Under to action of force `P` the constant acceleration of block `B` is `3ms^(-2)` to the right At the instant when the velcoity of `B` is `2ms^(-1)` to the right determine the absolute velocity of point `C` of the cable
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Under the action of force P, the constant acceleration of block B is 6 m//sec^(2) up the incline. For the instant when the velocity of B is 3 m//sec up the incline. Choose the correct option(s)

A block A has a velocity of 0.6ms^(-1) the right. Determine the velocity of cylinder B.

A block A has a velocity of 0.6ms^(-1) the right. Determine the velocity of cylinder B.

Block A is kept on block B as shown in figure. It is known that acceleration of block A is 2 m//s^(2) towards right and acceleration of block B is 3 m//s^(2) towards right under the effect of unknown forces. Direction of friction force acting on A by B (mu_(AB) = 0.3)

Block A is kept on block B as shown in figure. It is known that acceleration of block A is 2 m//s^(2) towards right and acceleration of block B is 3 m//s^(2) towards right under the effect of unknown forces. Direction of friction force acting on A by B (mu_(AB) = 0.3)

Two blocks A and B are shown in figure. Block A moves to the left with a constant velocity of 6m/s. Find : (a) Velocity of the blocks B. (b) Velocity of the point P of the string. Relative velocity of the point M of the cable with respect to the point P.

For the pulley system shown in fig. each of the cables at A and B is given a velocity of 2ms^(-1) in the direction of the arrow. Determine the upward velocity v of the load m.

For the pulley system shown in fig. each of the cables at A and B is given a velocity of 2ms^(-1) in the direction of the arrow. Determine the upward velocity v of the load m.

Under the action of a given coulombic force the acceleration of an electron is 3.5 xx 10^(25) ms^(-2) . Then the magnitude of the acceleration of a proton under the action of same force is nearly