Generally, you just integrate the equation for velocity.
No. Displacement is just the final location minus the initial location, regardless of the path.
If displacement of a particle is zero in a uniform circular motion, then the distance travelled by that particle is not zero, kinetic energy is constant, speed is constant and work done is zero
The maximum displacement of a particle of a wave is called the amplitude. It refers to how far the particle moves from its equilibrium position as the wave passes through it.
The distance travelled by a particle cannot be zero when displacement is not zero because unlike distance which is a scalar, displacement is a vector quantity implying that it has both direction and magnitude.
Yes, the directions of velocity and displacement of a particle can be different. Velocity is a vector quantity that includes both speed and direction, while displacement is a vector quantity that represents the change in position. Therefore, it is possible for a particle to move in one direction while its displacement changes in another direction.
No. Displacement is just the final location minus the initial location, regardless of the path.
If displacement of a particle is zero in a uniform circular motion, then the distance travelled by that particle is not zero, kinetic energy is constant, speed is constant and work done is zero
The maximum displacement of a particle of a wave is called the amplitude. It refers to how far the particle moves from its equilibrium position as the wave passes through it.
The distance travelled by a particle cannot be zero when displacement is not zero because unlike distance which is a scalar, displacement is a vector quantity implying that it has both direction and magnitude.
To conduct a mean square displacement calculation, you first need to track the position of a particle over time. Then, calculate the squared distance the particle has moved from its starting point at each time interval. Finally, average these squared distances to find the mean square displacement, which represents the average distance the particle has traveled from its starting point over time.
The distance travelled by a particle cannot be zero when displacement is not zero because unlike distance which is a scalar, displacement is a vector quantity implying that it has both direction and magnitude.
Yes, the directions of velocity and displacement of a particle can be different. Velocity is a vector quantity that includes both speed and direction, while displacement is a vector quantity that represents the change in position. Therefore, it is possible for a particle to move in one direction while its displacement changes in another direction.
Negative
The statement is incorrect. The maximum displacement of a particle from its equilibrium position in a wave is known as the amplitude of the wave, not the amplitude of the particle itself.
distance travel led by a particle in a given interval of time is known as displacement. displacement=distance traveled by time taken.Displacement may be zero. it is path length which a particle travels.distance should not be zero.
The displacement of a particle is independent of the path taken if only the initial and final positions are considered. It is determined by the difference between the final and initial positions, regardless of how the particle got there. This is a result of displacement being a vector quantity, where only the magnitude and direction matter, not the path taken.
To find average velocity, you need to know the displacement. If you knew displacement, average velocity would be found by: V = Displacement / time