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(B) The bandwidth of a resonant circuit is defined as the difference between the two frequencies at which the power or the output voltage drops to a s

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$600$

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(B) The bandwidth of a resonant circuit is defined as the difference between the two frequencies at which the power or the output voltage drops to a specific fraction of its peak value. In an $L-C-R$ series circuit,the output voltage across the resistor is $V_{out} = I_{rms} R = \frac{V_0 R}{\sqrt{R^2 + (X_L - X_C)^2}}$. At resonance,$V_{out}$ is maximum $(V_0)$. The frequencies at which the output voltage falls to half its peak value are given by $f_1 = 200 \,Hz$ and $f_2 = 800 \,Hz$. The bandwidth is defined as the difference between these two half-power frequencies: $	ext{Bandwidth} = f_2 - f_1$. Substituting the given values: $	ext{Bandwidth} = 800 \,Hz - 200 \,Hz = 600 \,Hz$.

The output voltage (taken across the resistance) of an $L-C-R$ series resonant circuit falls to half its peak value at a frequency of $200 \,Hz$ and again reaches the same value at $800 \,Hz$. The bandwidth of this circuit is ............. $\,Hz$.

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