Two coils have mutual inductance 0.005 H. The current changes in the first coil according to equation `I = I_(0)` sin `omega t`, where `I_(0) = 10 A` and `omega = 100 pi` rad `s^(-1)`. The maximum value of induced emf in the second coil is

Two coils have a mutual inductance 0.005 H. The current changes in the first coil according to the equation I = I_(0) sin omegat "where" I_(0) = 10 A and omega = 100pi rad s^(-1) . The maximum value of emf induced in the second coil is

Two coils have a mutual inductance 0.005 H, The current changes in the first coil according to the equation i= i_(m) sin omega t where i_(m) = 10 A and omega= 100pi rad s^(-1) . The maximum value of the emf induced in the second coil is

Two coils have amutual inductance 0.005 H. The current changes in the first coil according to the equation I= i_m sin omega t , where i_m = 10 A and w= 100 pi rad s^(-1) . The maximum value of the emf induced in the second coil is:

Two coils have a mutual inductance 0.005 H. The alternating current changes in the first coil according to equation I = underset(o)(I) sin omega t, where underset(o)(I) = 10 A and omega = 100 pi rads^(-1) . The maximum value of emf in the second coil is (in volt)

Two coils have a mutual inductance of 0.005H. The current changes in the first coil according to equation I=I_0 sin omegat , where I_0 = 10A and omega = 100pi rad/sec. The maximum value of emf in the second coil is ___

Two coils have a mutual inductance 0.005 H . The current changes in the first coil according to equation I=I_(0)sin omegat , where I_(0)=10A and omega=100pi radian//sec . The maximum value of e.m.f. in the second coil is