In the given figure, a man of true mass $M$ is standing on a weighing machine placed in a cabin. The cabin is joined by a string with a body of mass $m$. Assuming no friction, and negligible mass of cabin and weighing machine, the measured mass of man is (normal force between the man and the machine is proportional to the mass)

The string shown in figure passes over a small smooth pulley rigidly attached to trolley $A$. If the speed of trolley is constant and equal to $v_{\mathrm{A}}$ towards right, the speed and magnitude of acceleration of block $B$ at the instant shown in figure are,

The given figure shows a block of mass $m$ placed on a smooth wedge of mass $M$. Calculate the minimum value of $M\text{'}$ and tension in the string so that the block of mass $m$ moves vertically downward with acceleration $10 \mathrm{m} {\mathrm{s}}^{-2}$.

In the given figure, a small block of mass $m$ is kept on the block of mass $M$. Then

A block of mass $m$ is placed on a wedge. The wedge can be accelerated in four manners marked as $\left(1\right), \left(2\right), \left(3\right)$ and $\left(4\right)$ as shown in figure. If the normal reactions in situations $\left(1\right), \left(2\right), \left(3\right)$ and $\left(4\right)$ are $N_{1^{,}}{N}_2, N_{3,}$ and $N_4,$, respectively and acceleration with which the block slides on the wedge in the situations are $b_1, b_2, b_3,$ and $b_4$, respectively. Then

Seven pulleys are connected with the help of three light strings as shown in figure. Consider $P_3,P_4,P_5$ as light pulleys and pulleys $P_6$ and $P_7$ have masses $m$ each. For this arrangement, mark the correct statement$\left(s\right)$.

In the figure shown, $A$ and $B$ are free to move. All the surfaces are smooth. Then $(0<\theta <{90}^{°})$

Two blocks of masses $m_1=2 \mathrm{kg}$ and $m_2=4 \mathrm{kg}$ hang over a massless pulley as shown in the figure. A force $F_0=100 \mathrm{N}$ acting at the axis of the pulley accelerates the system upwards. Then