A string of mass m and length l is hanging from ceiling as shown in the Fig. Wave in string move upward. `v_A`and `v_B` are the speed of wave at A and B respectively. Then `v_B`is :

In the network shown in fig. , points A, B, and C are at potentials of 70 V, 0, and 10V, respectively.

A wave pulse is generated in a string that lies along x- axis. At the points A and B, as shown in the figure, if R_A and R_B are the ratio of wave speed to the particle speed respectively then:

A mass m is moving with velocity (bar v) along a line y = x as shown in the figure. Which one is correct statement about angular momentum L_A , and L_B about the points A and B respectively?

A uniform rope of mass 0.1 kg and length 2.45 m hangs from a ceiling. (a) Find the speed of transverse wave in the rope at a point 0.5 m distant from the lower end. (b) Calculate the time taken by a transverse wave to travel the full length of the rope.

A stone of mass m tied to a string of length l is rotated in a circle with the other end of the string as the centre. The speed of the stone is v. If the string breaks, the stone will move

A particle of mass m is suspended from a ceiling through a string of length L. The particle moves in a horizontal circle of radius r. Find a. the speed of the particle and b. the tension in the string. Such a system is called a conical pendulum.

A particle of mass m is suspended from a ceiling through a string of length L. The particle moves in a horizontal circle of radius r. Find a. the speed of the particle and b. the tension in the string. Such a system is called a conical pendulum.

The block of mass m_(0)=muL is attached to a uniform string of mass M=muL and length L as shown in the figure. If a wave pulse is produced near the block, then the time it taken to reach the ceiling is

Find velocity of wave is string A & B .

Find velocity of wave is string A & B .