Figure shows a square loop of resistance 1`Omega` of side 1 m being moved towards right at a constant speed of 1m/s. The front edge enters the 3m wide magnetic field (B=1T) at t=0 . Draw the graph of current induced in the loop as time passes. ( Take anticlockwise direction of current as positive )

Figure shows a squre loop of side 5 cm being mo ved towards right at a constant speed of 1cm//sec . The front edge just enters the 20 cm wide magnetic field at t=0 . Find the induced emf in the loop at t=2s and t=10s.

Figure shown a square loop of side l being moved towards right at a constant speed v . The front edge enters th emagnetic field B at t=0 . The width of field is 3l . Sketch induced emf versus time graph.

A square loop of side l being moved towards right at a constant speed v as shown in figure. The front edge enters the magnetic field B at t = 0. The width of field is 4l. Sketch induced emf versus time graph.

A square loop of side 5 cm enters a magnetic field with 1cms^(-1) . The front edge enters the magnetic emf?

A square loop of side 20 cm and resistance 1 Omega is moved towards right with a constant speed v_0 . The right arm of the loop is in a uniform magnetic field of 5 T. The field is perpendicular to the plane of the loop and is going into it. The loop is connected to a network of resistors each of value 4 Omega. What should be the value of v_0 so that a steady current of 2 mA flows in the loop ?

A train is moving towards north with a speed of 25 m/s. if the vertical component of the earth's magnetic field is 0.2 xx 10^(-4) T, the emf induced in the axle 1.5 m long is

A square wire of resistance 1.3Omega and side 1cm is moving in uniform magnetic field B=1T with speed 1cm//sec as shown in figure then the current in loop is :

Figure show a square loop of side 0.5 m and resistance 10Omega . The magnetic field has a magnitude B=1.0T . The work done in pulling the loop out of the field slowly and uniformly in 2.0s is

Figures shows a square loop of side 1m and resistance 1Omega . The magnetic field on left side of line PQ has a magnitude B=1.0T. The work done in pulling the loop out of the field uniformly in 1 s is

A square conductind loop, 20.0 cm on a side placed in the same magnetic field as shown in Fig. 3.195, center of the magnetic field region, where dB//dt = 0.035 T s^(-1) . The current induced in the loop if its resistance is 2.00 Omega is