A current loop consists of two identical semicircular parts each of radius R, one lying in the x-y plane and the other in x-z plane. If the current in the loop is 'i' the resultant magnetic field due to the two semicircular parts at their common centre is

Two similar coils of radius R are lying concentrically with their planes at right angles to each other. The currents flowing in them are I and 2 I, respectively. The resultant magnetic field induction at the centre will be

A straight wire carrying a current of 12 A is bent into a semi-circular arc of radius 2.0 cm as shown in Fig. (a). Consider the magnetic field B at the centre of the arc. (a) What is the magnetic field due to the straight segments? (b) In what way the contribution to B from the semicircle differs from that of a circular loop and in what way does it resemble? (c) Would your answer be different if the wire were bent into a semi-circular arc of the same radius but in the opposite way as shown in Fig. (b)?

A wire loop formed by joining two semicircular sections of radii R_(1) and R_(2) and centre C carries a current I as shown in the figure . The resultant magnetic field at C has a magnitude of

A circular loop of radius R, carrying current I, lies in xy plane with its centre at origin. The total magnetic flux density at centre is :

Two identical circular loops of metal wire are lying on a table without touching each other. Loop A carries a current which increases with time. In response, the loop B

A vibration magnetometer consists of two identical bar magnets placed one over the other such that they are perpendicular and bisect each other. The time period of oscillation in a horizontal magnetic field 2^(5/4)s . One of the magnets is removed and if the other magnet oscillates in the time field, then the time period in second is