An infinitely long wire of uniform cross section carries a current whose current density varies as `j=br^(alpha)`. Where `b=(10^(7))/(pi)`unit,` alpha=.1`unit and `r` the distance from axis. The magnetic induction at a distance `0.25` from axis is given by `(nxx5)/(3)x10^(-2)` tesla. Find `n`

An infinitely long cylinderical wire of radius R is carrying a current with current density j=alphar^(3) (where alpha is constant and r is the distance from the axis of the wire). If the magnetic fixed at r=(R)/(2) is B_(1) and at r=2R is B_(2) then the ratio (B_(2))/(B_(1)) is

Suppose that the current density in a wife of radius a varies with r according to J = Kr^(2) , where K is a constant and r is the distance from the axis of the wire. Find the megnetic field at a point distance r from the axis when (a) r a

A long cylinder of uniform cross section and radius R is carrying a current i along its length and current density is uniform cross section and radius r in the cylinder parallel to its length. The axis of the cylinderical cavity is separated by a distance d from the axis of the cylinder. Find the magnetic field at the axis of cylinder.

Suppose that the current density in a wire of radius a varius with r according to Kr^2 where K is a constant and r is the distance from the axis of the wire. Find the magnetic field at a point at distance r form the axis when (a) rlta and (b) rgta.

In a long cylindrical wire of radius R, magnetic induction varies with the distance from axis as B = cr^(alpha) . Find the function of current density in wire with the distance from axis of wire.

A long cylindrical conductor of radius R carries a current i as shown in the figure. The current density J varies across the cross-section as J = kr^(2) , where, k is a constant. Find an expression for the magnetic field B at a distance r (lt R) from the axis

The magnetic induction at a distance r from a straight, infinitely long wire in air and carrying a current I is given by