The magnetic flux `(phi)` (in Wb) linked with a `100 Omega` coil changes with time t (in s) according to the relation `phi=8t^(2)-2t+1`. What is the value of induced current (in A) in the coil at t = 2 s?

The magnetic flux linked with a coil satisfies the relation phi=4t^(2)+6t+9 Wb where t is the time in second. The e.m.f. induced in the coil at t =2 second is

The magnetic flux through a coil is varying according to the relation phi=(4t^(2)+2t-5)Wb , t measured in seconds. Calculate the induced current through the coil at t = 2s, if the resistance of the coil is 5Omega .

The magnetic flux throgh a coil perpendicular to the plane is changing according to the relation phi=(3t^3+2t^2+50)Wb . Calculate the induced current through the coil at t = 3 sec, if the resistance of the coil is 3Omega .

The magnetic flux (phi) linked with a coil varies with time (t) as phi=at^(n) , where a and n are constants. The induced emf in the coil is e. Which of the following are correct?

The magnetic flux linked with a coil is phi = (3t^2- 2t + 2) mwb. What emf is induced in the coil at t = 1 sec?—

A particle moves according to the law s=t^(3)-9t^(2)+24t . The distance covered by the particle before it first comes to rest is -

The magnetic flux linked with a coil varies with time t as phi=at^(2)+bt+c , where a, b and c are constants. The emf induced in the coil will be zero at a time of

The position-time relation of a moving particle is x = 2t -3t^(2) . What is the maximum positive velocity of the particle?

The magnetic flux across a loop of resistance 10Omega is given by phi = 5t^2 -4t +1 induced in the loop after 0.2 sec ?

At time t the magnetic flux is given by- phi = 5t^3- 100t + 300 . What will.be the induced emf after 3 sec?