Series circuits

The circuits you used at Stage 7 were all series circuits. Series means all the components are connected end-to-end or one after the other. We sometimes say the components are connected in series.

In a series circuit, there is only one path for the current to flow. This means the current is the same all the way around a series circuit. In a series circuit, all of the current flowing out of one component flows into the next component.

The circuit in this diagram is a series circuit.

If the switch in this circuit is opened, both the lamp and the buzzer will stop operating. They both stop operating at the same time because the current in the whole circuit stops flowing when the switch is opened.

If we want to operate the lamp and the buzzer separately from the same cell, then we need a parallel circuit.

Parallel circuits

In a parallel circuit, there is more than one path for the current to flow. The paths where the current can flow are called branches.

The name parallel comes from the circuit diagram because the branches are drawn using parallel lines. The components in each of the branches are sometimes said to be connected in parallel.

Look at the parallel circuit in the diagram to the right. Current from the cell flows to the branch in the circuit. At the branch, the current is divided. If the two lamps are the same, the current will be divided equally between them.

When the current comes to the other side where the branches join again, the current combines (adds together) again.

The parallel circuit in this diagram below has ammeters to show how the current is shared between the branches.

Advantages of parallel circuits

In a parallel circuit, the current through a branch can keep flowing, even if the current stops flowing in the other branches.

This means:

• components in the same circuit can be switched on and off independently
• if a component in one branch stops working, the other branches are not affected

Look at the parallel circuit in the diagram on the right. The circuit has two branches. Each branch has a lamp and a switch.

When switch S₁ is closed, then lamp L₁ will light. This will not affect lamp L₂ because L₂ is on a different branch.

When switch S₂ is closed, then lamp L₂ will light. This will not affect lamp L₁ because L₁ is on a different branch.

If both lamps are switched on and lamp L₁ stops working, then lamp L₂ will not be affected.

Components in a parallel circuit can be switched on and off separately by having switches on each branch. The components can also be all switched on or off together if the switch is between the cell and the branches.

Look at this second circuit diagram on the right. For any lamp to light in this circuit, switch S₄ must be closed.

Switches S₁, S₂ and S₃ can then be used to control each lamp separately.

If all the lamps are on, then opening S₄ will cause all of the lamps to go off.

If all the lamps are off, but switches S₁, S₂ and S₃ are closed, then closing S₄ will cause all lamps to light together.

Connecting What You've Learned

In the previous lesson, you explored parallel circuits — systems where electric current can take multiple paths. You learned that in parallel circuits, the voltage across each component is the same, and adding more components doesn't reduce the brightness of the bulbs because the current divides across the branches.

Now, you're ready to dig deeper into what makes this happen: voltage. Understanding voltage is key to predicting how components behave in both series and parallel circuits. You'll see how changing the voltage affects things like brightness, current strength, and energy transfer.

This next section will help you answer questions like: What exactly is voltage? How does it drive current? And why does it behave differently in parallel vs. series circuits?

What is voltage?

Voltage is linked to the electrical energy in a circuit. Voltage is measured in units called volts. The symbol for volts is V.

Voltage is related to the electrical energy supplied to a circuit by the cell, battery or power supply. Voltage is linked to energy, but it is not the same as energy.

Most cells supply 1.5 V. A battery is two or more cells connected in series. Batteries commonly supply 6 V, 9 V or 12 V. Each of the cells or batteries in this picture has a different voltage.

The sockets found on the walls of buildings supply a mains voltage. Mains in this context means an electrical supply that comes from a power station or generator of some kind. In most countries the mains voltage is between 220 and 240 V. In some countries, the mains voltage is 110 or 120 V. The next picture shows some mains sockets from different countries.

Sometimes, we refer to the source of energy in a circuit as the supply. The supply could be a cell, a battery, a power supply or the mains.

This diagram shows circuit symbols for a battery made from two cells, a battery made from many cells, and a 240 V mains supply.

Voltage is also linked to the energy changed by components in a circuit. For example, lamps change electrical energy into light and thermal energy. Most components have a voltage rating.

The lamps used in schools for electrical experiments are often rated at 3 V or 6 V. The rating tells us the maximum voltage that can be used.

Measuring voltage

Voltage is measured using a voltmeter.

This picture shows a digital voltmeter, an analogue voltmeter and the circuit symbol for a voltmeter.

A voltmeter is connected in a different way to an ammeter.

An ammeter measures the current flowing through a component, so the ammeter is connected in series with the component.

The voltmeter measures the energy difference either side of a component, so the voltmeter is connected in parallel with the component.

Look at the drawing of the circuit and circuit diagram. The ammeter is connected in series with the lamp and the voltmeter is connected in parallel with the lamp.

Voltage in a series circuit

Energy is always conserved, so the energy changed by the components in a circuit must be equal to the energy supplied by the cell, battery or power supply.

That means the voltages across each component in a series circuit must add up to the voltage of the supply.

Look at the circuit in this diagram. All three lamps are identical. They change the same quantity of energy, so have the same voltage. The voltage across all the lamps adds up to the voltage from the battery.

Look at this next circuit, where the components are not the same.

In this circuit, the lamp is changing more energy than the buzzer, so the voltage across the lamp is higher than the buzzer. The voltages across the lamp and buzzer add up to the voltage of the battery.

The voltages across all the components in a series circuit add up to the voltage of the supply.

We discovered at Stage 7 that the current is the same all the way around a series circuit. This is because the circuit has no branches and the current can only flow in one path. The voltage in a series circuit can be different across different components.

Adding more components in a series circuit

The voltage from the supply in a series circuit is shared between each of the components. That means adding components such as lamps or buzzers will cause each component to get a smaller share of the voltage.

Compare these two series circuits. Both have the same type of battery and both have identical lamps.

Adding more components in a series circuit will decrease the current. As components are added, it becomes more difficult for the power supply to push the electrons around the circuit.

Compare these two series circuits. The one with more components has a smaller current.

Adding more cells in a series circuit increases the voltage of the supply.

One 1.5 V cell gives a supply voltage of 1.5 V.
Two 1.5 V cells gives a supply voltage of 2 × 1.5 V = 3 V.
A 12 V battery contains eight cells each of 1.5 V making 8 × 1.5 V = 12 V.

Increasing the number of cells in the same series circuit will:

• increase the current in the circuit
• increase the voltage across each component

Voltage in a parallel circuit

Look carefully at the drawing of a parallel circuit.
Lamp 1 is connected directly across the terminals of the 1.5 V cell. The voltage across lamp 1 is 1.5 V.

If you follow the wires from lamp 2, you can get to the terminals of the cell without going through lamp 1. That means we can think of lamp 2 also being connected directly across the terminals of the cell. That means the voltage across lamp 2 is also 1.5 V.

The voltages across each of the branches of a parallel circuit are equal to the voltage of the supply.

The voltage of the battery in both circuits is 9 V.
In the left circuit, the voltage across each lamp is also 9 V.

Look at the right circuit and you will see that the voltage across the branches of a parallel circuit is the same whether or not the components are the same. The lamp and the buzzer are different, but the voltage across the branches is still the same (9 V).

Last topic explained that the current can be different in the branches of a parallel circuit. This is because the current can flow in different paths. The voltage in all branches of a parallel circuit is the same.

Adding more components in a parallel circuit

Adding more branches to a parallel circuit gives more paths for the current to flow through. The more paths there are for current to flow through, the easier it becomes. That means the current through the cell increases.

Compare these two parallel circuits. Each has the same type of battery and the lamps are identical.

Adding more components to any one branch of a parallel circuit will decrease the current in that branch. Remember that the voltage across any branch will be the same, so adding more components in the branch makes it harder for current to flow in that branch.

Adding cells to a parallel circuit increases the supply voltage so it also:

• increases the voltage across each branch
• increases the current through the cell
• increases the current through each branch