Exploring example spaces: what are they like and how do we move around them? Anne Watson Jasper, October 2006.

Exploring example spaces: what are they like and how do we move around them? Anne Watson Jasper, October 2006

2,4,6,8 … 5,7,9,11 … 9,11,13,15 …

► Make up a similar sequence of your own for which your neighbour will find the sum of the first five terms.

2, 4, 6, 8 … 2, 5, 8, 11 … 2, 23, 44, 65 …

2,4,6,8 … 3,6,9,12 … 4,8,12,16 …

Principle 1 ► All learners have a natural propensity to  see patterns,  to seek structure,  classify,  generalise ….

2,4,6,8 … 5,7,9,11 … 9,11,13,15 …

2, 4, 6, 8 … 2, 5, 8, 11 … 2, 23, 44, 65 …

2,4,6,8 … 3,6,9,12 … 4,8,12,16 …

Principle 2 ► Example spaces can be characterised by their dimensions of variation and ranges of of change

The largest … ► Sketch a quadrilateral whose sides are all equal in length. Area? ► Sketch a quadrilateral for which two pairs of sides are equal in length, and which has the largest possible area. ► Sketch a quadrilateral for which three lines are equal in length, and which has the largest possible area. ► … same for no lines equal

Principle 3 ► Constraints make the problem more interesting/ harder/ more conceptual

► Write down a pair of numbers which have a difference of 2 ► ….. and another pair

Principle 4 ► Example spaces are individual, and learners can be prompted to extend their example spaces

► Write down a pair of numbers which have a difference of 9 ► ….. and another pair

► On a nine-pin geoboard, create a triangle which has a height of two units.  and another ► Using dynamic geometry software, find the class of triangles which have a height of two. ► Construct a triangle which has a height of two and a height of one.  and another

Principle 5 Example spaces are dependent on context and tools Example spaces are dependent on context and tools

Example of what?

Principle 6 ► Examples have to be examples of something:  classes of objects  concepts  techniques  problems and questions  appropriate objects which satisfy certain conditions  ways of answering questions  ways to construct proofs  …. so on

Sorting examples ► Think of a number ► Add 3 to it and also subtract 3 from it; also multiply it by 3 and divide it by 3 ► Now put your four answers in increasing order, and label then with their operations ► If you change the 3 to something else, is the order always the same for your starting number? ► If you change your starting number, but preserve 3, what different orders can you achieve? ► What if you change both the starting number and the 3?

Principle 7 ► You can explore and extend your example spaces by:  sorting  comparing  combining  … what else?

Can you see any fractions?

Can you see 1 ½ of something?

Principle 8 ► The process of creating examples is dependent on the way it is prompted

Examples of methods ► Think of as many ways as you can to enlarge a rectangle by a scale factor of 2

► Sequences:  what does “like this” mean?  we all look for patterns ► Quadrilateral  start from what we know and make it harder by adding constraints ► Difference of 2 ..and another – push beyond the obvious ► Triangle with height 2  fix properties to encourage play with concepts ► Grid - of what?  similarity as a tool, or as a muddle? ► Use 3 to +, -, ×, ÷  Using learners’ own example spaces to sort, compare, relate … ► Seeing fractions  open/closed questions ► Enlarging rectangles  shifting to more powerful methods