Transconductance of MOS Differential Amplifier on Small-Signal Operation Solution

STEP 0: Pre-Calculation Summary
Formula Used
Transconductance = Total Current/Effective Voltage
gm = It/Vov
This formula uses 3 Variables
Variables Used
Transconductance - (Measured in Siemens) - Transconductance is the change in the drain current divided by the small change in the gate/source voltage with a constant drain/source voltage.
Total Current - (Measured in Ampere) - Total current is the total or modulated current of an AM modulator.
Effective Voltage - (Measured in Volt) - Effective voltage or overdrive voltage is excess of voltage across oxide over thermal voltage is termed.
STEP 1: Convert Input(s) to Base Unit
Total Current: 0.625 Milliampere --> 0.000625 Ampere (Check conversion here)
Effective Voltage: 2.5 Volt --> 2.5 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
gm = It/Vov --> 0.000625/2.5
Evaluating ... ...
gm = 0.00025
STEP 3: Convert Result to Output's Unit
0.00025 Siemens -->0.25 Millisiemens (Check conversion here)
FINAL ANSWER
0.25 Millisiemens <-- Transconductance
(Calculation completed in 00.004 seconds)

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9 Differential Configuration Calculators

Differential Voltage Gain in MOS Differential Amplifier
Go Differential Gain = Transconductance*(1/(Common Emitter Current Gain*Resistance of Primary Winding in Secondary)+(1/(1/(Common Emitter Current Gain*Resistance of Secondary Winding in Primary))))
Total Input Offset Voltage of MOS Differential Amplifier given Saturation Current
Go Input Offset Voltage = sqrt((Change in Collector Resistance/Collector Resistance)^2+(Saturation Current for DC/Saturation Current)^2)
Minimum Input Common-Mode Range of MOS Differential Amplifier
Go Common-Mode Range = Threshold Voltage+Effective Voltage+Voltage between Gate and Source-Load Voltage
Input Offset Voltage of MOS Differential Amplifier given Saturation Current
Go Input Offset Voltage = Threshold Voltage*(Saturation Current for DC/Saturation Current)
Input Offset Voltage of MOS Differential Amplifier when Aspect Ratio Mismatches
Go Input Offset Voltage = (Effective Voltage/2)*(Aspect Ratio/Aspect Ratio 1)
Maximum Input Common-Mode Range of MOS Differential Amplifier
Go Common-Mode Range = Threshold Voltage+Load Voltage-(1/2*Load Resistance)
Input Voltage of MOS Differential Amplifier on Small-Signal Operation
Go Input Voltage = Common-Mode DC Voltage+(1/2*Differential Input Signal)
Input Offset Voltage of MOS Differential Amplifier
Go Input Offset Voltage = Output DC Offset Voltage/Differential Gain
Transconductance of MOS Differential Amplifier on Small-Signal Operation
Go Transconductance = Total Current/Effective Voltage

Transconductance of MOS Differential Amplifier on Small-Signal Operation Formula

Transconductance = Total Current/Effective Voltage
gm = It/Vov

What is meant by differential input signals in a MOS differential amplifier?

Differential amplifiers apply gain not to one input signal but to the difference between two input signals. This means that a differential amplifier naturally eliminates noise or interference that is present in both input signals.

How do differential amplifiers work?

A differential amplifier multiplies the voltage difference between two inputs (Vin+ - Vin-) by some constant factor Ad, the differential gain. A differential amplifier also tends to reject the part of the input signals that are common to both inputs (Vin+ + Vin)/2 . This is referred to as the common-mode signal.

How to Calculate Transconductance of MOS Differential Amplifier on Small-Signal Operation?

Transconductance of MOS Differential Amplifier on Small-Signal Operation calculator uses Transconductance = Total Current/Effective Voltage to calculate the Transconductance, The Transconductance of MOS differential amplifier on small-signal operation formula is defined as change in drain current divided by small change in gate/source voltage with constant drain/source voltage. Typical values of gm for small-signal field-effect transistor are 1 to 30 millisiemens. Transconductance is denoted by gm symbol.

How to calculate Transconductance of MOS Differential Amplifier on Small-Signal Operation using this online calculator? To use this online calculator for Transconductance of MOS Differential Amplifier on Small-Signal Operation, enter Total Current (It) & Effective Voltage (Vov) and hit the calculate button. Here is how the Transconductance of MOS Differential Amplifier on Small-Signal Operation calculation can be explained with given input values -> 3600 = 0.000625/2.5.

FAQ

What is Transconductance of MOS Differential Amplifier on Small-Signal Operation?
The Transconductance of MOS differential amplifier on small-signal operation formula is defined as change in drain current divided by small change in gate/source voltage with constant drain/source voltage. Typical values of gm for small-signal field-effect transistor are 1 to 30 millisiemens and is represented as gm = It/Vov or Transconductance = Total Current/Effective Voltage. Total current is the total or modulated current of an AM modulator & Effective voltage or overdrive voltage is excess of voltage across oxide over thermal voltage is termed.
How to calculate Transconductance of MOS Differential Amplifier on Small-Signal Operation?
The Transconductance of MOS differential amplifier on small-signal operation formula is defined as change in drain current divided by small change in gate/source voltage with constant drain/source voltage. Typical values of gm for small-signal field-effect transistor are 1 to 30 millisiemens is calculated using Transconductance = Total Current/Effective Voltage. To calculate Transconductance of MOS Differential Amplifier on Small-Signal Operation, you need Total Current (It) & Effective Voltage (Vov). With our tool, you need to enter the respective value for Total Current & Effective Voltage 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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