(B) In a series $LCR$ circuit, the total voltage (e.m.f.) '$e$' is given by the phasor sum of the voltages across the individual components:$e = \sqrt

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(B) In a series $LCR$ circuit, the total voltage (e.m.f.) '$e$' is given by the phasor sum of the voltages across the individual components:$e = \sqrt{V_R^2 + (V_L - V_C)^2}$Given:$V_R = 40 \,V$$V_L = 80 \,V$$V_C = 40 \,V$Substituting these values into the formula:$e = \sqrt{(40)^2 + (80 - 40)^2}$$e = \sqrt{1600 + (40)^2}$$e = \sqrt{1600 + 1600}$$e = \sqrt{3200}$$e = \sqrt{1600 \times 2}$$e = 40 \sqrt{2} \,V$

Class 12 Physics Alternating Current RL, RC and LC AC Circuits

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An $A.C.$ source is connected to a series $LCR$ circuit. If the voltage across $R$ is $40 \,V$, the voltage across $L$ is $80 \,V$, and the voltage across $C$ is $40 \,V$, then the e.m.f. '$e$' of the $A.C.$ source is:

MHT CET 2023 All MHT CET

A
$40 \,V$
B
$40 \sqrt{2} \,V$
C
$80 \,V$
D
$160 \,V$

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Class 12

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Alternating Current

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RL, RC and LC AC Circuits

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Draw the effective equivalent circuit of the circuit shown in the figure at very high frequencies and find the effective impedance.

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An $A.C.$ source is connected to a series $LCR$ circuit. If the voltage across $R$ is $40 \,V$, the voltage across $L$ is $80 \,V$, and the voltage across $C$ is $40 \,V$, then the e.m.f. '$e$' of the $A.C.$ source is:

Similar Questions

In an $LR$-circuit,the inductive reactance is equal to the resistance $R$ of the circuit. An e.m.f. $E = E_0 \cos(\omega t)$ is applied to the circuit. The power consumed in the circuit is:

$A$ virtual current of $4 \, A$ and $50 \, Hz$ flows in an $AC$ circuit containing a coil. The power consumed in the coil is $240 \, W$. If the virtual voltage across the coil is $100 \, V$,its inductance will be:

An e.m.f. $E = E_{0} \sin \omega t$ is applied to a circuit containing $L$ and $R$ in series. If $X_{L} = R$,then the power dissipated in the circuit is

The power factor of a $CR$ circuit is $\frac{1}{\sqrt{2}}$. If the frequency of an $AC$ signal is halved,then the power factor of the circuit will become:

Draw the effective equivalent circuit of the circuit shown in the figure at very high frequencies and find the effective impedance.

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