One end of a `2.4 - m`string is held fixed and the other end is attached to a weightless ring that can slide along a frictionless rod as shown in Fig. 7.86. The three longest possible wavelength for standing waves in this string are respectively

What is maximum possible wavelength of standing waves in 1m long string if it is fixed at both ends

A 50-kg ball is attached to one end of a 1m cord that has a mass of 0.10kg . The other end o the cord is attached to a ring that can slide on a frictionless horizontal shaft AB , as shown in the diagram. A horizontal blow is delivered to the cord and excites the fundamental vibratiion with a maximum transverse velocity of 15m//s . Assume that the ball remains essentially stationary as the cord vibrates. [g=9.8m//s^(2)]

A string fixed at both ends is 8.40 m long and has a mass of 0.120 kg . It is subjected to a tension of 96.0 N and set oscillating. (a) What is the speed of the waves on the string? (b) What is the longest possible wavelength for a standing wave ? (c) Give the frequency of the wave.

A particle, held by a string whose other end is attached to a fixed point C, moves in a circle on a horizontal frictionless surface. If the string is cut, the angular momentum of the particle about the point C

One end of a thin straight elastic string is fixed at A(4,-1) and the other end B is at (1,2) in the unstretched condition. If the string is stretched to triple its length to the point C , then find the coordinates of this point.

In a standing wave 4 nodes and 3 antinodes are formed between two fixed end of string of length 6 m.Then the wave length of the standing wave is

A uniform rod of mass m is hinged at one end and other end is connected to a light extensible string having length L.If the Young s modulus and crosssectional area of the wire is Y and A respectively then the elongation in the string is

A spring of mass m lies on a smooth table. One, end of it is clamped to the vertical wall and other end is attached to a mass m ( as shown in fig) and is placed on a horizontal frictionless surface. If the block of mass M is given a velocity v_(0) towards right find the K.E. of the system . ( AsSigmae velocity in spring is varying linearly).

One end of a taut string of length 3m along the x-axis is fixed at x = 0 . The speed of the waves in the string is 100ms^(-1) . The other end of the string is vibrating in the y-direction so that stationary waves are set up in the string. The possible wavelength (s) of these sationary waves is (are)

A string of lenth l fixed at one end carries a mass m at the other end. The strings makes (2)/(pi)revs^(-1) around the axis through the fixed end as shown in the figure, the tension in the string is