5.1.4 Circuits

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In electrical circuits, the arrangement of resistors affects the overall resistance of the circuit. There are two common ways to connect resistors: in series and in parallel. Each configuration has its own rule for calculating the total resistance.

1. Series and Parallel Resistors

Series Connection: The total resistance, $R_T$ , is the sum of the individual resistances.

R_T = R_1 + R_2 + R_3 + \dots

Parallel Connection: The reciprocal of the total resistance is the sum of the reciprocals of the individual resistances.

\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2} + \frac{1}{R_3} + \dots

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Example Calculation

To find the total resistance in a mixed series and parallel circuit:

Calculate the resistance of the parallel section first:

\frac{1}{R_{\text{parallel}}} = \frac{1}{4} + \frac{1}{16} = \frac{5}{16}

So,\ R_{\text{parallel}} = :highlight[3.2 \, \Omega]

Use the series rule to add the resistances:

R_T = 10 \, \Omega + 3 \, \Omega + 3.2 \, \Omega = :highlight[16.2 \, \Omega]

Therefore, the total resistance is $:highlight[16.2\ Ω.]$

2. Power and Energy Transfer in Circuits

Power ( $P$ ) is the rate of energy transfer. It is calculated using:

P = \frac{E}{t} \quad \text{or} \quad P = VI \quad \text{or} \quad P = I^2 R \quad \text{or} \quad P = \frac{V^2}{R}

where $E$ is the energy transferred, $V$ is the potential difference, $I$ is the current, and $R$ is the resistance.

Energy Transferred (E):

E = VIt

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Example Problem

If a lamp has a power rating of $:highlight[60]$ W and operates at $:highlight[240]$ V, calculate the energy used in $:highlight[2]$ minutes and the current in the lamp.

Energy Calculation: Convert time to seconds: $2 \text{ minutes} = :highlight[120 \text{ s}]$ .

E = Pt = 60 \times 120 = :highlight[7200 \, \text{J}]

Current Calculation:

I = \frac{P}{V} = \frac{60}{240} = :highlight[0.25 \, \text{A}]

3. Series and Parallel Circuits – Current and Voltage Distribution

Series Circuits:
- The current is the same throughout the circuit.
- The total potential difference (p.d.) across the circuit is the sum of the potential differences across each component.

Parallel Circuits:
- The total current is the sum of the currents through each branch.
- The potential difference across each branch is the same.

4. Battery Cells in Series and Parallel

When connected in series, the total voltage is the sum of each cell's voltage.

V_T = V_1 + V_2 + V_3 + \dots

When identical cells are connected in parallel, the total voltage remains the same as a single cell's voltage.

5. Kirchhoff's Laws

Kirchhoff's First Law: The total current flowing into a junction is equal to the total current flowing out. This is based on conservation of charge.
Kirchhoff's Second Law: In any closed loop within a circuit, the sum of the electromotive forces (e.m.f.s) is equal to the sum of the potential drops. This law follows the conservation of energy.

Circuits Simplified Revision Notes for A-Level AQA Physics

5.1.4 Circuits

1. Series and Parallel Resistors

Example Calculation

2. Power and Energy Transfer in Circuits

Example Problem

3. Series and Parallel Circuits – Current and Voltage Distribution

4. Battery Cells in Series and Parallel

5. Kirchhoff's Laws

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