As shown in the figure, a conducting rod of length I, mass m and resistance R falls through a magnetic field `vecB` in a plane perpendicular to plane of figure. Find terminal velocity of rod.

The sides of a square shaped frame, Shown in the diagram are made of wires of resistances r_(1) and r_(2) The frame is places in a uniform magnetic field, which is perpendicular to the plane of figure and is increasing at a constant rate. The resistance that should be connected across the diagonal of frame, so that this wire is warmed up at greatest rate is given by R=(n r_(1)r_(2))/(r_(1)+r_(2)) . Find n.

As shown in fig. a conducting ring R is placed on the axis of a bar magnet M. The plane of R is perpendicular to the axis M can move along this axis _____

A conducting rod of length I and velocity v moves in a magnetic field B. If rho is the resistivity of the material of rod, then the induced current produced in the rod is _____

One U shaped conducting frame is placed in a plane perpendicular to uniform magnetic field B. One conducting rod of mass m and length l is kept perpendicular to parallel sides of this frame. At time t = 0, this rod is pushed perpendicular to its length with initial velocity v_g . Prove that its velocity at the end of time t is v_t=v_0 "exp" ((-B^2l^2)/(mR)t) where R=resistance of external circuit and l=perpendicular distance between two parallel slides .

A conducting rod of mass 1 kg and length 1 m is suspended by two strings, so as to remain horizontal. If 2T horizontal magnetic field is applied perpendicular to the length of the rod then what amount of current should be passed through this rod to remove tension in two strings ? (Take g = 10ms^(-2) )

Find the moment of inertia and radius of gyration of uniform cross-section rod of mass M and length l about an axis through a point at distance (l)/(3) from one end and perpendicular to the length of rod.

A weightless rigid rod with a load at the end is hinged at point A to the wall so that it can rotate in all directions (Fig). The rod is kept in the horizontal position by a vertical inextensible thread of length 1, fixed at its midpoint. The load receives a momentum in the direction perpendicular to the plane of the figure. Determine the period T of small oscillations of the system.

A rod of mass m and resistance R slides smoothly over two parallel conducting wires kept sloping at an angle theta with respect to the horizontal as shown in figure. The circuit is closed through a perfect conductor at the top. There is a constant magnetic field vecB along the vertical direction. If the rod is initially at rest, find the velocity of the rod as a function of time.

One metallic ring of radius 2 m has a conducting rod connected between centre and rim of wheel. It rotates in a plane perpendicular to uniform magnetic field 1 T with frequency 25"rev"/s . Find emf induced across the rod.

A graph shown in the figure represents the variation of uniform magnetic field with time. If this field linked with a conducting loop completely and its perpendicular to the plane of the coil. In which time interval of induced emf in the coil is maximum ?