Calculate magnetic induction at point O if the wire carrying
a current I has the shape shown in Fig.

(The radius of the curved part of the wire is equal to R and linear parts of the wire are very long.)

The magnetic induction at the point O, if the wire carries a current I, is

Find the magnetic induction at point O, if the current carrying wire is in the shape shown in the figure.

A current I flows along a thin wire shaped as shown in figure. The radius of the curved part of the wire is r. The field at the centre O of the coil is:

Find the magnetic induction of the field at the point O at a loop with current I , whose shape is illustrated in figure (a)In figure a the radii a and b , as well as the angle varphi are known (b)In figure b ,the raidus a and the side b are known. (c)A current I=5.0 A flows along a thin wire shaped as shown in figure.The radius of a curved part of the wire is equal to R=120 mm ,the angle 2varphi=90^(@) .Find the magnetic induction of the field at the point O .

A conducting wire carrying a current I is bent into the shape as shown. The net magnetic field at the centre O of the circular arc of radius R

Calculate the magnetic field at point O for the current-carrying wire segment shown in Fig. The wire consists of two straight portions and a circular arc of radius a, which subtends an angle theta .

The magnetic field strength at a point P distant r due to an infinite straight wire carrying a current i is as shown in the figure

A long wire carrying current 'I' is bent into the shape as shown in the figure. The net magnetic field intensity at the centre 'O' is

Two very long, straight wires carrying, currents as shown in Fig. Find all locations where the net magnetic field is zero.

A part of a long wire carrying a current i is bent into a circle of radius r as shown in figure. The net magnetic field at the centre O of the circular loop is