Evaluate
where A and omega are constants. `int^t _0 A sin omega dt `

y=Asin omegat where A and omega are constants. Find (d^(2)y)/(dt^(2)) .

A point moves in the plane xy according to the law x=a sin omegat , y=a(1-cos omega t) , where a and omega are positive constants. Find: (a) the distance s traversed by the point during the time tau ,

The position vector of the particle is r(t)=acos omegat hati+a sin omega thatj , where a and omega are real constants of suitable dimensions. The acceleration is

For a particle moving in the x-y plane, the x and y coordinates are changing as x=a sin omega t and y = a ( 1-cos omega t ) , where 'a' and omega constants. Then, what can be inferred for the trajectory of the particle ?

A particle of mass 'm' is moving in the x-y plane such that its x and y coordinate vary according to the law x = a sin omega t and y = a cos omega t where 'a' and 'omega' are positive constants and 't' is time. Find (a) equation of the path. Name the trajectory (path) (b) whether the particle moves in clockwise or anticlockwise direction magnitude of the force on the particle at any time t .

Consider an object of mass m moving in free space with velocity given by vec(v) = v_(0) cos omega t hat (i) +v_(0) sin omegat hat (j) . Here v_(0) and omega are constants and t represents time. calculate force acting on object and angle between force and momentum.

If x = A//2 at t = 0 , Find phase constant (alpha) in x = A sin (omega t + alpha) , at t = 0 , a particle executing SHM is going along negative x axis

A particle moves so that its position vector is given by vec r = cos omega t hat x + sin omega t hat y , where omega is a constant which of the following is true ?

A particle moves so that its position vector is given by vec r = cos omega t hat x + sin omega t hat y , where omega is a constant which of the following is true ?

A particle moves such that its momentum vector vecp(t) = cos omega t hati + sin omega t hatj where omega is a constant and t is time. Then which of the following statements is true for the velocity vec v(t) and acceleration veca (t) of the particle :