The magnetic flux `phi` through a coil is varying w.r.t. time 't' according to the relation `phi=5t^(2)+4t+3` weber. Calculate the induced e.m.f. and current in the coil at `t=3` sec. The resistance of the coil is `2Omega`.

The magnetic flux throug a coil perpendicular to the plane is given by phi=5t^(3)+4t^(2)+2t calculate the induced emf through the coil at t =2S.

The magnetic flux (in weber) linked with a coil of resistance 10Omega is varying with respect to time t as phi=4t^(2)+2t+1 . Then the current in the coil at time t=1 second is

A conducting loop in the form of a half circle of r=10cm is placed in a magnetic field as shown. The strength of the magnetic field is given by the relation B=5t^(2)+3t+5 where B is in Tesla and t- the time in seconds. The resistance of the loop is 3Omega . An ideal cell of e.m.f. E = 1.5V is connected to the loop. Calculate the induced e.m.f. and net current in the loop at t = 15 sec.

The magnetic flux passing through a coil perpendicular to is plane is a function of time and is given by Phi_(B)=(2t^(3)+4t^(2)+8t+8) Wb. If he resistance of the coil is 5Omega, determine the induced current through the coil at a time t = 3 second.

The flux of magnetic field through a closed conducting loop changes with time according to the equation, Phi = at^2 + bt+ c (a) Write the SI units of a,b and c. (b) if the magnitudes of a,b and c are 0.20, 0.40 and 0.60 respectely, find the induced emf at t = 2 s.

A particle moves along the x-axis in such a way that its coordinates x varies with time 't' according to the equation x=2-5t+6t^(2) . What is the initial velocity of the particle?

A particle moves in a straight line according to the relation: x = t ^ { 3 } - 4 t ^ { 2 } + 3 t Find the acceleration of the particle at displacement equal to zero.

A particle moves along a line according to the law s(t)=2t^(3)-9t^(2)+12t-4 , where tge0 . At what times the particle changes direction?