Magnetic fields at two points on the axis of a circular coil at a distance of `0.05m` and `0.2 m` from the centre are in the ratio `8:1`. The radius of the coil is

If B_1 is the magnetic field induction at a point on the axis of a circular coil of radius R situated at adistance R sqrt 3 and B_2 is the magnetic field at the centre of the coil, then ratio of B_1/B_2 is equal to

The ratio of magnetic induction at a point along the axis of a circular coil of radius 'a' at a distance x to a point where x tends to zero is [x>>a]

The magnetic induction at a point on the axis of a circular current carrying coil at a distance equal to the radius of coil carrying a current of 0.5 A is

The ratio of magnetic induction at a point along the axis of a circular coil of radius a at a distance x to a point where x tends to zero is [x gt gt a]

The magnetic field on the axis of a circular current carrying conductor of radius r at a distance r from centre is B_(a) and the magnetic field at its centre is B_(c ) . The value of B_(a) : B_(c ) is

The magnetic induction at a point distant 15 cm on the axis of a short bar magnet of moment 0.5 A m is

Choose the corect options. The magnetic field at a point A on the axis of a small bar magnet is equal to the field at a point B on the equator of same magnet. The ratio of distance of A and B from centre of magnet is A. 2^3 B. 2^(-1//3) C. 2^(-2//3) D. 2^(1//3)

The magnetic field at the centre of a circular coil of radius r carrying current l is B_(1) . The field at the centre of another coil of radius 2r carrying same current l is B_(2) . The ratio (B_(1))/(B_(2)) is

Calculate the magnitude of the magnetic induction due to a circular coil of 400 turns and radius 0.05 cm, carrying a current of 5A, at a point on the axis of the coil at a distance of 0.1 m from the centre of the coil.

The ratio of magnetic field at the centre of a current carrying circular coil to its magnetic momnts is x. If the current and radius both are doubble the new ratio will become