Acceleration: Difference between revisions

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In common speech, the '''acceleration'''  of an object is the increase of its speed  per unit time.   In daily language  the term acceleration is only used for an ''increase'' in speed; a ''decrease'' in speed is usually called deceleration.  
In common parlance, the '''acceleration'''  of an object is the ''increase'' of its speed  per unit time, while a ''decrease'' in speed is usually called deceleration. In [[physics]], acceleration is the rate of change of an object's ''[[velocity]]''. Since velocity is a [[Vector_(mathematics)|vector]] quantity, a change in either its magnitude or direction are both considered changes and result in an acceleration. As such, an object traveling at a constant speed around a circular path is also undergoing acceleration due to the directional change in motion.


In [[physics]], speed is the absolute value (magnitude) of [[velocity]], a [[vector]]. Physicists define velocity of a point in space as the  [[derivative]] of the position-vector  of the point with respect to time. Conventionally, the position of a point is designated by by '''r''' (a vector),  velocity by  '''v''', acceleration (a vector)  by '''a''',  and time by ''t'' (a [[scalar]]). Hence
==Physics definition of acceleration==
In physics, speed is the absolute value (magnitude) of velocity, a vector. Physicists define the velocity of a point in space as the  [[derivative]] of the position-vector  of the point with respect to time. Conventionally, the position of a point is designated by '''r''' (a vector),  velocity by  '''v''', acceleration (a vector)  by '''a''',  and time by ''t'' (a [[scalar]]). Hence,
:<math>
:<math>
\mathbf{v}\, \stackrel{\mathrm{def}}{=}\,  \frac{d \mathbf{r}}{dt}.
\mathbf{v}\, \stackrel{\mathrm{def}}{=}\,  \frac{d \mathbf{r}}{dt}
</math>
</math>
The acceleration '''a''' is the derivative of '''v''' with respect to time,
and the acceleration '''a''' is the derivative of '''v''' with respect to time,
:<math>
:<math>
\mathbf{a} \, \stackrel{\mathrm{def}}{=}\,  \frac{d \mathbf{v}}{dt}.
\mathbf{a} \, \stackrel{\mathrm{def}}{=}\,  \frac{d \mathbf{v}}{dt}.
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\mathbf{a} = \frac{d^2 \mathbf{r}}{dt^2}.
\mathbf{a} = \frac{d^2 \mathbf{r}}{dt^2}.
</math>
</math>
The direction and length of '''a''' may vary from one instant to the other. Since it is not meaningful to compare two non-parallel vectors, the term ''deceleration'' is hardly ever used in physics. The second derivative of '''r''',  whatever its magnitude or direction, is referred to as acceleration. The unit of acceleration is length per time squared (in [[SI]]: m s<sup>&minus;2</sup>).  
The direction and length of '''a''' may vary from one instant to the other. Since it is not meaningful to compare two non-parallel vectors, the term ''deceleration'' is hardly ever used in physics. The second derivative of '''r''' with respect to time,  whatever its magnitude or direction, is referred to as acceleration. The unit of acceleration is length per time squared (in [[SI]]: m s<sup>&minus;2</sup>).
 


==Acceleration of a body==
If the object is not a point, but a body of finite extent,  we recall that the motion of the body can be separated in a [[translation]] of the [[center of mass]] and a [[rotation]] around the center of mass. The  definitions just given then apply to the position '''r''' of the center of mass and the translational velocity and translational acceleration of the center of mass of the body.
If the object is not a point, but a body of finite extent,  we recall that the motion of the body can be separated in a [[translation]] of the [[center of mass]] and a [[rotation]] around the center of mass. The  definitions just given then apply to the position '''r''' of the center of mass and the translational velocity and translational acceleration of the center of mass of the body.


The rotational motion of the body is somewhat more difficult to describe. In particular one can prove that there cannot exist in three dimensions a set of angular coordinates such that their first derivative with respect to time is the angular velocity, see [[rigid rotor]] for more details.
The rotational motion of the body is somewhat more difficult to describe. In particular one can prove that there cannot exist in three dimensions a set of angular coordinates such that their first derivative with respect to time is the angular velocity, see [[rigid rotor]] for more details.
Accordingly, angular acceleration cannot be given as second derivatives of some coordinates  with respect to time (except for the special case of rotation around an axis fixed in space).
Accordingly, angular acceleration cannot be given as second derivatives of some coordinates  with respect to time (except for the special case of rotation around an axis fixed in space).
 
==Relation to force==
One of the fundamental laws of physics is [[Isaac Newton|Newton]]'s second law. This states that the acceleration  of the center of mass of a (rigid) body is proportional to the [[force]] acting on the body. The relation between force and acceleration being linear, the proportionality constant is a property of the body only; it is the [[mass]] of the body.
One of the fundamental laws of physics is [[Isaac Newton|Newton]]'s second law. This states that the acceleration  of the center of mass of a (rigid) body is proportional to the [[force]] acting on the body. The relation between force and acceleration being linear, the proportionality constant is a property of the body only; it is the [[mass]] of the body.


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\mathbf{F} = - m \boldsymbol{\nabla}\big( V(\mathbf{r})\big),
\mathbf{F} = - m \boldsymbol{\nabla}\big( V(\mathbf{r})\big),
</math>
</math>
with ''m'' the total mass of the body. Comparing with Newton's second law, we see that &minus;'''&nabla;''' ''V'' is the acceleration of the body (provided ''m''<b>&nabla;</b>''V'' is the ''only'' force operative on the body). An example of an acceleration due to  a potential is the  [[acceleration due to gravity]].
with ''m'' the total mass of the body.<ref> A force equal to minus the gradient of a potential is ''non-dissipative''. Friction is an example of a dissipative force.</ref> Comparing with Newton's second law, we see that &minus;'''&nabla;''' ''V'' is the acceleration of the body (provided ''m''<b>&nabla;</b>''V'' is the ''only'' force operative on the body). An example of an acceleration due to  a potential is the  [[acceleration due to gravity]].
 
==References==
{{reflist}}
 
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In common parlance, the acceleration of an object is the increase of its speed per unit time, while a decrease in speed is usually called deceleration. In physics, acceleration is the rate of change of an object's velocity. Since velocity is a vector quantity, a change in either its magnitude or direction are both considered changes and result in an acceleration. As such, an object traveling at a constant speed around a circular path is also undergoing acceleration due to the directional change in motion.

Physics definition of acceleration

In physics, speed is the absolute value (magnitude) of velocity, a vector. Physicists define the velocity of a point in space as the derivative of the position-vector of the point with respect to time. Conventionally, the position of a point is designated by r (a vector), velocity by v, acceleration (a vector) by a, and time by t (a scalar). Hence,

and the acceleration a is the derivative of v with respect to time,

Accordingly, acceleration is the second derivative of the position of a point in space with respect to time,

The direction and length of a may vary from one instant to the other. Since it is not meaningful to compare two non-parallel vectors, the term deceleration is hardly ever used in physics. The second derivative of r with respect to time, whatever its magnitude or direction, is referred to as acceleration. The unit of acceleration is length per time squared (in SI: m s−2).

Acceleration of a body

If the object is not a point, but a body of finite extent, we recall that the motion of the body can be separated in a translation of the center of mass and a rotation around the center of mass. The definitions just given then apply to the position r of the center of mass and the translational velocity and translational acceleration of the center of mass of the body.

The rotational motion of the body is somewhat more difficult to describe. In particular one can prove that there cannot exist in three dimensions a set of angular coordinates such that their first derivative with respect to time is the angular velocity, see rigid rotor for more details. Accordingly, angular acceleration cannot be given as second derivatives of some coordinates with respect to time (except for the special case of rotation around an axis fixed in space).

Relation to force

One of the fundamental laws of physics is Newton's second law. This states that the acceleration of the center of mass of a (rigid) body is proportional to the force acting on the body. The relation between force and acceleration being linear, the proportionality constant is a property of the body only; it is the mass of the body.

In classical mechanics it is frequently the case that the force on a body is proportional to the gradient of a potential V,

with m the total mass of the body.[1] Comparing with Newton's second law, we see that − V is the acceleration of the body (provided mV is the only force operative on the body). An example of an acceleration due to a potential is the acceleration due to gravity.

References

  1. A force equal to minus the gradient of a potential is non-dissipative. Friction is an example of a dissipative force.