In vector form the magnetic induction dB at a point of distance r from centre of element of length dl is given as

A short magnetic dipole has magnetic moment 0.5 Am2. Calculate the magnetic induction at a distance of 20 cm from the centre of the magnetic dipole on the axis and the equitorial line [ mu_o = 4pi xx 10^-7 SI unit].

The magnetic induction at the centre of a current carrying circular coil of radius 10cm is 5sqrt(5) times the magnetic induction at a point on its axis. The distance of the point from the centre of the coil in m is

The magnetic induction at an axial point is equal to the magnetic induction at an equatorial point. Calculate the ratio of their distances from the centre of the dipole.

A bar magnet has pole strength of 10 A-m and a magnetic length of 5cm. Find the magnetic induction at a point 10 cm from either of its two poles [ mu_o = 4pi xx 10^-7 XI unit].

In the above problem, what will be the magnetic field B inside the wire at a distance r from its centre. If the current density J is uniform across the cross section of the wire.

The magnetic induction due to a bar magnet at a point on its axis is directed from

The number of turns in a circular coil of wire is 10 and average radius of each turn is 8 cm. A current of 5A is passed through the coil. Find the magnetic induction due to the current at a point at a distance of 6 cm on the axis of the coil from the centre.

The magnetic induction at centre of loop due to current flowing through small element 'dl' is given as dB = mu_(0)/(4pi)(Idl sin theta)/r^(2) where theta is

The magnetic induction at a point P on the axis is equal to the magnetic induction at a point Q on the equator of a short magnetic dipole. What is the ratio of the distances of P and Q from the centre of the dipole?