If various elements, i.e., resistance capacitance and inductance which are in series and having values `1000 Omega, 1 mu F` and `2.0 H` respectively. Given emf as, `V = 100 sqrt(2) sin 1000 t` volts
voltages across the capacitor is

If various elements, i.e., resistance capacitance and inductance which are in series and having values 1000 Omega, 1 mu F and 2.0 H respectively. Given emf as, V = 100 sqrt(2) sin 1000 t volts voltage across the inductor is

If various elements, i.e., resistance capacitance and inductance which are in series and having values 1000 Omega, 1 mu F and 2.0 H respectively. Given emf as, V = 100 sqrt(2) sin 1000 t volts Voltage across the resistor is

Find the voltage across the various elements, i.e., resistance, capacitance and inductance which are in series and having values 1000 Omega, 1muF and 2.0 H respectively . Given emf as, V = 100sqrt2 sin 1000 t V

Find the voltage across the various elements, i.e., resistance, capacitance and inductance which are in series and having values 100Omega, 1muF and 2.0H , respectively. Given emf is V=100sqrt2sin1000t volt

Find the potential difference across resistance, capacitance and inductance in series LCR circuit where L=2.0 H, C = 1 mu F and R = 100 Omega . The applied emf has the form V= 100 sqrt(2) sin (1000 t)

In the series L-C-R circuit shown in the figure, the rms voltage across the resistor and inductor are 400 V and 700 V respectively. If the applied voltage is E=500sqrt(2)sin(omega t) , then the peak voltage across the capacitor is

A 100 Omega resistance is connected in series with a 4 H inductor. The voltage across the resistor is V_(R) = 2 sin (1000 t) V . The voltage across the inductors is

A resistor of 500 Omega and an inductance of 0.5 H are in series with an ac source which is given by V=100sqrt(2)sin(1000t) . The power factor of the combination is

A choke coil of resistance 5 Omega and inductance 0.6 H is in series with a capacitance of 10 (mu)F . If a voltage of 200 V is applied and the frequency is adjusted to resonance, the current and voltage across the inductance and capacitance are (I_0), (V_0) and (V_1) respectively. we have

An alternating e.m.f. of 0.1 V is applied across an LCR series circuit having R = 2 Omega, C = 40 mu F and L = 100 mH . At resonance, the voltage drop across the inductor is