Follow these instructions to make a five-pointed snowflake from a square of paper.
It's hard to make a snowflake with six perfect lines of symmetry, but it's fun to try!
This practical activity challenges you to create symmetrical designs by cutting a square into strips.
This practical problem challenges you to create shapes and patterns with two different types of triangle. You could even try overlapping them.
This practical problem challenges you to make quadrilaterals with a loop of string. You'll need some friends to help!
Have you ever noticed the patterns in car wheel trims? These questions will make you look at car wheels in a different way!
Watch this "Notes on a Triangle" film. Can you recreate parts of the film using cut-out triangles?
Use the information on these cards to draw the shape that is being described.
Explore ways of colouring this set of triangles. Can you make symmetrical patterns?
Can you recreate this Indian screen pattern? Can you make up similar patterns of your own?
Can you place the blocks so that you see the reflection in the picture?
This problem explores the shapes and symmetries in some national flags.
Can you deduce the pattern that has been used to lay out these bottle tops?
Systematically explore the range of symmetric designs that can be created by shading parts of the motif below. Use normal square lattice paper to record your results.
Someone at the top of a hill sends a message in semaphore to a friend in the valley. A person in the valley behind also sees the same message. What is it?
What is the missing symbol? Can you decode this in a similar way?
This activity investigates how you might make squares and pentominoes from Polydron.
Use the clues about the symmetrical properties of these letters to place them on the grid.
What mathematical words can be used to describe this floor covering? How many different shapes can you see inside this photograph?
Mathematics is the study of patterns. Studying pattern is an opportunity to observe, hypothesise, experiment, discover and create.
What is the same and what is different about these tiling patterns and how do they contribute to the floor as a whole?
Place the numbers 1, 2, 3,..., 9 one on each square of a 3 by 3 grid so that all the rows and columns add up to a prime number. How many different solutions can you find?
Create a pattern on the small grid. How could you extend your pattern on the larger grid?
Find the missing coordinates which will form these eight quadrilaterals. These coordinates themselves will then form a shape with rotational and line symmetry.
Are these statements always true, sometimes true or never true?
These images are taken from the Topkapi Palace in Istanbul, Turkey. Can you work out the basic unit that makes up each pattern? Can you continue the pattern? Can you see any similarities and. . . .
Using the 8 dominoes make a square where each of the columns and rows adds up to 8
An article for students and teachers on symmetry and square dancing. What do the symmetries of the square have to do with a dos-e-dos or a swing? Find out more?