A wooden object floats in water kept in as beaker. The object is near a side of the beaker figure. Let `P_1,P_2,P_3` be the pressure at the three points A,B and C of the bottom as shown in the figure.

Compare the pressure at the point P in the three tubes shown in the figure .

An object of uniform density is allowed to float in water kept in a beaker. The object has triangular cross-section as shown in the figure. If the water pressure measured at the three points A, B and C below the object are P_(A), P_(B) " and " P_(C ) respectively. Then

Water is flowing through a long horizontal tube. Let P_A and P_B be the pressures at two points A and B of the tube

A wooden block is floating on water kept in a beaker. 40% of the block is above the water surface. Now the beaker is kept inside a lift that starts going upward with acceleration equal to g//2 . The block will then

A transparent solid sphere of radius 2 cm and density rho floats in a transparent liquid of density 2rho kept in a beaker. The bottom of the beaker is spherical in shape with radius of curvature 8 cm and is silvered to make it concave mirror as shown in the figure. When an object is placed at a distance of 10 cm directly above the centre of the sphere C, its final image coincides with it. Find h (as shown in the figure ), the height of the liquid surface in the beaker from the apex of the bottom. Consider the paraxial rays only. The refractive index of the sphere is 3//2 and that of the liquid is 4//3.

For V versus T curves at constant pressure P_1 and P_2 for and ideal gas shown in figure-

Three vessels A,B,and C of different shapes contain a water upto the same height as shown in the figure . P_(A) ,P_(B) ,and P_(C) be the pressure exerted by the water at the bottom of the vessels A ,B and C respectively . Then

A liquid of density rho is filled in a beaker of cross section A to a height H and then a cylinder of mass M and cross-section a is made to float in it as shown in If the atmospheric pressure is P_0 find the pressure (a) at the top face B of the cylinder (b) at the bottom face C of the cylinder and (c ) at the base D of the beaker. (d) Can ever these pressure be equal ?