Find the emf across points `P` and `Q` which are diametrically opposite points a semicircular closed loop moving in a magnetic field as shown in . Also draw the electrical equivalence od each branch.

Find the emf across points P and Q which are diametrically opposite points of a semicircular closed loop moving in a magnetic field as shown in .

Two point P and Q. diametrically opposite on a disc of radius R have linear velocities v and 2v as shown in figure. Find the angular speed of the disc.

Shows a rod of length l and resistance r moving on two rails shorted by a resistance R . A uniform magnetic field B is present normal to the plane of rod and rails. Show the electrical equivalence of each branch.

Shows a rectangular loop moving in a uniform magnetic equivalence of each branch. What is the net induced emf.

In Fig, find the magnetic field at point P. The loop is lying in x-y plane.

Find magnetic field at point P shown in Fig. point P is on the bisector of angle between the wires.

A wheel having mass m has charges +q and –q on diametrically opposite points. It remains in equilibrium on a rough inclined plane in the presence of uniform vertical electric field E =

A wheel having mass m has charges +q and -q on diametrically opposite points. It remains in equilibrium on a rough inclined plane in the presence of a uniform vertical electric field E. The value of E is

Two long wires are placed parallel to each other 10cm apart as shown in figure. The magnetic field at point P is

A cell is connected across two points P and Q of a uniform circular conductor, figure. Prove that the magnetic field at its centre O will be zero.