✖Magnetic Flux is a measure of the total magnetic field passing through a surface.ⓘ Magnetic Flux [Φ]			+10% -10%
✖Reluctance is a measure of the opposition that a material or a magnetic circuit offers to the establishment of a magnetic flux.ⓘ Reluctance [R]			+10% -10%

✖Magnetomotive Voltage describes the potential difference or voltage associated with the generation of a magnetic field within a coil or magnetic circuit.ⓘ Magnetomotive Force given Reluctance and Magnetic Flux [V_m]

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Magnetomotive Force given Reluctance and Magnetic Flux

Formula

`"V"_{"m"} = "Φ"*"R"`

Example

`"400AT"="20000Wb"*"0.02AT/Wb"`

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Magnetomotive Force given Reluctance and Magnetic Flux Solution

STEP 0: Pre-Calculation Summary

Formula Used

Magnetomotive Voltage = Magnetic Flux*Reluctance
V_m = Φ*R
This formula uses 3 Variables

Variables Used

Magnetomotive Voltage - (Measured in Ampere-Turn) - Magnetomotive Voltage describes the potential difference or voltage associated with the generation of a magnetic field within a coil or magnetic circuit.
Magnetic Flux - (Measured in Weber) - Magnetic Flux is a measure of the total magnetic field passing through a surface.
Reluctance - (Measured in Ampere-Turn per Weber) - Reluctance is a measure of the opposition that a material or a magnetic circuit offers to the establishment of a magnetic flux.

STEP 1: Convert Input(s) to Base Unit

Magnetic Flux: 20000 Weber --> 20000 Weber No Conversion Required
Reluctance: 0.02 Ampere-Turn per Weber --> 0.02 Ampere-Turn per Weber No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

V_m = Φ*R --> 20000*0.02

Evaluating ... ...

V_m = 400

STEP 3: Convert Result to Output's Unit

400 Ampere-Turn --> No Conversion Required

FINAL ANSWER

400 Ampere-Turn <-- Magnetomotive Voltage

(Calculation completed in 00.004 seconds)

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< 21 Electrowave Dynamics Calculators

Magnetic Force by Lorentz Force Equation

Go Magnetic Force = Charge of Particle*(Electric Field+(Speed of Charged Particle*Magnetic Flux Density*sin(Incidence Angle)))

Characteristic Impedance of Line

Go Characteristic Impedance = sqrt(Magnetic Permeability*pi*10^-7/Dielectric Permitivitty)*(Plate Distance/Plate Width)

Total Resistance of Coaxial Cable

Go Total Resistance of Coaxial Cable = 1/(2*pi*Skin Depth*Electrical Conductivity)*(1/Inner Radius of Coaxial Cable+1/Outer Radius of Coaxial Cable)

Inductance per unit Length of Coaxial Cable

Go Inductance per unit Length of Coaxial Cable = Magnetic Permeability/2*pi*ln(Outer Radius of Coaxial Cable/Inner Radius of Coaxial Cable)

Conductance of Coaxial Cable

Go Conductance of Coaxial Cable = (2*pi*Electrical Conductivity)/ln(Outer Radius of Coaxial Cable/Inner Radius of Coaxial Cable)

Radian Cutoff Angular Frequency

Go Cutoff Angular Frequency = (Mode Number*pi*[c])/(Refractive Index*Plate Distance)

Inner Resistance of Coaxial Cable

Go Inner Resistance of Coaxial Cable = 1/(2*pi*Inner Radius of Coaxial Cable*Skin Depth*Electrical Conductivity)

Outer Resistance of Coaxial Cable

Go Outer Resistance of Coaxial Cable = 1/(2*pi*Skin Depth*Outer Radius of Coaxial Cable*Electrical Conductivity)

Resistance of Cylindrical Conductor

Go Resistance of Cylindrical Conductor = Length of Cylindrical Conductor/(Electrical Conductivity*Cross Sectional Area of Cylindrical)

Inductance between Conductors

Go Conductor Inductance = Magnetic Permeability*pi*10^-7*Plate Distance/(Plate Width)

Magnitude of Wavevector

Go Wave Vector = Angular Frequency*sqrt(Magnetic Permeability*Dielectric Permitivitty)

Magnetization using Magnetic Field Strength, and Magnetic Flux Density

Go Magnetization = (Magnetic Flux Density/[Permeability-vacuum])-Magnetic Field Strength

Magnetic Flux Density using Magnetic Field Strength, and Magnetization

Go Magnetic Flux Density = [Permeability-vacuum]*(Magnetic Field Strength+Magnetization)

Skin Effect Resistivity

Go Skin Effect Resistivity = 2/(Electrical Conductivity*Skin Depth*Plate Width)

Cutoff Wavelength

Go Cutoff Wavelength = (2*Refractive Index*Plate Distance)/Mode Number

Absolute Permeability using Relative Permeability and Permeability of Free Space

Go Absolute Permeability of Material = Relative Permeability of Material*[Permeability-vacuum]

Phase Velocity in Microstrip Line

Go Phase Velocity = [c]/sqrt(Dielectric Permitivitty)

Free Space Magnetic Flux Density

Go Free Space Magnetic Flux Density = [Permeability-vacuum]*Magnetic Field Strength

Internal Inductance of Long Straight Wire

Go Internal Inductance of Long Straight Wire = Magnetic Permeability/(8*pi)

Magnetomotive Force given Reluctance and Magnetic Flux

Go Magnetomotive Voltage = Magnetic Flux*Reluctance

Magnetic Susceptibility using Relative Permeability

Go Magnetic Susceptibility = Magnetic Permeability-1

Magnetomotive Force given Reluctance and Magnetic Flux Formula

Magnetomotive Voltage = Magnetic Flux*Reluctance
V_m = Φ*R

What is the significance reluctance as the ratio of the magnetomotive force to the total flux ?

In the field of electromagnetic engineering, resistance—which is the magnetomotive force ratio—is extremely important. This ratio offers important insights into the behavior of materials and circuits inside the magnetic domain. It functions as the magnetic circuit counterpart of Ohm's Law.

Reluctance's main significance comes from its capacity to measure the resistance that a substance or circuit offers to the creation of a magnetic field. Reluctance, which is similar to electrical resistance in that it represents resistance to the flow of magnetic flux, is an important consideration in the design and optimization of magnetic circuits. Reluctance is a crucial factor that we consider when carefully designing electromagnetic devices, such as transformers and inductors.

How to Calculate Magnetomotive Force given Reluctance and Magnetic Flux?

Magnetomotive Force given Reluctance and Magnetic Flux calculator uses Magnetomotive Voltage = Magnetic Flux*Reluctance to calculate the Magnetomotive Voltage, Magnetomotive Force given Reluctance and Magnetic Flux formula indicates how much magnetomotive force is required to establish a certain amount of magnetic flux in a magnetic circuit. Magnetomotive Voltage is denoted by V_m symbol.

How to calculate Magnetomotive Force given Reluctance and Magnetic Flux using this online calculator? To use this online calculator for Magnetomotive Force given Reluctance and Magnetic Flux, enter Magnetic Flux (Φ) & Reluctance (R) and hit the calculate button. Here is how the Magnetomotive Force given Reluctance and Magnetic Flux calculation can be explained with given input values -> 400 = 20000*0.02.

FAQ

What is Magnetomotive Force given Reluctance and Magnetic Flux?

Magnetomotive Force given Reluctance and Magnetic Flux formula indicates how much magnetomotive force is required to establish a certain amount of magnetic flux in a magnetic circuit and is represented as V_m = Φ*R or Magnetomotive Voltage = Magnetic Flux*Reluctance. Magnetic Flux is a measure of the total magnetic field passing through a surface & Reluctance is a measure of the opposition that a material or a magnetic circuit offers to the establishment of a magnetic flux.

How to calculate Magnetomotive Force given Reluctance and Magnetic Flux?

Magnetomotive Force given Reluctance and Magnetic Flux formula indicates how much magnetomotive force is required to establish a certain amount of magnetic flux in a magnetic circuit is calculated using Magnetomotive Voltage = Magnetic Flux*Reluctance. To calculate Magnetomotive Force given Reluctance and Magnetic Flux, you need Magnetic Flux (Φ) & Reluctance (R). With our tool, you need to enter the respective value for Magnetic Flux & Reluctance 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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