Two coils of self inductance L_1 and L_2 are placed near each other so that the total flux in one coil is partially linked with the other. Their mutual inductance (M) will be given by

Two coils of self-inductance L_(1) and L_(2) are placed closed to each other so that total flux in one coil is completely linked with other. If M is mutual inductance between them, then

Two different coils of self inductance L 1 ​ and L 2 ​ are placed close to each other so that the effective flux in one coil is completely linked with other. If M is the mutual inductance between them, then

Two coils of self-inductance 2mH and 8 mH are placed so close together that the effective flux in one coil is completely linked with the other. The mutual inductance between these coil is

Two coils of self-inductance 2mH and 8 mH are placed so close together that the effective flux in one coil is completely linked with the other. The mutual inductance between these coil is

The inductors of self inductance L_(1) and L_(2) are put in series .

Two identical coils each of self-inductance L , are connected in series and are placed so closed to each other that all the flux from one coil links with the other. The total self-inductance of the system is

Two coils of wires A and B are mutually at right angles to each other as shown in the figure. If the current in one coil is changed, then in the other coil

A coil of self-inductance L is placed in an external magnetic field (no current flows in the coil). The total magnetic flux linked with the coil is phi . The magnetic field energy stored in the coil is

Two coil are placed close to each other. The mutual inductance of the pair of coils depends upon.

Two coils of self inductance L_(1) and L_(2) are connected in parallel and then connected to a cell of emf epsilon and internal resistance - R. Find the steady state current in the coils.