In the figure shown the acceleration of A is, `bara_(A)=(15hati+15hatj)m//s^(2).` If A is sliding on B then the acceleration of B is.

In the figure shown the acceleration of A is, vec(a)_(A) = 15 hat (i) + 15 hat (j) then the acceleration of B is (A remains in contact in B)

In the figure shown the accelerationof A is a_(A) = (15 hati + 15 hatj) . Then the acceleration of B is (A remain in contact with B)

In the figure shown the accelerationof A is a_(A) = (15 hati + 15 hatj) . Then the acceleration of B is (A remain in contact with B)

In the figure shown the acceleration of A is, veca =15hati+15hatj then the acceleration of B is: (A remains in contact with B)

In fig, the acceleration of A is vec(a)_(A)=15hat(i)+15hat(j) . Then the acceleration of B is (A remains in constact with B)

In fig, the acceleration of A is vec(a)_(A)=15hat(i)+15hat(j) . Then the acceleration of B is (A remains in constact with B)

In the figure shown, the acceleration of block of mass m_(2) is 2m//s^(2) . The acceleration of m_(1) :

In the figure shown, the acceleration of block of mass m_(2) is 2m//s^(2) . The acceleration of m_(1) :

If acceleration of A is 2m//s^(2) to left and acceleration of B is 1m//s^(2) to left, then acceleration of C is-

If acceleration of A is 2m//s^(2) to left and acceleration of B is 1m//s^(2) to left, then acceleration of C is-