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.

The amount of charge passed in time t through a cross-section of a wire is Q(t)=At^(2)+Bt+C. (a)Write the dimensional formulae for A,B and C. (b) If the numerical values of A,B,and C are 5,3 and 1 respectively in SI units,find the value of the current at t=5 s.

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 equation 4ax^2 + 3bx + 2c = 0 where a, b, c are real and a+b+c = 0 has

In triangle A B C , the equation of the right bisectors of the sides A B and A C are x+y=0 and y-x=0 , respectively. If A-=(5,7) , then find the equation of side B Cdot

A body oscillates with SHM according to the equation (in SI units), x = 5 cos [2pi t + pi//4] . At t = 1.5 s, calculate the (a) displacement, (b) speed and (c) acceleration of the body.

If a ,b ,c in R , then find the number of real roots of the equation =|x c-b-c x a b-a x|=0

If a ,b and c are in A.P. and one root of the equation a x^2+b c+c=0 is 2 , the find the other root dot

A conducting loop of area 5.0 cm^2 is placed in a magnetic field which varies sinusoidally with time as B = B_0 sin omegat where B_0 = 0.20 T and omega = 300 s^(-1) . The normal to the coil makes an angle of 60^@ with the field. Find (a) the maximum emf induced in the coil, (b) the emf induced at t = (pi/900)s and (c) the emf induced at t = (pi/600)s .

A straight metal wire crosses a magnetic field of flux 4 m Wb in a time 0.4 s. Find the magnitude of the emf induced in the wire.