The magnitude of displacement is the shortest distance between the initial and final position. In case of a particle completing one full round around a circle the displacement is ZERO. Because the initial and final positions are one and the same
The only case in which the magnitude of displacement and displacement are exactly the same is when the displacement occurs in a straight line. In such a scenario, the magnitude of displacement (distance between initial and final positions) will be equal to the displacement (change in position) as there is no change in direction.
Displacement can be used to find the change in position of an object from its initial position. It is a vector quantity that gives both the magnitude and direction of this change. Displacement is often used in physics to calculate distance, velocity, and acceleration.
-- Distance is a scalar quantity, whereas displacement is a vector. -- Distance is the integral of magnitude of displacement. -- Magnitude of displacement is always less than or equal to distance. -- The two quantities are equal when the motion is in a straight line.
To find the displacement from a negative velocity-time graph, you need to calculate the area under the curve for the portion representing displacement. If the velocity is negative, the displacement will be in the opposite direction. The magnitude of the displacement is equal to the absolute value of the area under the curve.
The magnitude of displacement is equal to distance when an object moves in a straight line without changing direction. This occurs when displacement and distance have the same direction.
The magnitude of two displacement vectors, of magnitude x and y, is sqrt(x2 + y2)
The only case in which the magnitude of displacement and displacement are exactly the same is when the displacement occurs in a straight line. In such a scenario, the magnitude of displacement (distance between initial and final positions) will be equal to the displacement (change in position) as there is no change in direction.
Magnitude and Direction :) -hayley
Displacement can be used to find the change in position of an object from its initial position. It is a vector quantity that gives both the magnitude and direction of this change. Displacement is often used in physics to calculate distance, velocity, and acceleration.
-- Distance is a scalar quantity, whereas displacement is a vector. -- Distance is the integral of magnitude of displacement. -- Magnitude of displacement is always less than or equal to distance. -- The two quantities are equal when the motion is in a straight line.
To find the displacement from a negative velocity-time graph, you need to calculate the area under the curve for the portion representing displacement. If the velocity is negative, the displacement will be in the opposite direction. The magnitude of the displacement is equal to the absolute value of the area under the curve.
Distance traveled is equal to the magnitude of the displacement vector when the motion is in a straight line.
The magnitude of displacement is equal to distance when an object moves in a straight line without changing direction. This occurs when displacement and distance have the same direction.
it is the dot product of displacement and force . i.e. Fdcos(A) where F is the magnitude of force , d is the magnitude of displacement and A is the angle between them
The magnitude of the displacement is always equal to or greater than the distance traveled. This is because the magnitude of displacement is the shortest distance between the initial and final positions, while distance traveled is the total length of the path taken.
meters.
Distance and displacement are similar because both have magnitude.However, displacement is a vector quantity since it has both magnitude and direction whereas distance is a scalar quantity since it has only magnitude.