The angular velocities of three bodies in `SHM` are `omega_(1), omega_(2), omega_(3)` with their respective amplitudes as `A_(1),A_(2),A_(3)`. If all three bodies have same mass and maximum velocity then

Three particles describes circular path of radii r_(1),r_(2) and r_(3) with constant speed such that all the particles take same time to complete the revolution. If omega_(1),omega_(2),omega_(3) be the angular velocity v_(1),v_(2),v_(3) be linear velocities and a_(1),a_(2),a_(3) be linear acceleration than :

If a_(1),a_(2),a_(3) are the last three digits of 17^(256) respectively then the value of a_(2)-a_(1)-a_(3) is equal

Two waves of nearly same amplitude , same frequency travelling with same velocity are superimposing to give phenomenon of interference . If a_(1) and a_(2) be their respectively amplitudes , omega be the frequency for both , v be the velocity for both and Delta phi is the phase difference between the two waves then ,

If two independent waves are y_(1)=a_(1)sin omega_(1) and y_(2)=a_(2) sin omega_(2)t then

The number of all three element subsets of the set {a_(1),a_(2),a_(3)......a_(n)} which contain a_(3) , is

In the adjacent figure, all the pulleys are frictioniess and massless, all the stringes are also massless. The relation between a_(1),a_(2) and a_(3) is (where a_(1),a_(2) and a_(3) are the acceleration of masses m_(1),m_(2) and m_(3) respectively in the direction as shown in the figure)

If a_(1),a_(2),a_(3),a_(4) are positive real numbers such that a_(1)+a_(2)+a_(3)+a_(4)=16 then find maximum value of (a_(1)+a_(2))(a_(3)+a_(4))

The maximum acceleration of a body moving is SHM is a_(0) and maximum velocity is v_(0) . The amplitude is given by