Power Gain of Tunnel Diode Calculator

✖Voltage Reflection Coefficient depends on the load impedance and the impedance of the transmission line or circuit it is connected to.ⓘ Voltage Reflection Coefficient [Γ]

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✖Power Gain of Tunnel Diode depends on the circuit configuration and the operating point of the diode.ⓘ Power Gain of Tunnel Diode [gain]

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Formula

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Power Gain of Tunnel Diode

Formula

`"gain" = "Γ"^2`

Example

`"0.0169dB"=("0.13")^2`

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Power Gain of Tunnel Diode Solution

STEP 0: Pre-Calculation Summary

Formula Used

Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2
gain = Γ^2
This formula uses 2 Variables

Variables Used

Power Gain of Tunnel Diode - (Measured in Decibel) - Power Gain of Tunnel Diode depends on the circuit configuration and the operating point of the diode.
Voltage Reflection Coefficient - Voltage Reflection Coefficient depends on the load impedance and the impedance of the transmission line or circuit it is connected to.

STEP 1: Convert Input(s) to Base Unit

Voltage Reflection Coefficient: 0.13 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

gain = Γ^2 --> 0.13^2

Evaluating ... ...

gain = 0.0169

STEP 3: Convert Result to Output's Unit

0.0169 Decibel --> No Conversion Required

FINAL ANSWER

0.0169 Decibel <-- Power Gain of Tunnel Diode

(Calculation completed in 00.004 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

Power Gain of Tunnel Diode Formula

Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2
gain = Γ^2

What is Tunnel Diode?

A tunnel diode (also known as a Esaki diode) is a type of semiconductor diode that has effectively “negative resistance” due to the quantum mechanical effect called tunneling. Tunnel diodes have a heavily doped pn junction that is about 10 nm wide.

How to Calculate Power Gain of Tunnel Diode?

Power Gain of Tunnel Diode calculator uses Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2 to calculate the Power Gain of Tunnel Diode, Power Gain of Tunnel Diode depends on the circuit configuration and the operating point of the diode. Generally, tunnel diodes are used in oscillator circuits or as negative resistance amplifiers. Power Gain of Tunnel Diode is denoted by gain symbol.

How to calculate Power Gain of Tunnel Diode using this online calculator? To use this online calculator for Power Gain of Tunnel Diode, enter Voltage Reflection Coefficient (Γ) and hit the calculate button. Here is how the Power Gain of Tunnel Diode calculation can be explained with given input values -> 0.0169 = 0.13^2.

FAQ

What is Power Gain of Tunnel Diode?

Power Gain of Tunnel Diode depends on the circuit configuration and the operating point of the diode. Generally, tunnel diodes are used in oscillator circuits or as negative resistance amplifiers and is represented as gain = Γ^2 or Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2. Voltage Reflection Coefficient depends on the load impedance and the impedance of the transmission line or circuit it is connected to.

How to calculate Power Gain of Tunnel Diode?

Power Gain of Tunnel Diode depends on the circuit configuration and the operating point of the diode. Generally, tunnel diodes are used in oscillator circuits or as negative resistance amplifiers is calculated using Power Gain of Tunnel Diode = Voltage Reflection Coefficient^2. To calculate Power Gain of Tunnel Diode, you need Voltage Reflection Coefficient (Γ). With our tool, you need to enter the respective value for Voltage Reflection Coefficient 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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