A traffic policeman standing at the intersection sees 2 cars A & B turning at angles `53^(@)&90^(@)` respectively (as shown in the figure). Their velocities are `V_(A)=20m//s`, `V_(B)=10m//s`. Then, which car appears to be moving faster to the traffic policeman:-

Two particles A and B are projected simultaneously in the directins shown in figure with velocities v_(A) = 20 m//s and v_(B) = 10 m//s respectively. They collide in air after 1/2 s. Find (a) the angle theta (b) the distance x.

A and B are moving with the same speed 10m/s in the direction E-30^(@)-N and E-30^(@)-S respectively. Find the relative velocity of A w.r.t. B.

Airplanes A and B are flying with constant velocity in the same vertical plane at angles 30^(@) and 60^(@) with respect to the horizontal respectively as shown in figure . The speed of A is 100sqrt(3) m//s . At time t = 0 s , an observer in A finds B at a distance of 500 m . The observer sees B moving with a constant velocity perpendicular to the line of motion of A . If at t = t_(0) , A just escapes being hit by B ,t_(0) , A just escapes being hit by B , t_(0) in seconds is

A man 'A' moves in north direction with speed 10m/s and another man B moves in E-30^(@)-N with 10 m//s . Find the relative velocity of B w.r.t. A.

Two masses A and B of mass M and 2M respectively are connected by a compressed ideal spring. The system in placed on a horizontal frictionless table and given a velocity uhat(k) in the z-direction as shown in the figure. The spring is then released. In the subsequent motion the line from B to A alwyas points along the hat(i) unit vector. All some instant of time mass B has a x-component of velocity as v_(x)hat(i) . The velocity vec(v)_(A) of mass A at that instant is :-

Blocks shown in figure moves with constant velocity 10 m/s towards right. All surgaces in contact are rough. The friction force applied by B on A is :-

In the figure shown the acceleration of A is, bara_(A)=(15hati+15hatj)m//s^(2). If A is sliding on B then the acceleration of B is.

A ball is thrown from the top of 36m high tower with velocity 5m//ss at an angle 37^(@) above the horizontal as shown. Its horizontal distance on the ground is closest to [ g=10m//s^(2) :

AB is a cylinder of length 1m fitted with a thin flexible diaphragm C at the middle and other thin flexible diaphragms A and B at the ends. The portions AC and BC contain hydrogen and oxygen gases respectively. The diaphragms A and B are set into vibrations of same frequency. What is the minimum frequency of these vibrations for which diaphragms C is a node? (Under the conditions of experiment v_(H_(2) = 1100m//s , v_(0_(2) = 300m//s ).

A block of mass 10 kg, moving with acceleration 2m//s^(2) on horizontal rough surface is shown in figure then find the value of frictional coefficient.