A rod having length l and resistance `R` is moving with velocity v on a `pi` shape conductor. Find the current in the rod.

In Fig a rod of length l and mass m moves with an intial velocity u on a fixed frame containing inductor L and resistance R.PQ and MN are smooth conducting wires. There is auniform magnetic field of strength B . Initially, there is no current in the inductor. find the total cherge flows through the inductor by the time, velocity of rod becomes nu_(f) and the rod has travelled a distance x .

A conducting rod of length l is moving in a transverse magnetic field of strength B with veocity v. The resistance of the rod is R. The current in the rod is

A rod of length l is moving velocity v "in magnetic field" b as seen in . Find the emf induced in all three cases. (a)

A rod of mass m and length l is connected with a light rod of length l . The composite rod is made to rotate with angular velocity omega as shown in the figure. Find the a. translational kinetic energy. b. rotational kinetic energy. c. total kinetic energy of rod.

A sliding rod AB of resistance R is shown in the figure. Here magnetic field B is constant and is out of the paper. Parallel wires have no resistance and the rod is moving with constant velocity v. The current in the sliding rod AB when switch S is closed at time t=0 is

A frame a bed and a sliding rod PQ of resistance R , start moving with the velocities v and 2v respectively parallel to a long wire carrying steady current I , as shown in the figure.

A conducting circular loop of radius a and resistance per unit length R is moving with a constant velocity v_0 , parallel to an infinite conducting wire carrying current i_0 . A conducting rod of length 2a is approaching the centre of the loop with a constant velocity v_0/2 along the direction 2 of the current. At the instant t = 0 , the rod comes in contact with the loop at A and starts sliding on the loop with the constant velocity. Neglecting the resistance of the rod and the self-inductance of the circuit, find the following when the rod slides on the loop. (a) The current through the rod when it is at a distance of (a/2) from the point A of the loop. (b) Force required to maintain the velocity of the rod at that instant.

In the figure shown a conducting rod of length l , resistnace R and mass m is moved with a constant velocity v .The magnetic field B varies with time t as B=5 t , where t is time in second.At t=0 the area of the loop containing capacitor and the rod is zero and the capacitor is uncharged.The rod started moving at t=0 on the fixed smooth conducting rails which have negligible resistance.Find (i)The current in the circuit as a function of time t . (ii)If the above system is kept in vertical plane such that the rod can move vertically downward due of gravity and other parts are kept fixed and B =constant = B_(0) .then find the maximum current in the circuit.

A rod of mass m , length l and resistance R is sliding down on a smooth inclined parallel rails with a cinstant velocity v . If a uniform horizontal magnetic field B exists, then find thevalue of B .

A rod of length l and resistance r rotates about one end as shown in figure.Its othr end touches a conducting ring a of negligible resistance. A resistance R is connected between centre and periphery.Draw the electrical equivalence and find the current in the resistance R .There is a uniform magnetic field B directed as shown.