In a diode detector, output circuit consist of `R=1Momegasmf`,C=1pF.Calculate the carrier frequency it can detect.

In a diode detector , output circuit consists of R = 1 M omega and C = 1 pF . Calculate the carrier frequency it can detect.

In a diode AM detector with the output circuit consists of R= 1M Omega and C=1 pF would be more suitable for detecting a carrier signal of

The RMS voltage of 10v is applied to a series LCR circuit having R=10ohm, L=1mH and C=10 mu F . Calculate the current at resonance and Q -value of the circuit at resonance.

Assertion: In L-C-R series AC circut, X_(L)= X_(C) = R at a given frequency. When frequency is doubled, the impedance of the circuit is sqrt(13)/2 R. Reason: The given frequency is resonance frequency.

An AC voltage source is applied across an R-C circuit. Angular frequency of the source is omega , resistance is R and capacitance is C. The current registered is I. If now the frequency of source is changed to omega/2 (but maintaining the same voltage), the current in the circuit is found to be two third. calculate the ratio of reactance to resistance at the original frequency omega .

Statement-1 in a diode AM detector R=1kOmega and C=10pF circuit is good enough to detect a carrier signal of 100 kHz. Statement-2: the condition (1)/(f_(c))ltltRC

A capacitor of capacitance 250 pF is connected in parallel with a choke coil having inductance of 1.6 xx 10^(-2) H and resistance 20 Omega . Calculate (a) the resonance frequency and (b) the circuit impedance at resonance.

Keeping the source of frequency equal to the resonating frequency of the series LCR circuit, if the three elements L, C and R in are arranged in parallel , show that the total current in the parallel LCR circuit is a minimum at this frequency. Obtain the r.m.s. value of current in each brach of the circuit for the elements and source specified in for this frequency.

Figure here, shows a series L-C-R circuit connected to a variable frequency 230 V source. L = 5.0H, C = 80 muF and r = 40 Omega (a) Determine the source frequency which drives the circuit in resonance. (b) Obtain the impedance of the circuit and the amplitude of current at the resonating frequency. (c) Determine the rms potential drops across the three elements of the circuit. show that the potential drop across the L-C combination is zero at the resonating frequency.

An LCR circuit has L = 10 mH, R = 3 Omega and C = 1 mu F connected in series to a source of 15cos omega t .volt. Calculate the current ampliuted and the average power dissipated per cycle at a frequency 10% lower than the resonance frequency.