An electro magnetic wave of wavelength `300` metre can be transmitted centre.A condenser of capacity `2.5muF` is available.Calculate the inductance of the required coil for a resonant circuit.Use `pi^(2)=10`.

An electro magnetic wave of wavelength 300 metre can be transmitted by a transmission centre. A condenser of capacity 2.5muF is available. Calculate the inductance of the required coil for a resonant circuit.Use pi^(2)=10 .

A transmitter transmits at a wavelength of 300 m. A condenser of capacitance 2.4 (mu)F is being used. The value of the inductance for the resonant circuit is approximately

A circuit has a resistance of 50 ohms and an inductance of 3/pi henry.It is connected in series with a condenser of 40/pi muF and AC supply voltage of 200 V and 50 cycles/sec.Calculate (i)the impedance of the circuit. (ii)the p.d. across inductor coil and condenser. (iii)Power factor

An inductor coil of inductance 17 mH is constructed from a copper wire of length 100 m and cross - sectional are 1mm^2 . Calculate the time constant of the circuit if this inductor is joined across an ideal battery. The resistivity of copper = 1.7 X 10^(-8) Omega m.

A coil of inductance L=5H and resistance R=55Omega is connected in series to the mains alternating voltage of frequency f=50Hz in series. What can be the non-zero capacitance of the capacitor (in muF ) connected in series with the coil, if the power dissipated has to remain unchanged. (take pi^(2)=10 )

A coil of inductance L = 5//8 H and of resistance R = 62.8 (Omega) is connected to the mains alternating voltage of frequency 50 Hz. What can be the capacitance of the capacitor (in (mu)F) connected in series with the coil if the power dissipated has to remain unchanged? Take (pi)^(2) = 10 .

The diagram shows a circuit having a coil of resistance R = 2.5 (Omega) and inductance L connected to a conducting rod PQ which can slide on perfectly conducting circular ring of radius 10 cm with its centre at 'P'. Assume that friction and gravity are absent and a constant uniform magnetic field of 5 T exist as shown in Fig. At t = 0, the circuit is switched on and simultaneously a time varying external torque is applied on the rod so that it rotates about P with a constant angular velocity 40 rad//s . Find magnitude of this torque (in milli Nm) when current reaches half of its maximum value. Neglect the self-inductance of the loop formed by the circuit.

Two circular coils of radii 5.0 cm and 10 cm carry equal currents of 2.0 A. The coils have 50 and 100 turns respectively and are placed in such a way that their planes as well as the centres coincide. Find the magnitude of the magnetic field B at the common centre of the coils if the currents in the coils are (a) in the same sense (b) in the opposite sense.

The equation of progressive wave is given by y=10sin[300pi(t-(x)/(480))] where x and y are in metre and t is in second. Calculate the amplitude frequency time period and wavelength of the wave.

The current in a coil is changed from 5A to 10A in 10^(-2) s. Then, an emf of 50mV is induced in a coil near by it. Calculate mutual inductance of two coils.