A movie theater is 3 blocks due north of a supermarket, and a beauty parlor is 4 blocks due east of the movie theate. How many blockes long is the steet that runs directly from the supermarket to the beauty parlor?

A movie theatre has 3 entrances and 4 exists. In how many ways can a man enter and exit from the theatre?

small block of mass 200 g is kept at the top of a frictionless incline which is 10 m long and 3.2 m high. How much work was required a. to lift the block from the ground nd put it at the top b. to side the block up the incline? What will be the speed of the block when it reaches the ground if, c. it falls off the incline and drops vertically on the ground d. it slides down the incline? Take g=10 m/s^2 .

Weight of a body depends directly upon acceleration due to gravity g . Value of g depends upon many factors. It depends upon the shape of earth, rotation earth etc. Weight of a body at a pole is more then that at a place on equator because g is maximum at poles and minimum on equator. Acceleration due to gravity g varies with latitude lambda as per relation given below : g_(rot)=g-Romega^(2)cos^(2)lambda where R is radius of earth and omega is angular velocity of earth. A body of mass m weighs W_(r ) in a train at rest. The train then begins to run with a velocity v around the equator from west to east. It observed that weight W_(m) of the same body in the moving train is different from W_(r ) . Let v_(e ) be the velocity of a point on equator with respect to axis of rotation of earth and R be the radius of the earth. Clearly the relative between earth and trainwill affect the weight of the body. Difference between Weight W_(r ) and the gravitational attraction on the body can be given as

Weight of a body depends directly upon acceleration due to gravity g . Value of g depends upon many factors. It depends upon the shape of earth, rotation earth etc. Weight of a body at a pole is more then that at a place on equator because g is maximum at poles and minimum on equator. Acceleration due to gravity g varies with latitude lambda as per relation given below : g_(rot)=g-Romega^(2)cos^(2)lambda where R is radius of earth and omega is angular velocity of earth. A body of mass m weighs W_(r ) in a train at rest. The train then begins to run with a velocity v around the equator from west to east. It observed that weight W_(m) of the same body in the moving train is different from W_(r ) . Let v_(e ) be the velocity of a point on equator with respect to axis of rotation of earth and R be the radius of the earth. Clearly the relative between earth and trainwill affect the weight of the body. Weight W_(m) of the body can be given as

A balloon is tied to a block. The mass of the block is 2kg . The tension of the string between the balloon and the block is 30N . Due to the wind, the string has an angle 0 relative to the vertical direction. costheta=4//5 and sintheta=3//5 . Assume the acceleration due to gravity is g = 10 m//s^(2) . Also assume the block is small so the force on the block from the wind can be ignored. Then the x-component and the y-component of the acceleration a of the block.

A balloon is tied to a block. The mass of the block is 2kg . The tension of the string between the balloon and the block is 30N . Due to the wind, the string has an angle 0 relative to the vertical direction. costheta=4//5 and sintheta=3//5 . Assume the acceleration due to gravity is g = 10 m//s^(2) . Also assume the block is small so the force on the block from the wind can be ignored. Then the x-component and the y-component of the acceleration a of the block.

Alicia lives in a town whose streets are on a grid system, with all streets running east - west or north - south without breaks. Her school, located on a corner, lies three blocks south and three blocks east of her hoem, also located on a corner. If Alicia only walks wouth or east on her way to school, how many possible routes can she take to school?

A wooden box is placed on a table. The normal force on the box from the table is N_(1) . Now another identical box is kept on first box and the normal force on lower block due to upper block is N_(2) and normal force on lower block by the table is N_(3) . For this situtation, mark out the correct statement (s).

A 100 kg block is started with a speed of 2.0 m s^(-1) on a long, rough belt kept fixed in a horizontal position. The coefficient of kinetic friction between the block and the belt is 0.20. (a) calculate the change in the internal energy of the block-belt system as the block comes to a stop on the belt. (b) consider the situation from a frame of reference moving at 2.0 m s^(-1) along the initial velocity of the block. as seen from this frame, the block is gently put on a moving belt and in due time the block starts moving with the belt at 2.0 m s^(-1) , calculate the increase in the kinetic energy of the block as it stops slipping past the belt. (c ) find the work done in this frame by the external force holding the belt.