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Commutation Period For Boost Regulator (DCM) Calculator

Category Engineering
Inductance is the tendency of an electric conductor to oppose a change in the electric current flowing through it.Inductance [L]
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output current is the current the amplifier draws from the signal sourceoutput current [i]
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A duty cycle or power cycle is the fraction of one period in which a signal or system is activeduty Cycle [D]
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Input voltage is the voltage supplied to the deviceInput voltage [Vi]
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Output voltage signifies the voltage of the signal after it has been amplified. Output voltage [Vo]
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The time commutation is the process of transferring current from one connection to another within an electric circuitCommutation Period For Boost Regulator (DCM) [T.C]
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Shobhit Dimri
Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat
Shobhit Dimri has created this Calculator and 100+ more calculators!
Urvi Rathod
Vishwakarma Government Engineering College (VGEC), Ahmedabad
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11 Other formulas that you can solve using the same Inputs

Decay of Current in LR Circuit
Decay of current in L-R circuit=Current when T=0*e^(-Time Period Of Progressive Wave/(Inductance/Resistance)) GO
Growth of Current in LR Circuit
Growth of current in LR circuit=(e/Resistance)*(1-e^(-Time/(Inductance/Resistance))) GO
Capacitance For The Parallel RLC Circuit When Q-Factor Is Given
Capacitance=(Inductance*Quantity Factor*Quantity Factor)/(Resistance*Resistance) GO
Capacitance For The Series RLC Circuit When Q-Factor Is Given
Capacitance=Inductance/(Quantity Factor*Quantity Factor*Resistance*Resistance) GO
Self Resonance Frequency
Self resonance frequency=1/(2*3.14*(Inductance*Transition Capacitance)^1/2) GO
Resistance For The Series RLC Circuit When Q-Factor Is Given
Resistance=sqrt(Inductance)/(Quantity Factor*sqrt(Capacitance)) GO
Q-factor For The Series RLC Circuit
Quantity Factor=sqrt(Inductance)/(Resistance*sqrt(Capacitance)) GO
Resistance For The parallel RLC Circuit When Q-Factor Is Given
Resistance=Quantity Factor/(sqrt(Capacitance/Inductance)) GO
Q-factor For The Parallel RLC Circuit
Quantity Factor=Resistance*(sqrt(Capacitance/Inductance)) GO
Time Constant of LR Circuit
Time constant of L-R circuit=Inductance/Resistance GO
Time Constant For The RC Circuit When The Inductance Is Given
Time constant=Inductance/Resistance GO

2 Other formulas that calculate the same Output

Commutation Period For Buck Regulator (DCM)
time commutation=2*Inductance*output current /((Input voltage-Output voltage )*duty Cycle*(duty Cycle+delta)) GO
Commutation Period For Buck-Boost Regulator (DCM)
time commutation=2*Output voltage *Inductance*output current /(Input voltage^2*duty Cycle^2) GO

Commutation Period For Boost Regulator (DCM) Formula

time commutation=(2*Inductance*output current /duty Cycle^2*Input voltage)*((Output voltage /Input voltage)-1)
T.C=(2*L*i/D^2*V<sub>i</sub>)*((V<sub>o</sub>/V<sub>i</sub>)-1)
More formulas
Duty Cycle For Boost Regulator (DCM) GO
Output Voltage For Boost Regulator (DCM) GO
Output Current For Boost Regulator (DCM) GO
Inductor Value For Boost Regulator (DCM) GO

What is Boost Regulator(DCM)?

A Boost Regulator(DCM) is a DC-to-DC power converter that steps up the voltage from its input to its output.

How to Calculate Commutation Period For Boost Regulator (DCM)?

Commutation Period For Boost Regulator (DCM) calculator uses time commutation=(2*Inductance*output current /duty Cycle^2*Input voltage)*((Output voltage /Input voltage)-1) to calculate the time commutation, The Commutation Period For Boost Regulator (DCM) formula is defined as the process of transferring current from one connection to another within an electric circuit. time commutation and is denoted by T.C symbol.

How to calculate Commutation Period For Boost Regulator (DCM) using this online calculator? To use this online calculator for Commutation Period For Boost Regulator (DCM), enter Inductance (L), output current (i), duty Cycle (D), Input voltage (Vi) and Output voltage (Vo) and hit the calculate button. Here is how the Commutation Period For Boost Regulator (DCM) calculation can be explained with given input values -> 90000 = (2*50*1/0.1^2*1)*((10/1)-1).

FAQ

What is Commutation Period For Boost Regulator (DCM)?
The Commutation Period For Boost Regulator (DCM) formula is defined as the process of transferring current from one connection to another within an electric circuit and is represented as T.C=(2*L*i/D^2*Vi)*((Vo/Vi)-1) or time commutation=(2*Inductance*output current /duty Cycle^2*Input voltage)*((Output voltage /Input voltage)-1). Inductance is the tendency of an electric conductor to oppose a change in the electric current flowing through it, output current is the current the amplifier draws from the signal source, A duty cycle or power cycle is the fraction of one period in which a signal or system is active, Input voltage is the voltage supplied to the device and Output voltage signifies the voltage of the signal after it has been amplified. .
How to calculate Commutation Period For Boost Regulator (DCM)?
The Commutation Period For Boost Regulator (DCM) formula is defined as the process of transferring current from one connection to another within an electric circuit is calculated using time commutation=(2*Inductance*output current /duty Cycle^2*Input voltage)*((Output voltage /Input voltage)-1). To calculate Commutation Period For Boost Regulator (DCM), you need Inductance (L), output current (i), duty Cycle (D), Input voltage (Vi) and Output voltage (Vo). With our tool, you need to enter the respective value for Inductance, output current , duty Cycle, Input voltage and Output 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 time commutation?
In this formula, time commutation uses Inductance, output current , duty Cycle, Input voltage and Output voltage . We can use 2 other way(s) to calculate the same, which is/are as follows -
  • time commutation=2*Inductance*output current /((Input voltage-Output voltage )*duty Cycle*(duty Cycle+delta))
  • time commutation=2*Output voltage *Inductance*output current /(Input voltage^2*duty Cycle^2)
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