If the current in the ineer loop changes according to `i=2t^(2)` then, find the current in the capacitor as a function of time.

Find the current in the loop

Find the current in the loop.

Find the current in the loop.

In the circuit shown, switch S is closed at time t = 0 . Find the current through the inductor as a function of time t .

Figure. shows two concentric coplanar coils with radii a and b(alt ltb) . A current I = 2t flows in the smaller loop. Neglecting self-inductance of the larger loop, a. find the mutual inductance of the two coils, b. find the emf induced in the larger coil, c. if the resistance of the larger loop is R , find the current in it as a function of time.

Figure shows tow concentric coplanar coils with radii a and b (a lt lt b) . A current i=2t flows in the smaller loop. Neglecting self inductance of larger loop (a) Find the mutual inductance of two coils. (b) Find the emf induced in the larger coil (c) If the resistance of the larger loop is R find the current in it as a function of time.

A square loop of side length d has a capacitor of capacitance C and the resistance of the loop is R. In the plane of the loop there is a long straight current carrying wire having current I. The distance of the straight wire from the loop is d as shown in figure. The current in the straight wire is made to grow with time as I = alpha t where alpha = 2 As^(-1) . Neglect self inductance of the loop. (a) Find the charge on the capacitor as a function of time (t). (b) Find the heat generated in the loop as a function of time. (c) Who supplies energy for heat dissipation?

A conducting loop having resistance R contains a capacitor of capacitance C. A uniform magnetic field B is applied perpendicular to the plane of the loop. The magnetic field is made to change with time as depicted in the graph [t_(0) = 2RC] . Plot the variation of charge on the capacitor as a function of time (t).