## Voltage across Passive Filter Capacitor Solution

STEP 0: Pre-Calculation Summary
Formula Used
Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component
Vc = β*Vt
This formula uses 3 Variables
Variables Used
Voltage across the Passive Filter Capacitor - (Measured in Volt) - Voltage across the Passive Filter Capacitor is created by the interaction of the fundamental frequency component of the input voltage and the reactance of the capacitor.
Filter Transfer Function - Filter Transfer Function is a mathematical representation of how the filter affects the frequency components of an input signal.
Fundamental Frequency Component - (Measured in Volt) - Fundamental Frequency Component is the voltage at the desired operating frequency of the filter.
STEP 1: Convert Input(s) to Base Unit
Filter Transfer Function: 18 --> No Conversion Required
Fundamental Frequency Component: 7 Volt --> 7 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Vc = β*Vt --> 18*7
Evaluating ... ...
Vc = 126
STEP 3: Convert Result to Output's Unit
126 Volt --> No Conversion Required
126 Volt <-- Voltage across the Passive Filter Capacitor
(Calculation completed in 00.004 seconds)
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## < 15 Power Filters Calculators

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Phase Angle = 2*arctan(2*pi*Frequency*Resistance*Capacitance)
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Resonant Frequency = 1/(2*pi*sqrt(Inductance*Capacitance))
Tuned Factor of Hybrid Filter
Tuned Factor = (Angular Frequency-Angular Resonant Frequency)/Angular Resonant Frequency
Voltage across Passive Filter Capacitor
Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component
Angular Resonant Frequency of Passive Filter
Angular Resonant Frequency = (Resistance*Quality Factor)/Inductance
Quality Factor of Passive Filter
Quality Factor = (Angular Resonant Frequency*Inductance)/Resistance
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Gain of Converter = DC Voltage/(2*Triangular Waveform Amplitude)
Amplitude of Active Power Filter
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## Voltage across Passive Filter Capacitor Formula

Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component
Vc = β*Vt

## What is the purpose of a passive filter capacitor?

A passive filter capacitor serves various purposes in electronic circuits, primarily for frequency filtering and power factor correction. Here's a detailed explanation of its functions:

Frequency Filtering: Passive filter capacitors are crucial components in electronic circuits for filtering out unwanted frequency components from a signal. They block or attenuate specific frequencies while allowing the desired frequencies to pass through.

Power Factor Correction: Passive filter capacitors play a significant role in improving power factor, especially in circuits with inductive loads. Inductive loads, such as motors and transfor

## How to Calculate Voltage across Passive Filter Capacitor?

Voltage across Passive Filter Capacitor calculator uses Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component to calculate the Voltage across the Passive Filter Capacitor, The Voltage across Passive Filter Capacitor formula is defined as the voltage across the capacitor is controlled by generating a voltage at the fundamental frequency of the input voltage. Voltage across the Passive Filter Capacitor is denoted by Vc symbol.

How to calculate Voltage across Passive Filter Capacitor using this online calculator? To use this online calculator for Voltage across Passive Filter Capacitor, enter Filter Transfer Function (β) & Fundamental Frequency Component (Vt) and hit the calculate button. Here is how the Voltage across Passive Filter Capacitor calculation can be explained with given input values -> 126 = 18*7.

### FAQ

What is Voltage across Passive Filter Capacitor?
The Voltage across Passive Filter Capacitor formula is defined as the voltage across the capacitor is controlled by generating a voltage at the fundamental frequency of the input voltage and is represented as Vc = β*Vt or Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component. Filter Transfer Function is a mathematical representation of how the filter affects the frequency components of an input signal & Fundamental Frequency Component is the voltage at the desired operating frequency of the filter.
How to calculate Voltage across Passive Filter Capacitor?
The Voltage across Passive Filter Capacitor formula is defined as the voltage across the capacitor is controlled by generating a voltage at the fundamental frequency of the input voltage is calculated using Voltage across the Passive Filter Capacitor = Filter Transfer Function*Fundamental Frequency Component. To calculate Voltage across Passive Filter Capacitor, you need Filter Transfer Function (β) & Fundamental Frequency Component (Vt). With our tool, you need to enter the respective value for Filter Transfer Function & Fundamental Frequency Component and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well. Let Others Know