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Example: Predicting the location of a object undergoing constant velocity motion
A cart is given a slight push along a near frictionless track (as shown in the video below). After the push, the cart is observed to move with a near constant velocity $\vec{v}_{cart} =\langle 1.2, 0, 0 \rangle \dfrac{m}{s}$. Determine its location after 3 seconds.
Setup
You need to predict the location of the cart using the information provided and any information that you can collect or assume.
Facts
- The cart moves to the right.
- The cart's velocity is given by $\vec{v}_{cart} =\langle 1.2, 0, 0 \rangle \dfrac{m}{s}$.
Lacking
- The initial location of the cart is not known.
Approximations & Assumptions
- The interactions of the cart with its surroundings, over the interval that you care about, are negligible. That is, the cart moves with a constant velocity.
- As a result, the average and instantaneous velocity are equivalent.
- We will assume the initial location of the cart is $\vec{r}_{i}$.
Representations
- The location of the cart can be predicted using the position update formula, $\vec{r}_f = \vec{r}_i + \vec{v}_{avg} \Delta t$
- The motion of the cart is represented using the following motion diagram.
Solution
We can compute the final location,
$\vec{r}_f = \vec{r}_i + \vec{v}_{avg} \Delta t = \vec{r}_i + \vec{v}_{cart} \Delta t = \vec{r}_i + \langle 1.2, 0, 0 \rangle \dfrac{m}{s} (3 s) = \vec{r}_i + \langle 3.6, 0, 0 \rangle m$