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\begin{large}\[ \vec{a} = \frac{d\vec{v}}{dt} \qquad \mbox{or} \qquad \vec{a}=\frac{\sum \vec{F}}{m} \]\end{large}

\begin{large}\[ \int_{v_{\rm i}}^{v} dv = \int_{t_{\rm i}}^{t} a\: dt \] \end{large}

\begin{large} \[ v - v_{\rm i} = a(t-t_{\rm i}) \] \end{large}

\begin{large} \[ v = v_{\rm i} + a (t-t_{\rm i}) \] \end{large}

\begin{large}\[ vh2. Defnition 
{excerpt} 
The time rate of change of velocity.  Acceleration is a vector quantity.  For one-dimensional motion, the direction is often specified by the mathematical sign of the acceleration.  A positive acceleration indicates motion in one (arbitrarily chosen) direction, while a negative acceleration indicates the opposite direction.  An acceleration that points in the direction opposite of the velocity is sometimes called a deceleration.
{excerpt}

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h2. Representations

h4. Differential 
  {latex}\begin{Large} $v = \frac{dx}{dt}$\]\end{Large}{latex}
h4. Integral
 {latex}\begin{Large} $v_{\rm f} = vlarge}

 \begin{large} \[ \frac{dx}{dt} = v_{\rm i} + a t - a t_{\rm i} \] \end{large}

 \begin{large} \[ \int_{x_{\rm i}+}}^{x} dx = \int_{t_{\rm i}}^{t} \left( v_{\rm f}}a\:dt$i} - at_{\rm i} + a t\right)\:dt \]   \end{Large}{latexlarge}

 \begin{large} \[ x - x_{\rm i} = v_{\rm i} (t-t_{\rm i}) - a t_{\rm i} (t-t_{\rm i}) + \frac{1}{2}a( t^{2} - t}\\
{latex}\begin{Large}$v_{\rm f}^{2}=v_{\rm i}^{2}) \] \end{large}

\begin{large}\[ x = }+2\int_{x_{\rm i}}^{x + v_{\rm i} (t-t_{\rm f}}a\:dx$\end{Large}{latex}
h4. Graphical
  Besides explicit velocity graphs, velocity can be found from the slope of a distance vs. time graph or (if the initial velocity is known) by adding the area under an acceleration vs. time graph to the initial velocity.
h4. Through Motion Diagrams
  In a motion diagram, the velocity can be estimated by looking at the spacing of the individual snapshots (assuming that the snapshots are separated by equal time intervals).

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h2. Relevant Models

 {children:page=Two-Dimensional Motion (General)|depth=all}

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h2. Relevant Examples

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i}) + \frac{1}{2} a (t^{2} - 2 t t_{\rm i} + t_{\rm i}^{2}) \] \end{large}

\begin{large} \[ x = x_{\rm i} + v_{\rm i} (t-t_{\rm i}) + \frac{1}{2} a (t - t_{\rm i})^{2} \] \end{large}

\begin{large}\[ \frac{dv}{dt} = a \] \end{large}

\begin{large} \[ \frac{dv}{dx}\frac{dx}{dt} = a \] \end{large}

\begin{large} \[ \frac{dv}{dx}v = a \] \end{large}

\begin{large} \[ \int_{v_{\rm i}}^{v} v \:dv = \int_{x_{\rm i}}^{x} a \:dx \] \end{large}

\begin{large}\[ v^{2} = v_{\rm i}^{2} + 2 a (x-x_{\rm i}) \] \end{large}