A 2 μF capacitor, 100 Ω resistor and 8 H inductor are connected in series with an AC source. Find the frequency for maximum current and the maximum current if peak emf is 200 V.

C = 2 μF = 2 × 10⁻⁶ F, R = 100 Ω, L = 8 H, V₀ = 200 V.

Maximum current flows at resonance. √LC = √(8 × 2 × 10⁻⁶) = √(16 × 10⁻⁶) = 4 × 10⁻³.

f₀ = 1/[2π × 4 × 10⁻³] = 39.8 Hz. This frequency is called the resonant frequency. At resonance, Z = R, so I_0max = 200/100 = 2 A.

Common Mistake: Using rms voltage with peak current formula.

Exam Tip: At maximum current in a series LCR circuit, immediately use X_L = X_C and Z = R.

A 40 Ω resistor, 3 mH inductor and 2 μF capacitor are connected in series to a 110 V, 5000 Hz AC source. Calculate the current.

R = 40 Ω, L = 3 mH = 3 × 10⁻³ H, C = 2 μF, V = 110 V, f = 5000 Hz.

X_L = 2π × 5000 × 0.003 = 94.25 Ω. X_C = 1/(2π × 5000 × 2 × 10⁻⁶) = 15.92 Ω.

Net reactance = 94.25 − 15.92 = 78.33 Ω. Z = √(40² + 78.33²) = 87.95 Ω. I = 110/87.95 = 1.25 A.

Common Mistake: Forgetting to convert mH and μF into SI units.

Exam Tip: First identify whether the circuit is inductive or capacitive from X_L − X_C.

A capacitor, 100 Ω resistor and inductor L = 4/π² H are connected across 200 V, 50 Hz. Find capacitance and current when current is in phase with voltage.

R = 100 Ω, L = 4/π² H, V = 200 V, f = 50 Hz.

Current is in phase with voltage, so the circuit is at resonance. ω = 2πf = 100π rad s⁻¹.

C = 1/[(100π)² × (4/π²)] = 1/40000 F = 25 × 10⁻⁶ F = 25 μF. I = 200/100 = 2 A.

Common Mistake: Treating “in phase” as zero current instead of resonance.

Exam Tip: In phase in series LCR means φ = 0, X_L = X_C.

A 50 μF capacitor, 0.05 H inductor and 48 Ω resistor are connected to ε = 310 sin314t. Find reactance, nature and phase angle.

C = 50 μF, L = 0.05 H, R = 48 Ω, ω = 314 rad s⁻¹.

X_L = 314 × 0.05 = 15.7 Ω. X_C = 1/(314 × 50 × 10⁻⁶) = 63.7 Ω.

Net reactance = X_L − X_C = −48 Ω, so the circuit is capacitive. tanφ = 48/48 = 1, hence φ = 45°.

Common Mistake: Missing the negative sign of X_L − X_C.

Exam Tip: If X_C is larger, write “current leads voltage.”

An LCR series circuit has L = 100 mH, C = 100 μF, R = 120 Ω and ε = 30 sin100t V. Find impedance, peak current and resonant frequency.

L = 0.1 H, C = 100 μF = 10⁻⁴ F, R = 120 Ω, V₀ = 30 V, ω = 100 rad s⁻¹.

X_L = 100 × 0.1 = 10 Ω. X_C = 1/(100 × 10⁻⁴) = 100 Ω.

Z = √[120² + (10 − 100)²] = √(14400 + 8100) = 150 Ω. I₀ = 30/150 = 0.2 A.

f₀ = 1/[2π√(0.1 × 10⁻⁴)] = 50.3 Hz ≈ 50 Hz.

Common Mistake: Confusing source angular frequency 100 rad s⁻¹ with resonant frequency.

Exam Tip: Use the given ω for impedance, but use L and C only for resonance frequency.

A 12 Ω resistance and inductance 0.05/π H are in series across 130 V, 50 Hz. Calculate current and voltages across R and L.

R = 12 Ω, L = 0.05/π H, V = 130 V, f = 50 Hz.

X_L = 2π × 50 × (0.05/π) = 5 Ω. Z = √(12² + 5²) = 13 Ω.

I = 130/13 = 10 A. V_R = 10 × 12 = 120 V. V_L = 10 × 5 = 50 V.

Common Mistake: Adding 120 V and 50 V algebraically to get source voltage.

Exam Tip: In AC, element voltages are phasors; use vector addition.

A capacitor, 5 Ω resistor and 50 mH inductor are in series with 100 V, 50 Hz. Voltage is in phase with current. Find C and impedance.

R = 5 Ω, L = 50 mH = 0.05 H, f = 50 Hz.

Since voltage is in phase with current, the circuit is at resonance. ω = 2πf = 100π rad s⁻¹.

C = 1/[(100π)² × 0.05] = 2.02 × 10⁻⁴ F. At resonance, Z = R = 5 Ω.

Common Mistake: Using 100 V in the capacitance formula.

Exam Tip: Resonance capacitance depends on f and L, not on applied voltage.

In an AC circuit with constant supply voltage and variable frequency, for what frequency will voltage across resistance R be maximum?

The supply voltage is constant and frequency is variable. The circuit is a series LCR circuit as shown in the referenced figure.

For constant supply voltage, V_R becomes maximum when current I becomes maximum. In a series LCR circuit, current is maximum at resonance, where X_L = X_C.

Substituting the L and C values from the figure in f₀ = 1/(2π√LC) gives f₀ = 500 Hz.

Common Mistake: Maximizing V_R independently of current.

Exam Tip: In a series circuit, maximum V_R means maximum current, hence resonance.

A 50 Hz AC source is connected to a 50 mH inductor and a bulb. Find capacitance to be connected in series for maximum brightness.

f = 50 Hz, L = 50 mH = 0.05 H.

The bulb glows brightest when current is maximum, which occurs at resonance. ω = 2πf = 100π rad s⁻¹.

C = 1/[(100π)² × 0.05] = 2.02 × 10⁻⁴ F.

Common Mistake: Taking maximum brightness as maximum resistance.

Exam Tip: Bulb brightness depends on current; maximum current occurs at resonance.

A 200 km telegraph wire has capacitance 0.014 μF per km and carries AC of 50 kHz. Find series inductance for minimum impedance. Take π = √10.

Total C = 200 × 0.014 μF = 2.8 μF = 2.8 × 10⁻⁶ F, f = 50 kHz = 5 × 10⁴ Hz, π² = 10.

ω = 2π × 5 × 10⁴ = 10⁵π rad s⁻¹. Therefore ω² = 10¹⁰π² = 10¹¹.

L = 1/(10¹¹ × 2.8 × 10⁻⁶) = 3.57 × 10⁻⁶ H = 0.00357 mH.

Common Mistake: Missing that capacitance is given per km and must be multiplied by 200 km.

Exam Tip: If a supplied answer differs by 100 times, recheck whether kHz has been copied correctly.

A series LCR circuit has L = 2.0 H, C = 32 μF, R = 10 Ω. Find resonant angular frequency and Q value.

L = 2.0 H, C = 32 μF = 32 × 10⁻⁶ F, R = 10 Ω.

LC = 2 × 32 × 10⁻⁶ = 64 × 10⁻⁶. √LC = 8 × 10⁻³.

ω₀ = 1/(8 × 10⁻³) = 125 rad s⁻¹. Q = (125 × 2)/10 = 25.

Common Mistake: Taking √(64 × 10⁻⁶) as 16 × 10⁻³ instead of 8 × 10⁻³.

Exam Tip: Q can be checked quickly by Q = (1/R)√(L/C).

A series LCR circuit is connected to 200 V, 50 Hz. Voltages across R, C and L are 200 V, 250 V and 250 V. Explain the voltage paradox and find current if R = 40 Ω.

V = 200 V, V_R = 200 V, V_C = 250 V, V_L = 250 V, R = 40 Ω.

The voltages cannot be added algebraically because V_R, V_L and V_C are phasors. Since V_L = V_C, their opposite phasors cancel.

Thus V = V_R = 200 V. Current through the resistor is I = V_R/R = 200/40 = 5 A.

Common Mistake: Adding 200 + 250 + 250 = 700 V as scalar voltages.

Exam Tip: V_L and V_C are 180° opposite in the phasor diagram.

An inductor 200 mH, capacitor 400 μF and resistor 10 Ω are in series with a 50 V variable-frequency source. Find angular frequency for maximum power, effective current and Q-factor.

L = 200 mH = 0.2 H, C = 400 μF = 4 × 10⁻⁴ F, R = 10 Ω, V = 50 V.

Maximum power dissipation occurs at resonance. LC = 0.2 × 4 × 10⁻⁴ = 8 × 10⁻⁵.

ω₀ = 1/√(8 × 10⁻⁵) = 111.8 rad s⁻¹. Effective current I = 50/10 = 5 A.

Q = (111.8 × 0.2)/10 = 2.236 = √5.

Common Mistake: Reporting only current and forgetting angular frequency.

Exam Tip: Maximum power in series LCR always means resonance and cosφ = 1.

A sinusoidal voltage of peak value 10 V is applied to series LCR with R = 10 Ω, C = 1 μF and L = 1 H. Find peak voltage across inductor at resonance and Q-factor.

V₀ = 10 V, R = 10 Ω, C = 1 μF = 10⁻⁶ F, L = 1 H.

ω₀ = 1/√(1 × 10⁻⁶) = 1000 rad s⁻¹. Therefore X_L = 1000 × 1 = 1000 Ω.

I₀ = 10/10 = 1 A. Peak voltage across inductor = I₀X_L = 1 × 1000 = 1000 V.

Q = X_L/R = 1000/10 = 100.

Common Mistake: Assuming voltage across each element must be less than source voltage.

Exam Tip: At resonance, V_L and V_C may be Q times the source voltage.