Four rods, two of length a and two of length b, are linked to form
a kite. The linkage is moveable so that the angles change. What is
the maximum area of the kite?
How many differently shaped rectangles can you build using these
equilateral and isosceles triangles? Can you make a square?
This gives a short summary of the properties and theorems of cyclic quadrilaterals and links to some practical examples to be found elsewhere on the site.
For this problem, you will need to print off a set of quadrilateral cards . You'll also need a copy of the game grid
Shuffle eight cards, and lay them on the grid in the spaces marked "property card". Your challenge is to draw a quadrilateral in each square, so that the quadrilateral has both the properties at the top of the column and at the start of the row. There might be some that aren't possible! If you like, you could play this with a friend, taking turns to draw shapes. If you can't draw a shape, pass
and see whether your partner can, the winner is the one who draws the last shape.
You might find it helpful to draw the shapes on spotty paper; there are squares here and isometric paper here (this might help you find areas and angles).
Can you select 8 cards and arrange them so that you can fill in all of the squares? What cards did you use? What about none of the squares?
What's the smallest number of different shapes you need to fill in the grid? What shapes are these, and what cards did you use?