NVAMediumJEE 2025LCR Circuits & Resonance

JEE Physics 2025 Question with Solution

For the AC circuit shown in the figure, R=100kΩR = 100 \, k\Omega and C=100pFC = 100 \, pF, and the phase difference between VinV_{in} and (VBVA)(V_B - V_A) is 9090^\circ. The input signal frequency is 10x10^x rad/sec, where xx is:

AC source connected across two vertical RC branches; left branch has resistor on top and capacitor below with node A between them, right branch has capacitor on top and resistor below with node B between them.

Answer

Correct answer:5

Step-by-step solution

Standard Method

Given: R=100×103ΩR = 100 \times 10^3 \, \Omega, C=100×1012FC = 100 \times 10^{-12} \, \text{F}, and the phase difference between VinV_{in} and (VBVA)(V_B - V_A) is 9090^\circ.

Find: The value of xx if the input angular frequency is written as 10x10^x rad/sec.

Using the phase condition stated in the solution for the RC circuit:

ωRC=1\omega RC = 1

Now substitute the given values:

ω×(100×103)×(100×1012)=1\omega \times (100 \times 10^3) \times (100 \times 10^{-12}) = 1

So,

ω×105=1\omega \times 10^{-5} = 1

Hence,

ω=105rad/sec\omega = 10^5 \, \text{rad/sec}

Therefore, in the form 10x10^x rad/sec, we get x=5x = 5.

Using the phase relation between the two branches

Given: Two identical RC branches are connected as shown, with midpoint potentials VAV_A and VBV_B. Also, R=100×103ΩR = 100 \times 10^3 \, \Omega and C=100×1012FC = 100 \times 10^{-12} \, \text{F}.

Find: The exponent xx in the angular frequency 10x10^x rad/sec.

As stated in the extracted solution, the branch phase angles are equal in magnitude and opposite in direction. Therefore, if the phase difference between VinV_{in} and (VBVA)(V_B - V_A) is 9090^\circ, each branch contributes 4545^\circ.

For an RC branch at 4545^\circ, the resistive and capacitive reactances are equal:

R=XCR = X_C

Using

XC=1ωCX_C = \frac{1}{\omega C}

we get

R=1ωCR = \frac{1}{\omega C}

So,

ω=1RC\omega = \frac{1}{RC}

Now substitute the values:

RC=(100×103)(100×1012)=105RC = (100 \times 10^3)(100 \times 10^{-12}) = 10^{-5}

Thus,

ω=1105=105rad/sec\omega = \frac{1}{10^{-5}} = 10^5 \, \text{rad/sec}

Therefore, the required exponent is 5.

Time-constant shortcut

Given: R=100×103ΩR = 100 \times 10^3 \, \Omega and C=100×1012FC = 100 \times 10^{-12} \, \text{F}.

Find: xx in 10x10^x rad/sec.

When the phase condition leads to ωRC=1\omega RC = 1, the angular frequency is immediately:

ω=1RC\omega = \frac{1}{RC}

Now,

RC=105×1010=105RC = 10^5 \times 10^{-10} = 10^{-5}

Therefore,

ω=105rad/sec\omega = 10^5 \, \text{rad/sec}

So the frequency is of the form 10x10^x rad/sec with x=5x = 5.

This shortcut works because the required phase condition fixes the circuit exactly at the point where the RC time constant satisfies ωτ=1\omega \tau = 1 with τ=RC\tau = RC.

Common mistakes

  • Using ff instead of angular frequency ω\omega. The question already gives the input signal frequency in rad/sec, which corresponds to angular frequency. Do not divide by 2π2\pi unless the question asks for frequency in Hz.

  • Multiplying RR and CC incorrectly. Here, 100×103100 \times 10^3 and 100×1012100 \times 10^{-12} give 10510^{-5}, not 10610^{-6}. Keep powers of ten separate and combine them carefully.

  • Assuming the answer must come from tan90=\tan 90^\circ = \infty directly. The extracted solution uses the circuit phase condition to reach ωRC=1\omega RC = 1. Follow the stated branch-phase relation rather than treating the series RC formula in isolation.

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