Consider a force acting on a particle given as `vec( F) = yhat( i ) + xhat( j)` , where ( x, y ) is the instantaneous location of the particle. This type of force is `:`

Force acting on a particle is given by F=(A-x)/(Bt) , where x is in metre and t is in seconds. The dimensions of B is -

The velocity of a particle of mass 2 kg is given by vec(v)=at hat(i)+bt^(2)hat(j) . Find the force acting on the particle.

Path traced by a moving particle in space is called trajectory of the particle. Shape of trajectiry is decided by the forces acting on the particle. When a coordinate system is associated with a particle motion, the curve equation in which the particle moves [y=f(x)] is called equation of trajectory. It is just giving us the relation among x and y coordinates of the particle i.e. the locus of particle. To find equation of trajectory of a particle, find first x and y coordinates of the particle as a function of time eliminate the time factor. The position vector of car w.r.t. its starting point is given as vec(r)=at hat(i)- bt^(2) hat(j) where a and b are positive constants. The locus of a particle is:-

A particle of mass 'm' moves along the quarter section of the circular path whose centre is at the origin . The radius of the circular path is 'a' . A force vec(F)=yhat(i)-xhat(j) newton acts on the particle, where x,y denote the coordinates of position of the particle. Calculate the work done by this force in taking, the particle from point, A(a,0) to point B(0,a) along the circular path.

The position vector of a particle is given by vec(r ) = k cos omega hat(i) + k sin omega hat(j) = x hat(i) + yhat(j) , where k and omega are constants and t time. Find the angle between the position vector and the velocity vector. Also determine the trajectory of the particle.

A particle with charge +Q is moving on X - Y plane. Magnetic field existing in the region is given as vecB = B_(o)hatk . At a certain instant of time net magnetic force acting on the particle is vecF = F_(0) hati + 2F_(0)hatj . Find the instantaneous velocity of particle.

A particle has initial velocity vec(v)=3hat(i)+4hat(j) and a constant force vec(F)=4hat(i)-3hat(j) acts on the particle. The path of the particle is :

A particle of mass 2kg moves under a force given by vec(F)=-(8N//m)(xhat(i)+yhat(j)) where hat(i) and hat(j) are unit vectors in the x and y directions. The particle is projected from the origin in xy plane with an initial velocity vec(v)=(3m//s)hat(i)+(4m//s)hat(j) . Select correct statement(s).

When force vec(F)_(1),vec(F)_(2),vec(F)_(3) are acting on a particle of mass m , the particle remains in equilibrium. If the force vec(F)_(1) is now removed then the acceleration of the particle is :