# How To Make A Parallel Circuit On Breadboard

By | September 15, 2023

## How to Make a Parallel Circuit on a Breadboard

A parallel circuit is a type of electrical circuit in which the components are connected in parallel. This means that each component is connected to the power source (such as a battery) and to each other, but not in series. In a series circuit, the components are connected in a single line, and the current flows through each component in turn. In a parallel circuit, the current can flow through any of the components, and the total current is the sum of the currents through each individual component. Parallel circuits are used in a variety of applications, such as lighting circuits, power distribution circuits, and computer circuits. They are often used when it is important to provide multiple paths for the current to flow, or when it is necessary to protect individual components from damage. To make a parallel circuit on a breadboard, you will need the following materials: * A breadboard * A battery * A resistor * A light bulb * Wires 1.

### Assemble the circuit.

First, connect the battery to the breadboard. The positive terminal of the battery should be connected to one of the power rails on the breadboard, and the negative terminal should be connected to the other power rail. Next, connect the resistor to the breadboard. The resistor should be connected between the positive terminal of the battery and one of the breadboard's rows. Finally, connect the light bulb to the breadboard. The light bulb should be connected between the resistor and the other breadboard row. 2.

### Test the circuit.

Once the circuit is assembled, you can test it by turning on the battery. The light bulb should light up. You can also vary the resistance of the resistor to see how it affects the brightness of the light bulb. If you increase the resistance of the resistor, the light bulb will become dimmer. If you decrease the resistance of the resistor, the light bulb will become brighter. 3.

### Understanding parallel circuits.

In a parallel circuit, the total current is the sum of the currents through each individual component. This means that if you increase the current through one component, the current through all of the other components will also increase. The voltage across each component in a parallel circuit is the same. This means that if you increase the voltage across one component, the voltage across all of the other components will also increase. The power dissipated by each component in a parallel circuit is the same. This means that if you increase the power dissipated by one component, the power dissipated by all of the other components will also increase. Parallel circuits are often used in applications where it is important to provide multiple paths for the current to flow, or when it is necessary to protect individual components from damage. Here are some of the advantages of using parallel circuits: *

### Increased current capacity:

Parallel circuits can handle more current than series circuits. This is because the total current in a parallel circuit is the sum of the currents through each individual component. *

### Redundancy:

Parallel circuits provide redundancy in case one of the components fails. If one component in a parallel circuit fails, the other components will still be able to function. *

### Protection from damage:

Parallel circuits can protect individual components from damage. If one component in a parallel circuit fails, the other components will not be affected. Here are some of the disadvantages of using parallel circuits: *

### Increased resistance:

Parallel circuits have a higher resistance than series circuits. This is because the total resistance of a parallel circuit is the reciprocal of the sum of the reciprocals of the resistances of each individual component. *

### Increased voltage drop:

Parallel circuits have a higher voltage drop than series circuits. This is because the total voltage drop across a parallel circuit is the sum of the voltage drops across each individual component. *

### Increased power dissipation:

Parallel circuits dissipate more power than series circuits. This is because the total power dissipated by a parallel circuit is the sum of the power dissipated by each individual component. Parallel circuits are a versatile and powerful tool for electrical engineers. They can be used in a variety of applications, from lighting circuits to power distribution circuits. By understanding the principles of parallel circuits, you can use them to design and build circuits that meet your specific needs.

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