Neutral Voltage using Reactive Power
Go
Created Line to Neutral Voltage using Real Power
Go
Created RMS Voltage using Reactive Power
Go
Created RMS Voltage using Real Power
Go
Created Voltage using Complex Power
Go
Created Voltage using Power Factor
Go
Created Voltage using Reactive Power
Go
Created Voltage using Real Power
Go
Created Armature Induced Voltage of Series DC motor given Voltage
Go
Created Input Power of Series DC Motor
Go
Created Voltage Equation of Series DC Motor
Go
Created Voltage of Series DC Motor given Input Power
Go
Verified Conductance of Channel of MOSFET using Gate to Source Voltage
Go
Verified Overdrive Voltage
Go
Verified Overdrive Voltage when MOSFET Acts as Amplifier with Load Resistance
Go
Verified Positive Voltage given Device Parameter in MOSFET
Go
Verified Saturation Voltage of MOSFET
Go
Verified Treshold Voltage of MOSFET
Go
Verified Voltage across Gate and Source of MOSFET on Operation with Differential Input Voltage
Go
Verified Voltage at Drain Q2 in MOSFET
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12 More Voltage Calculators
Go
Created Receiving End Voltage using Impedance (STL)
Go
Created Receiving End Voltage using Receiving End Power (STL)
Go
Created Receiving End Voltage using Transmission Efficiency (STL)
Go
Created Sending End Voltage in Transmission Line
Go
Created Sending End Voltage using Power Factor(STL)
Go
Created Sending End Voltage using Sending End Power (STL)
Go
Created Sending End Voltage using Transmission Efficiency (STL)
Go
Created Transmitted Inductance (SC Line)
Go
Verified Collector to Emitter Voltage at Saturation
Go
Verified Small Signal Input Voltage given Transconductance
Go
Verified Voltage across Collector-Emitter of BJT Amplifier
Go
Verified Voltage between Gate and Source
Go
8 More Voltage Calculators
Go
Created Terminal Voltage for DC Shunt Generator
Go
1 More Voltage and EMF Calculators
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Created Induced EMF given Linear Synchronous Speed
Go
Created Induced Voltage given Power
Go
Created EMF Induced in Primary Winding
Go
Created EMF Induced in Primary Winding given Input Voltage
Go
Created EMF Induced in Primary Winding given Voltage Transformation Ratio
Go
Created EMF Induced in Secondary Winding
Go
Created EMF Induced in Secondary Winding given Voltage Transformation Ratio
Go
Created Input Voltage when EMF Induced in Primary Winding
Go
Created Output Voltage given EMF Induced in Secondary Winding
Go
Created Primary Voltage given Voltage Transformation Ratio
Go
Created Secondary Voltage given Voltage Transformation Ratio
Go
Created Self-Induced EMF in Primary Side
Go
Created Self-Induced EMF in Secondary Side
Go
1 More Voltage and EMF Calculators
Go
Created Armature Induced Voltage of Series DC Generator
Go
Created Terminal Voltage of Series DC Generator
Go
Created Terminal Voltage of Series DC Generator given Output Power
Go
Created Voltage of Shunt DC Motor
Go
Created Voltage of Shunt DC Motor given Shunt Field Current
Go
Created Back EMF of Synchronous Motor given Armature Winding Constant
Go
Created Back EMF of Synchronous Motor using Mechanical Power
Go
Created Load Voltage of Synchronous Motor given 3 Phase Mechanical Power
Go
Created Load Voltage of Synchronous Motor using 3 Phase Input Power
Go
Created Voltage Equation of Synchronous Motor
Go
Created Voltage of Synchronous Motor given Input Power
Go
Created A-Phase EMF using Negative Sequence Current (LGF)
Go
Created A-Phase EMF using Positive Sequence Current(LGF)
Go
Created A-Phase EMF using Positive Sequence Voltage (LGF)
Go
Created A-Phase EMF using Zero Sequence Current (LGF)
Go
Created A-Phase Voltage(LGF)
Go
Created Negative Sequence Voltage for LGF
Go
Created Negative Sequence Voltage using A-Phase Current (LGF)
Go
Created Positive Sequence Voltage for L-G-F
Go
Created Positive Sequence Voltage using Positive Sequence Current
Go
Created Zero Sequence Voltage for LGF
Go
Created Zero Sequence Voltage using A-Phase Current (LGF)
Go
Created Zero Sequence Voltage using Positive Sequence Current
Go
4 More Voltage and EMF Calculators
Go
Created B-Phase Voltage (LLF)
Go
Created B-Phase Voltage using C-Phase Current (LLF)
Go
Created C-Phase Voltage (LLF)
Go
Created C-Phase Voltage using C-Phase Current (LLF)
Go
Created Negative Sequence Voltage (LLF)
Go
Created Positive Sequence Voltage (LLF)
Go
7 More Voltage and EMF Calculators
Go
Created A-Phase EMF using Positive Sequence Voltage (LLGF)
Go
Created A-Phase Voltage using Zero Sequence Voltage (LLGF)
Go
Created B-Phase Voltage using Fault Current (LLGF)
Go
Created B-Phase Voltage using Zero Sequence Current (LLGF)
Go
Created B-Phase Voltage using Zero-Sequence Voltage (LLGF)
Go
Created C-Phase Voltage using Fault Current (LLGF)
Go
Created C-Phase Voltage using Zero Sequence Current (LLGF)
Go
Created Negative Sequence Voltage using Negative Sequence Current (LLGF)
Go
Created Positive Sequence Voltage using Fault Impedance (LLGF)
Go
Created Zero Sequence Voltage using A-Phase Voltage (LLGF)
Go
Created Zero Sequence Voltage using B-Phase Voltage (LLGF)
Go
Created Zero Sequence Voltage using Fault Impedance (LLGF)
Go
3 More Voltage and EMF Calculators
Go
Verified Input Resistance with Feedback of Feedback Voltage Amplifier Given Loop Gain
Go
Verified Output Resistance with Feedback Voltage Amplifier
Go
Verified Output Voltage of Feedback Voltage Amplifier
Go
2 More Voltage Feedback Amplifiers Calculators
Go
Verified Additional Capacitance
Go
Verified Capacitance of Voltmeter
Go
Verified Range of Voltmeter
Go
Verified Self-Capacitance of Coil
Go
Verified Voltage across Capacitance
Go
Verified Voltage across Capacitance while Charging
Go
Verified Voltmeter current
Go
Verified Voltmeter Resistance
Go
Verified Volts per Division
Go
8 More Voltmeter Specifications Calculators
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Verified Current in pressure coil circuit
Go
Verified Resistance of coil S1
Go
Verified Resistance of Watt-meter pressure Coil
Go
Verified Total copper loss in secondary winding circuit
Go
Verified Voltage applied to wattmeter pressure coil
Go
Verified Voltage Induced in S2
Go
Verified Wattmeter Reading
Go
8 More Wattmeter Circuit Calculators
Go
Verified Antenna Beamwidth
Go
15 More Wave Propagation Calculators
Go
Verified Bending Moment given Bending Stress
Go
Verified Bending Stress Caused Due to Bending Moment
Go
Verified Bending Stress given Resultant Shear Stress in Weld
Go
Verified Distance of Point in Weld from Neutral Axis given Bending Stress in Weld
Go
Verified Moment of Inertia of all Welds given Bending Moment
Go
Verified Primary Shear Stress given Resultant Shear Stress
Go
Verified Primary Shear Stress-induced due to Eccentric Load
Go
Verified Resultant Shear Stress in Weld
Go
Verified Polar Moment of Inertia of Thickened Hollow Welded Shaft
Go
Verified Radius of Shaft given Torsional Shear Stress in Weld
Go
Verified Thickness of Shaft given Torsional Shear Stress in Weld
Go
Verified Torsional Moment given Torsional Shear Stress in Weld
Go
Verified Torsional Shear Stress in Weld
Go
2 More Welded Joints Subjected to Torsional Moment Calculators
Go
Verified Width of Each Leaf given Bending Stress in Plate
Go
Verified Width of Each Leaf given Bending Stress in Plate Extra Full Length
Go
Verified Width of Each Leaf given Bending Stress on Graduated Length Leaves
Go
Verified Width of Each Leaf given Deflection at Load Point Graduated Length Leaves
Go
Verified Width of Strip given Angle of Rotation of Arbor with Respect to Drum
Go
Verified Width of Strip given Bending Stress induced at uuter end of Spring
Go
Verified Width of Strip given Deflection of one End of Spring
Go
Verified Width of Strip given Deflection of one End of Spring with Respect to Other End
Go
Verified Width of Strip given Strain Energy Stored in Spring
Go
Created Area of X-Section using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Area of X-Section using Resistance(Two-Wire One Conductor Earthed)
Go
Created Area of X-Section using Volume(Two-Wire One Conductor Earthed)
Go
Created Area of X-Section(Two-Wire One Conductor Earthed)
Go
Created K(Two-Wire One Conductor Earthed)
Go
Created Length of Line using Area of X-Section(Two-Wire One Conductor Earthed)
Go
Created Length of Line using Line Losses(Two-Wire One Conductor Earthed)
Go
Created Length of Wire using K(Two-Wire One Conductor Earthed)
Go
Created Length of Wire using Resistance(Two-Wire One Conductor Earthed)
Go
Created Line Losses using Area of X-section(Two-Wire One Conductor Earthed)
Go
Created Line Losses using K(Two-Wire One Conductor Earthed)
Go
Created Line Losses(Two-Wire One Conductor Earthed)
Go
Created Volume of Conductor Material(Two-Wire One Conductor Earthed)
Go
Created Volume using K(Two-Wire One Conductor Earthed)
Go
Created Area of X-Section using Line Losses(Two-Wire Mid-Point Earthed)
Go
Created Area of X-Section using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
Go
Created Area of X-Section(Two-Wire Mid-Point Earthed)
Go
Created Constant using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
Go
Created Constant(Two-Wire Mid-Point Earthed)
Go
Created Length of Wire using Line Losses(Two-Wire Mid-Point Earthed)
Go
Created Length using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
Go
Created Line Losses using Volume of Conductor Material(2-Wire Mid-Point Earthed OS)
Go
Created Line Losses(Two-Wire Mid-Point Earthed)
Go
Created Volume of Conductor Material(Two-Wire Mid-Point Earthed)
Go
Created Volume using K(Two-Wire Mid-Point Earthed)
Go
Created Area of X-Section using Line Losses(DC 3-Wire)
Go
Created Area of X-Section using Volume of Conductor Material (DC 3-Wire)
Go
Created Area of X-Section(DC 3-Wire)
Go
Created Constant using Volume of Conductor Material (DC 3-Wire)
Go
Created Constant(DC 3-Wire)
Go
Created Length using Area of X-Section(DC 3-Wire)
Go
Created Length using Constant(DC 3-Wire)
Go
Created Length using Line Losses(DC 3-Wire)
Go
Created Length using Volume of Conductor Material (DC 3-Wire)
Go
Created Line Losses using Area of X-Section(DC 3-Wire)
Go
Created Line Losses using Constant(DC 3-Wire)
Go
Created Line Losses using Volume of Conductor Material (DC 3-Wire)
Go
Created Line Losses(DC 3-Wire)
Go
Created Volume of Conductor Material (DC 3-Wire)
Go
Created Volume of Conductor Material using Area of X-Section(DC 3-Wire)
Go
Created Volume of Conductor Material using Constant(DC 3-Wire)
Go
Created Area of X-Section using Line Losses (Single-Phase Two-Wire OS)
Go
Created Area of X-Section using Load Current (Single-Phase Two-Wire OS)
Go
Created Area of X-Section(Single-Phase Two-Wire OS)
Go
Created Constant using Line Losses (Single-Phase Two-Wire OS)
Go
Created Constant using Load Current (Single-Phase Two-Wire OS)
Go
Created Constant(Single-Phase Two-Wire OS)
Go
Created Length of Wire using Area of X-Section(Single-Phase Two-Wire OS)
Go
Created Length using Line Losses (Single-Phase Two-Wire OS)
Go
Created Length using Load Current (Single-Phase Two-Wire OS)
Go
Created Line Losses using Area of X-Section(Single-Phase Two-Wire OS)
Go
Created Line Losses using Load Current (Single-Phase Two-Wire OS)
Go
Created Line Losses(Single-Phase Two-Wire OS)
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Created Volume of Conductor Material using Line Losses (Single-Phase Two-Wire OS)
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Created Volume of Conductor Material using Load Current (Single-Phase Two-Wire OS)
Go
Created Volume of Conductor Material(Single-Phase Two-Wire OS)
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Created Area of X-Section using Line Losses (Single Phase Two Wire Mid-Point OS)
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Created Area of X-Section using Load Current (Single Phase Two Wire Mid-Point OS)
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Created Area of X-Section(Single Phase Two Wire Mid-Point Earthed)
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Created Constant (Single Phase Two Wire Mid-Point Earthed)
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Created Constant using Line Losses (Single Phase Two Wire Mid-Point OS)
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Created Constant using Load Current (Single Phase Two Wire Mid-Point OS)
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Created Length of Wire using Area of X-Section(Single Phase Two Wire Mid-Point Earthed OS)
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Created Length using Load Current (Single Phase Two-Wire Mid-Point OS)
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Created Line Losses using Area of X-Section(Single Phase Two Wire Mid-Point Earthed OS)
Go
Created Line Losses using Load Current (Single Phase Two Wire Mid-Point OS)
Go
Created Volume of Conductor Material using Line Losses (Single Phase Two Wire Mid-Point OS)
Go
Created Volume of Conductor Material using Load Current (Single Phase Two Wire Mid-Point OS)
Go
Created Area of X-Section using Line Losses (Single-Phase Three-Wire OS)
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Created Area of X-Section using Load Current (Single-Phase Three-Wire OS)
Go
Created Area of X-section using Volume of Conductor Material (Single-Phase Three-Wire OS)
Go
Created Area of X-Section(Single-Phase Three-Wire OS)
Go
Created Constant using Line Losses (Single-Phase Three-Wire OS)
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Created Constant using Load Current (Single-Phase Three-Wire OS)
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Created Constant using Volume of Conductor Material (Single-Phase Three-Wire OS)
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Created Constant(Single-Phase Three-Wire OS)
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Created Length of Wire using Area of X-Section(Single-Phase Three-Wire OS)
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Created Length using Line Losses (Single-Phase Three-Wire OS)
Go
Created Length using Load Current (Single-Phase Three-Wire OS)
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Created Length using Volume of Conductor Material (Single-Phase Three-Wire OS)
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Created Line Losses using Area of X-Section(Single-Phase Three-Wire OS)
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Created Line Losses using Load Current (Single-Phase Three-Wire OS)
Go
Created Line Losses using Volume of Conductor Material (Single-Phase Three-Wire OS)
Go
Created Line Losses(Single-Phase Three-Wire OS)
Go
Created Volume of Conductor Material using Line Losses (Single-Phase Three-Wire OS)
Go
Created Volume of Conductor Material using Load Current (Single-Phase Three-Wire OS)
Go
Created Volume of Conductor Material(Single-Phase Three-Wire OS)
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Created Area of X-Section using Line Losses (2-Phase 4-Wire OS)
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Created Area of X-Section using Load Current (2-Phase 4-Wire OS)
Go
Created Area of X-Section(2-Phase 4-Wire OS)
Go
Created Constant using Line Losses (2-Phase 4-Wire OS)
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Created Constant using Load Current (2-Phase 4-Wire OS)
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Created Constant(2-Phase 4-Wire OS)
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Created Length of Wire using Area of X-Section(2-Phase 4-Wire OS)
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Created Length using Line Losses (2-Phase 4-Wire OS)
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Created Length using Load Current (2-Phase 4-Wire OS)
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Created Line Losses using Area of X-Section(2-Phase 4-Wire OS)
Go
Created Line Losses using Load Current (2-Phase 4-Wire OS)
Go
Created Line Losses(2-Phase 4-Wire OS)
Go
Created Volume of Conductor Material using Area of X-Section(2-Phase 4-Wire OS)
Go
Created Volume of Conductor Material using Line Losses (2-Phase 4-Wire OS)
Go
Created Volume of Conductor Material using Load Current (2-Phase 4-Wire OS)
Go
Created Volume of Conductor Material(2-Phase 4-Wire OS)
Go
Created Area of X-Section using Resistance (3-Phase 4-Wire OS)
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Created Area of X-section using Volume of Conductor Material (3-Phase 4-Wire OS)
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Created Area of X-Section(3-Phase 4-Wire OS)
Go
Created Constant using Volume of Conductor Material (3-Phase 4-Wire OS)
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Created Constant(3-Phase 4-Wire OS)
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Created Length of Wire using Area of X-Section(3-Phase 4-Wire OS)
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Created Length of Wire using Resistance (3-Phase 4-Wire OS)
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Created Length using Volume of Conductor Material (3-Phase 4-Wire OS)
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Created Line Losses using Area of X-Section(3-Phase 4-Wire OS)
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Created Line Losses using Volume of Conductor Material (3-Phase 4-Wire OS)
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Created Line Losses(3-Phase 4-Wire OS)
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Created Volume of Conductor Material using Constant(3-Phase 4-Wire OS)
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Created Volume of Conductor Material(3-Phase 4-Wire OS)
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Created Area of X-Section(3-Phase 3-Wire OS)
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Created Constant(3-Phase 3-Wire OS)
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Created Length of Wire using Area of X-Section(3-Phase 3-Wire OS)
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Created Line Losses using Area of X-Section(3-Phase 3-Wire OS)
Go
Created Line Losses(3-Phase 3-Wire OS)
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Created Volume of Conductor Material(3-Phase 3-Wire OS)
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Created Area of X-Section using Line Losses (Two-Phase Three-Wire OS)
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Created Area of X-Section using Resistance (Two-Phase Three-Wire OS)
Go
Created Area of X-Section using Volume of Conductor Material (Two-Phase Three-Wire OS)
Go
Created Area of X-Section(Two-Phase Three-Wire OS)
Go
Created Constant using Volume of Conductor Material (Two-Phase Three-Wire OS)
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Created Constant(Two-Phase Three-Wire OS)
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Created Length of Wire using Area of X-Section(Two-Phase Three-Wire OS)
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Created Length of Wire using Resistance (Two-Phase Three-Wire OS)
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Created Length using Line Losses (Two-Phase Three-Wire OS)
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Created Length using Volume of Conductor Material (Two-Phase Three-Wire OS)
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Created Line Losses using Area of X-Section(Two-Phase Three-Wire OS)
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Created Line Losses using Volume of Conductor Material (Two-Phase Three-Wire OS)
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Created Line Losses(Two-Phase Three-Wire OS)
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Created Volume of Conductor Material using Area of X-Section(Two-Phase Three-Wire OS)
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Created Volume of Conductor Material(Two-Phase Three-Wire OS)
Go
Created Area of X-Section (1-Phase 2-Wire US)
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Created Area of X-Section using Constant (1-Phase 2-Wire US)
Go
Created Area of X-Section using Line Losses (1-Phase 2-Wire US)
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Created Area of X-Section using Load Current (1-Phase 2-Wire US)
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Created Area of X-Section using Resistance (1-Phase 2-Wire US)
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Created Area of X-Section using Volume of Conductor Material (1-Phase 2-Wire US)
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Created Constant (1-Phase 2-Wire US)
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Created Constant using Area of X-Section (1-Phase 2-Wire US)
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Created Constant using Line Losses (1-Phase 2-Wire US)
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Created Constant using Load Current (1-Phase 2-Wire US)
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Created Constant using Resistance (1-Phase 2-Wire US)
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Created Constant using Volume of Conductor Material (1-Phase 2-Wire US)
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Created Length of Wire using Constant (1-Phase 2-Wire US)
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Created Length using Area of X-Section (1-Phase 2-Wire US)
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Created Length using Line Losses (1-Phase 2-Wire US)
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Created Length using Load Current (1-Phase 2-Wire US)
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Created Length using Resistance (1-Phase 2-Wire US)
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Created Length using Volume of Conductor Material (1-Phase 2-Wire US)
Go
Created Voltage of Conductor Material (1-Phase 2-Wire US)
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Created Volume of Conductor Material using Area of X-Section (1-Phase 2-Wire US)
Go
Created Volume of Conductor Material using Constant (1-Phase 2-Wire US)
Go
Created Volume of Conductor Material using Line Losses (1-Phase 2-Wire US)
Go
Created Volume of Conductor Material using Load Current (1-Phase 2-Wire US)
Go
Created Angle using Area of X-Section (3 Phase 4 Wire US)
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Created Angle using Line Losses (3 Phase 4 Wire US)
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Created Angle using Load Current (3 Phase 4 Wire US)
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Created Area of X-Section (3 Phase 4 Wire US)
Go
Created Area of X-Section using Volume of Conductor Material (3 Phase 4 Wire US)
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Created Area using Line Losses (3 Phase 4 Wire US)
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Created Constant using Volume of Conductor Material (3 Phase 4 Wire US)
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Created Length using Area of X-Section (3 Phase 4 Wire US)
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Created Length using Line Losses (3 Phase 4 Wire US)
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Created Line Losses (3 Phase 4 Wire US)
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Created Line Losses using Area of X-Section (3 Phase 4 Wire US)
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Created Line Losses using Load Current (3 Phase 4 Wire US)
Go
Created Line Losses using Volume of Conductor Material (3 Phase 4 Wire US)
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Created Volume of Conductor Material (3 Phase 4 Wire US)
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Created Volume of Conductor Material using Load Current (3 Phase 4 Wire US)
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Created Volume of Conductor Material when Area and Length is Given(3 Phase 4 Wire US)
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Created Volume of Conductor Material when K is Given(3 Phase 4 Wire US)
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Created Volume of Conductor Material when Resistance is Given(3 Phase 4 Wire US)
Go
Created Area of X Section using Volume of Conductor Material (3 Phase 3 Wire US)
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Created Constant using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Line Losses (3 Phase 3 Wire US)
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Created Line Losses using Volume of Conductor Material (3 Phase 3 Wire US)
Go
Created Volume of Conductor Material (3 Phase 3 Wire US)
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Created Volume of Conductor Material when Area and Length is Given(3 Phase 3 Wire US)
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Created Volume of Conductor Material when K is Given(3 Phase 3 Wire US)
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Created Volume of Conductor Material when Load Current is Given(3 Phase 3 Wire US)
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Created Volume of Conductor Material when Resistance is Given(3 Phase 3 Wire US)
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Created Angle of Pf using Line Losses (2-Phase 3-Wire US)
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Created Angle of PF using Volume of Conductor Material (2 Phase 3 Wire US)
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Created Angle using Current in Each Outer (2-Phase 3-Wire US)
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Created Angle using Current in Neutral Wire (2-Phase 3-Wire US)
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Created Area of X Section using Volume of Conductor Material (2 Phase 3 Wire US)
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Created Area of X-Section using Line Losses (2-Phase 3-Wire US)
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Created Area using Resistance of Natural Wire (2-Phase 3-Wire US)
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Created Constant using Volume of Conductor Material (2 Phase 3 Wire US)
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Created Length using Line Losses (2-Phase 3-Wire US)
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Created Length using Resistance of Natural Wire (2-Phase 3-Wire US)
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Created Length using Volume of Conductor Material (2 Phase 3 Wire US)
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Created Line Losses using Volume of Conductor Material (2 Phase 3 Wire US)
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Created Volume of Conductor Material (2 Phase 3 Wire US)
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Created Volume of Conductor Material using Area and Length(2 Phase 3 Wire US)
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Created Volume of Conductor Material using Constant(2 Phase 3 Wire US)
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Created Volume of Conductor Material using Load Current (2 Phase 3 Wire US)
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Created Volume of Conductor Material using Resistance (2 Phase 3 Wire US)
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Created Area of X-Section (DC Three-Wire US)
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Created Area of X-section using Volume of Conductor Material(DC Three-Wire US)
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Created Constant using Volume of Conductor Material(DC Three-Wire US)
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Created Length using Area of X-Section (DC Three-Wire US)
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Created Length using Line Losses (DC Three-Wire US)
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Created Length using Volume of Conductor Material(DC Three-Wire US)
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Created Line Losses (DC Three-Wire US)
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Created Line Losses using Area of X-Section (DC Three-Wire US)
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Created Line Losses using Resistance (DC Three-Wire US)
Go
Created Line Losses using Volume of Conductor Material(DC Three-Wire US)
Go
Created Volume of Conductor Material (DC Three-Wire US)
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Created Volume of Conductor Material using Area and Length(DC Three-Wire US)
Go
Created Volume of Conductor Material using Constant(DC Three-Wire US)
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Created Volume of Conductor Material using Load Current (DC Three-Wire US)
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Created Volume of Conductor Material using Resistance (DC Three-Wire US)
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Created Angle of PF using Volume of Conductor Material(1 Phase 3 Wire US)
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Created Angle using Area of X Section (1 Phase 3 Wire US)
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Created Area of X-Section using Line Losses (1 Phase 3 Wire US)
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Created Constant using Volume of Conductor Material(1 Phase 3 Wire US)
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Created Length using Area of X Section (1 Phase 3 Wire US)
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Created Length using Line Losses (1 Phase 3 Wire US)
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Created Length using Volume of Conductor Material(1 Phase 3 Wire US)
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Created Line Losses using Area of X Section (1 Phase 3 Wire US)
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Created Line Losses using Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Volume of Conductor Material using Area and Length (1 Phase 3 Wire US)
Go
Created Volume of Conductor Material using Constant(1 Phase 3 Wire US)
Go
Created Volume of Conductor Material using Load Current(1 Phase 3 Wire US)
Go
Created Volume of Conductor Material using Resistance (1 Phase 3 Wire US)
Go
Created Volume of Conductor Material(1 Phase 3 Wire US)
Go
Created Angle using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Angle using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
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Created Area using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Area using Volume of Conductor Material (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Length using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Length using Line Losses (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Length using Volume of Conductor Material (1-Phase 2-Wire Mid-Point Earthed)
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Created Line Losses using Area of X-Section (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Volume of Conductor Material (1-Phase 2-Wire Mid-Point Earthed)
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Created Volume of Conductor Material using Area and Length(1-Phase 2-Wire Mid-Point US)
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Created Volume of Conductor Material using Constant(1-Phase 2-Wire Mid-Point Earthed)
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Created Volume of Conductor Material using Load Current (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Volume of Conductor Material using Resistance (1-Phase 2-Wire Mid-Point Earthed)
Go
Created Area using Line Losses (2 Phase 4 Wire US)
Go
Created Area using Volume of Conductor Material (2 Phase 4 Wire US)
Go
Created Length using Area of X-Section (2 Phase 4 Wire US)
Go
Created Length using Line Losses (2 Phase 4 Wire US)
Go
Created Length using Volume of Conductor Material (2 Phase 4 Wire US)
Go
Created Line Losses (2 Phase 4 Wire US)
Go
Created Line Losses using Area of X-Section (2 Phase 4 Wire US)
Go
Created Line Losses using Load Current (2 Phase 4 Wire US)
Go
Created Line Losses using Volume of Conductor Material (2 Phase 4 Wire US)
Go
Created Volume of Conductor Material (2 Phase 4 Wire US)
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Created Volume of Conductor Material Main(2 Phase 4 Wire US)
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Created Volume of Conductor Material using Constant(2 Phase 4 Wire US)
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Created Volume of Conductor Material using Load Current (2 Phase 4 Wire US)
Go
Created Volume of Conductor Material using Load Current(2 Phase 4 Wire US)
Go
Created Area using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Length using Area of X-Section (2-Wire Mid-Point Earthed DC US)
Go
Created Length using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Line Losses using Area of X-Section (2-Wire Mid-Point Earthed DC US)
Go
Created Line Losses using Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Volume of Conductor Material (2-Wire Mid-Point DC US)
Go
Created Volume of Conductor Material using Area and Length (2-Wire Mid-Point DC US)
Go
Created Volume of Conductor Material using Load Current (2-Wire Mid-Point DC US)
Go
Created Volume of Conductor Material using Resistance (2-Wire Mid-Point DC US)
Go
Created Area of X-Section (DC Two-Wire US)
Go
Created Length using Area of X-Section (DC Two-Wire US)
Go
Created Length using Line Losses (DC Two-Wire US)
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Created Line Losses (DC Two-Wire US)
Go
Created Line Losses using Area of X-Section(DC Two-Wire US)
Go
Created Line Losses using Resistance (DC Two-Wire US)
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Created Volume of Conductor Material (DC Two-Wire US)
Go
Created Volume of Conductor Material using Area and Length(DC Two-Wire US)
Go
Created Volume of Conductor Material using Load Current (DC Two-Wire US)
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Created Volume of Conductor Material using Resistance (DC Two-Wire US)
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Created Current 1 (Y Parameter)
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Created Current 1 given Y11 Parameter (Y Parameter)
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Created Current 1 given Y12 Parameter (Y Parameter)
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Created Current 2 (Y Parameter)
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Created Current 2 given Y21 Parameter (Y Parameter)
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Created Current 2 given Y22 Parameter (Y Parameter)
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Created Driving Point Input Admittance (Y11)
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Created Driving Point Output Admittance (Y22)
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Created Input Transfer Admittance (Y12)
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Created Output Transfer Admittance (Y21)
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Created Y11 Parameter in Terms of G Parameters
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Created Y11 Parameter in Terms of H Parameters
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Created Y11 Parameter in Terms of T Parameters
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Created Y11 Parameter in Terms of Z Parameters
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Created Y12 Parameter in Terms of H Parameters
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Created Y12 Parameter in Terms of Z Parameters
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Created Y21 Parameter in Terms of T Parameters
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Created Y21 Parameter in Terms of Z Parameters
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Created Y22 Parameter in Terms of T Parameters
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Created Y22 Parameter in Terms of Z Parameters
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Created Current 1 given Voltage 1 (Z Parameter)
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Created Current 1 given Z11 Parameter (Z Parameter)
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Created Current 1 given Z21 Parameter (Z Parameter)
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Created Current 2 given Voltage 1 (Z Parameter)
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Created Current 2 given Voltage 2 (Z Parameter)
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Created Current 2 given Z22 Parameter (Z Parameter)
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Created Driving Point Input Impedance (Z11)
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Created Driving Point Output Impedance (Z22)
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Created Input Transfer Impedance (Z12)
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Created Output Transfer Impedance (Z21)
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Created Voltage 1 (Z Parameter)
Go
Created Voltage 2 (Z Parameter)
Go
Created Z11 Parameter given Voltage 1 (Z Parameter)
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Created Z11 Parameter in Terms of G Parameters
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Created Z11 Parameter in Terms of H Parameters
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Created Z11 Parameter in Terms of T Parameters
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Created Z11 Parameter in Terms of Y Parameters
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Created Z12 Parameter given Voltage 1 (Z Parameter)
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Created Z12 Parameter in Terms of H Parameters
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Created Z12 Parameter in Terms of T' Parameters
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Created Z21 Parameter given Voltage 2 (Z Parameter)
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Created Z21 Parameter in Terms of G Parameters
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Created Z22 Parameter given Voltage 2 (Z Parameter)
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Created Zero Sequence Current (One Conductor Open)
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Created Zero Sequence Current using Zero Sequence Voltage (One Conductor Open)
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Created Zero Sequence Impedance using Zero Sequence Voltage (One Conductor Open)
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Created Zero Sequence Voltage using Zero Sequence Impedance (One Conductor Open)
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Created Zero Sequence Current using Zero Sequence Voltage (Two Conductor Open)
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Created Zero Sequence Impedance using Zero Sequence Voltage (Two Conductor Open)
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Created Zero Sequence Potential Difference (Two Conductor Open)
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Created Zero Sequence Potential Difference using Potential Difference between B-Phase(Two Conductor Open)
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Created Zero Sequence Voltage using Zero Sequence Current (Two Conductor Open)
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1 More Zero Sequence Calculators
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Created Delta H given A Parameter
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Created Delta H given B Parameter
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Created Delta H given B' Parameter
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Created Delta H given Delta T'
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Created Delta H given Delta Y
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Created Delta H given Delta Z
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Created Delta H given G21 Parameter
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Created Delta H given Y22 Parameter
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Created Delta H given Z11 Parameter
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Created Delta T given A' Parameter
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Created Delta T given B' Parameter
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Created Delta T given C' Parameter
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Created Delta T given D' Parameter
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Created Delta T given Delta G
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Created Delta T given Delta H
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Created Delta T given Delta Y
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Created Delta T given Delta Z
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Created Delta T' given A Parameter
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Created Delta T' given Delta G
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Created Delta T' given Delta H
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Created Delta T' given Delta Z
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Created Delta Y given A Parameter
Go
Created Delta Y given Delta H
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Created Delta Y given Delta T
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Created Delta Y given G11 Parameter
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Created Delta Y given G12 Parameter
Go
Created Delta Z given A Parameter
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Created Delta Z given A' Parameter
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Created Delta Z given D Parameter
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Created Delta Z given Delta H Parameter
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Created Delta Z given Delta T' Parameter
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