A man throws a ball of mass m from a moving plank ( A ). The ball has a horizontal component of velocity u=3√34 m s- 1 with respect to ground towards another man standing on stationary plank ( B ), as shown in the figure. The combined mass of plank A with man as well as that of plank B with the other man is 2m each. the x-y plane represents the horizontal plane which is frictionless. If initially, plank A was moving with speed u hati with respect to ground, then the relative velocity of plank B (in m s- 1 ) with respect to plank A (after the man on plank B catches the ball) minus 10 m s- 1 is

Question

A man throws a ball of mass m from a moving plank ( A ). The ball has a horizontal component of velocity u=3√34 m s- 1 with respect to ground towards another man standing on stationary plank ( B ), as shown in the figure. The combined mass of plank A with man as well as that of plank B with the other man is 2m each. the x-y plane represents the horizontal plane which is frictionless. If initially, plank A was moving with speed u hati with respect to ground, then the relative velocity of plank B (in m s- 1 ) with respect to plank A (after the man on plank B catches the ball) minus 10 m s- 1 is <img class="img-fluid question-image" alt="Question" src="https://cdn.tardigrade.in/q/nta/p-0d5enb5lpsbbpqph.jpg" /> (A)  (B)  (C)  (D)

Tardigrade Admin · Accepted Answer

By conservation of momentum, 3mu hati=m(.ucos(37)o hati+usin(37)o hatj.)+2m overset arrow VA = overset arrow VA=(11 u/10) hati-(3 u/10) hatj Similarly = overset arrow VB=(4 u/15) hati+(3 u/10) hatj ∴ |VB A|=17 m s- 1

By conservation of momentum, 3mui^=m(ucos(37)oi^+usin(37)oj^​)+2mVA​→​ =VA​→​=1011u​i^−103u​j^​ Similarly =VB​→​=154u​i^+103u​j^​ ∴∣VBA​∣=17ms−1

By conservation of momentum,
$3 m u \hat{i} = m (u cos (37)^{o} \hat{i} + u s in (37)^{o} \hat{j}) + 2 m V_{A} \to$
$= V_{A} \to = \frac{11 u}{10} \hat{i} - \frac{3 u}{10} \hat{j}$
Similarly $= V_{B} \to = \frac{4 u}{15} \hat{i} + \frac{3 u}{10} \hat{j}$
$∴ ∣ V_{B A} ∣ = 17 m s^{- 1}$