ELE202 Study Hub | Electric Circuit Analysis

Exam Frequency Analysis

5 years of ELE202 exams analyzed. Every concept ranked by frequency with weighted priority scoring.

W21 Winter 2021 W22 Winter 2022 P23 Spring 2023 P24 Spring 2024 W25 Winter 2025 (×1.5 weight)

S Guaranteed Questions — 100% Frequency

These five concepts appear in every single exam and account for 100 marks total. Master these first.

Core Concepts

First-Order Transients (RL/RC) — Q1, ~20 marks
Nodal Analysis — Q2/3, ~20 marks
Mesh Analysis — Q2/3, ~20 marks
Thevenin Equivalent — Q4, ~20 marks
Power Calculations — Q5/6, ~20 marks

Weighted Priority

Weighted Score	5.4/5.0
Exams Tested	5/5 (100%)
Total Marks	~100 per exam

A High Frequency — 80%

Source Transformation Method

⚠ Required Method

Using other methods when Source Transformation is specified results in ZERO marks, even if your answer is mathematically correct.

Exam	Question	Purpose	Marks
W25	Q4(i)	Finding V_th	8
P24	Q4(1)	Finding V_th	8
W22	Q4(1)	Finding V_th	8
W21	Q4(1)	Finding V_th	8

Superposition Principle

Required for initial/final conditions when multiple sources are present. Used in 4/5 exams.

B Medium Frequency — 60%

Maximum Power Transfer

For maximum power: $$Z_L = Z_{th}^*$$ (complex conjugate)

Maximum power: $$P_{max} = \frac{|V_{th}|^2}{4 \cdot \text{Re}(Z_{th})}$$

Cramer's Rule

Explicitly required in W22, W21, P23 for solving matrix systems. 2 marks per application.

C Standard — 40%

Phasor Diagrams
Time-Domain Conversion

D Single Occurrence — 20%

Dependent Sources (W21)
Student Number Values (W21)

Required Methods Summary

Method	Exam	Question	Weight
Source Transformation	W25	Q4(i)	8 marks
	P24	Q4(1)	8 marks
	W22	Q4(1)	8 marks
	W21	Q4(1)	8 marks
Superposition	P23	Q1A(a)	5 marks
	P23	Q2(a)	9 marks
	W22	Q1b(i)	4 marks

Concept Workbook

Deep explanations of every tested concept. Circuit diagrams, formulas, and systematic solution processes.

S 1. First-Order RL Transients

First-order circuits contain one energy storage element. When a switch changes state, energy transfers between the storage element and resistors over time.

Universal Transient Equation

$$i_L(t) = i_L(\infty) + [i_L(0^+) - i_L(\infty)]e^{-t/\tau}$$

Basic RL Circuit

_s R t=0 L

Key Principles

Inductor at DC steady state (t → ∞): Acts as short circuit (wire)
Inductor at t = 0⁺: Acts as current source with value i_L(0⁺)
Current Continuity: $$i_L(0^+) = i_L(0^-)$$ — current cannot change instantaneously
Time Constant: $$\tau = \frac{L}{R_{th}}$$ where R_th is the Thevenin resistance seen by the inductor

6-Step Solution Process

Find i_L(0⁻) — Before Switch Action ▼

Circuit state: Steady state, switch in original position

Inductor: Replace with SHORT CIRCUIT (wire)

Calculate current through inductor using DC analysis.

Find i_L(0⁺) — Immediately After Switch ▼

Apply current continuity principle:

$$i_L(0^+) = i_L(0^-)$$

This is your initial condition.

Find i_L(∞) — New Steady State ▼

Circuit state: Switch in new position, steady state reached

Inductor: Again a SHORT CIRCUIT

Method: Use SUPERPOSITION if multiple sources present

Find τ — Time Constant ▼

Deactivate all sources, find R_th looking into inductor terminals:

$$\tau = \frac{L}{R_{th}}$$

Write i_L(t) Expression ▼

$$i_L(t) = i_L(\infty) + [i_L(0^+) - i_L(\infty)]e^{-t/\tau} \quad \text{for } t > 0$$

Find v_L(t) if Required ▼

$$v_L(t) = L\frac{di_L}{dt} = R_{th}[i_L(0^+) - i_L(\infty)]e^{-t/\tau}$$

S 2. First-Order RC Transients

Universal Transient Equation

$$v_C(t) = v_C(\infty) + [v_C(0^+) - v_C(\infty)]e^{-t/\tau}$$

Basic RC Circuit

_s R t=0 C

Key Differences from RL

Property	RL Circuit	RC Circuit
Time Constant	$\tau = L/R$	$\tau = RC$
Continuity	$i_L(0^+) = i_L(0^-)$	$v_C(0^+) = v_C(0^-)$
Steady State	L = Short Circuit	C = Open Circuit
At t = 0⁺	Current source	Voltage source

S 3. Nodal Analysis (AC Phasor)

Nodal analysis uses KCL at each non-reference node. Sum of currents entering = sum of currents leaving.

_s1 Z₁ V̄₁ Z₃ V̄₂ Ī_s Z₂

Process

Convert to phasor: $v(t) = V_m \cos(\omega t + \phi) \rightarrow \bar{V} = V_m \angle \phi$
Identify non-reference nodes: $\bar{V}_1, \bar{V}_2, \ldots$
Write KCL at each node
Express currents as $(\bar{V}_{node} - \bar{V}_{adjacent})/Z$
Form matrix and solve

Impedances

$$Z_R = R \quad \quad Z_L = j\omega L \quad \quad Z_C = \frac{1}{j\omega C} = \frac{-j}{\omega C}$$

S 4. Mesh Analysis (AC Phasor)

Mesh analysis uses KVL around each mesh (loop without other loops inside).

_s1 Z₁ Z₃ Z₂ V̄_s2 Ī₁ ↷ ↶ Ī₂

Key Points

Assign clockwise mesh currents: $\bar{I}_1, \bar{I}_2$
Shared elements: $(\bar{I}_1 - \bar{I}_2) \times Z$
Write KVL summing voltages around each mesh

S 5. Thevenin Equivalent

Any linear circuit can be reduced to a voltage source $\bar{V}_{th}$ in series with impedance $\bar{Z}_{th}$.

⚠ Required in 4/5 Exams

Source Transformation is the required method for finding $V_{th}$. Other methods = 0 marks.

Source Transformation

_s Z Transform I = V/Z I_s Z

Voltage → Current

$$I = \frac{V_s}{Z}$$

Current → Voltage

$$V = I_s \times Z$$

S 6. Power Calculations

Power Triangle

Quantity	Formula	Unit
Complex Power	$\bar{S} = \bar{V} \times \bar{I}^* = P + jQ$	VA
Apparent Power	$\|S\| = \|V\| \times \|I\|$	VA
Real Power	$P = \|S\| \times PF = I^2R$	W
Reactive Power	$Q = I^2X$	VAR
Power Factor	$PF = \cos(\theta) = P/\|S\|$	—

PF Sign Convention

Lagging PF (inductive): Q > 0, θ > 0

Leading PF (capacitive): Q < 0, θ < 0

B 7. Maximum Power Transfer

Maximum Power Condition

$$Z_L = Z_{th}^* \quad \text{(complex conjugate)}$$ $$P_{max} = \frac{|V_{th}|^2}{4 \cdot \text{Re}(Z_{th})}$$

Full Worked Solutions

Every question type solved step-by-step with redrawn circuits at each stage.

S RL Transient with Superposition (W25 Style)

Problem

Switch open for long time. At t=0, closes. Find $i_L(t)$ using SUPERPOSITION.

₁ t=0 R₂ I_s L

Find $i_L(0^-)$ — Before Switch Closes ▼

Circuit for t < 0: Switch OPEN, inductor = SHORT CIRCUIT (steady state)

Analysis: Only V source is active. The current source is disconnected by the open switch.

$$i_L(0^-) = \frac{V}{R_1} = \frac{24\text{ V}}{12\ \Omega} = 2\text{ A}$$

Find $i_L(0^+)$ — Current Continuity ▼

At t = 0⁺: The inductor acts as a CURRENT SOURCE with value $i_L(0^-)$

$$i_L(0^+) = i_L(0^-) = 2\text{ A}$$

Find $i_L(\infty)$ — Using SUPERPOSITION ▼

At t → ∞, switch is closed, inductor becomes SHORT CIRCUIT again.

Superposition: Analyze each source separately, then sum.

Due to V source alone (Iₛ → OPEN):

$$i_L' = \frac{V}{R_1} = 2\text{ A}$$

Due to Iₛ alone (V → SHORT):

$$i_L'' = I_s = 4\text{ A}$$

Total:

$$i_L(\infty) = i_L' + i_L'' = 2 + 4 = 6\text{ A}$$

Find τ — Time Constant ▼

Deactivate all sources to find $R_{th}$ seen by inductor:

V → SHORT, Iₛ → OPEN

$$R_{th} = R_1 \| R_2 = 12\ \Omega \| 6\ \Omega = 4\ \Omega$$ $$\tau = \frac{L}{R_{th}} = \frac{0.5\text{ H}}{4\ \Omega} = 0.125\text{ s}$$

Write $i_L(t)$ ▼

$$i_L(t) = 6 + (2 - 6)e^{-t/0.125} = 6 - 4e^{-8t}\text{ A}$$

Find $v_L(t)$ ▼

$$v_L(t) = L\frac{di_L}{dt} = 0.5 \times 32e^{-8t} = 16e^{-8t}\text{ V}$$

S Power Calculation — Find Z from Power Data

Given:

Apparent power $|S| = 500$ VA, PF $= 0.8$ leading, voltage $V = 100\angle 0°$ V at 60 Hz.

Find impedance Z and L or C value.

Find Current Magnitude ▼

$$|I| = \frac{|S|}{|V|} = \frac{500}{100} = 5\text{ A}$$

Find Impedance Magnitude ▼

$$|Z| = \frac{|V|}{|I|} = \frac{100}{5} = 20\ \Omega$$

Find Impedance Angle ▼

$$\theta = \cos^{-1}(PF) = \cos^{-1}(0.8) = 36.87°$$

Leading PF → capacitive: $\theta = -36.87°$

Write Impedance ▼

$$Z = 20\angle{-36.87°} = 20(0.8 - j0.6) = 16 - j12\ \Omega$$

Find C Value ▼

$$X_C = 12\ \Omega, \quad \omega = 2\pi \times 60 = 377\text{ rad/s}$$ $$C = \frac{1}{\omega X_C} = \frac{1}{377 \times 12} = 221\ \mu\text{F}$$

Answer: 16 Ω resistor in series with 221 μF capacitor

2-Day Intensive Study Plan

14-16 hours structured for maximum retention. Master all 5 exams independently.

Day 1: Transients + Analysis (8 hrs) Day 2: Power + Integration (8 hrs)