Load Conductance given Q-External Calculator

✖Resonant Angular Frequency is the frequency at which a resonant system vibrates with maximum amplitude when it is excited by an external force, expressed in radians per second.ⓘ Resonant Angular Frequency [ω_o]			+10% -10%
✖Capacitance at Vane Tips is defined as the ratio of the amount of electric charge stored on a conductor to a difference in electric potential at the vane tips.ⓘ Capacitance at Vane Tips [C_v]			+10% -10%
✖External Q-factor is a measure of the energy stored per cycle in a resonant circuit or device, relative to the energy lost per cycle due to all forms of dissipation.ⓘ External Q-Factor [Q_ext]			+10% -10%

✖Loaded Conductance is a measure of the ease with which a load, such as a circuit or a device, can conduct an electric current.ⓘ Load Conductance given Q-External [G_L]

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Load Conductance given Q-External

Formula

`"G"_{"L"} = ("ω"_{"o"}*"C"_{"v"})/"Q"_{"ext"}`

Example

`"2.5E^-5S"=("55e9rad/s"*"2.5pF")/"5500"`

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Load Conductance given Q-External Solution

STEP 0: Pre-Calculation Summary

Formula Used

Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor
G_L = (ω_o*C_v)/Q_ext
This formula uses 4 Variables

Variables Used

Loaded Conductance - (Measured in Siemens) - Loaded Conductance is a measure of the ease with which a load, such as a circuit or a device, can conduct an electric current.
Resonant Angular Frequency - (Measured in Radian per Second) - Resonant Angular Frequency is the frequency at which a resonant system vibrates with maximum amplitude when it is excited by an external force, expressed in radians per second.
Capacitance at Vane Tips - (Measured in Farad) - Capacitance at Vane Tips is defined as the ratio of the amount of electric charge stored on a conductor to a difference in electric potential at the vane tips.
External Q-Factor - External Q-factor is a measure of the energy stored per cycle in a resonant circuit or device, relative to the energy lost per cycle due to all forms of dissipation.

STEP 1: Convert Input(s) to Base Unit

Resonant Angular Frequency: 55000000000 Radian per Second --> 55000000000 Radian per Second No Conversion Required
Capacitance at Vane Tips: 2.5 Picofarad --> 2.5E-12 Farad (Check conversion here)
External Q-Factor: 5500 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

G_L = (ω_o*C_v)/Q_ext --> (55000000000*2.5E-12)/5500

Evaluating ... ...

G_L = 2.5E-05

STEP 3: Convert Result to Output's Unit

2.5E-05 Siemens --> No Conversion Required

FINAL ANSWER

2.5E-05 ≈ 2.5E-5 Siemens <-- Loaded Conductance

(Calculation completed in 00.020 seconds)

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Created by Simran Shravan Nishad

Sinhgad College Of Engineering (SCOE), Pune

Simran Shravan Nishad has created this Calculator and 25+ more calculators!

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Vellore Institute of Technology (VIT Vellore), Vellore

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< 14 Q-Factor Calculators

Q-Factor of Loaded Resonator Circuit

Go Q Factor of Loaded Resonator Circuit = (Resonant Angular Frequency*Capacitance at Vane Tips)/(Resonator Conductance+Conductance of Cavity)

Q-Factor of Loaded Catcher Cavity

Go Q Factor of Loaded Catcher Cavity = (1/Q Factor of Catcher Wall)+(1/Q Factor of Beam Loading)+(1/Q Factor of External Load)

Q-Factor of External Load

Go Q Factor of External Load = 1/(Q Factor of Loaded Catcher Cavity-(1/Q Factor of Beam Loading)-(1/Q Factor of Catcher Wall))

Q-Factor of Catcher Wall

Go Q Factor of Catcher Wall = 1/(Q Factor of Loaded Catcher Cavity-(1/Q Factor of Beam Loading)-(1/Q Factor of External Load))

Q-Factor of Beam Loading

Go Q Factor of Beam Loading = 1/(Q Factor of Loaded Catcher Cavity-(1/Q Factor of Catcher Wall)-(1/Q Factor of External Load))

Q-Factor of Microstrip Lines given Height and Frequency

Go Q-Factor of Microstrip Lines = 0.63*Height*sqrt(Conductivity*Frequency)

Resonant Angular Frequency given Q-External

Go Resonant Angular Frequency = (Loaded Conductance*External Q-Factor)/Capacitance at Vane Tips

Load Conductance given Q-External

Go Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor

External Q-Factor

Go External Q-Factor = (Capacitance at Vane Tips*Resonant Angular Frequency)/Loaded Conductance

Unloaded Q-factor

Go Unloaded Q-factor = Capacitance at Vane Tips*Angular Frequency/Conductance of Cavity

Quality Factor of Cavity Resonator

Go Q factor of Cavity Resonator = Resonant Frequency/(Frequency 2-Frequency 1)

Q-Factor for Copper Strip

Go Q-Factor of Copper Strip Lines = 4780*Height*sqrt(Frequency)

Q-Factor of Wide Microstrip Lines

Go Q-Factor of Microstrip Lines = 27.3/Conductor Attenuation Constant

Q-Factor given Dielectric Attenuation Constant

Go Q-Factor = 27.3/Dielectric Attenuation Constant

Load Conductance given Q-External Formula

Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor
G_L = (ω_o*C_v)/Q_ext

How is load conductance related with load resistance?

Load conductance is equal to the inverse of load resistance. This relationship is straightforward: as resistance increases, conductance decreases, and vice versa.

How to Calculate Load Conductance given Q-External?

Load Conductance given Q-External calculator uses Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor to calculate the Loaded Conductance, The Load Conductance given Q-External refers to how easily electric current can flow through a load in an electrical circuit. Loaded Conductance is denoted by G_L symbol.

How to calculate Load Conductance given Q-External using this online calculator? To use this online calculator for Load Conductance given Q-External, enter Resonant Angular Frequency (ω_o), Capacitance at Vane Tips (C_v) & External Q-Factor (Q_ext) and hit the calculate button. Here is how the Load Conductance given Q-External calculation can be explained with given input values -> 2.5E-5 = (55000000000*2.5E-12)/5500.

FAQ

What is Load Conductance given Q-External?

The Load Conductance given Q-External refers to how easily electric current can flow through a load in an electrical circuit and is represented as G_L = (ω_o*C_v)/Q_ext or Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor. Resonant Angular Frequency is the frequency at which a resonant system vibrates with maximum amplitude when it is excited by an external force, expressed in radians per second, Capacitance at Vane Tips is defined as the ratio of the amount of electric charge stored on a conductor to a difference in electric potential at the vane tips & External Q-factor is a measure of the energy stored per cycle in a resonant circuit or device, relative to the energy lost per cycle due to all forms of dissipation.

How to calculate Load Conductance given Q-External?

The Load Conductance given Q-External refers to how easily electric current can flow through a load in an electrical circuit is calculated using Loaded Conductance = (Resonant Angular Frequency*Capacitance at Vane Tips)/External Q-Factor. To calculate Load Conductance given Q-External, you need Resonant Angular Frequency (ω_o), Capacitance at Vane Tips (C_v) & External Q-Factor (Q_ext). With our tool, you need to enter the respective value for Resonant Angular Frequency, Capacitance at Vane Tips & External Q-Factor 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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