Maximum Power Gain of Microwave Transistor Calculator

✖Transit Time Cutoff Frequency is related as the time taken for charge carriers (electrons or holes) to transit through the device.ⓘ Transit Time Cutoff Frequency [f_TC]			+10% -10%
✖Power Gain Frequency refers to the frequency at which the power gain of the device begins to decrease.ⓘ Power Gain Frequency [f]			+10% -10%
✖Output Impedance refers to the impedance, or resistance, that a device or circuit presents to the external load connected to its output.ⓘ Output Impedance [Z_out]			+10% -10%
✖Input Impedence is the equivalent impedance or resistance that a device or circuit presents at its input terminals when a signal is applied.ⓘ Input Impedence [Z_in]			+10% -10%

✖Maximum Power Gain of a Microwave Transistor is the frequency at which the transistor operates optimally.ⓘ Maximum Power Gain of Microwave Transistor [G_max]

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Formula

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Maximum Power Gain of Microwave Transistor

Formula

`"G"_{"max"} = ("f"_{"TC"}/"f")^2*"Z"_{"out"}/"Z"_{"in"}`

Example

`"3.4E^-5"=("2.08Hz"/"80Hz")^2*"0.27Ω"/"5.4Ω"`

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Maximum Power Gain of Microwave Transistor Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum Power Gain of a Microwave Transistor = (Transit Time Cutoff Frequency/Power Gain Frequency)^2*Output Impedance/Input Impedence
G_max = (f_TC/f)^2*Z_out/Z_in
This formula uses 5 Variables

Variables Used

Maximum Power Gain of a Microwave Transistor - Maximum Power Gain of a Microwave Transistor is the frequency at which the transistor operates optimally.
Transit Time Cutoff Frequency - (Measured in Hertz) - Transit Time Cutoff Frequency is related as the time taken for charge carriers (electrons or holes) to transit through the device.
Power Gain Frequency - (Measured in Hertz) - Power Gain Frequency refers to the frequency at which the power gain of the device begins to decrease.
Output Impedance - (Measured in Ohm) - Output Impedance refers to the impedance, or resistance, that a device or circuit presents to the external load connected to its output.
Input Impedence - (Measured in Ohm) - Input Impedence is the equivalent impedance or resistance that a device or circuit presents at its input terminals when a signal is applied.

STEP 1: Convert Input(s) to Base Unit

Transit Time Cutoff Frequency: 2.08 Hertz --> 2.08 Hertz No Conversion Required
Power Gain Frequency: 80 Hertz --> 80 Hertz No Conversion Required
Output Impedance: 0.27 Ohm --> 0.27 Ohm No Conversion Required
Input Impedence: 5.4 Ohm --> 5.4 Ohm No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

G_max = (f_TC/f)^2*Z_out/Z_in --> (2.08/80)^2*0.27/5.4

Evaluating ... ...

G_max = 3.38E-05

STEP 3: Convert Result to Output's Unit

3.38E-05 --> No Conversion Required

FINAL ANSWER

3.38E-05 ≈ 3.4E-5 <-- Maximum Power Gain of a Microwave Transistor

(Calculation completed in 00.020 seconds)

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Maximum Power Gain of Microwave Transistor Formula

Maximum Power Gain of a Microwave Transistor = (Transit Time Cutoff Frequency/Power Gain Frequency)^2*Output Impedance/Input Impedence
G_max = (f_TC/f)^2*Z_out/Z_in

How is the maximum power gain represented graphically?

The maximum power gain is typically depicted on a graph of power gain versus frequency. The frequency at which the power gain peaks corresponds to the maximum power gain.

How to Calculate Maximum Power Gain of Microwave Transistor?

Maximum Power Gain of Microwave Transistor calculator uses Maximum Power Gain of a Microwave Transistor = (Transit Time Cutoff Frequency/Power Gain Frequency)^2*Output Impedance/Input Impedence to calculate the Maximum Power Gain of a Microwave Transistor, The Maximum Power Gain of Microwave Transistor formula is defined as the frequency at which the transistor operates optimally. Maximum Power Gain of a Microwave Transistor is denoted by G_max symbol.

How to calculate Maximum Power Gain of Microwave Transistor using this online calculator? To use this online calculator for Maximum Power Gain of Microwave Transistor, enter Transit Time Cutoff Frequency (f_TC), Power Gain Frequency (f), Output Impedance (Z_out) & Input Impedence (Z_in) and hit the calculate button. Here is how the Maximum Power Gain of Microwave Transistor calculation can be explained with given input values -> 3.4E-5 = (2.08/80)^2*0.27/5.4.

FAQ

What is Maximum Power Gain of Microwave Transistor?

The Maximum Power Gain of Microwave Transistor formula is defined as the frequency at which the transistor operates optimally and is represented as G_max = (f_TC/f)^2*Z_out/Z_in or Maximum Power Gain of a Microwave Transistor = (Transit Time Cutoff Frequency/Power Gain Frequency)^2*Output Impedance/Input Impedence. Transit Time Cutoff Frequency is related as the time taken for charge carriers (electrons or holes) to transit through the device, Power Gain Frequency refers to the frequency at which the power gain of the device begins to decrease, Output Impedance refers to the impedance, or resistance, that a device or circuit presents to the external load connected to its output & Input Impedence is the equivalent impedance or resistance that a device or circuit presents at its input terminals when a signal is applied.

How to calculate Maximum Power Gain of Microwave Transistor?

The Maximum Power Gain of Microwave Transistor formula is defined as the frequency at which the transistor operates optimally is calculated using Maximum Power Gain of a Microwave Transistor = (Transit Time Cutoff Frequency/Power Gain Frequency)^2*Output Impedance/Input Impedence. To calculate Maximum Power Gain of Microwave Transistor, you need Transit Time Cutoff Frequency (f_TC), Power Gain Frequency (f), Output Impedance (Z_out) & Input Impedence (Z_in). With our tool, you need to enter the respective value for Transit Time Cutoff Frequency, Power Gain Frequency, Output Impedance & Input 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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