Sam sent us her work on the problem, including the angles of all the triangles. Thank you Sam!

Can you see how she avoided counting any twice?

She first counted triangles with two corners on neighbouring pegs, then those two apart, and so on. She called two triangles the same if they had the same angles and not just if they used the same pegs. She explains this in a bit more detail below.

Here is her work:

First I labelled the points on the pegboard ABCD.
There are four possible triangles: ABC, ABD, ACD and BCD. However these triangles are all the same shape (you can see this by rotating triangle ABC) so we could say that there is only one type of triangle that we can make.

This triangle has angles 90^°, 45^° and 45^°. I know this because if you draw a square around the points ABCD and cut it in along the diagonal you get this triangle.

For the six point board, I again labelled the points as ABCDEF.

There are three possible triangles

ABC, with angles 120^°, 30^° and 30^°.
ABD, with angles 90^°, 60^° and 30^°.
ACE, with all angles 60^° (an equilateral triangle).

For the eight point board, I again labelled the pegs ABCDEFGH

There are five possible triangles

ABC, with angles 135^°, 22.5^° and 22.5^°.
ABD, with angles 112.5^°, 22.5^° and 45^°.
ABE, with angles 90^°, 22.5^° and 67.5^°.
ACE, with angles 90^°, 45^° and 45^°.
ACF, with angles 45^°, 67.5^° and 67.5^°.

Can you see how she worked out the angles in the triangles? If you have come across circle theorems you may find these helpful. Remember that the angles in a triangle add up to 180 degrees! You can divide the triangle (or the circle) into pieces whose angles you know to help you.

If you would like to have a go at this problem for yourself, you might like to print off these sheets if you're not using the interactivity:

Sheet of four-peg boards

Sheet of six-peg boards

Sheet of eight-peg boards