Three inductances are connected as shown below. Assuming no coupling, the resultant inductance will be-

(`L_(1)=0.75 H, L_(2)=L_(3)=0.5 H)`

Three inductances are connected as shown in figure. Calculate the resultant inductance.

Pure inductance of 3.0 H is connected as shown below. The equivalent inductance of the circuit is

Pure inductors each of inductance 3 H are connected as shown in figure. The equivalent inductance of the circuit is

Two pure inductors each of self inductance L are connected in series, the net inductance is

Three solenoid coils of same dimension, same number of turns and same number of layers of windings are taken. Coil 1 with inductance L_(1) was would using a wire of resistance 11Omega//m , coil 2 with inductance L_(2) was wound using the similar wire but the direction of winding was reversed in each layer, coil 3 with inductance L_(3) was wound using a superconducting wire. The self-inductance of the coils L_(1),L_(2) and L_(3) are

Two inductors of inductance L each are connected in series with opposite magnetic fluxes. The resultant inductance is (Ignore mutual inductance)

In Fig. coil 1 and coil 2 are wound on a long cylindrical insulator. The ends A' and B are joined together and current I is passed. Self-inductance of the two coils are L_(1) and L_(2) , and their mutual inductance is M . a. Show that this combination can be replaced by a single coil of equivalent inductange given by L_(eq) = L_(1) + L_(2) + 2M . b. How could the coils be reconnected by yieldings an equivalent inductance of L_(eq) = L_(1) + L_(2) - 2M .

What is the minimum value of inductance that can be obtained by combining three inductances of 1 H, 2 H and 3 H?