DC Transit Time Solution

STEP 0: Pre-Calculation Summary
Formula Used
DC Transient Time = Gate Length/Saturation Drift Velocity
To = Lg/Vds
This formula uses 3 Variables
Variables Used
DC Transient Time - (Measured in Second) - DC Transient Time refers to the time taken by an electron to travel from the cathode to the anode of an electron device and then back to the cathode.
Gate Length - (Measured in Meter) - Gate Length refers to the physical length of a transistor's channel region, crucial in determining a semiconductor device's performance, speed, and power consumption in integrated circuits.
Saturation Drift Velocity - (Measured in Meter per Second) - Saturation Drift Velocity refers to the maximum velocity that an electron or hole can attain in a given material when subjected to an electric field.
STEP 1: Convert Input(s) to Base Unit
Gate Length: 0.24 Meter --> 0.24 Meter No Conversion Required
Saturation Drift Velocity: 72 Meter per Second --> 72 Meter per Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
To = Lg/Vds --> 0.24/72
Evaluating ... ...
To = 0.00333333333333333
STEP 3: Convert Result to Output's Unit
0.00333333333333333 Second --> No Conversion Required
FINAL ANSWER
0.00333333333333333 0.003333 Second <-- DC Transient Time
(Calculation completed in 00.004 seconds)

Credits

Created by Shobhit Dimri
Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat
Shobhit Dimri has created this Calculator and 900+ more calculators!
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Vishwakarma Government Engineering College (VGEC), Ahmedabad
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13 Klystron Calculators

Width of Depletion Zone
Go Width of Depletion Region = sqrt((([Permitivity-silicon]*2)/([Charge-e]*Doping Density))*(Schottky Potential Barrier-Gate Voltage))
Mutual Conductance of Klystron Amplifier
Go Mutual Conductance of Klystron Amplifier = (2*Cathode Buncher Current*Beam Coupling Coefficient*First Order Bessel Function)/Input Signal Amplitude
Klystron Efficiency
Go Klystron Efficiency = (Beam Complex Coefficient*First Order Bessel Function)*(Catcher Gap Voltage/Cathode Buncher Voltage)
Bunching Parameter of Klystron
Go Bunching Parameter = (Beam Coupling Coefficient*Input Signal Amplitude*Angular Variation)/(2*Cathode Buncher Voltage)
Beam Loading Conductance
Go Beam Loading Conductance = Conductance of Cavity-(Loaded Conductance+Copper Loss Conductance)
Copper Loss of Cavity
Go Copper Loss Conductance = Conductance of Cavity-(Beam Loading Conductance+Loaded Conductance)
Cavity Conductance
Go Conductance of Cavity = Loaded Conductance+Copper Loss Conductance+Beam Loading Conductance
Anode Voltage
Go Anode Voltage = Power Generated in Anode Circuit/ (Anode Current*Electronic Efficiency)
Resonant Frequency of Cavity
Go Resonant Frequency = Q factor of Cavity Resonator*(Frequency 2-Frequency 1)
Input Power of Reflex Klystron
Go Reflex Klystron Input Power = Reflex Klystron Voltage*Reflex Klystron Beam Current
DC Transit Time
Go DC Transient Time = Gate Length/Saturation Drift Velocity
Power Loss in Anode Circuit
Go Power Loss = DC Power Supply*(1-Electronic Efficiency)
DC Power Supply
Go DC Power Supply = Power Loss/(1-Electronic Efficiency)

DC Transit Time Formula

DC Transient Time = Gate Length/Saturation Drift Velocity
To = Lg/Vds

What is Microwave Cavity?

A microwave cavity or radiofrequency cavity is a special type of resonator, consisting of a closed metal structure that confines electromagnetic fields in the microwave region of the spectrum.

How to Calculate DC Transit Time?

DC Transit Time calculator uses DC Transient Time = Gate Length/Saturation Drift Velocity to calculate the DC Transient Time, DC Transit Time is the time taken by an electron to travel through the length of a vacuum tube or a semiconductor device. It is also called the "carrier transit time." This time depends on the length of the device, the velocity of the electron, and the electric field that accelerates the electron. DC Transient Time is denoted by To symbol.

How to calculate DC Transit Time using this online calculator? To use this online calculator for DC Transit Time, enter Gate Length (Lg) & Saturation Drift Velocity (Vds) and hit the calculate button. Here is how the DC Transit Time calculation can be explained with given input values -> 0.003333 = 0.24/72.

FAQ

What is DC Transit Time?
DC Transit Time is the time taken by an electron to travel through the length of a vacuum tube or a semiconductor device. It is also called the "carrier transit time." This time depends on the length of the device, the velocity of the electron, and the electric field that accelerates the electron and is represented as To = Lg/Vds or DC Transient Time = Gate Length/Saturation Drift Velocity. Gate Length refers to the physical length of a transistor's channel region, crucial in determining a semiconductor device's performance, speed, and power consumption in integrated circuits & Saturation Drift Velocity refers to the maximum velocity that an electron or hole can attain in a given material when subjected to an electric field.
How to calculate DC Transit Time?
DC Transit Time is the time taken by an electron to travel through the length of a vacuum tube or a semiconductor device. It is also called the "carrier transit time." This time depends on the length of the device, the velocity of the electron, and the electric field that accelerates the electron is calculated using DC Transient Time = Gate Length/Saturation Drift Velocity. To calculate DC Transit Time, you need Gate Length (Lg) & Saturation Drift Velocity (Vds). With our tool, you need to enter the respective value for Gate Length & Saturation Drift Velocity 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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