k is the force constant of a spring. The work done in increasing its extension from `l_(1)` to `l_(2)` will be:

20 J work is required to stretch a spring through 0.1 m. Find the force constant of the spring If the spring is further stretched through 0.1 m, calculate work done

The time period of a mass suspended by a spring (force constant K) is T. If the spring is cut into three equal pieces, what will be the force constant of each part? If the same mass be suspended from one piece what will be the periodic time?

A spring of force constant k is cut into the length of ratio 1:2:3 . They are connected in series and the new force constant is k' . Then they are connected in parallel and force constant is k",. Then k':k":

Derive the expression for resultant spring constant when two springs having constant k_(1) and k_(2) are connected in parallel.

Derive the expression for resultant spring constant when two springs having constant k_(1) and k_(2) are connected in series.

Two similar springs p and Q have spring constants Kp and kQ, such that Kp>KQ. The are stretched, first by the same amount ( case a), then by the same force (case b). The work done by the springs Wp and WQ are related as, in case (a) and case (b), respectively:

If the work done by force on the body is positive then its kinetic energy

Let R be the relation over the set of all straight lines in a plane such that l_(1) Rl_(2) hArr l_(1)bot l_(2) . Then R is

A body of mass m is attached to the spring which is elongated to 25 cm by an applied for from its equilibrium position, (a) Calculate the potential energy stored in the spring-mass system? (b) What is the work done by the spring force in this elongation? (C) Suppose the spring is compressed to the same 25 cm, calculate the potential energy stored and also the work done by the spring force during compression. (The spring constant, k=0.1Nm^(-1)) .