A uniform rope has been placed on a sloping surface as shown in the figure. The vertical separation and horizontal separation between the end points of the rope are H and X respectively. The friction coefficient `(mu)` is just good enough to prevent the rope from sliding down. Find the value of `mu`.

A uniform rope ABCDE has mass M and it is laid along two incline surfaces (AB and CD) and two horizontal surfaces (BC and DE) as shown in figure. The four parts of the rope AB, BC, CD and DE are of equal lengths. The coefficient of friction (mu) is uniform along the entire surface and is just good enough to prevent the rope from sliding. (a) Find mu (b) x is distance measured along the length of the rope starting from point A. Plot the variation of tension in the rope (T) with distance x. (c) Find the maximum tension in the rope.

A uniform rod is placed on two spinning wheels as shown in figure. The axes of the wheels are separated by a distance l=20 cm , the coefficient of friction between that in this case the rod performs harmonic oscillations. Find the period of these oscillations.

A uniform rope of total length l is at rest on a table with fraction f of its length hanging (see figure). If the coefficient of friction between the table and the chain is mu then

In the situration shown in the figure the friction coefficient between M and the horizontal surface is mu . The force F is applied at an angle theta with vertical. The correct statements are

Two block of same mass'm' are joined with an dideal spring of spring constant k and sept on a rough surface as shown in figure. The spring is initially unstretched and coefficient of friction between the blocks and horizontal surface is mu and 2 mu respectively. What should be the maximum speed of block 'A' such that the block 'B' does not move ?

In the situatiobn shown in the figure the friction coefficient between M and the horizontal surface is mu . The force F is applied at an angle theta with vertical. The correct statements are :

A force F is applied on the top of a cube as shown in the figure. The coefficient of friction between the cube and the ground is mu . If F is gradually increased, find the value of mu for which the cube will topple before sliding.