A cell is connected between the points A and C of a circular conductor ABCD of centre `O` .` angle` ` AOC = 60^(@)`. If` B_(​1) and B_(​2)` are the magnitudes of the magnetic fields at O due to the currents in ABC and ADC respectively, the ratio `(B_(1))/(B_(2))`, is

A cell is connected between the point A and C of a circular conductor ABCD of centre O, /_AOC = 60^(@) . If B_(1_ and B_(2) are the magnitude of magnetic fields at O due to the currents in ABC and ADC respectively, the ratio of B_(1)//B_(2) is.

The magnitude of the magnetic field at O ( centre of the circular part ) due to the current - carrying coil as shown is :

The figure shows tow coaxial circulalr loop a1 and 2, which forms same solid angle theta at point O . If B_1 and B_2 are the magnetic fields produced at the point O due to loop 1 and 2 respectively, then

A magnetic compass needl oscillates 30 times per minute at a place where the dip is 45^(@) and 40 times per minute where the dip is 30^(@) if B_(1) and B_(2) are respectively the total magnetic field due to the earth at the two places then the ratio B_(1)//B_(2) is best given by

A and B are two concentric circular conductors of centre O and carrying currents i_(1) and i_(2) as shown in the adjacent figure. If ratio of their radii is 1:2 and ratio of the flux densities at O due to A and B is 1:3 , then the value of i_(1)//i_(2) is

Two coils are having magnetic field B and 2B at their centres and current i and 2i then the ratio of their radius is

Torques tau_(1) and tau_(2) are required for a magnetic needle to remain perpendicular to the magnetic fields at two different places. The magnetic field at those places are B1 and B2 respectively, then (B_(1))/(B_(2)) is

As shown in figure a cell is connected across two points A and B of a uniform circular conductor of radius r. Prove that the magnetic field induction at its centre O will be zero.

A cylinderical conductor of radius R is carrying constant current. The plot of the magnitude of the magnetic field, B with the distance, d from the centre of the conductor , is correctly represented by the figure:

The dipole moment of a circular loop carrying a current I, is m and the magnetic field at the centre of the loop is B_(1) . When the dipole moment is doubled by keeping the current constant, the magnetic field at the centre of the loop is B_(2) . The ratio (B_(1))/(B_(2)) is: