The electric field strength depends only on the `x` and `y` coordinates according to the law `E = a (x i + yj) (x^(2) + y^(2))`, where `a` is a constant , `i` and `j` are the unit vectors of the `x` and `y` axes. Find the flux of the vector `E` through a sphere of raidus `R` with its centre at the origin of coordinates.

The electric field strength depends only on the x and y coordinates according to the law E = (a(xhati+ y hatj))/(x^(2) + y^(2)) , where a is a constant hati and hatj are unit vectors of the x and y axes . Find the potential difference between x = 1 and x = 5 :

Find the potential varphi (x,y) of an electrostatic field E = 2axyi + a (x^(4) - y^(2)) j , where a is a constant, I and J are the unit vectors of the x and y axes.

The intensity of an electric field depends only on the coordinates x and y as follows, E = (a(xhati +y hatj))/(x^(2)+y^(2)) where, a is constant and hati and hatj are the unit vectors of the x and y axes. Find the charges within a sphere of radius R with the centre at the origin.

Determine the electric field strength vector if the potential of this field depends on x, coordinates as (a) V = a (x^2 — y^2) (b) V = axy where, a is a constant.

In an interial reference frame K there is only magnetic field with induction B = b (yl -x)//(x^(2) + y^(2)) , where b is a constane, i and j are the unit vectors of the x and y axes. Find the elecric field strength E' in the frame K' moving relative to the frame K with a constatn non-relative velocity v = vk, k is the unit vector of the z-axis. The z' axis is assumed to coincule with the z axis. What is the shape of the field E' ?

A force F=Ai+Bj is applied to a point whose radius vector relative to the origin of coordinates O is equal to r=ai+bj , where a, b, A, B are constants, and i,j are the unit vectors of the x and y axes. Find the moment N and the arm l of the force F relative to the point O.