A rope of length L has its mass per unit langth `lambda` varies according to the function `lambda(x)=e^(x//L)`. The rope is pulled by a constant force of 1 N on a smooth horizontal surface. The tension in the rope at `x=L//2` is :

A uniform rope of length of length L is pulled by a force F on a smooth surface. Find tension in the rope at a distance x from the end where force is applied.

A uniform rope of length L is pulled by a constant force F. What is the tension in the rope at a distance l from the end where it is applied?

A uniform rope of length L is pulled by a constant force F. What is the tension in the ropww at a distance l from the end where it is applied?

A straight rope of length 'L' is kept on a frictionless horizontal surface and a force 'F' is applied to one end of the rope in the direction of its length and away from that end. The tension in the rope at a distance 'I from that end is 9

Figure shows a rope of variable mass whose linear mass density is given by , lambda = Ax , where A is + ve constant and x is distance from left end . It b is placed on a smooth horizontal surface . A force F is acting on it as shown . (i) Find total mass of the rope . (ii) Find tension at point P.

A cart of mass M is tied to one end of a massless rope of length 10 m . The other end of the rope is in the hands of a man of mass M . The entire system is on a smooth horizontal surface. The man is at x=0 and the cart at x=10 m . If the man pulls the cart by the rope, the man and the cart will meet at the point