A conducting wire of length l is turned in the form of a circular coil and a current I is passed through it. For the torque, due to magnetic field produced at its centre, to be maximum, the number of turns in the coil will be

Magnetic field produced by current carrying coil depends upon the number of turns in the coil.

A conducting wire of length L is bent in the form of an equilateral triangle. If current I is made to pass through it, then calculate the magnetic field intensity at the centre of the triangle.

Explain magnetic field produced by current carrying coil depends upon the number of turns in the coil.

Due to 10 A of current flowing in a circular coil of 10 cm radius , the magnetic field produced at its centre is 3.14xx10^-3 Wb/ m^2 . The number of turns in the coil will be

Due to 10 ampere of current flowing in a circular coil of 10 cm radius, the magnetic field produced at its centre is 3.14xx10^(-3) Weber//m^(3) . The number of turns in the coil will be

A wire of length l is bent in the form a circular coil of some turns. A current I flows through the coil. The coil is placed in a uniform magnetic field B. The maximum torqur on the coil can be

When equal current is passed through two coils equal magnetic field is produced at their centres. If the ratio of number of turns in the coils is 8:15 then the ratio of the their radii will be

One of the two identical conducting wires of length L is bent in the form of a circular loop and the other one into a circular coil of N identical turns. If the same current passed in both, the ratio of the magnetic field at the central of the loop (B_(L)) to that at the central of the coil (B_(C)) , i.e. (B_(L))/(B_(C)) will be :

A circular coil of one turn carries a current I. The same wire is then bent to from a smaller circular coil of 2 turns and the same current is passed through it. What is the relations between the fields at the centre of the coils in the second and first case ?