A uniform rope of mass M=0.1kg and length L=10m hangs from the celling. `[g=10m//s^(2)]` :-

Find the time taken by a transverse wave to travel the full length fo a uniform rope of mass 0.1 kg and length 2.45 m hangs from the ceiling

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 uniform rope of mass 0.1 kg and length 2.5 m hangs from ceiling. The speed of transverse wave in the rope at upper end at a point 0.5 m distance from lower end will be

A uniform rope of mass m and length L hangs from a celling. (a) Show that the speed of a transverse wave on the rope is a function of y , the distance from the lower end, and is given by t = 2sqrt(L//g) .

An uniform rod of mass m=30 kg and length l=0.80 m is free to rotate about a horizontal axis O passing through its centre. A particle P of mass M=11.2 kg falls vertically through a height h=36/245 m and collides elastically with the rod at a distance l/4 from O . at the instant of collision the rod was stationary and was at angle alpha=37^(@) with horizontal as shown in figure Velocity of particle P after collision (g=10ms^(-2))

A uniform wire of length 20 m and weighing 5 kg hangs vertically. If g=10 m s^(-2) , then the speed of transverse waves in the middle of the wire is

the moment of inertia ofa uniform rod of mass 0.50 kg and length 1 m is 0.10 kg m^2 about a lline perpendicular to the rod. Find the distance of this line from the middle point of the rod.

The density of a uniform steel wire of mass 1.6 xx 10^(-2) kg , and length 2.5 m is 8 xx 10^(3) kg//m^(3) . When it is loaded by 8kg, it elongates by 1.25 mm. If g = 10 m//s^(2) , then the Young's modulus of the material of the wire is

A block of mass 2m is hanging at the lower and of a ropeof mass m and length the l, the other end being fixed to the ceililng. A pulse of wavelength lamda_(0) is produced at the lower of the rope. The speed of the pulseat the mid point of rope is: