In this article, we shall discuss different methods on How To Calculate Voltage In Parallel Circuits. A parallel connection divides the circuit into branches to let current distributively flow through all of them.

**Parallel circuits follow the law of conservation of energy. Voltage can be said as electrical work done per unit charge. Electric fields are conservative, which means electrical work depends only on starting and end points. All the branches have a common initial and final node in a parallel connection. Therefore voltage is equal.**

**Read more on…..Parallel Circuit Function:Complete Insights and FAQs**

**How To Calculate Voltage In Parallel Circuit- Numerical Examples**

**Q1. As shown in the circuit, two equally valued resistors are joined with a voltage source in parallel. Some values are given: i**_{1}= 3 A, equivalent resistance R_{eq}= 15 ohm . Find the source voltage V_{s}.

_{1}= 3 A, equivalent resistance R

_{eq}= 15 ohm . Find the source voltage V

_{s}.

Let us assume R_{1} = R_{2} = R ohm. Therefore, the equivalent resistance,

*R _{eq} = (1/R + 1/R)^{-1} = R/2Ω*

Given R/2 = 15, So the value of each resistor = 15 × 2 = 30 ohm. The value of current i_{1} is given as 3 A.

As it is a parallel circuit, voltage across a branch will be the same voltage across any other branch, and that will be the supply voltage as well. Hence, the source voltage,

*V _{s }= current in a branch x corresponding resistance value = i_{1} x R = 3 x 30 = 90 V *

**Q2. A parallel network consists of five resistors, R, 2R, 4R, 8R, and 16R. Net current in the network is I. Find the voltage in the branch containing the 4R resistor.**

We shall first find out the equivalent resistance of the network for calculating the voltage at any point of the network. The equivalent resistance in a parallel circuit is,

*R _{eq} = (1/R_{1} + 1/R_{2 }+ 1/R_{3} … + 1/R_{n})^{-1}*

Here,* R _{eq} = ((1/R + (1/2R + (1/4R + (1/8R + (1/16R)^{-1} = (16R/31)Ω*

The total current in the circuit is given as I Amp.

Therefore, source voltage *V _{s} = I x 16R/31 = 16IR/31 V*

We know that a parallel circuit’s source voltage is the same as the voltage in any branch of the circuit. So, the voltage in the branch containing the 4R resistor is 16IR/31 V.

**How To Calculate Voltage In Parallel Circuit- FAQs**

**How to find total voltage in a parallel circuit?**

In a parallel circuit, the total voltage is the same as the branch voltages. In other words, the voltage remains the same across all the branches joined in parallel. Branches are just different paths for current.

**Steps for calculating voltage in a parallel circuit with resistance and total current given are:**

**Find the equivalent resistance using the formula-***R*_{eq}= (1/R_{1}+ 1/R_{2 }+ 1/R_{3}… + 1/R_{n})^{-1}**Multiply Req with the total current.**

**If only one resistance and the respective current value are given, multiply them to get the voltage.**

**Read more on……Parallel Circuit Examples: Complete Insights and FAQs**

**How to find missing voltage in a parallel circuit?**

By “missing voltage” in a parallel circuit, we mean the supplied voltage as it is the same for all the branches. So, if we have any current and resistance value, we can find out the voltage in the parallel circuit.

**Let us understand this with the help of an example. Suppose there are two resistors of 2 ohms and 4 ohms connected in parallel. Current passing through the 2-ohm resistor is given as 1.5 A. We know supply voltage V _{s}= branch voltage V_{1} = branch voltage V_{2}. Therefore, missing voltage V = iR = 2 x 1.5 = 3 x V.**

**How to find source voltage in a series parallel circuit?**

According to the principle of a parallel circuit, the voltage in every branch is the same and equal to the source voltage. If the source voltage is Vs and the branch voltages are V_{1}, V_{2},….V_{n} then V_{s} = V_{1} = V_{2} =….= V_{n}.

**If the source voltage is given, we already have the branch voltages. If the source voltage is unknown and current values are given, we can find out the voltage with the help of ohm’s law. For example, if the current through a branch is 5 A and the resistance value is 2 ohms, the voltage is simply 5 × 2 = 10 V.**

**Read more on……Is Current The Same In Parallel: Complete Insights and FAQs**

**How to find applied voltage in a parallel circuit?**

Applied voltage in parallel circuitry refers to the source voltage or the battery voltage. It is given, or we can compute it with the help of other information provided, such as current and resistance values.

**Applied voltages mean the voltage given to an element. In a parallel circuit, the applied voltage is the total voltage. It is also the same as voltage drops in individual branches of the circuit. But if the parallel circuit is not the only part of the network, the applied voltage and branch voltages won’t be equal.**

### Equations and Calculations

**Ohm’s Law**:

- Ohm’s Law states ( V = IR ), where ( V ) is voltage, ( I ) is current, and ( R ) is resistance.
- In a parallel circuit, the voltage across each component (branch) is equal to the source voltage.

**Total Current in Parallel Circuits**:

- The total current supplied by the source is the sum of the currents through each parallel branch.
- Using Ohm’s Law: .

### Examples

**Simple Parallel Circuit**:

- Suppose you have a parallel circuit with a 12V battery and three resistors (R1, R2, R3) of values 4Ω, 6Ω, and 12Ω, respectively.
- The voltage across each resistor is 12V.
- The current through each resistor is , , and .
- Total current from the battery is .

**Parallel Circuit as Part of a Larger Network**:

- If a parallel circuit is a portion of a more extensive network, the applied voltage to the parallel section might differ from the source voltage.
- For instance, if there’s a series component with a voltage drop, the voltage across the parallel portion will be the source voltage minus the voltage drop across the series component.
- Example: A 12V battery with a series resistor (2Ω) and a parallel section. If 2V drops across the series resistor, the applied voltage to the parallel circuit is 10V (12V – 2V).

**Also Read:**

- Does the amplitude of a signal impact its energy
- Amplifier vs receiver what s the difference
- Is there a significant energy saving when switching to leds
- When should a differentiator circuit be used
- Do diodes have a lifespan or wear out over time
- How does a flip flop affect frequency division
- Why are certain frequencies attenuated in a given system
- What is an amplifier
- How can one minimize flip flop glitches
- What are the advantages of using leds over traditional light sources

Hi……I am Kaushikee Banerjee completed my master’s in Electronics and Communications. I am an electronics enthusiast and am currently devoted to the field of Electronics and Communications. My interest lies in exploring cutting-edge technologies. I’m an enthusiastic learner and I tinker around with open-source electronics.