🔍
🔍

Credits

Birsa Institute of Technology (BIT), Sindri
Payal Priya has created this Calculator and 500+ more calculators!
Vishwakarma Government Engineering College (VGEC), Ahmedabad
Urvi Rathod has verified this Calculator and 1000+ more calculators!

Maximum voltage gain at the bias point Solution

STEP 0: Pre-Calculation Summary
Formula Used
voltage_gain = (Supply Voltage-Output voltage)*2/modulus(Effective voltage or overdrive voltage)
Av = (Vi-Vo)*2/modulus(Vov)
This formula uses 2 Functions, 3 Variables
Functions Used
mod - Modulo function, mod(dividend, divisor)
modulus - Modulus of number, modulus
Variables Used
Supply Voltage - Supply Voltage is the input voltage source which flows through the zener diode. (Measured in Volt)
Output voltage - Output voltage signifies the voltage of the signal after it has been amplified. (Measured in Volt)
Effective voltage or overdrive voltage - Effective voltage or overdrive voltage is excess of voltage across oxide over thermal voltage is termed (Measured in Volt)
STEP 1: Convert Input(s) to Base Unit
Supply Voltage: 12 Volt --> 12 Volt No Conversion Required
Output voltage: 10 Volt --> 10 Volt No Conversion Required
Effective voltage or overdrive voltage: 250 Volt --> 250 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Av = (Vi-Vo)*2/modulus(Vov) --> (12-10)*2/modulus(250)
Evaluating ... ...
Av = 0.016
STEP 3: Convert Result to Output's Unit
0.016 Decibel --> No Conversion Required
0.016 Decibel <-- voltage gain
(Calculation completed in 00.016 seconds)

< 10+ Basic Principles Calculators

Voltage across gas oxide when MOSFET acts as an amplifier
voltage_across_the_oxide = Threshold voltage+((sqrt(2*MOSFET transconductance parameter*Load Resistance*Supply Voltage+1)-1))/MOSFET transconductance parameter*Load Resistance Go
Voltage across collector-emitter when MOSFET acts as an amplifier
voltage_across_collector_emitter = Supply Voltage-Load Resistance*Saturation current*e^(Voltage across the base–emitter junction/Threshold voltage) Go
Output voltage when MOSFET acts as an amplifier
output_voltage = Supply Voltage-1/2*MOSFET transconductance parameter*Load Resistance*(Voltage across the oxide-Threshold voltage)^2 Go
Output voltage when the transistor is biased
output_voltage = Supply Voltage-1/2*MOSFET transconductance parameter*Load Resistance*(Voltage across the oxide-Threshold voltage)^2 Go
Collector current in active region when transistor acts as an amplifier
collector_current = Saturation current*e^(Voltage across the base–emitter junction/Threshold voltage) Go
Drain current when transistor acts as an amplifier
drain_current = 1/2*MOSFET transconductance parameter*(Voltage across the oxide-Threshold voltage)^2 Go
Overdrive voltage when MOSFET acts as an amplifier
effective_voltage_or_overdrive_voltage = modulus(Voltage across the oxide)-Threshold voltage Go
Output Voltage of the voltage amplifier
output_voltage_of_amplifier = Supply Voltage-Drain current*Load Resistance Go
Output Voltage of BJT Amplifier
output_voltage = Supply Voltage-Drain current of BJT*Load Resistance Go
Bias voltage of the transistor
bias_voltage = Voltage across the oxide+Input voltage Go

Maximum voltage gain at the bias point Formula

voltage_gain = (Supply Voltage-Output voltage)*2/modulus(Effective voltage or overdrive voltage)
Av = (Vi-Vo)*2/modulus(Vov)

What is voltage gain?

The difference between the output signal voltage level in decibels and the input signal voltage level in decibels; this value is equal to 20 times the common logarithm of the ratio of the output voltage to the input voltage.

How to Calculate Maximum voltage gain at the bias point?

Maximum voltage gain at the bias point calculator uses voltage_gain = (Supply Voltage-Output voltage)*2/modulus(Effective voltage or overdrive voltage) to calculate the voltage gain, Maximum voltage gain at the bias point is the amount of voltage that an electronic device needs in order to power on and function. voltage gain and is denoted by Av symbol.

How to calculate Maximum voltage gain at the bias point using this online calculator? To use this online calculator for Maximum voltage gain at the bias point, enter Supply Voltage (Vi), Output voltage (Vo) and Effective voltage or overdrive voltage (Vov) and hit the calculate button. Here is how the Maximum voltage gain at the bias point calculation can be explained with given input values -> 0.016 = (12-10)*2/modulus(250).

FAQ

What is Maximum voltage gain at the bias point?
Maximum voltage gain at the bias point is the amount of voltage that an electronic device needs in order to power on and function and is represented as Av = (Vi-Vo)*2/modulus(Vov) or voltage_gain = (Supply Voltage-Output voltage)*2/modulus(Effective voltage or overdrive voltage). Supply Voltage is the input voltage source which flows through the zener diode, Output voltage signifies the voltage of the signal after it has been amplified and Effective voltage or overdrive voltage is excess of voltage across oxide over thermal voltage is termed.
How to calculate Maximum voltage gain at the bias point?
Maximum voltage gain at the bias point is the amount of voltage that an electronic device needs in order to power on and function is calculated using voltage_gain = (Supply Voltage-Output voltage)*2/modulus(Effective voltage or overdrive voltage). To calculate Maximum voltage gain at the bias point, you need Supply Voltage (Vi), Output voltage (Vo) and Effective voltage or overdrive voltage (Vov). With our tool, you need to enter the respective value for Supply Voltage, Output voltage and Effective voltage or overdrive voltage and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate voltage gain?
In this formula, voltage gain uses Supply Voltage, Output voltage and Effective voltage or overdrive voltage. We can use 10 other way(s) to calculate the same, which is/are as follows -
• collector_current = Saturation current*e^(Voltage across the base–emitter junction/Threshold voltage)
• output_voltage_of_amplifier = Supply Voltage-Drain current*Load Resistance
• output_voltage = Supply Voltage-Drain current of BJT*Load Resistance
• drain_current = 1/2*MOSFET transconductance parameter*(Voltage across the oxide-Threshold voltage)^2
• output_voltage = Supply Voltage-1/2*MOSFET transconductance parameter*Load Resistance*(Voltage across the oxide-Threshold voltage)^2
• voltage_across_the_oxide = Threshold voltage+((sqrt(2*MOSFET transconductance parameter*Load Resistance*Supply Voltage+1)-1))/MOSFET transconductance parameter*Load Resistance
• effective_voltage_or_overdrive_voltage = modulus(Voltage across the oxide)-Threshold voltage
• voltage_across_collector_emitter = Supply Voltage-Load Resistance*Saturation current*e^(Voltage across the base–emitter junction/Threshold voltage)
• output_voltage = Supply Voltage-1/2*MOSFET transconductance parameter*Load Resistance*(Voltage across the oxide-Threshold voltage)^2
• bias_voltage = Voltage across the oxide+Input voltage
Where is the Maximum voltage gain at the bias point calculator used?
Among many, Maximum voltage gain at the bias point calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
{FormulaExamplesList}
Let Others Know