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{td:align=center|bgcolor=#F2F2F2}*[Model Hierarchy]*
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h2. Description and Assumptions
{excerpt}This model is applicable to a single [point particle] subject to an acceleration that is constrained to one dimension and which is either parallel to or anti-parallel to the particle's initial velocity.{excerpt}
h2. Problem Cues
In practice, this model is only useful when a one-dimensional acceleration is given that has a _known_ time dependence that is _not_ sinusoidal. If the acceleration is constant, the sub-model [One-Dimensional Motion with Constant Acceleration|1-D Motion (Constant Acceleration)] should be used. If the acceleration is sinusoidal (described by a sine, cosine, or sum of the two), the sub-model [Simple Harmonic Motion] should be used. Thus, in practice, the problem cue for this model is that the acceleration will be given as an explicit and integrable function of time, most often a polynomial (the acceleration might also be plotted as a linear function of time).
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h2. Prerequisite Knowledge
h4. Prior Models
* [1-D Motion (Constant Velocity)]
* [1-D Motion (Constant Acceleration)]
h4. Vocabulary
* [position (one-dimensional)]
* [velocity]
* [acceleration]
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h2. System
h4. Constituents
A single [point particle|point particle] (or a system treated as a point particle with position specified by the center of mass).
h4. State Variables
Time (_t_), position (_x_) , and velocity (_v_).
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h2. Interactions
h4. Relevant Types
Some time-varying external influence that is confined to one dimension.
h4. Interaction Variables
Acceleration (_a_(_t_)).
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h2. Model
h4. Laws of Change
Differential Forms:
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{latex}\begin{large}\[ \frac{dv}{dt} = a\]\end{large}{latex}\\
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{latex}\begin{large}\[ \frac{dx}{dt} = v\]\end{large}{latex}\\
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Integral Forms:
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{latex}\begin{large}\[ v(t) = v(t_{0})+\int_{t_{0}}^{t} a\;dt\]\end{large}{latex}\\
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{latex}\begin{large}\[ x(t) = x(t_{0})+\int_{t_{0}}^{t} v\;dt\]\end{large}{latex}\\
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h2. Diagrammatical Representations
* Acceleration versus time graph.
* Velocity versus time graph.
* Position versus time graph.
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h2. Relevant Examples
None yet.
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