Suppose the earth was covered by an oceam of uniform depth `h,(hltltR)` Let `sigma` be densityof ocean and `p` be mean density of earth. Let `Deltag` be the approxemate difference of value of net acceleration duet to gravity between the bottom of the ocean and top `(Deltag=g+("top")-g_("bottom"))`. Choose the correct option.

Choose the correct alternative (a)Acceleration due to gravity increase/decrease with increasing altitude. (b) Acceleration due to gravity increase/decrease with increasing depth (assume the earth to be a sphere of uniform density). (c ) Acceleration due to gravity is independer of mass of the earth/mass of the body. (d) The formula - GM m ((1)/(r_(2)) - (1)/(r_(1))) is more/less accurate than the formula mg (r_(2) - r_(1)) for the difference of potential energy between two points r_(2) and r_(1) distance away from the centre of earth.

At a depth h_(1)=(R)/(2) from the surface of the earth acceleration due to gravity is g_(1). It’s value changes by Deltag_(1) when one moves down further by 1 km. At a height h_(2) above the urface of the earth acceleration due to gravity is g_(9). It’s value changes by Deltag_(2) when one moves up further by 1 km. If Deltag_(1)=Deltag_(2) find h_(2). Assume the earth to be a uniform phere of radius R.

One end of a string of length L is tied to the ceiling of a lift acceleration upwards with an acceleration 2g . The other end of the string is free. The linear mass density of the string varies linearly from 0 to lambda from bottom to top. Choose the correct option(s)

Let g_(h) and g_(d) the acceleration due to gravity at height h above the earth s surface and at depth d below the earth surface respecitively if g_(n) = g_(d) then the releation between h and d is

An engineer is designing a spring to be placed at the bottom of an elevator shaft, if the elevator cable should break at a height h above the top of the spring, calculate the required value of the spring constant k, so that passsengers undergo an acceleration of no more than 10 g when brought to rest, Let M be the total mass of the elevator and passengers