🏠 Home › 📚 CSEC Physics › ⚡ Current Electricity

Current Electricity: Circuits, Ohm’s Law & Resistance

CSEC Physics: Electrical Energy & Circuits

Essential Understanding: Current electricity involves the flow of electric charge through conductors. Understanding circuits, resistance, and the relationship between voltage, current, and resistance is fundamental to how all modern technology works – from smartphones to the power grid.

🔑 Key Skill: Ohm’s Law ($V = IR$)

📈 Exam Focus: Series & Parallel Circuit Calculations

🎯 Problem Solving: Circuit Analysis & Resistance

Core Concepts: Understanding Electric Current

⚡

Electric Current ($I$)

Definition: The rate of flow of electric charge through a conductor.

Formula: $$I = \frac{Q}{t}$$

$I$: Current (Amperes, A)
$Q$: Charge (Coulombs, C)
$t$: Time (seconds, s)

Unit: Ampere (A) or Amperes

Note: 1 Ampere = 1 Coulomb/second

🔋

Potential Difference / Voltage ($V$)

Definition: The work done to move a unit charge between two points in a circuit. It is the “push” that drives current through the circuit.

Formula: $$V = \frac{W}{Q}$$

$V$: Potential Difference (Volts, V)
$W$: Work done (Joules, J)
$Q$: Charge (Coulombs, C)

Unit: Volt (V)

Note: 1 Volt = 1 Joule/Coulomb

🧱

Electrical Resistance ($R$)

Definition: The opposition that a conductor offers to the flow of electric current.

Formula: $$R = \frac{V}{I}$$

$R$: Resistance (Ohms, $\Omega$)
$V$: Potential Difference (Volts, V)
$I$: Current (Amperes, A)

Unit: Ohm ($\Omega$ – Greek letter omega)

💡

Electrical Power ($P$)

Definition: The rate at which electrical energy is transferred or consumed in a circuit.

Formulas:

$$P = VI$$
$$P = I^2R$$
$$P = \frac{V^2}{R}$$

Unit: Watt (W)

Ohm’s Law

The most fundamental relationship in DC circuit analysis:

$$V = IR$$

The Ohm’s Law Triangle: Cover the quantity you want to solve for to see the formula.

For $V$: $V = I \times R$

For $I$: $I = \frac{V}{R}$

For $R$: $R = \frac{V}{I}$

Interactive Circuit Lab

🔌

Circuit Builder & Ohm’s Law Explorer

Objective: Explore how voltage, current, and resistance are related. Adjust the voltage and resistance to see how current changes in the circuit.

Voltage (V)

12 V

Current (I)

1.20 A

Resistance (R)

10 Ω

Calculation: Using $I = \frac{V}{R}$

I = 12 / 10 = 1.20 A

Factors Affecting Resistance

The resistance of a conductor depends on four main factors:

Resistance Formula

$$R = \rho \frac{L}{A}$$

Where:

$\rho$ (rho) = Resistivity of the material ($\Omega \cdot m$)
$L$ = Length of the conductor (m)
$A$ = Cross-sectional area ($m^2$)

📏

Length ($L$)

Relationship: Resistance is directly proportional to length.

$$R \propto L$$

Explanation: Longer conductors have more atoms for electrons to collide with, increasing resistance.

⬜

Cross-Sectional Area ($A$)

Relationship: Resistance is inversely proportional to area.

$$R \propto \frac{1}{A}$$

Explanation: Thicker wires provide more pathways for current, reducing resistance.

🔬

Material (Resistivity $\rho$)

Explanation: Different materials have different resistivities.

Good conductors: Copper, Silver, Aluminum ($\rho$ very low)
Resistors: Carbon, Constantan ($\rho$ moderate)
Insulators: Rubber, Plastic, Glass ($\rho$ very high)

🌡️

Temperature

Relationship: For most conductors, resistance increases with temperature.

Explanation: Higher temperature causes more lattice vibrations, increasing electron collisions.

Exception: For some materials (thermistors), resistance decreases with temperature.

Key Observations:

Resistance is directly proportional to length ($R \propto L$)
Resistance is inversely proportional to cross-sectional area ($R \propto \frac{1}{A}$)
Thicker wires (larger diameter) have lower resistance

Series Circuits

In a series circuit, components are connected one after another in a single loop. There is only one path for the current to flow.

Series Circuit Rules

1. Current ($I$): The current is the same throughout all components.

$$I_{\text{total}} = I_1 = I_2 = I_3 = \dots$$

2. Voltage ($V$): The total voltage is the sum of individual voltage drops.

$$V_{\text{total}} = V_1 + V_2 + V_3 + \dots$$

3. Resistance ($R$): The total resistance is the sum of individual resistances.

$$R_{\text{total}} = R_1 + R_2 + R_3 + \dots$$

Series Circuit Diagram

💡

Worked Example: Series Circuit

Problem: Two resistors of 4Ω and 6Ω are connected in series to a 20V battery. Calculate: (a) the total resistance, (b) the current in the circuit, and (c) the voltage across each resistor.

Calculate Total Resistance:
$$R_{\text{total}} = R_1 + R_2 = 4\Omega + 6\Omega = 10\Omega$$

Calculate Current using Ohm’s Law:
$$I = \frac{V}{R} = \frac{20V}{10\Omega} = 2A$$

Calculate Voltage across each resistor:
$$V_1 = I \times R_1 = 2A \times 4\Omega = 8V$$
$$V_2 = I \times R_2 = 2A \times 6\Omega = 12V$$
Check: $V_1 + V_2 = 8V + 12V = 20V$ ✓

Series Circuit Characteristics

If one component fails (open circuit), the entire circuit stops working
Total resistance is always greater than the largest individual resistance
Voltage drops add up to the source voltage

Parallel Circuits

In a parallel circuit, components are connected across the same voltage source, providing multiple paths for current to flow.

Parallel Circuit Rules

1. Voltage ($V$): The voltage is the same across all parallel branches.

$$V_{\text{total}} = V_1 = V_2 = V_3 = \dots$$

2. Current ($I$): The total current is the sum of currents in individual branches.

$$I_{\text{total}} = I_1 + I_2 + I_3 + \dots$$

3. Resistance ($R$): The reciprocal of total resistance is the sum of reciprocals.

$$\frac{1}{R_{\text{total}}} = \frac{1}{R_1} + \frac{1}{R_2} + \frac{1}{R_3} + \dots$$

For two resistors in parallel:

$$R_{\text{total}} = \frac{R_1 \times R_2}{R_1 + R_2}$$

Parallel Circuit Diagram

🏠

Worked Example: Parallel Circuit

Problem: Three resistors of 2Ω, 3Ω, and 6Ω are connected in parallel across a 12V battery. Calculate: (a) the total resistance, (b) the current through each resistor, and (c) the total current.

Calculate Total Resistance:
$$\frac{1}{R_{\text{total}}} = \frac{1}{2} + \frac{1}{3} + \frac{1}{6} = \frac{3}{6} + \frac{2}{6} + \frac{1}{6} = \frac{6}{6} = 1$$
$$R_{\text{total}} = 1\Omega$$

Calculate Current through each resistor (V = 12V for all):
$$I_1 = \frac{V}{R_1} = \frac{12}{2} = 6A$$
$$I_2 = \frac{V}{R_2} = \frac{12}{3} = 4A$$
$$I_3 = \frac{V}{R_3} = \frac{12}{6} = 2A$$

Calculate Total Current:
$$I_{\text{total}} = I_1 + I_2 + I_3 = 6A + 4A + 2A = 12A$$
Check: $I_{\text{total}} = \frac{V}{R_{\text{total}}} = \frac{12}{1} = 12A$ ✓

Parallel Circuit Characteristics

If one component fails, other branches continue working
Total resistance is always less than the smallest individual resistance
Each branch gets the full source voltage

Combined Series-Parallel Circuits

Many real circuits contain both series and parallel components. The key is to simplify step by step.

🔧

Worked Example: Combined Circuit

Problem: A 4Ω resistor is connected in series with a parallel combination of two 6Ω resistors. The circuit is connected to a 24V battery. Calculate the total current.

Simplify the parallel section first:
Two 6Ω resistors in parallel:
$$R_{\text{parallel}} = \frac{6 \times 6}{6 + 6} = \frac{36}{12} = 3\Omega$$

Calculate total resistance:
$$R_{\text{total}} = R_{\text{series}} + R_{\text{parallel}} = 4\Omega + 3\Omega = 7\Omega$$

Calculate total current:
$$I_{\text{total}} = \frac{V}{R_{\text{total}}} = \frac{24V}{7\Omega} \approx 3.43A$$

🎯

CSEC Examination Mastery Tip

Step-by-Step Approach for Complex Circuits:

Identify which components are in series and which are in parallel
Start simplifying from the furthest point from the battery working back
Calculate equivalent resistances step by step
Find total current using Ohm’s Law ($I = \frac{V}{R_{\text{total}}}$)
Work backwards to find currents and voltages in individual components
ALWAYS draw a circuit diagram with your values labeled

Comparing Series and Parallel Circuits

Characteristic	Series Circuit	Parallel Circuit
Current ($I$)	Same through all components	Splits between branches; total = sum of branch currents
Voltage ($V$)	Split between components; total = sum of voltage drops	Same across all components
Resistance ($R$)	Total = sum of individual resistances ($R_{\text{total}} > R_{\text{any}}$)	Reciprocal formula; total < smallest resistance ($R_{\text{total}} < R_{\text{any}}$)
Failure Mode	One component fails → entire circuit stops	One component fails → other branches still work
Common Use	String lights, switches, fuses	Household wiring, car tail lights, appliances

CSEC Practice Arena

Test Your Understanding

A charge of 50C flows through a conductor in 10 seconds. What is the current?

0.5 A

5 A

500 A

60 A

Solution: $$I = \frac{Q}{t} = \frac{50}{10} = 5A$$

What is the total resistance of three 6Ω resistors connected in series?

2 Ω

6 Ω

12 Ω

18 Ω

Solution: $$R_{\text{total}} = R_1 + R_2 + R_3 = 6 + 6 + 6 = 18\Omega$$

Two 12Ω resistors are connected in parallel. What is the equivalent resistance?

6 Ω

12 Ω

24 Ω

4 Ω

Solution: For two equal resistors in parallel: $$R_{\text{total}} = \frac{R}{n} = \frac{12}{2} = 6\Omega$$
Or using formula: $$R_{\text{total}} = \frac{12 \times 12}{12 + 12} = \frac{144}{24} = 6\Omega$$

A 100W electric bulb is connected to a 240V supply. What is the resistance of the bulb?

240 Ω

2.4 Ω

576 Ω

24 Ω

Solution: $$P = \frac{V^2}{R}$$ so $$R = \frac{V^2}{P} = \frac{240^2}{100} = \frac{57600}{100} = 576\Omega$$

Which statement is TRUE about parallel circuits?

Total resistance is greater than any individual resistance

The current is the same through all components

The voltage is the same across all components

Total resistance equals the sum of all resistances

Explanation: In parallel circuits, all components are connected directly across the voltage source, so they all experience the same voltage. In series circuits, current is the same through all components.

CSEC Past Paper Questions

📝

CSEC Past Paper Practice

The following questions are based on actual CSEC Physics examination patterns. Practice these to prepare for your exams!

(CSEC 2022 Paper 2) Two resistors of resistance 3Ω and 6Ω are connected in series to a battery of emf 9V. Calculate: (a) the total resistance of the circuit (b) the current flowing in the circuit (c) the potential difference across the 3Ω resistor.

Solution:

(a) Total Resistance:
$$R_{\text{total}} = R_1 + R_2 = 3\Omega + 6\Omega = 9\Omega$$

(b) Current:
$$I = \frac{V}{R} = \frac{9V}{9\Omega} = 1A$$

(c) Potential Difference across 3Ω resistor:
$$V = IR = 1A \times 3\Omega = 3V$$

(CSEC 2021 Paper 2) (a) State Ohm’s Law. (b) A wire of length 2m has a resistance of 4Ω. If the same wire is stretched to a length of 4m, what is the new resistance? (Assume the cross-sectional area remains constant).

Solution:

(a) Ohm’s Law:
The current flowing through a conductor is directly proportional to the potential difference across it, provided the temperature remains constant.
Or: $$V = IR$$

(b) New Resistance:
Since $$R \propto L$$ (resistance is directly proportional to length), and length doubles from 2m to 4m:
New resistance = $$4\Omega \times 2 = 8\Omega$$

(CSEC 2020 Paper 2) (a) State two differences between series and parallel circuits. (b) Three identical lamps are connected in parallel across a 12V supply. If the current through each lamp is 0.5A, calculate (i) the total current (ii) the resistance of each lamp.

Solution:

(a) Two differences:

In series, current is the same through all components; in parallel, current splits.
In series, total resistance equals sum; in parallel, total resistance is less than smallest.
In series, if one component fails, all stop; in parallel, others continue.

(b)(i) Total Current:
$$I_{\text{total}} = 3 \times 0.5A = 1.5A$$

(b)(ii) Resistance of each lamp:
$$R = \frac{V}{I} = \frac{12V}{0.5A} = 24\Omega$$

(CSEC 2019 Paper 2) (a) What is meant by the resistivity of a material? (b) A copper wire has a resistance of 2Ω and a length of 100m. Calculate its resistance if it is replaced by another copper wire of the same material but with (i) twice the length (ii) half the cross-sectional area.

Solution:

(a) Resistivity:
The resistivity of a material is the resistance of a unit length of the material having unit cross-sectional area. It is a property of the material itself.

(b)(i) Twice the length:
Since $$R \propto L$$, new resistance = $$2\Omega \times 2 = 4\Omega$$

(b)(ii) Half the cross-sectional area:
Since $$R \propto \frac{1}{A}$$, if area is halved, resistance doubles.
New resistance = $$2\Omega \times 2 = 4\Omega$$

Key Examination Insights

Common Mistakes to Avoid

Confusing series and parallel formulas
Forgetting that voltage is the same in parallel (not current)
Not showing working for calculations
Using the wrong units (always check units before calculating)
Forgetting that adding resistors in parallel decreases total resistance

Success Strategies

Always draw circuit diagrams with labeled values
Write formulas before substituting values
Check your answers using Kirchhoff’s Laws
Remember: $V = IR$ is your best friend
For parallel, start with $\frac{1}{R_{\text{total}}}$ when you have different values

Electrical Energy and Power

Power Formulas

$$P = VI = I^2R = \frac{V^2}{R}$$

Energy: $E = P \times t$ (Joules) or $E = VIt$ (Joules)

💡

Worked Example: Electrical Power

Problem: A kettle has a power rating of 2kW when connected to a 240V supply. Calculate (a) the current drawn by the kettle (b) the resistance of the heating element.

Convert units:
Power $P = 2kW = 2000W$
Voltage $V = 240V$

(a) Calculate Current:
Using $P = VI$, rearrange to get $I = \frac{P}{V}$
$$I = \frac{2000W}{240V} = 8.33A$$

(b) Calculate Resistance:
Using $P = \frac{V^2}{R}$, rearrange to get $R = \frac{V^2}{P}$
$$R = \frac{240^2}{2000} = \frac{57600}{2000} = 28.8\Omega$$