Maximum Applied Current across Diode Calculator

✖Maximum Applied Voltage across a diode is the highest voltage that can be applied to the diode without causing permanent damage or breakdown.ⓘ Maximum Applied Voltage [V_m]			+10% -10%
✖Reactive Impedence measure of the opposition that a circuit presents to a current when a voltage is applied.ⓘ Reactive Impedence [X_c]			+10% -10%

✖Maximum Applied Current is defined as the maximum value of the forward current that a PN junction or diode can carry without damaging the device.ⓘ Maximum Applied Current across Diode [I_m]

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Formula

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Maximum Applied Current across Diode

Formula

`"I"_{"m"} = "V"_{"m"}/"X"_{"c"}`

Example

`"0.014A"="77mV"/"5.5H"`

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Maximum Applied Current across Diode Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence
I_m = V_m/X_c
This formula uses 3 Variables

Variables Used

Maximum Applied Current - (Measured in Ampere) - Maximum Applied Current is defined as the maximum value of the forward current that a PN junction or diode can carry without damaging the device.
Maximum Applied Voltage - (Measured in Volt) - Maximum Applied Voltage across a diode is the highest voltage that can be applied to the diode without causing permanent damage or breakdown.
Reactive Impedence - (Measured in Henry) - Reactive Impedence measure of the opposition that a circuit presents to a current when a voltage is applied.

STEP 1: Convert Input(s) to Base Unit

Maximum Applied Voltage: 77 Millivolt --> 0.077 Volt (Check conversion here)
Reactive Impedence: 5.5 Henry --> 5.5 Henry No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

I_m = V_m/X_c --> 0.077/5.5

Evaluating ... ...

I_m = 0.014

STEP 3: Convert Result to Output's Unit

0.014 Ampere --> No Conversion Required

FINAL ANSWER

0.014 Ampere <-- Maximum Applied Current

(Calculation completed in 00.020 seconds)

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Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat

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< 16 Non Linear Circuits Calculators

Room Temperature

Go Ambient Temperature = (2*Diode Temperature*((1/(Coupling Coefficient*Q Factor))+(1/((Coupling Coefficient*Q Factor)^2) )))/(Noise Figure of Up-Converter-1)

Average Diode Temperature using Single Side Band Noise

Go Diode Temperature = (Noise Figure of Single Side Band-2)*((Output Resistance of Signal Generator*Ambient Temperature)/(2*Diode Resistance))

Noise Figure of Single Side Band

Go Noise Figure of Single Side Band = 2+((2*Diode Temperature*Diode Resistance)/(Output Resistance of Signal Generator*Ambient Temperature))

Noise Figure of Double Side Band

Go Noise Figure of Double Side Band = 1+((Diode Temperature*Diode Resistance)/(Output Resistance of Signal Generator*Ambient Temperature))

Voltage Reflection Coefficient of Tunnel Diode

Go Voltage Reflection Coefficient = (Impedance Tunnel Diode-Characteristic Impedance)/(Impedance Tunnel Diode+Characteristic Impedance)

Amplifier Gain of Tunnel Diode

Go Amplifier Gain of Tunnel Diode = Negative Resistance in Tunnel Diode/(Negative Resistance in Tunnel Diode-Load Resistance)

Ratio Negative Resistance to Series Resistance

Go Ratio Negative Resistance to Series Resistance = Equivalent Negative Resistance/Total Series Resistance at Idler Frequency

Tunnel Diode Output Power

Go Output Power of Tunnel Diode = (Voltage Tunnel Diode*Current Tunnel Diode)/(2*pi)

Bandwidth using Dynamic Quality Factor

Go Bandwidth = Dynamic Q-Factor/(Angular Frequency*Series Resistance of Diode)

Dynamic Q Factor

Go Dynamic Q-Factor = Bandwidth/(Angular Frequency*Series Resistance of Diode)

Maximum Applied Current across Diode

Go Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence

Reactive Impedence

Go Reactive Impedence = Maximum Applied Voltage/Maximum Applied Current

Maximum Applied Voltage across Diode

Go Maximum Applied Voltage = Maximum Electric Field*Depletion Length

Negative Conductance of Tunnel Diode

Go Negative Conductance Tunnel Diode = 1/(Negative Resistance in Tunnel Diode)

Magnitude of Negative Resistance

Go Negative Resistance in Tunnel Diode = 1/(Negative Conductance Tunnel Diode)

Power Gain of Tunnel Diode

Go Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2

Maximum Applied Current across Diode Formula

Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence
I_m = V_m/X_c

What is Power Frequency Voltage?

The ratio of breakdown voltage for any insulation or gap due to an impulse voltage of specified t1/t2 or shape to power frequency breakdown voltage is defined as impulse ratio.

How to Calculate Maximum Applied Current across Diode?

Maximum Applied Current across Diode calculator uses Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence to calculate the Maximum Applied Current, The Maximum Applied Current across Diodeice formula is defined as the Maximum value of the forward current that a PN junction or diode can carry without damaging the device. Maximum Applied Current is denoted by I_m symbol.

How to calculate Maximum Applied Current across Diode using this online calculator? To use this online calculator for Maximum Applied Current across Diode, enter Maximum Applied Voltage (V_m) & Reactive Impedence (X_c) and hit the calculate button. Here is how the Maximum Applied Current across Diode calculation can be explained with given input values -> 0.014 = 0.077/5.5.

FAQ

What is Maximum Applied Current across Diode?

The Maximum Applied Current across Diodeice formula is defined as the Maximum value of the forward current that a PN junction or diode can carry without damaging the device and is represented as I_m = V_m/X_c or Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence. Maximum Applied Voltage across a diode is the highest voltage that can be applied to the diode without causing permanent damage or breakdown & Reactive Impedence measure of the opposition that a circuit presents to a current when a voltage is applied.

How to calculate Maximum Applied Current across Diode?

The Maximum Applied Current across Diodeice formula is defined as the Maximum value of the forward current that a PN junction or diode can carry without damaging the device is calculated using Maximum Applied Current = Maximum Applied Voltage/Reactive Impedence. To calculate Maximum Applied Current across Diode, you need Maximum Applied Voltage (V_m) & Reactive Impedence (X_c). With our tool, you need to enter the respective value for Maximum Applied Voltage & Reactive Impedence 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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