The displacement x of a particle varies with time according to the relation `x=(a)/(b)(1-e^(-bt))`.Then

The position of a particle moving along the x-axis depends on the time according to the equation x=ct^(2)-bt^(3) , where x is in meters and t in seconds. (a)What units must c and b have ?Let their numerical value be 3.0 and 2.0, respectively. (b)What distance does the particle move. (c)WHat is its displacement? At t=1.0,2.0,3.0 and 4.0 ,What are (d) its velocities and (e) its accelretions?

The position of a particle moving along the x-axis depends on the time according to the equation x=ct^(2)-bt^(3) , where x is in meters and t in seconds . (a) What units must c and b have ? Let their numerical value be 3.0"and"2.0 , respectively. (b) What distance does the particle move, (c) What is its displacement ? At t=1.0,2.0,3.0"and"4.0s, what are (d) its velocities and (e) its acceleration?

The displacement of a particle moving in a straight line is given by the expression x=At^(3)+Bt^(2)+Ct+D in metres, where t is in seconds and A,B,C and D are constant. The ratio between the initial acceleration and initial velocity is

The displacement of a particle varies according to relation x=4[cos pi t + sin pi t ] . The amplitude of the particle is

The displacement of a particle moving in a straight line Is given by the expression x = At^(3) + Bt^(2) + Ct + D meters, where t is in seconds and A, B, C and D are constants. The ratio between the initial acceleration and initial velocity is

The electric potential (V) in volts varies with x (in metre) according to the relation V = 5 + 4x^(2) . The force experienced by a negative charge of 2 mu C located at x = 0.5 m is

The velocity of a particle varies with time as per the law vec(V) = vec(a) + vec(b)t where vec(a) and vec(b) are two constant vectors. The time at which velocity of the particle is perpendicular to velocity of the particle at t= 0 is