All the pulleys are ideal, string is massless then rate of work done by gravity at the given instant is `(-x xx 10^(2))W` then calculate `x` :

If pulley is ideal and string is massless then reading of weighing machine is (5x)/(3)kg then calculate x. : (g = 10 m//s^(2))

In the arrangment shown pulley is ideal and string is massless. 5kg block is moving on the smooth surface. When theta is 37^(@) , then acceleration of 5kg and 10 kg blocks are a_(1) and a_(2) while tension in string is T then : ( g =10 m//s^(2) ) :

A diatomic ideal gas is expanded at constant pressure. If work done by the system is 10 J then calculated heat absorbed.

Two moles of an ideal gas undergoes the process depicted below. Given that ((deltaP)/(deltaT))_(v) is x xx 10^(-y) , then calculate the value of (y-x).

For the reaction x+2y to3z the rate at a given instant of time can be represented as:

Pulleys are ideal and string are massless. The masses of blocks are m_(1) = 4kg and m_(2) = 1kg as shown.If all surfaces are smooth then the acceleration of m_(2) in m//s^(2) is ( g =10 m//s^(2) )

There is a system of infinite pulleys and springs.Spring constants are in GP as k 2k 4k 8k.........oo as shown in the figure.All the pulleys are massless frictionless and strings are massless and inextensible.Then time period of small oscillations of the block will be (Mass of block is m ). qquad (in ) (i) 2

In fig. both pulleys and the string are massless and all the surfaces are frictionless. Given m_(1)=1kg, m_(2)= 2kg, m_(3)=3kg . The acceleration of m_(1) is

In fig. both pulleys and the string are massless and all the surfaces are frictionless. Given m_(1)=1kg, m_(2)= 2kg, m_(3)=3kg . The acceleration of m_(3) is