Trajectory of a particle in a projectile motion is given as `y=x-(x^(2))/80`. Here `x` and `y` are in metre. For this projectile motion the following with `g=10m//s^(2)`.

Trajectory of particle in a projectile motion is given as y=x- x^(2)/80 . Here, x and y are in meters. For this projectile motion, match the following with g=10 m//s^(2) . {:(,"Column-I",,"Column-II"),((A),"Angle of projection (in degrees)",(P),20),((B),"Angle of velocity with horizontal after 4s (in degrees)",(Q),80),((C),"Maximum height (in meters)",(R),45),((D),"Horizontal range (in meters)",(S),30),(,,(T),60):}

Trajectory of particle in a projectile motion is given as y = x - (x^(2))/(80) . Here x and y are in metre. For this projectile motion match the following with g = 10 ms^(-2) .

Trajectory of particle in a projectile motion is given as: y=x-(x^(2)//80) (x and y are in meters). Take g=10m//s^(2) .

Trajectory of a particle in a projectile motion is given by y=x-x^(2)/80 where x and y are in meters. Match the column-1 and column-2. {:(,"Column-I",,"Column-II"),("(A)","x coordinate at height of 15 m",,"(P) 20 m"),("(B)",underset("point of projection at x= 100 m")"vertical distnce of particle from",,"(Q) 80 m"),("(C)","Horizontal range",,"(R) 60 m"),(,,,"(S) 25 m"):}

The potential energy (in joules ) function of a particle in a region of space is given as: U=(2x^(2)+3y^(2)+2x) Here x,y and z are in metres. Find the maginitude of x compenent of force ( in newton) acting on the particle at point P ( 1m, 2m, 3m).

Trajectory of a projectile is given by y = alphax + betax^2 . Then find (alpha + beta) .

The trajectory of a projectile in a vertical plane is y=sqrt(3)x-2x^(2) . [g=10 m//s^(2)] Time of flight of the projectile is :-

If y=x-x^2 is the path of a projectile, then which of following is incorrect ( g=10m//s^2 ):

The trajectory of a projectile in a vertical plane is y=sqrt(3)x-2x^(2) . [g=10 m//s^(2)] Range OA is :-