Rolling Around

Faisal from Arnold House School offered a strategy for working on this problem:

What we did was take a dart board and rolled it around 4 metre rulers.

It travelled a straight line along the ruler. The bullseye of the board stayed the same distance away from the ruler.

After each corner the bullseye made a curve a quarter of a circle (which is 90 degrees) so after the experiment is over the bullseye would have turned a whole circle.

The distance travelled is the length of the 4 metre rulers plus the circumference of the circle.

We had several more good solutions for the first part of this problem from pupils at Highcliffe Primary School. Whitney and Joe said:

The new shape (i.e. the locus of the centre of the circle) will be a square with rounded corners.

Sam and John explained that the length of the locus ...

In effect, in circumnavigating the corners, the centre of the circle rotates completely around a point on the circle's circumference one time, and, since the distance from the centre to the edge is the same as the distance from the edge to the centre, this part of the path is the length of the circumference. On the straight sections, the length of the path is equal to the length of the sides, making it equal to the perimeter of the square.

The length of the path is the perimeter of the square plus the circumference of the circle.

By like reasoning, when the circle rolls around a triangle, as it rounds the corners the circle will turn around completely once, which results in the centre of the circle tracing out the circumference, which, when added to the perimeter of the triangle will give the length of the path.

In general, as a circle rolls around a convex polygon, the length of the path of the centre of the circle will be the perimeter of the polygon plus the circumference of the circle, the locus of the path being a distance away from the polygon equal to the radius of the circle.

Very thorough explanations; thank you Oliver and Bill .