A 20 gram weight produces an extension of 2 cm in a vertical spring. A mass of 100 gram is suspended at its bottom and left pulling down. Calculate the frequency of its vibration.

A 40 gm mass produces on extension of 4 cm in a vertical spring. A mass of 200 gm is suspended at its bottom and left pulling down. Calculate the frequency of its vibration.

The vertical extension in a light spring by a weight of 1 kg suspended from the wire is 9.8 cm . The period of oscillation

A mass of 2 kg is suspended from a vertical spring. An additional force of 2.5 N stretches it by 1 cm. (i) Calculate the force constant. (ii) Calculate the frequecny of oscillations, if the spring is stretched by the given force and then released.

A block of weight W produces an extension of 9cm when it is hung by an elastic spring of length of 60cm and is in equilibrium. The spring is cut into two parts, one of length 40cm and the other of length 20cm . The same load W hangs in equilibrium supported by both parts as shwon in figure. The extension in cm noe is

Spring is pulled down by 2 cm. What is amplitude of its motion?

A mass m is suspended from a spring of length l and force constant K . The frequency of vibration of the mass is f_(1) . The spring is cut into two equal parts and the same mass is suspended from one of the parts. The new frequency of vibration of mass is f_(2) . Which of the following relations between the frequencies is correct

A rectangular tank having base 15 cm xx 20 cm is filled with water (density rho = 1000 kg//m^(2)) up to 20 cm and force constant K = 280 N//m is fixed to the bottom of the tank so that the spring remains vertical. This sysytem is in an elevator moving downwards with acceleration a = 2 m//s^(2) . A cubical block of side l = 10 cm and mass m = 2 kg is gently placed over the spring and released gradually, as shown in the figure. a. Calculate compression of the spring in equilibrium position. b. If the block is slightly pushed down from equilibrium position and released, calculate frequency of its vertical oscillations.

A string vibrates in its first normal mode with a frequency of 220 vibrations //s . The vibrating segment is 70.0 cm long and has a mass of 1.20g. (a) Find the tension in the string. (b) Determine the frequency of vibration when the string vibrates in three segments.