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Don't skip this activity if you use nonrectangular basis vectors! 1)
Draw a picture on the board showing $d\rr$ as the infinitesimal change in the position vector $\rr$ between two infinitesimally close points.
Most groups will miss the factor of $r$ in the $\phat$ component of $d\rr$. Watch for this as you walk around the classroom. A good thing to point out is that $d\phi$ is not a length.
Some groups will then remember the formula for arclength and be able to figure out the rest on their own. Other groups will need to be reminded about the relationship between arclength and radius on a circle. A good way to do this is to ask them for the formula for the circumference of a circle, then half a circle, a quarter, etc. Make sure to give the angles in radians! Eventually, they get the point.
Some students may wonder whether the top of the (Cartesian) rectangle is $\pm dx\,\ii$. This question is ill-posed, since the sign of $dx$ itself depends on which way you're going; you can't change your mind in the middle of a problem. The safest way to resolve such problems is to anchor all vectors to the same point, as shown in the figures.
For the polar rectangle, many students will realize that that there are second-order differences between the two arcs, but few will realize that there are also second-order differences in the radial sides, due to changes in $\rhat$.
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