Output Voltage of Controlled Source Transistor Calculator

✖Voltage gain is defined as the ratio of the output voltage to the input voltage.ⓘ Voltage Gain [A_v]			+10% -10%
✖Electric Current is the time rate of flow of charge through a cross sectional area.ⓘ Electric Current [i_t]			+10% -10%
✖Short circuit transconductance is the electrical characteristic relating the current through the output of a device to the voltage across the input of a device.ⓘ Short Circuit Transconductance [g'_m]			+10% -10%
✖Differential output signal is a measure of the voltage between two distinct output signals.ⓘ Differential Output Signal [V_od]			+10% -10%
✖Final Resistance is a measure of the opposition to current flow in an electrical circuit. Resistance is measured in ohms, symbolized by the Greek letter omega (Ω).ⓘ Final Resistance [R_final]			+10% -10%
✖Resistance of primary winding in secondary is the resistance that is available in primary winding of secondary.ⓘ Resistance of Primary Winding in Secondary [R₁]			+10% -10%

✖The DC Component of Gate to Source Voltage refers to the voltage applied between the gate and source terminals, which controls the flow of current between the drain and source terminals.ⓘ Output Voltage of Controlled Source Transistor [V_gsq]

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Formula

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Output Voltage of Controlled Source Transistor

Formula

`"V"_{"gsq"} = ("A"_{"v"}*"i"_{"t"}-"g'"_{"m"}*"V"_{"od"})*(1/"R"_{"final"}+1/"R"_{"1"})`

Example

`"10.0982V"=("4.21"*"4402mA"-"2.5mS"*"100.3V")*(1/"0.00243kΩ"+1/"0.0071kΩ")`

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Output Voltage of Controlled Source Transistor Solution

STEP 0: Pre-Calculation Summary

Formula Used

DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary)
V_gsq = (A_v*i_t-g'_m*V_od)*(1/R_final+1/R₁)
This formula uses 7 Variables

Variables Used

DC Component of Gate to Source Voltage - (Measured in Volt) - The DC Component of Gate to Source Voltage refers to the voltage applied between the gate and source terminals, which controls the flow of current between the drain and source terminals.
Voltage Gain - Voltage gain is defined as the ratio of the output voltage to the input voltage.
Electric Current - (Measured in Ampere) - Electric Current is the time rate of flow of charge through a cross sectional area.
Short Circuit Transconductance - (Measured in Siemens) - Short circuit transconductance is the electrical characteristic relating the current through the output of a device to the voltage across the input of a device.
Differential Output Signal - (Measured in Volt) - Differential output signal is a measure of the voltage between two distinct output signals.
Final Resistance - (Measured in Ohm) - Final Resistance is a measure of the opposition to current flow in an electrical circuit. Resistance is measured in ohms, symbolized by the Greek letter omega (Ω).
Resistance of Primary Winding in Secondary - (Measured in Ohm) - Resistance of primary winding in secondary is the resistance that is available in primary winding of secondary.

STEP 1: Convert Input(s) to Base Unit

Voltage Gain: 4.21 --> No Conversion Required
Electric Current: 4402 Milliampere --> 4.402 Ampere (Check conversion here)
Short Circuit Transconductance: 2.5 Millisiemens --> 0.0025 Siemens (Check conversion here)
Differential Output Signal: 100.3 Volt --> 100.3 Volt No Conversion Required
Final Resistance: 0.00243 Kilohm --> 2.43 Ohm (Check conversion here)
Resistance of Primary Winding in Secondary: 0.0071 Kilohm --> 7.1 Ohm (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

V_gsq = (A_v*i_t-g'_m*V_od)*(1/R_final+1/R₁) --> (4.21*4.402-0.0025*100.3)*(1/2.43+1/7.1)

Evaluating ... ...

V_gsq = 10.0982040862459

STEP 3: Convert Result to Output's Unit

10.0982040862459 Volt --> No Conversion Required

FINAL ANSWER

10.0982040862459 ≈ 10.0982 Volt <-- DC Component of Gate to Source Voltage

(Calculation completed in 00.004 seconds)

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Created by Payal Priya

Birsa Institute of Technology (BIT), Sindri

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National Institute Of Technology (NIT), Hamirpur

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< 11 Common-Source Amplifier Calculators

Overall Feedback Voltage Gain of Common-Source Amplifier

Go Feedback Voltage Gain = -MOSFET Primary Transconductance*(Input Resistance/(Input Resistance+Signal Resistance))*(1/Drain Resistance+1/Load Resistance+1/Finite Output Resistance)^-1

Output Voltage of Controlled Source Transistor

Go DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary)

Output Resistance at Another Drain of Controlled Source Transistor

Go Drain Resistance = Resistance of Secondary Winding in Primary+2*Finite Resistance+2*Finite Resistance*MOSFET Primary Transconductance*Resistance of Secondary Winding in Primary

Output Resistance of CS Amplifier with Source Resistance

Go Drain Resistance = Finite Output Resistance+Source Resistance+(MOSFET Primary Transconductance*Finite Output Resistance*Source Resistance)

Open-Circuit Voltage Gain of CS Amplifier

Go Open Circuit Voltage Gain = Finite Output Resistance/(Finite Output Resistance+1/MOSFET Primary Transconductance)

Transconductance in Common Source Amplifier

Go MOSFET Primary Transconductance = Unity Gain Frequency*(Gate to Source Capacitance+Capacitance Gate to Drain)

Overall Voltage Gain of Source Follower

Go Overall Voltage Gain = Load Resistance/(Load Resistance+1/MOSFET Primary Transconductance)

Current Gain of Controlled Source Transistor

Go Current Gain = 1/(1+1/(MOSFET Primary Transconductance*Resistance between Drain and Ground))

Emitter Voltage with respect to Voltage Gain

Go Emitter Voltage = Collector Voltage/Voltage Gain

Total Voltage Gain of CS Amplifier

Go Voltage Gain = Load Voltage/Input Voltage

Load Voltage of CS Amplifier

Go Load Voltage = Voltage Gain*Input Voltage

< 18 CV Actions of Common Stage Amplifiers Calculators

Output Voltage of Controlled Source Transistor

Go DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary)

Input Resistance of Common-Base Circuit

Go Input Resistance = (Emitter Resistance*(Finite Output Resistance+Load Resistance))/(Finite Output Resistance+(Load Resistance/(Collector Base Current Gain+1)))

Output Resistance at Another Drain of Controlled Source Transistor

Go Drain Resistance = Resistance of Secondary Winding in Primary+2*Finite Resistance+2*Finite Resistance*MOSFET Primary Transconductance*Resistance of Secondary Winding in Primary

Output Resistance of Emitter-Degenerated CE Amplifier

Go Drain Resistance = Finite Output Resistance+(MOSFET Primary Transconductance*Finite Output Resistance)*(1/Emitter Resistance+1/Small Signal Input Resistance)

Input Resistance of Common Emitter Amplifier given Small-Signal Input Resistance

Go Input Resistance = (1/Base Resistance+1/Base Resistance 2+1/(Small Signal Input Resistance+(Collector Base Current Gain+1)*Emitter Resistance))^-1

Output Resistance of CS Amplifier with Source Resistance

Go Drain Resistance = Finite Output Resistance+Source Resistance+(MOSFET Primary Transconductance*Finite Output Resistance*Source Resistance)

Input Resistance of Common-Emitter Amplifier given Emitter Resistance

Go Input Resistance = (1/Base Resistance+1/Base Resistance 2+1/((Total Resistance+Emitter Resistance)*(Collector Base Current Gain+1)))^-1

Instantaneous Drain Current using Voltage between Drain and Source

Go Drain Current = Transconductance Parameter*(Voltage across Oxide-Threshold Voltage)*Voltage between Gate and Source

Transconductance in Common Source Amplifier

Go MOSFET Primary Transconductance = Unity Gain Frequency*(Gate to Source Capacitance+Capacitance Gate to Drain)

Input Resistance of Common Emitter Amplifier

Go Input Resistance = (1/Base Resistance+1/Base Resistance 2+1/Small Signal Input Resistance)^-1

Input Impedance of Common-Base Amplifier

Go Input Impedance = (1/Emitter Resistance+1/Small Signal Input Resistance)^(-1)

Signal Current in Emitter given Input Signal

Go Signal Current in Emitter = Fundamental Component Voltage/Emitter Resistance

Transconductance using Collector Current of Transistor Amplifier

Go MOSFET Primary Transconductance = Collector Current/Threshold Voltage

Fundamental Voltage in Common-Emitter Amplifier

Go Fundamental Component Voltage = Input Resistance*Base Current

Input Resistance of Common-Collector Amplifier

Go Input Resistance = Fundamental Component Voltage/Base Current

Resistance of Emitter in Common-Base Amplifier

Go Emitter Resistance = Input Voltage/Emitter Current

Emitter Current of Common-Base Amplifier

Go Emitter Current = Input Voltage/Emitter Resistance

Load Voltage of CS Amplifier

Go Load Voltage = Voltage Gain*Input Voltage

Output Voltage of Controlled Source Transistor Formula

How do you control voltage in a circuit?

To reduce the voltage in half, we simply form a voltage divider circuit between 2 resistors of equal value (for example, 2 10KΩ) resistors. To divide voltage in half, all you must do is place any 2 resistors of equal value in series and then place a jumper wire in between the resistors.

How to Calculate Output Voltage of Controlled Source Transistor?

Output Voltage of Controlled Source Transistor calculator uses DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary) to calculate the DC Component of Gate to Source Voltage, The Output voltage of controlled source transistor formula is defined as the voltage that is controlled by a voltage elsewhere in a circuit. In practice, a VCVS is often used in modeling operational amplifiers (op-amps), and can also be used in modeling a voltage signal chain more generally. DC Component of Gate to Source Voltage is denoted by V_gsq symbol.

How to calculate Output Voltage of Controlled Source Transistor using this online calculator? To use this online calculator for Output Voltage of Controlled Source Transistor, enter Voltage Gain (A_v), Electric Current (i_t), Short Circuit Transconductance (g'_m), Differential Output Signal (V_od), Final Resistance (R_final) & Resistance of Primary Winding in Secondary (R₁) and hit the calculate button. Here is how the Output Voltage of Controlled Source Transistor calculation can be explained with given input values -> 2.589591 = (4.21*4.402-0.0025*100.3)*(1/2.43+1/7.1).

FAQ

What is Output Voltage of Controlled Source Transistor?

The Output voltage of controlled source transistor formula is defined as the voltage that is controlled by a voltage elsewhere in a circuit. In practice, a VCVS is often used in modeling operational amplifiers (op-amps), and can also be used in modeling a voltage signal chain more generally and is represented as V_gsq = (A_v*i_t-g'_m*V_od)*(1/R_final+1/R₁) or DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary). Voltage gain is defined as the ratio of the output voltage to the input voltage, Electric Current is the time rate of flow of charge through a cross sectional area, Short circuit transconductance is the electrical characteristic relating the current through the output of a device to the voltage across the input of a device, Differential output signal is a measure of the voltage between two distinct output signals, Final Resistance is a measure of the opposition to current flow in an electrical circuit. Resistance is measured in ohms, symbolized by the Greek letter omega (Ω) & Resistance of primary winding in secondary is the resistance that is available in primary winding of secondary.

How to calculate Output Voltage of Controlled Source Transistor?

The Output voltage of controlled source transistor formula is defined as the voltage that is controlled by a voltage elsewhere in a circuit. In practice, a VCVS is often used in modeling operational amplifiers (op-amps), and can also be used in modeling a voltage signal chain more generally is calculated using DC Component of Gate to Source Voltage = (Voltage Gain*Electric Current-Short Circuit Transconductance*Differential Output Signal)*(1/Final Resistance+1/Resistance of Primary Winding in Secondary). To calculate Output Voltage of Controlled Source Transistor, you need Voltage Gain (A_v), Electric Current (i_t), Short Circuit Transconductance (g'_m), Differential Output Signal (V_od), Final Resistance (R_final) & Resistance of Primary Winding in Secondary (R₁). With our tool, you need to enter the respective value for Voltage Gain, Electric Current, Short Circuit Transconductance, Differential Output Signal, Final Resistance & Resistance of Primary Winding in Secondary 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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