Find the values of `ointvecB.vec(dl)` for the loops `L_1, L_2 and L_3` in Fig. (The sense of `vec(dl)` is mentioned in the figure)

the value of oint barB.bar(dl) for the loop L is

Rank the value of ointvec(B)vec(dl) for the closed paths shown in figure from the smallest to largest.

Rank the value of ointvec(B)vec(dl) for the closed paths shown in figure from the smallest to largest.

Current I_(0) is flowing through a bent wire atoctobtod in z-x plane as shown in figure, then ointvecB.vec(dl) over the loop PQRS lying in the X-Y plane as shown in figure, due to the bent wire acbd

A: In any magnetic field region the line integral ointvecB.vec(dl) along a closed loop is always zero. R: The magnetic field vecB in the expressioin oint vecB.vec(dl) is due to the currents enclosed only by the loop.

Find oint vec(B).vec(dl) over following loops (direction in which integration has to be performed is indicated by arrows)

A cylinder wire of radius R is carrying uniformly distributed current I over its cross-section. If a circular loop of radius r is taken as amperian loop, then the variation value of oint vec(B)* vec(dl) over this loop with radius 'r' of loop will be best represented by

Find the value of int_(-l/2)^(+l/2)M/l x^(2) dx where M and l are constants .

Consider three converging lenses L_1, L_2 and L_3 having identical geometrical construction. The index of refraction of L_1 and L_2 are mu_1 and mu_2 respectively. The upper half of the lens L_3 has a refractive index mu_1 and the lower half has mu_2 . A point object O is imaged at O_1 by the lens L_1 and at O_2 by the lens L_2 placed in same position . If L_3 is placed at the same place.

Assertion : An emf vec(E) is induced in a closed loop where magnetic flux is varied. The induced vec(E) is not a conservative field. Reason : The line intergral vec(E).vec(dl) around the closed loop is non-zero.