In the figure a mass m is hung by a light spring and a light string as shown .Both the spring and the string make an angle `theta` with the horizontal at equilbrium .If the string is suddenly cut then the instantaneous acceleration of the mass m is :

A mass M is hung with a light inextensible string as shown in Find the tension in the horizontal part of the string .

A body of mass m is suspended by two strings making angles alpha and beta with the horizontal. Find the tensions in the strings.

If the string & all the pulleys are ideal, acceleration of mass m is :-

A pendulum bob of mass m charge q is at rest with its string making an angle theta with the vertical in a uniform horizontal electric field E. The tension in the string in

A mass of M kg is suspended by a weightless string. The horizontal force required to displace it until string makes an angle of 45^@ with the initial vertical direction is:

Two blocks A and B of same mass m attached with a light spring are suspended by a string as shown in fig. Find the acceleration of block A and B just after the string is cut.

A body of mass m is attached by an inelastic string to a suspended spring of spring constant k . Both the string and the spring have negligible mass and the string is inextensible and of length L . Initially, the mass m is at rest. Q. If the mass m is now raised up to point A (the top end of the string see fig. and allowed to fall from rest, the maximum extension of the spring in the subsequent motion will be

A thin uniform bar of mass m and length 2L is held at an angle 30^@ with the horizontal by means of two vertical inextensible strings, at each end as shown in figure. If the string at the right end breaks, leaving the bar to swing, determine the tension in the string at the left end and the angular acceleration of the bar immediately after string breaks.

A uniform rod of mass 15 kg is held stationary at 37 degree with the help of a light string as shown in Fig. The tension in the string is

The string the spring and the puley shown in figure are light. Find the time period of the mass m.