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Level Five > Geometry and Measurement

Vince's Problem

Keywords:
Achievement Objectives:

Achievement Objective: Deduce the angle properties of intersecting and parallel lines and the angle properties of polygons and apply these properties.

Specific Learning Outcomes: 

Find the centre of a circle using common material or mathematical construction tools.

Description of mathematics: 

This problem is an application of some geometry ideas to a ‘practical’ situation. It is nice to be able to put into practice some of the theoretical work in geometry that, at times, may appear to have no use.

To be able to make any progress with it the students need to know how right angles and circles are related. The first obvious thing linking the two is the fact that the angle in a semicircle is a right angle. This leads to the first solution. The neat part about this is that you don’t require any sophisticated mathematical instruments to be able to solve the problem. The material that you want is just lying around in most rooms.

But if you draw a secant to a circle and bisect that secant, the bisector goes through the centre of the circle. This produces two solutions but does rely on the use of ruler and compasses

Required Resource Materials: 
cardboard (to make the circle)
scissors
constructing tools
Copymaster of the problem in English
Copymaster of the problem in Māori
Activity: 

Problem

Vince was making a toy clock to give to his sister for her birthday. He used a dinner plate to draw a circle on a piece of wood and cut out the circle using his father’s jig saw. He now wants to find the centre of the circle so that he can attach the hands of the clock. He remembered hearing somewhere that this could be done using a right angle but he couldn’t remember how this was done. Can you help him find a way?

vince1.

Teaching sequence

  1. Introduce the problem to the class.
  2. Brainstorm ideas for approaching the problem. Ask
    What do you know about circles?
    What connection can you think of between a circle and a right angle?
  3. As the students work on the problem in pairs you might check their progress and ask the following questions to extend their thinking:
    What strategies helped you find the answer?
    How did you know when you had the solution and could stop looking?
  4. Share answers. Get the students to write them on the board as they are given. Ask the class to use the methods to find the centre of a circle. Which do they think is the most accurate method? Let them write up what they did in their maths books.

Solution to the problem

First Solution: Take a large piece of paper with a right angle in the corner. Put the corner on the edge of the circle and mark where the two edges of the paper meet the circle.  If these marks are joined the line passes through the centre of the circle.

If this process is repeated after putting the corner of the paper on another place on the edge of the circle, another line passing through the centre can be drawn. These lines cross at the centre.

Why does this work? This is just an application of the fact that the angle subtended by an arc is a right angle if and only if the arc is a semi-circle. Because the angle in the corner of the paper is a right angle, the points where the paper touches the circle must be cut off a semi-circle. This can only be done if the line between the two points is a diameter.

Next it is clear that two different diameters can only intersect in the centre of the circle.

Second Solution: Draw an arbitrary line across the circle. Suppose that the line meets the circle at A and B. The bisector of AB is a diameter of the circle. Two such diameters meet at the centre of the circle.

(The bisector can be found using a standard construction. Make equal arcs with centres A and B. These arcs will intersect at P and Q. The line PQ is the required bisector.)

vince4.

Third Solution: Draw an arbitrary line across the circle. The bisector of this line is a diameter. The mid-point of this diameter is the centre of the circle.

(The mid-point is again a standard construction. In fact it is the same construction that produces the bisector.)

AttachmentSize
VincesProblem.pdf37.54 KB
VincesProblemMaori.pdf49.28 KB

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