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Voltage to Frequency Conversion Factor in ICs Calculator

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Output Signal Frequency refers to the rate at which a signal changes or oscillates in an electrical or electronic system.Output Signal Frequency [fo]
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-10%
Input Voltage is the electrical potential difference applied to the input terminals of a component or system.Input Voltage [Vi]
+10%
-10%
voltage to frequency conversion factor in ICs is a process where an input voltage signal is converted into a corresponding frequency output.Voltage to Frequency Conversion Factor in ICs [Kv]
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Formula

Voltage to Frequency Conversion Factor in ICs

Formula
`"K"_{"v"} = "f"_{"o"}/"V"_{"i"}`

Example
`"0.488889Hz/V"="1.1Hz"/"2.25V"`

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Voltage to Frequency Conversion Factor in ICs Solution

STEP 0: Pre-Calculation Summary
Formula Used
Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage
Kv = fo/Vi
This formula uses 3 Variables
Variables Used
Voltage to Frequency Conversion Factor in ICs - (Measured in Hertz per Volt) - voltage to frequency conversion factor in ICs is a process where an input voltage signal is converted into a corresponding frequency output.
Output Signal Frequency - (Measured in Hertz) - Output Signal Frequency refers to the rate at which a signal changes or oscillates in an electrical or electronic system.
Input Voltage - (Measured in Volt) - Input Voltage is the electrical potential difference applied to the input terminals of a component or system.
STEP 1: Convert Input(s) to Base Unit
Output Signal Frequency: 1.1 Hertz --> 1.1 Hertz No Conversion Required
Input Voltage: 2.25 Volt --> 2.25 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Kv = fo/Vi --> 1.1/2.25
Evaluating ... ...
Kv = 0.488888888888889
STEP 3: Convert Result to Output's Unit
0.488888888888889 Hertz per Volt --> No Conversion Required
FINAL ANSWER
0.488888888888889 0.488889 Hertz per Volt <-- Voltage to Frequency Conversion Factor in ICs
(Calculation completed in 00.004 seconds)
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19 Bipolar IC Fabrication Calculators

Resistance of Rectangular Parallelepiped
​ Go Resistance = ((Resistivity*Thickness of Layer)/(Width of Diffused Layer*Length of Diffused Layer))*(ln(Width of Bottom Rectangle/Length of Bottom Rectangle)/(Width of Bottom Rectangle-Length of Bottom Rectangle))
Impurity Atoms Per Unit Area
​ Go Total Impurity = Effective Diffusion*(Emitter Base Junction Area*((Charge*Intrinsic Concentration^2)/Collector Current)*exp(Voltage Base Emitter/Thermal Voltage))
Conductivity of N-Type
​ Go Ohmic Conductivity = Charge*(Electron Doping Silicon Mobility*Equilibrium Concentration of N-Type+Hole Doping Silicon Mobility*(Intrinsic Concentration^2/Equilibrium Concentration of N-Type))
Conductivity of P-Type
​ Go Ohmic Conductivity = Charge*(Electron Doping Silicon Mobility*(Intrinsic Concentration^2/Equilibrium Concentration of P-Type)+Hole Doping Silicon Mobility*Equilibrium Concentration of P-Type)
Ohmic Conductivity of Impurity
​ Go Ohmic Conductivity = Charge*(Electron Doping Silicon Mobility*Electron Concentration+Hole Doping Silicon Mobility*Hole Concentration)
Gate Source Capacitance Given Overlap Capacitance
​ Go Gate Source Capacitance = (2/3*Transistor's Width*Transistor's Length*Oxide Capacitance)+(Transistor's Width*Overlap Capacitance)
Collector-Current of PNP Transistor
​ Go Collector Current = (Charge*Emitter Base Junction Area*Equilibrium Concentration of N-Type*Diffusion Constant For PNP)/Base Width
Saturation Current in Transistor
​ Go Saturation Current = (Charge*Emitter Base Junction Area*Effective Diffusion*Intrinsic Concentration^2)/Total Impurity
Capacitive Load Power Consumption given Supply Voltage
​ Go Capacitive Load Power Consumption = Load Capacitance*Supply Voltage^2*Output Signal Frequency*Total Number of Outputs Switching
Sheet Resistance of Layer
​ Go Sheet Resistance = 1/(Charge*Electron Doping Silicon Mobility*Equilibrium Concentration of N-Type*Thickness of Layer)
Resistance of Diffused Layer
​ Go Resistance = (1/Ohmic Conductivity)*(Length of Diffused Layer/(Width of Diffused Layer*Thickness of Layer))
Current Density Hole
​ Go Hole Current Density = Charge*Diffusion Constant For PNP*(Hole Equilibrium Concentration/Base Width)
Impurity with Intrinsic Concentration
​ Go Intrinsic Concentration = sqrt((Electron Concentration*Hole Concentration)/Temperature Impurity)
Emitter Injection Efficiency
​ Go Emmitter Injection Efficiency = Emitter Current/(Emitter Current due to Electrons+Emitter Current due to Holes)
Breakout Voltage of Collector Emitter
​ Go Collector Emitter Breakout Voltage = Collector Base Breakout Voltage/(Current Gain of BJT)^(1/Root Number)
Emitter Injection Efficiency given Doping Constants
​ Go Emmitter Injection Efficiency = Doping on N-side/(Doping on N-side+Doping on P-side)
Current Flowing in Zener Diode
​ Go Diode Current = (Input Reference Voltage-Stable Output Voltage)/Zener Resistance
Voltage to Frequency Conversion Factor in ICs
​ Go Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage
Base Transport Factor given Base Width
​ Go Base Transport Factor = 1-(1/2*(Physical Width/Electron Diffusion Length)^2)

Voltage to Frequency Conversion Factor in ICs Formula

Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage
Kv = fo/Vi

What factors affect the accuracy of voltage-to-frequency conversion in ICs?

Factors such as temperature variations, supply voltage changes, and component tolerances can affect the accuracy of voltage-to-frequency conversion. Manufacturers provide specifications and compensation techniques to enhance accuracy.

How to Calculate Voltage to Frequency Conversion Factor in ICs?

Voltage to Frequency Conversion Factor in ICs calculator uses Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage to calculate the Voltage to Frequency Conversion Factor in ICs, The Voltage to Frequency Conversion Factor in ICs formula is defined as the relationship between an input voltage signal and the resulting output frequency of the IC. Voltage to Frequency Conversion Factor in ICs is denoted by Kv symbol.

How to calculate Voltage to Frequency Conversion Factor in ICs using this online calculator? To use this online calculator for Voltage to Frequency Conversion Factor in ICs, enter Output Signal Frequency (fo) & Input Voltage (Vi) and hit the calculate button. Here is how the Voltage to Frequency Conversion Factor in ICs calculation can be explained with given input values -> 0.488889 = 1.1/2.25.

FAQ

What is Voltage to Frequency Conversion Factor in ICs?
The Voltage to Frequency Conversion Factor in ICs formula is defined as the relationship between an input voltage signal and the resulting output frequency of the IC and is represented as Kv = fo/Vi or Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage. Output Signal Frequency refers to the rate at which a signal changes or oscillates in an electrical or electronic system & Input Voltage is the electrical potential difference applied to the input terminals of a component or system.
How to calculate Voltage to Frequency Conversion Factor in ICs?
The Voltage to Frequency Conversion Factor in ICs formula is defined as the relationship between an input voltage signal and the resulting output frequency of the IC is calculated using Voltage to Frequency Conversion Factor in ICs = Output Signal Frequency/Input Voltage. To calculate Voltage to Frequency Conversion Factor in ICs, you need Output Signal Frequency (fo) & Input Voltage (Vi). With our tool, you need to enter the respective value for Output Signal Frequency & Input 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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