The equation of motion of a particle starting at `t=0` is given by `x=5sin(20t+π/3)`, where x is in centimeter and t is in second. When does the particle come to rest for the second time?

The equation of motion of a particle started at t=0 is given by x=5sin(20t+pi/3) , where x is in centimetre and t in second. When does the particle a. first come rest b. first have zero acceleration c. first have maximum speed?

The equation of motion of a particle started at t=0 is given by x=5sin(20t+pi/3) , where x is in centimetre and t in second. When does the particle a. first come rest b. first have zero acceleration c. first have maximum speed?

A force acts on a 3.0 gm particle in such a way that the position of the particle as a function of time is given by x=3t-4t^(2)+t^(3) , where xx is in metres and t is in seconds. The work done during the first 4 seconds is

The motion of a particle executing simple harmonic motion is given by X = 0.01 sin 100 pi (t + 0.05) , where X is in metres andt in second. The time period is second is

Consider a particle moving in simple harmonic motion according to the equation x=2.0cos(50pit+tan^-1 0.75) where x is in centimetre and t in second. The motion is started at t=0. a. When does the particle come to rest for the first time? B. When does the acceleration have its maximum magnitude for the first time? c. When does the particle comes to rest for the second time?

The motion of a particle along a straight line is described by equation : x = 8 + 12 t - t^3 where x is in meter and t in second. The retardation of the particle when its velocity becomes zero is.

The motion of a particle along a straight line is described by equation : x = 8 + 12 t - t^3 where x is in metre and t in second. The retardation of the particle when its velocity becomes zero is.

The displacement of a particle is moving by x = (t - 2)^2 where x is in metres and t in second. The distance covered by the particle in first 4 seconds is.

The displacement of a particle is moving by x = (t - 2)^2 where x is in metres and t in second. The distance covered by the particle in first 4 seconds is.

The position x of a particle with respect to time t along the x-axis is given by x=9t^(2)-t^(3) where x is in meter and t in second. What will be the position of this particle when it achieves maximum speed along the positive x direction