NVAMediumJEE 2023Kirchhoff's Laws & Circuits

JEE Physics 2023 Question with Solution

As shown in the figure, the voltmeter reads 2V2 \, \text{V} across a 5Ω5 \, \Omega resistor. The resistance of the voltmeter is _____ Ω\Omega.

A circuit with a 3 V cell, a 2 ohm resistor in series, and a 5 ohm resistor connected in parallel with a voltmeter on the right branch.

Answer

Correct answer:20

Step-by-step solution

Standard Method

Given: A 3V3 \, \text{V} source, a 2Ω2 \, \Omega resistor, and a branch containing a 5Ω5 \, \Omega resistor in parallel with a voltmeter of resistance RR. The voltmeter reads 2V2 \, \text{V}.

Find: The resistance RR of the voltmeter.

Since the 5Ω5 \, \Omega resistor and the voltmeter are in parallel, the potential difference across each is 2V2 \, \text{V}.

Current through the 5Ω5 \, \Omega resistor is

I1=25I_1 = \frac{2}{5}

The source is 3V3 \, \text{V}, so the remaining potential drop across the 2Ω2 \, \Omega resistor is

32=1V3 - 2 = 1 \, \text{V}

Hence the total current through the series 2Ω2 \, \Omega resistor is

I=12I = \frac{1}{2}

Using junction law at the parallel branch,

I=I1+I2I = I_1 + I_2

So,

12=25+I2\frac{1}{2} = \frac{2}{5} + I_2 I2=1225=110I_2 = \frac{1}{2} - \frac{2}{5} = \frac{1}{10}

This I2I_2 is the current through the voltmeter. Therefore,

R=VI2=21/10=20ΩR = \frac{V}{I_2} = \frac{2}{1/10} = 20 \, \Omega

Therefore, the resistance of the voltmeter is 20Ω20 \, \Omega.

Equivalent Resistance Method

Given: The voltmeter of resistance RR is in parallel with the 5Ω5 \, \Omega resistor, and this parallel combination is in series with 2Ω2 \, \Omega.

Find: The value of RR.

The equivalent resistance of the parallel part is

5R5+R\frac{5R}{5+R}

So total resistance is

Req=2+5R5+RR_{eq} = 2 + \frac{5R}{5+R}

The total current from the 3V3 \, \text{V} source is

I=3ReqI = \frac{3}{R_{eq}}

Because the parallel branch has a voltage of 2V2 \, \text{V}, the series 2Ω2 \, \Omega resistor has a drop of 1V1 \, \text{V}, so total current is also

I=12I = \frac{1}{2}

Equating and solving gives R=20ΩR = 20 \, \Omega.

Therefore, the resistance of the voltmeter is 20Ω20 \, \Omega.

Common mistakes

  • Treating the voltmeter and the 5Ω5 \, \Omega resistor as if they were in series. They are connected across the same two nodes, so they are in parallel. Use equal voltage across both branches, not equal current.

  • Using the full 3V3 \, \text{V} across the 5Ω5 \, \Omega resistor. The voltmeter reading shows that the parallel branch has only 2V2 \, \text{V} across it. The remaining 1V1 \, \text{V} is across the 2Ω2 \, \Omega resistor.

  • Assuming an ideal voltmeter with infinite resistance. This question specifically asks for the voltmeter resistance, so the meter draws current and must be treated as a finite resistor in parallel.

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