A dip circle is at right angles to the magnetic meridian. The apparent dip is

Magnetic meridian is an imaginary:

A bar magnet of magnetic moment M is placed at right angles to magnetic induction B. If a force F is experience by each pole of the magnet, the length of the magnet will be

At 45^@ to the magnetic meridian, the apparent dip is 30^@ . Find the true dip.

If theta_1 and theta_2 be the apparent angles of dip observed in two vertical planes at right angles to each other,then the true angle of dip is give by :

A magnetic needle is free to rotate in a vertical plans parallel to the magnetic meridian has its north tip down at 60^(@) with horizontal . The horizontal component of the earth's magnetic field at the place is known to be 0.4 xx 10^(-4) T determine the magnitude of earth's magnetic field at the place.

A magnetic needle free to rotate in a vertical plane parallel to the magnetic meridian has its north tip pointing down at 22^@ with the horizontal . The horizontal component of the earth's magnetic field at the place is known to be 0.35 G . Determine the magnitude of the earth's magnetic field at the place.

A dip circle is taken to geomagnetic equator. The needle is allowed to move in a vertical plane perpendicular to the magnetic meridian. The needle will stay

The angle of dip at the magnetic equator is

A magnetic needle is free to rotate in a vertical plance which makes an angle of 60^@ with the magnetic meridian. If the needle stays in a direction making an angle of tan^(-1) (2sqrt(3)) with the horizontal, what would be the dip at that place?

At a certain location in Africa, a compass 12^@ west of the geographic north. The northe tip of the magnetic needle of a dip circle in the plane of magnetic meridian points 60^@ above the horizontal . The horizontal component of the earth's field measured to be 0.16 G. Specify the direction and magnitude of the earth's field at the location.