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Velocity and Acceleration in Polar Coordinates: Instructor's Guide

Main Ideas

  1. Students derive expressions for the velocity and acceleration in polar coordinates

Students' Task

Estimated Time: 30 minutes

Carry out calculations of velocity and acceleration in polar coordinates

Prerequisite Knowledge

Props/Equipment

Activity: Introduction

The activity begins by asking the students to write on whiteboard what ${\bf{v}} = \frac{d{\bf{r}}}{dt}$ is. Students propose two alternatives, ${d{\bf{r}}\over{d{t}}} = {d{r}\over{d{t}}} {\bf\hat{r}}$ and ${d{\bf{r}}\over{d{t}}} = {d{r}\over{d{t}}} {\bf\hat{r}} + {d{\phi}\over{d{t}}} {\bf\hat{\phi}}$. A discussion ensues about which is correct. The proper formula is derived using $\frac{d{\bf{r}}}{dt} = \frac{d{r}}{dt} {\bf\hat{r}} + r \frac{d{\bf\hat{r}}}{dt}$. This result is further justified by drawing the velocity vector and discussing the fact that ${\bf\hat{r}}$ changes as $\phi$ changes.

Students are then asked to find values for ${d{ {\bf\hat{r}}}\over{d{t}}}$ and ${d{ {\bf\hat{\phi}}}\over{d{t}}}$. Students are given the handout cfvpolarhand.pdf and asked to carry out calculations of $\bf{v}$ and $\bf{a}$ in polar coordinates.

Activity: Student Conversations

Activity: Wrap-up

After students have completed the calculations, it is important to quickly review the answers and the procedure for calculating them.

$$ {\bf{v}} = {\bf{\dot{r}}} = \dot{r} {\bf\hat r} + r \dot \phi {\bf\hat \phi}$$ $$ {\bf{a}} = {\bf{\dot{v}}} = {\bf{\ddot{r}}} = \left(\ddot{r}- r \dot{\phi}^2\right) {\bf\hat r} + \left( r \ddot{\phi} + 2 \dot{r}\dot{\phi}\right) {\bf\hat \phi}$$

Notes on these derivations can be found in the Central Forces course notes Section 8

Extensions

This activity leads smoothly into a mini-lecture defining the kinetic energy and angular momentum in polar coordinates.