Resistance at Second Temperature Solution

STEP 0: Pre-Calculation Summary
Formula Used
Final Resistance = Initial Resistance*((Temperature Coefficient+Final Temperature)/(Temperature Coefficient+Initial Temperature))
R2 = R1*((T+Tf)/(T+To))
This formula uses 5 Variables
Variables Used
Final Resistance - (Measured in Ohm) - The final resistance is crucial in achieving impedance matching and minimizing signal reflections. Final resistance is a measure of the opposition to current flow in an electrical circuit.
Initial Resistance - (Measured in Ohm) - Initial resistance in a transmission line refers to the resistance component present in the line at its starting point or input end.
Temperature Coefficient - (Measured in Kelvin) - Temperature coefficient, is the change in electrical resistance of a substance with respect to per degree change in temperature. It's constants depend upon the particular conductor material.
Final Temperature - (Measured in Kelvin) - The final temperature reached by a transmission line or an antenna depends on the balance between the power dissipated and the heat dissipation capabilities.
Initial Temperature - (Measured in Kelvin) - The initial temperature in a transmission line and antenna can vary depending on various factors such as environmental conditions, power levels, and the specific design of the equipment.
STEP 1: Convert Input(s) to Base Unit
Initial Resistance: 3.99 Ohm --> 3.99 Ohm No Conversion Required
Temperature Coefficient: 243 Kelvin --> 243 Kelvin No Conversion Required
Final Temperature: 27 Kelvin --> 27 Kelvin No Conversion Required
Initial Temperature: 200 Kelvin --> 200 Kelvin No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
R2 = R1*((T+Tf)/(T+To)) --> 3.99*((243+27)/(243+200))
Evaluating ... ...
R2 = 2.43182844243792
STEP 3: Convert Result to Output's Unit
2.43182844243792 Ohm --> No Conversion Required
FINAL ANSWER
2.43182844243792 2.431828 Ohm <-- Final Resistance
(Calculation completed in 00.020 seconds)

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Created by Vidyashree V
BMS College of Engineering (BMSCE), Bangalore
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Verified by Saiju Shah
Jayawantrao Sawant College of Engineering (JSCOE), Pune
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Resistance at Second Temperature
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Resistance at Second Temperature Formula

​LaTeX ​Go
Final Resistance = Initial Resistance*((Temperature Coefficient+Final Temperature)/(Temperature Coefficient+Initial Temperature))
R2 = R1*((T+Tf)/(T+To))

How does resistance vary with respect to temperature?

The resistivity of any conductive material varies linearly over an operating temperature, and therefore, the resistance of any conductor suffers the same variations. As temperature rises, the conductor
resistance increases linearly, over normal operating temperatures.

How to Calculate Resistance at Second Temperature?

Resistance at Second Temperature calculator uses Final Resistance = Initial Resistance*((Temperature Coefficient+Final Temperature)/(Temperature Coefficient+Initial Temperature)) to calculate the Final Resistance, The Resistance at Second Temperature formula is defined as the changes in the resistivity of any conductive material which varies linearly over an operating temperature, and therefore, the resistance of any conductor suffers the same variations. As temperature rises, the conductor resistance increases linearly, over normal operating temperatures, according to the mentioned formula. Final Resistance is denoted by R2 symbol.

How to calculate Resistance at Second Temperature using this online calculator? To use this online calculator for Resistance at Second Temperature, enter Initial Resistance (R1), Temperature Coefficient (T), Final Temperature (Tf) & Initial Temperature (To) and hit the calculate button. Here is how the Resistance at Second Temperature calculation can be explained with given input values -> 2.437923 = 3.99*((243+27)/(243+200)).

FAQ

What is Resistance at Second Temperature?
The Resistance at Second Temperature formula is defined as the changes in the resistivity of any conductive material which varies linearly over an operating temperature, and therefore, the resistance of any conductor suffers the same variations. As temperature rises, the conductor resistance increases linearly, over normal operating temperatures, according to the mentioned formula and is represented as R2 = R1*((T+Tf)/(T+To)) or Final Resistance = Initial Resistance*((Temperature Coefficient+Final Temperature)/(Temperature Coefficient+Initial Temperature)). Initial resistance in a transmission line refers to the resistance component present in the line at its starting point or input end, Temperature coefficient, is the change in electrical resistance of a substance with respect to per degree change in temperature. It's constants depend upon the particular conductor material, The final temperature reached by a transmission line or an antenna depends on the balance between the power dissipated and the heat dissipation capabilities & The initial temperature in a transmission line and antenna can vary depending on various factors such as environmental conditions, power levels, and the specific design of the equipment.
How to calculate Resistance at Second Temperature?
The Resistance at Second Temperature formula is defined as the changes in the resistivity of any conductive material which varies linearly over an operating temperature, and therefore, the resistance of any conductor suffers the same variations. As temperature rises, the conductor resistance increases linearly, over normal operating temperatures, according to the mentioned formula is calculated using Final Resistance = Initial Resistance*((Temperature Coefficient+Final Temperature)/(Temperature Coefficient+Initial Temperature)). To calculate Resistance at Second Temperature, you need Initial Resistance (R1), Temperature Coefficient (T), Final Temperature (Tf) & Initial Temperature (To). With our tool, you need to enter the respective value for Initial Resistance, Temperature Coefficient, Final Temperature & Initial Temperature and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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