The magnetic field I nan reigion is given by `B=B_(0) (X)/(a)K`. A Squrae edges along the x and y axis. The loop is moved with a constant velocity . The emf induced in the loop is

The magnetic field in a region is given by vec(B)=B_(0)(1+(x)/(a))hat(k) . A square loop of edge length 'd' is placed with its edge along X-axis and Y-axis. The loop is moved with a constant velocity vec(V)=V_(0)hat(i) . The emf induced in the loop is

The magnetic field existing in a region is given by vecB =B_0(1+(x)/(l))vec k. A square loop of edge l and carrying a current I, is placed with its edges parallel to the x-y axes. Find the magnitude of the net magnetic force experienced by the loop.

In the figure ABCDEFA is closed conducting wire loop. The part AFE is a portion of an ellipse, (X^(2))/(4a^(2))+(Y^(2))/(a^(2))=1 and BCD is a portion of the ellipse (X^(2))/(9a^(2))+(Y^(2))/(4a^(2))=1 A uniform magnetic field vecB=B_(0)hatk exists in this region. If the frame is rotated about the y- axis with a constant angulat velocity 'omega' . Find the maximum emf induced in the loop.

The magnetic field existing in a region is gicen by vecB =B_0(1+(x)/(l))vec k. A square loop of edge l and carrying a current I, is placed with its edges parallel to the x-y axes. Find the magnitude of the net magnetic force experienced by the loop.

A semi-circular loop of radius R is placed in a uniform magnetic field as shown. It is pulled with a constant velocity. The induced emf in the loop is

The magnetic field existing in a region is given by , B=B_(0)((x)/(L)+(x^(2))/(L^(2)))hatk .A square loop edge L carrying a current I is placed with its parallel to the X and Y-axis Find the net magnetic force experienced by the loop

The magnetic field in a region is given by vecB=B_(0)/Lxhatk where L is a fixed length.A conducting rod of length lies along the X -axis between the origin and the point (L,0,0) .If the rod moves with a velocity vecv=v_(0) hatj the emf induced between the ends of the rod.

A uniform magnetic field is restricted within a region of radius 1m. The magnetic field changes with time(t) as vecB=B_0((2t)/3)hatk . A loop of radius 2m is outside the region of magnetic field as shown in figure. The emf induced in loop is

A square loop ABCD of edge a moves to the right with a velocity v parallel to AB . There is a uniform magnetic field of magnitude B , direction into the paper, in the region between PQ and RS only. I, II and III are three ppositions of the loop. (i) The emf induced in the loop has magnitude B a v in all three position (II) induced emf is zero in second position (iii) Induced emf is anticlockwise in position II (iv) The induced emf is clockwise in position III

A uniform magnetic field existsin region given by vec(B) = 3 hat(i) + 4 hat(j)+5hat(k) . A rod of length 5 m is placed along y -axis is moved along x - axis with constant speed 1 m//sec . Then the magnitude of induced e.m.f in the rod is :