An ideal resistance R, ideal inductance L , ideal capacitance C and AC volt meters `V_(1) , V_(2) , V_(3)` and `V_(4)` are connected to an AC source as shown . At resonance.

For an ideal gas, C_(p) and C_(v) are related as

In a series resonant circuit the ac voltages across resistance R , inductance L and capacitance C are 5V, 10V and 10V respectively. The ac voltage applied to the circuit will be

An ammeter, a voltmeter V and a resistance R are connected as shown . Ameneter reads 2 A . Voltmeter reading is 10 V. Then R is

A uniform electric field in the plane of the paper as shown. Here A, B, C,D are the points on the circle. V_(1), V_(2),V_(3),V_(4) are the potentials at those points respectively. Then

A resistor of 100 Omega , inductance of 1 H and a capacitor of capacitance 10.13 xx 10^(-6) F are in series. This combination is connected to an A.C source of 200 V, 50 Hz. Find this current in the circuit and the p.d. across the resistor.

A 1.0 mH inductance, a 10 muF capacitance and a 5.0 ohm resistance are connected in series to an a.c. source. It is found that the inductor and the capacitor show equal reactances. The reactance should be nearest to

Entropy change for an isothermal expansion of one mole of an ideal gas from volume V_(1) to V_(2) is :

A series LCR circuit is connected to 230 V a.c. source of variable frequency. The inductance of the coil is 5 H capacitance of the capacitor is 5 mu F and resistance is 40 Omega . At resonance calculate , (a) The resonant frequency , (b) current is the circuit and (c ) the inductive reactance.

A series LRC circuit comprising of an inductor of inductance 3H, a resistor of resistance 7.4Omega and a capacitor of capacitance 27muF . When connected to an a.c source, the circuit resonates at a particular frequency. Calculate angular resonant frequency and quality factor of the resonant circuit.