A series LCR circuit with `L = 80 mH, C = 50 mu F` and `R = 60 ohm` is connected to a variable frequency 220 V source. Determine (i) the source frequency which drives the circuitin resonance (iii) the quality factor Q of the circuit.

A series LCR circuit with L = 4.0 H, C = 100 mu F and R = 60 Omega is connected to a variable frequency 240 V source. Calculate (i) angular frequency of the source which drives the circuit in resonance, (ii) current at the resonating frequency, (iii) rms potential drop across the inductance at resonance.

A series LCR circuit with L = 4.0 h, C = 100 mu F and R = 60 Omega is connected to a varialbe frequency 240 V source. Calcalate (i) angular frequency of the source which drives the circuit in resonace, (ii) current at the resonating frequency, (iii) rms potential drop across the inductro at resonance.

The given circuit diagram shows a series LCR circuit connected to a variable frequency 230 V source. Determine the source frequency which drives the circuit in resonance.

Fig. shows series LCR circuit with L = 5.0 H, C = 80 mu F, R = 40 Omega connected to a variable frequency 240 V source. Calculate (i) the angular frequency of the source which drives the circuit at resonance. (ii) Current at the resonating frequency. (iii) the rms pot. drop across the capacitor at resonance.

Fig. shows series LCR circuit with L = 5.0 H, C = 80 mu F, R = 40 Omega connected to a variable frequency 240 V source. Calculate (i) the angular freuquency of the source which drives the circuit at resonance. (ii) Current at the resonanting frequency. (iii) the rms pot. drop across the capacitor at resonance.

A series LER circuit with C = 80 mu F , L = 5.0 H and R = 40 Omega is connected to a variable frequency 240 V a.c. source Calculate (i) angular frequency of the source which drives the circuit in resonanace. (ii) current at the resonating frequency. (iii) rms pot. drop across the capacitor.

The figure shows a series LCR circuit with L=10.0 H_(2), C=40 mu F, R=60 Omega connected to a variable frequency 240 V source. Calculate (i) The angular frequency of the source which drives the circuit at resonance. (ii) The current at the resonating frequency. (iii) The rms potential drop across the capacitor at resonance.

The figure shows a series LCR circuit with L=10.0 H_(2), C=40 mu F, R=60 Omega connected to a variable frequency 240 V source. Calculate (i) The angular frequency of the source which drives the circuit at resonance. (ii) The current at the resonating frequency. (iii) The rms potential drop across the capacitor at resonance.

The figure shows a series LCR circuit connected to a varriable of 200 V source with L=50 mH, C=80muF and R=40Omega find. (i) the source frequency which drives the circuit in resonance, (ii) the quality factor (Q) of the circuit.

Figure shows a series LCR circuit connected to a variable frequency 230 V source. The source frequency which drives the circuit the circuit in resonance is