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That's the magnitude of its acceleration.
-- The magnitude of acceleration is equal to the time rate of change of speed. -- The magnitude of acceleration is equal to the time rate of change of the magnitude of velocity. -- Acceleration and velocity are both vectors.
The centripetal acceleration is v2/r, directed toward the center of the circle..
Acceleration has two parts ... its size and its direction.To find the size (magnitude):-- pick a time interval-- measure the speed at the beginning of the interval-- measure the speed at the end of the interval-- subtract the speed at the beginning from the speed at the end-- divide that difference by the length of the time interval-- the result is the magnitude of acceleration during that time interval
Acceleration is a vector quantity because it has both magnitude and direction.
That's the magnitude of its acceleration.
There is no information that shows any relationship with time. Since acceleration is a variable related to time, it is impossible to answer the question.
magnitude of acceleration=change of velocity/time invertal
With that information, you can find the average magnitudeof the accelerationduring that period of time. You can't tell what either the magnitude or directionwere at any time during, only the average magnitude for the whole interval.
-- The magnitude of acceleration is equal to the time rate of change of speed. -- The magnitude of acceleration is equal to the time rate of change of the magnitude of velocity. -- Acceleration and velocity are both vectors.
You can't. Acceleration is change in velocity. If given a constant velocity, the acceleration is zero.
acceleration times speed
yes, Acceleration is vector quatity!!. Its has both magnitude and direction
The centripetal acceleration is v2/r, directed toward the center of the circle..
Zero is.
gravity
Acceleration has two parts ... its size and its direction.To find the size (magnitude):-- pick a time interval-- measure the speed at the beginning of the interval-- measure the speed at the end of the interval-- subtract the speed at the beginning from the speed at the end-- divide that difference by the length of the time interval-- the result is the magnitude of acceleration during that time interval