7 M

3(a) State and prove Gauss's Law. Derive the point form of Gauss's Law relates the flux leaving any closed surface to the charge enclosed.

7 M

3(b) Evaluate both sides of divergence theorem for the field D = 2xy ax + x ² ay C/m ² and the rectangular parallelepiped formed by the planes x = 0 and 1, y = 0 and 2 and z = 0 and 3.

7 M

4(a) Write a brief note on potential gradient

7 M

Solved any one question from Q.5 & Q.6

4(b) A dipole of moment p = 6a _z nC.m is located at the origin in free space. Find the potential V & Electric Field intensity E at point P(r = 4, θ = 20 ^° , φ = 0 ^° ).

7 M

5(a) Write brief note boundary conditions for perfect dielectric materials

7 M

5(b) Find E at point P(3,1,2) for the two coaxial conducting cylinders, if potential V = 50 V at ρ = 2 m and V = 20 V at ρ = 3 m.

7 M

6(a) State Bio-Savart law for the steady magnetic field. Also derive the expression for the magnetic field intensity for an infinitely long straight filament carrying a direct current I.

7 M

Solved any one question from Q.7 & Q.8

6(b) For any vector field, show explicitly that divergence of the curl of any vector is Zero.

7 M

7(a) Derive the expression for the torque acting on the loop in the presence of magnetic field B, relating the dipole moment and the magnetic field B.

7 M

7(b) State Maxwell's equations in integral form and explain physical significance of the equations.

7 M

8(a) State and prove Poynting's theorem relating to the flow of energy at a point in space in an electromagnetic field.

7 M

8(b) Write a brief note on uniform plane wave propagation in free space.

7 M