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{td:align=center|bgcolor=#F2F2F2}*[Model Hierarchy]*
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h2. Description and Assumptions
{excerpt:hidden=true}*System:* One [point particle] constrained to move in a circle at constant speed. --- *Interactions:* [Centripetal acceleration|centripetal acceleration].{excerpt}
This model applies to a single [point particle] moving in a circle of fixed radius (assumed to lie in the _xy_ plane with its center at the origin) with constant speed. It is a subclass of the [Rotational Motion] model defined by α=0 and _r_ = _R_.
h2. Problem Cues
Usually uniform circular motion will be explicitly specified if you are to assume it. (Be especially careful of _vertical_ circles, which are generally _nonuniform_ circular motion because of the effects of gravity. Unless you are specifically told the speed is constant in a vertical loop, you should not assume it to be.) You can also use this model to describe the acceleration in _instantaneously_ uniform circular motion, which is motion along a curved path with the tangential acceleration instantaneously equal to zero. This will usually apply, for example, when a particle is at the top or the bottom of a vertical loop, when gravity is not changing the _speed_ of the particle.
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h2. Prerequisite Knowledge
h4. Prior Models
* [1-D Motion (Constant Velocity)]
* [1-D Motion (Constant Acceleration)]
h4. Vocabulary and Procedures
* [tangential acceleration]
* [centripetal acceleration]
* [angular frequency]
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h2. System
A single [point particle|point particle].
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h2. Interactions
The system must be subject to an acceleration (and so a net force) that is directed _radially inward_ to the center of the circular path, with no tangential component.
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h2. Model
h4. Relevant Definitions
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h5. Initial conditions
{latex}\begin{large}\[ x_{0} = x(t=0)\]
\[ y_{0} = y(t=0) \]
\[\theta_{0} = \theta(t=0)\]\end{large}{latex}
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h5. Centripetal acceleration
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{latex}\begin{large}\[ \vec{a}_{c} = -\frac{v^{2}}{R}\hat{r} = -\omega^{2}R\;\hat{r}\]\end{large}{latex}
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h5. Phase:
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