A very small circular loop of radius a is initially (at t=0) coplanar and concentric with a much larger fixed circular loop of radius b.A constant current I flows in the larger loop the smaller loop is rotated with a consatnt angular speed `omega` about the common diameter the emf induced in the samller loop as a function of time t is

A very small circular loop of radius a is initially (at t = 0) coplanar and concentric with a much larger fixed circular loop of radius b. A constant current l flows in the larger loop. The smaller loop is rotated with a constant angular speed omega about the common diameter. The emf induced in the smaller loop as a function of time t is

A very small circular loop of radius a is initially (at t = 0) coplaner and concentric with a much larger fixed circular loop of radius b. A constant I flows in the larger loop. The smaller loop is rotated with a constant angular speed omega about the common diameter. The emf induced in the smaller loop as a function of time t is

A very small circular loop of area 5xx10^(-4)m^2 , resistance 2Omega and negligible inductance is initally coplanar and concentric with a much larger fixed circular loop of radius 0.1 m. A constant current of 1A s passed in the bigger loop and the smaller loop is rotated with angular velocity omega rad/s about a diameter.Calculate induced current in the smaller loop, as a function of time

A very small circular loop of area 5xx10^(-4)m^2 , resistance 2Omega and negligible inductance is initally coplanar and concentric with a much larger fixed circular loop of radius 0.1 m. A constant current of 1A s passed in the bigger loop and the smaller loop is rotated with angular velocity omega rad/s about a diameter.Calculate the flux linked with the smaller loop.

A very small circular loop of area 5xx10^(-4)m^2 , resistance 2Omega and negligible inductance is initally coplanar and concentric with a much larger fixed circular loop of radius 0.1 m. A constant current of 1A passed in the bigger loop and the smaller loop is rotated with angular velocity omega rad/s about a diameter.Calculate induced emf

As shown in the figure, a rectangular loop of a conducting wire is moving away with a constant velocity v in a perpendicular direction from a very long straight conductor carrying a steady current I. When the breadth of the rectangular loop is very small compared to its distance from the straight conductor, how does the emf E induced in the loop vary with time t?

A conducting circular loop of radius r carries a constant current I. It is placed in a uniform magnetic field vec(B) such that vec(B) is perpendicular to the plane of the loop. The magnetic force acting on the loop is

As shown in the figure, a rectangular loop of a conducting wire is moving away with a constnant velocity v in a perpendicular direction from a very long straight conductor carrying a steady curent I. When the breadth of the rectangular loop is very small compared to its distance from the straight conductor, how does the emf E induced in the loop vary with time t?