Uniform magnetic field B=10T is acting in a region of length L=2m as shown. A squre loop of side `(L)/(2)` enters in it with constant acceleration `alpha=1m//s^(2)`. Resistance per unit length of the square frame is `1Omega//m. At, t=1s

Uniform magnetic field B =5 T is acting in the region of length L=5 m as shown in Fig. A square loop of side L//5 enters in it with constant acceleration a =1 m s^(-2) . Resistance per unit length of the square frame is 1 (Omega) m^(-1) . At t = 1 s

A rectangular frame ABCD, made of a uniform metal wire, has a straight connection between E and F made of the samae wire, as shown in fig. AEFD is a square of side 1m, and EB=FC=0.5m. The entire circuit is placed in steadily increasing, uniform magnetic field directed into the plane of the paper and normal to it. The rate of change of the magnetic field is 1T//s . The resistance per unit length of the wire is 1omega//m . Find the magnitude and directions of the currents in the segments AE, BE and EF.

A current of 10A is flowing in a equilateral triangle of side length l=1M as shown in figure. The magnetic field at center of triangle is:

A region of width L contains a uniform magnetic field B directed into the plane of the figure. A square conducing loop of side length l ( lt L) is kept with its side AB at the boundary of the field region (see Figure). The loop is pushed into the field region with a speed such that it just manages to exit the field region. Calculate the time needed for the entire loop to enter the field region after it is pushed. Mass and resistance of the loop is M and R respectively.

In the figure shown as uniform magnetic field |B|=0.5T is perpendicular to the plane of circuit. The sliding rod of length l=0.25 m moves uniformly with constant speed v=4ms^-1 . If the resistance of the sllides is 2Omega , then the current flowing through the sliding rod is

A unifrom magnetic field B exists in a cylindrical region of radius 1 cm as shown in figure. A uniform wire of length 16 cm and resistance 4.0 Omega is bent into a square frame and is placed with one side along a diameters of the cylindrical region. If the magnetic field increaes at a constant rate of 1 T/s find the current induced in the frame.

A plane loop, shaped as two squares of sides a = 1m and b = 0.4m is introduced into a uniform magnetic field _|_ to the plane of loop . The magnetic field varies as B = 10(-3)sin(100t) T . The qamplitude of the current induced in the loop if its resistance per unit length is r = 5 mOmega m^(-1) is

A uniform magnetic field B = 0.5 T exists in a circular region of radius R = 5m . A loop of radius R = 5 m encloses the magnetic field at t = 0 and then pulled at uniform speed v = 2m s^(-1) In the plane of the paper. Find the induced emf ("in" V) in the loop at time t = 3 s .

A vertical metal rod of length 1.5 m is at rest in the earth's magnetic field of B_(H)=4xx10^(-5)T . If it starts moving at right angle to the magnetic meridian with a uniform acceleration of 5m//s^(2) , then the instantaneous emf induced in it at the end of 2 s will be

A plane loop is shaped as two squares (Fig) and placed in a uniform magnetic field at right angle to the loop's plane. The magnetic induction varies with time as B =B_(0) sin (omega)t, where B_(0) = 10 mT and (omega) = 100 rads^(-1) . The wires do not touch at point A. If resistance per unit length of the loop is 50 m(Omega)// m , then amplitude of current induced in the loop is