aum naadis su u naspaian SLI am na pumunun auuT SUOI Ota UPISIN pp L am Unit 22. A dipole is placed at origin of coordinate system as shown in figure, find the electric field at point P (0, y). P (0.) 450 p

A dipole is placed at origin of corrdinate system as shown in figure, find the electric field at point P (0, y) .

A dipole is placed at origin of coordinate system as shown in figure, find the electric field at point P(0,y). [(KP)/(sqrt(2)y^(3))(-hat(i)-2hat(j))]

Three infinitely long charge sheets are placed as shown in the figure Find the electric field at the point P.

A dipole is placed at the origin such that its dipole moment is overset(rarr)p=-phati, The electric field and potential at (0,d,0) respectively are :

A dipole is placed at the origin such that its dipole moment is overset(rarr)p=-phati,0 . The electric field and potential at (0,d,0) respectively are :

Two positive and two negative charges are kept in x-y plane in free space as shown in the figure. The magnitude of electric field due to the system of charges at a point P(0, y) will be (y > > d)

Two positive and two negative charges are kept in x-y plane in free space as shown in the figure. The magnitude of electric field due to the system of charges at a point P(0, y) will be (y > > d)

Three semi - inifinte wires, each carrying a current of 1 A are placed on each of the coordinate axes with their ends at the origin, as shown in the figure. The magnetic induction at point P(-2m, 0,0) is

Three semi - inifinte wires, each carrying a current of 1 A are placed on each of the coordinate axes with their ends at the origin, as shown in the figure. The magnetic induction at point P(-2m, 0,0) is

Three short electric dipoles, each of dipole moment P, are placed at the vertices of an equilateral triangle of side length L. Each dipole has its moment oriented parallel to the opposite side of the triangle as shown in the fig. Find the electric field and potential at the centroid of the triangle