MCQMediumJEE 2026Combination of Resistors

JEE Physics 2026 Question with Solution

Two known resistances of RΩR \, \Omega and 2RΩ2R \, \Omega and one unknown resistance XΩX \, \Omega are connected in a circuit as shown in the figure. If the equivalent resistance between points AA and BB in the circuit is XΩX \, \Omega, then the value of XX is _____ Ω\Omega.

Circuit diagram between points A and B showing a bridge-like network with top branch resistors 2R and X in series and bottom branch resistor R.
  • A

    RR

  • B

    (31)R(\sqrt{3} - 1)R

  • C

    2(31)R2(\sqrt{3} - 1)R

  • D

    (3+1)R(\sqrt{3} + 1)R

Answer

Correct answer:B

Step-by-step solution

Standard Method

Given: Two known resistances are RR and 2R2R, and the unknown resistance is XX. The equivalent resistance between AA and BB is given to be XX.

Find: The value of XX.

From the circuit, the resistor RR is in parallel with the series combination 2R+X2R + X. Therefore,

Req=(2R+X)R(2R+X)+RR_{eq} = \frac{(2R + X)R}{(2R + X) + R}

Since Req=XR_{eq} = X,

X=(2R+X)R3R+XX = \frac{(2R + X)R}{3R + X}

Cross-multiplying,

X(3R+X)=2R2+RXX(3R + X) = 2R^2 + RX 3RX+X2=2R2+RX3RX + X^2 = 2R^2 + RX X2+2RX2R2=0X^2 + 2RX - 2R^2 = 0

Using the quadratic formula,

X=2R±(2R)24(1)(2R2)2X = \frac{-2R \pm \sqrt{(2R)^2 - 4(1)(-2R^2)}}{2} X=2R±4R2+8R22X = \frac{-2R \pm \sqrt{4R^2 + 8R^2}}{2} X=2R±12R22X = \frac{-2R \pm \sqrt{12R^2}}{2} X=2R±2R32X = \frac{-2R \pm 2R\sqrt{3}}{2} X=R±R3X = -R \pm R\sqrt{3}

Since resistance cannot be negative, we take the positive root.

X=(31)RX = (\sqrt{3} - 1)R

Therefore, the value of XX is (31)R(\sqrt{3} - 1)R, so the correct option is B.

Quadratic Setup from Equivalent Resistance

Given: The equivalent resistance of the network is itself equal to the unknown resistance XX.

Find: The value of XX by forming and solving the circuit equation.

The key idea is to first write the equivalent resistance of the visible series-parallel combination. The upper branch contains 2R2R and XX in series, so that branch has resistance

2R+X2R + X

This branch is in parallel with the lower branch of resistance RR. Hence,

Req=R(2R+X)R+(2R+X)R_{eq} = \frac{R(2R + X)}{R + (2R + X)} Req=R(2R+X)3R+XR_{eq} = \frac{R(2R + X)}{3R + X}

Now use the given condition Req=XR_{eq} = X:

X=R(2R+X)3R+XX = \frac{R(2R + X)}{3R + X}

Multiply both sides by 3R+X3R + X:

X(3R+X)=R(2R+X)X(3R + X) = R(2R + X)

Expand both sides:

3RX+X2=2R2+RX3RX + X^2 = 2R^2 + RX

Bring all terms to one side:

X2+2RX2R2=0X^2 + 2RX - 2R^2 = 0

This is a quadratic in XX. Solving,

X=2R±4R2+8R22X = \frac{-2R \pm \sqrt{4R^2 + 8R^2}}{2} X=2R±12R22X = \frac{-2R \pm \sqrt{12R^2}}{2} X=2R±2R32X = \frac{-2R \pm 2R\sqrt{3}}{2} X=R±R3X = -R \pm R\sqrt{3}

The physically acceptable value is the positive one:

X=(31)RX = (\sqrt{3} - 1)R

Therefore, the correct option is B.

Common mistakes

  • Treating all three resistors as if they are in simple series is incorrect because the branch containing RR is in parallel with the branch containing 2R2R and XX. First identify the network structure, then apply the parallel-resistance formula.

  • Writing the parallel combination denominator as 2R+X2R + X instead of R+(2R+X)=3R+XR + (2R + X) = 3R + X is wrong. In a parallel combination, the sum of the two branch resistances appears in the denominator.

  • Keeping the negative root of the quadratic is physically invalid here. Resistance must be positive, so after solving the quadratic, reject the negative value and keep the positive root only.

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