Distance between Anode and Cathode Solution

STEP 0: Pre-Calculation Summary
Formula Used
Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage)
d = (1/B0c)*sqrt(2*([Mass-e]/[Charge-e])*V0)
This formula uses 2 Constants, 1 Functions, 3 Variables
Constants Used
[Charge-e] - Charge of electron Value Taken As 1.60217662E-19
[Mass-e] - Mass of electron Value Taken As 9.10938356E-31
Functions Used
sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)
Variables Used
Distance Between Anode and Cathode - (Measured in Meter) - Distance Between Anode and Cathode refers to the placing distance between the anode and cathode terminal of a magnetron.
Hull Cutoff Magnetic Flux Density - (Measured in Tesla) - Hull Cutoff Magnetic Flux Density is the minimum magnetic flux density required to prevent electrons from reaching the anode in a vacuum tube.
Anode Voltage - (Measured in Volt) - Anode Voltage is the voltage applied to the anode or plate of a vacuum tube to attract and collect the electrons in the beam after they have passed through the device.
STEP 1: Convert Input(s) to Base Unit
Hull Cutoff Magnetic Flux Density: 0.009 Weber per Square Meter --> 0.009 Tesla (Check conversion here)
Anode Voltage: 26000 Volt --> 26000 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
d = (1/B0c)*sqrt(2*([Mass-e]/[Charge-e])*V0) --> (1/0.009)*sqrt(2*([Mass-e]/[Charge-e])*26000)
Evaluating ... ...
d = 0.0604155122113316
STEP 3: Convert Result to Output's Unit
0.0604155122113316 Meter --> No Conversion Required
FINAL ANSWER
0.0604155122113316 0.060416 Meter <-- Distance Between Anode and Cathode
(Calculation completed in 00.004 seconds)

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17 Magnetron Oscillator Calculators

Distance between Anode and Cathode
Go Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage)
Hull Cutoff Magnetic Flux Density
Go Hull Cutoff Magnetic Flux Density = (1/Distance Between Anode and Cathode)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage)
Hull Cut-off Voltage
Go Hull Cut off Voltage = (1/2)*([Charge-e]/[Mass-e])*Hull Cutoff Magnetic Flux Density^2*Distance Between Anode and Cathode^2
Electron Uniform Velocity
Go Electron Uniform Velocity = sqrt((2*Beam Voltage)*([Charge-e]/[Mass-e]))
Cyclotron Angular Frequency
Go Cyclotron Angular Frequency = Magnetic Flux Density in Z Direction*([Charge-e]/[Mass-e])
Circuit Efficiency in Magnetron
Go Circuit Efficiency = Resonator Conductance/(Resonator Conductance+Conductance of Cavity)
Anode Current
Go Anode Current = Power Generated in Anode Circuit/(Anode Voltage*Electronic Efficiency)
Magnetron Phase Shift
Go Phase Shift in Magnetron = 2*pi*(Number of Oscillation/Number of Resonant Cavities)
Repetition Frequency of Pulse
Go Repetition Frequency = (Spectral Line Frequency-Carrier Frequency)/Number of Samples
Spectral Line Frequency
Go Spectral Line Frequency = Carrier Frequency+Number of Samples*Repetition Frequency
Noise Ratio
Go Signal Noise Ratio = (Input Signal Noise Ratio/Output Signal Noise Ratio)-1
Space Charge Reduction Factor
Go Space Charge Reduction Factor = Reduced Plasma Frequency/Plasma Frequency
Electronic Efficiency
Go Electronic Efficiency = Power Generated in Anode Circuit/DC Power Supply
Modulation Linearity
Go Modulation Linearity = Maximum Frequency Deviation/Peak Frequency
Receiver Sensitivity
Go Receiver Sensitivity = Receiver Noise Floor+Signal Noise Ratio
Characteristic Admittance
Go Characteristic Admittance = 1/Characteristic Impedance
RF Pulse Width
Go RF Pulse Width = 1/(2*Bandwidth)

Distance between Anode and Cathode Formula

Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage)
d = (1/B0c)*sqrt(2*([Mass-e]/[Charge-e])*V0)

Magnetron is based on which principle?

The magnetron is based on the principle of interaction between the electron beam and the traveling electromagnetic RF waves

How to Calculate Distance between Anode and Cathode?

Distance between Anode and Cathode calculator uses Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage) to calculate the Distance Between Anode and Cathode, Distance between Anode and Cathode is the physical distance between the two electrodes, typically measured in meters or millimeters. This distance plays an important role in the performance of the electronic device, as it affects the electric field strength and the current flow between the electrodes. It is also called "inter electrode distance". Distance Between Anode and Cathode is denoted by d symbol.

How to calculate Distance between Anode and Cathode using this online calculator? To use this online calculator for Distance between Anode and Cathode, enter Hull Cutoff Magnetic Flux Density (B0c) & Anode Voltage (V0) and hit the calculate button. Here is how the Distance between Anode and Cathode calculation can be explained with given input values -> 0.060416 = (1/0.009)*sqrt(2*([Mass-e]/[Charge-e])*26000).

FAQ

What is Distance between Anode and Cathode?
Distance between Anode and Cathode is the physical distance between the two electrodes, typically measured in meters or millimeters. This distance plays an important role in the performance of the electronic device, as it affects the electric field strength and the current flow between the electrodes. It is also called "inter electrode distance" and is represented as d = (1/B0c)*sqrt(2*([Mass-e]/[Charge-e])*V0) or Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage). Hull Cutoff Magnetic Flux Density is the minimum magnetic flux density required to prevent electrons from reaching the anode in a vacuum tube & Anode Voltage is the voltage applied to the anode or plate of a vacuum tube to attract and collect the electrons in the beam after they have passed through the device.
How to calculate Distance between Anode and Cathode?
Distance between Anode and Cathode is the physical distance between the two electrodes, typically measured in meters or millimeters. This distance plays an important role in the performance of the electronic device, as it affects the electric field strength and the current flow between the electrodes. It is also called "inter electrode distance" is calculated using Distance Between Anode and Cathode = (1/Hull Cutoff Magnetic Flux Density)*sqrt(2*([Mass-e]/[Charge-e])*Anode Voltage). To calculate Distance between Anode and Cathode, you need Hull Cutoff Magnetic Flux Density (B0c) & Anode Voltage (V0). With our tool, you need to enter the respective value for Hull Cutoff Magnetic Flux Density & Anode 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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