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Voltage between collector-emitter at instantaneous power dissipation Solution

STEP 0: Pre-Calculation Summary
Formula Used
collector_to_emitter_voltage = Power Dissipation in Series Transistor/Collector current
VCESat = Pd/Ic
This formula uses 2 Variables
Variables Used
Power Dissipation in Series Transistor - Power Dissipation in Series Transistor (Measured in Watt)
Collector current - Collector current is an amplified output current of a bipolar junction transistor. (Measured in Ampere)
STEP 1: Convert Input(s) to Base Unit
Power Dissipation in Series Transistor: 6 Watt --> 6 Watt No Conversion Required
Collector current: 100 Ampere --> 100 Ampere No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
VCESat = Pd/Ic --> 6/100
Evaluating ... ...
VCESat = 0.06
STEP 3: Convert Result to Output's Unit
0.06 Volt --> No Conversion Required
FINAL ANSWER
0.06 Volt <-- Collector to emitter voltage at saturation
(Calculation completed in 00.016 seconds)

10+ Class A Output Stage Calculators

Bias current of the emitter-follower
input_bias_current = modulus((-Supply Voltage)+Saturation collector to emitter voltage)/Load resistance Go
Transfer characteristics of emitter-follower
output_voltage = Voltage-Base-emitter signal Voltage Go
Instantaneous power dissipation of emitter-follower
power_dissipated = Collector to emitter voltage at saturation*Collector current Go
Maximum transfer characteristics of emitter-follower in positive limit
maximum_voltage = Supply Voltage-Saturation collector to emitter voltage Go
Maximum voltage of emitter-follower when the transistor saturates
maximum_voltage = Supply Voltage-Saturation collector to emitter voltage Go
Saturation voltage between collector-emitter at maximum voltage
saturation_collector_to_emitter_voltage = Supply Voltage-Maximum Voltage Go
Minimum voltage of emitter-follower when the transistor saturates
min_voltage = -(Supply Voltage+Saturation collector to emitter voltage) Go
Saturation voltage between collector-emitter at minimum voltage
saturation_collector_to_emitter_voltage = Min voltage+Supply Voltage Go
Bias current in minimum transfer characteristics of emitter-follower in negative limit
input_bias_current = -(Min voltage/Load Resistance) Go
Minimum transfer characteristics of emitter-follower in negative limit
min_voltage = -(Input Bias Current*Load Resistance) Go

Voltage between collector-emitter at instantaneous power dissipation Formula

collector_to_emitter_voltage = Power Dissipation in Series Transistor/Collector current
VCESat = Pd/Ic

What is class A output stage? Where are class A amplifiers used?

A Class A amplifier stage passes the same load current even when no input signal is applied so large heatsinks are needed for the output transistors. These types of devices are basically two transistors within a single package, one small “pilot” transistor and another larger “switching” transistor. The Class A Amplifier more suitable for outdoor musical systems, since the transistor reproduces the entire audio waveform without ever cutting off. As a result, the sound is very clear and more linear, that is, it contains much lower levels of distortion.

How to Calculate Voltage between collector-emitter at instantaneous power dissipation?

Voltage between collector-emitter at instantaneous power dissipation calculator uses collector_to_emitter_voltage = Power Dissipation in Series Transistor/Collector current to calculate the Collector to emitter voltage at saturation, The Voltage between collector-emitter at instantaneous power dissipation formula is defined as the pressure from an electrical circuit's power source that pushes charged electrons (current) through a conducting loop, enabling them to do work such as illuminating a light. Collector to emitter voltage at saturation and is denoted by VCESat symbol.

How to calculate Voltage between collector-emitter at instantaneous power dissipation using this online calculator? To use this online calculator for Voltage between collector-emitter at instantaneous power dissipation, enter Power Dissipation in Series Transistor (Pd) and Collector current (Ic) and hit the calculate button. Here is how the Voltage between collector-emitter at instantaneous power dissipation calculation can be explained with given input values -> 0.06 = 6/100.

FAQ

What is Voltage between collector-emitter at instantaneous power dissipation?
The Voltage between collector-emitter at instantaneous power dissipation formula is defined as the pressure from an electrical circuit's power source that pushes charged electrons (current) through a conducting loop, enabling them to do work such as illuminating a light and is represented as VCESat = Pd/Ic or collector_to_emitter_voltage = Power Dissipation in Series Transistor/Collector current. Power Dissipation in Series Transistor and Collector current is an amplified output current of a bipolar junction transistor.
How to calculate Voltage between collector-emitter at instantaneous power dissipation?
The Voltage between collector-emitter at instantaneous power dissipation formula is defined as the pressure from an electrical circuit's power source that pushes charged electrons (current) through a conducting loop, enabling them to do work such as illuminating a light is calculated using collector_to_emitter_voltage = Power Dissipation in Series Transistor/Collector current. To calculate Voltage between collector-emitter at instantaneous power dissipation, you need Power Dissipation in Series Transistor (Pd) and Collector current (Ic). With our tool, you need to enter the respective value for Power Dissipation in Series Transistor and Collector current 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 Collector to emitter voltage at saturation?
In this formula, Collector to emitter voltage at saturation uses Power Dissipation in Series Transistor and Collector current. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • output_voltage = Voltage-Base-emitter signal Voltage
  • maximum_voltage = Supply Voltage-Saturation collector to emitter voltage
  • saturation_collector_to_emitter_voltage = Supply Voltage-Maximum Voltage
  • min_voltage = -(Input Bias Current*Load Resistance)
  • input_bias_current = -(Min voltage/Load Resistance)
  • min_voltage = -(Supply Voltage+Saturation collector to emitter voltage)
  • maximum_voltage = Supply Voltage-Saturation collector to emitter voltage
  • saturation_collector_to_emitter_voltage = Min voltage+Supply Voltage
  • input_bias_current = modulus((-Supply Voltage)+Saturation collector to emitter voltage)/Load resistance
  • power_dissipated = Collector to emitter voltage at saturation*Collector current
Where is the Voltage between collector-emitter at instantaneous power dissipation calculator used?
Among many, Voltage between collector-emitter at instantaneous power dissipation calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
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