Measure problems at primary level that require careful consideration.
Measure problems at primary level that may require determination.
Measure problems for primary learners to work on with others.
Measure problems for inquiring primary learners.
These pieces of wallpaper need to be ordered from smallest to largest. Can you find a way to do it?
Investigate how this pattern of squares continues. You could measure lengths, areas and angles.
What do these two triangles have in common? How are they related?
Can you put these shapes in order of size? Start with the smallest.
How many centimetres of rope will I need to make another mat just like the one I have here?
I cut this square into two different shapes. What can you say about the relationship between them?
These pictures were made by starting with a square, finding the half-way point on each side and joining those points up. You could investigate your own starting shape.
Use the interactivity to find all the different right-angled triangles you can make by just moving one corner of the starting triangle.
What shape has Harry drawn on this clock face? Can you find its area? What is the largest number of square tiles that could cover this area?
What is the total area of the four outside triangles which are outlined in red in this arrangement of squares inside each other?
My local DIY shop calculates the price of its windows according to the area of glass and the length of frame used. Can you work out how they arrived at these prices?
What is the largest number of circles we can fit into the frame without them overlapping? How do you know? What will happen if you try the other shapes?
Explore this interactivity and see if you can work out what it does. Could you use it to estimate the area of a shape?
In this game for two players, you throw two dice and find the product. How many shapes can you draw on the grid which have that area or perimeter?
These practical challenges are all about making a 'tray' and covering it with paper.
What is the largest 'ribbon square' you can make? And the smallest? How many different squares can you make altogether?
Can you help the children find the two triangles which have the lengths of two sides numerically equal to their areas?
This practical challenge invites you to investigate the different squares you can make on a square geoboard or pegboard.
Can you draw a square in which the perimeter is numerically equal to the area?
What happens to the area of a square if you double the length of the sides? Try the same thing with rectangles, diamonds and other shapes. How do the four smaller ones fit into the larger one?
How many ways can you find of tiling the square patio, using square tiles of different sizes?
What is the smallest number of tiles needed to tile this patio? Can you investigate patios of different sizes?
Cut differently-sized square corners from a square piece of paper to make boxes without lids. Do they all have the same volume?
Choose a box and work out the smallest rectangle of paper needed to wrap it so that it is completely covered.
Arrange your fences to make the largest rectangular space you can. Try with four fences, then five, then six etc.
These rectangles have been torn. How many squares did each one have inside it before it was ripped?
Investigate all the different squares you can make on this 5 by 5 grid by making your starting side go from the bottom left hand point. Can you find out the areas of all these squares?
What can you say about these shapes? This problem challenges you to create shapes with different areas and perimeters.
Explore one of these five pictures.
A follow-up activity to Tiles in the Garden.
A thoughtful shepherd used bales of straw to protect the area around his lambs. Explore how you can arrange the bales.
Are these statements always true, sometimes true or never true?
Investigate the area of 'slices' cut off this cube of cheese. What would happen if you had different-sized block of cheese to start with?
Use the information on these cards to draw the shape that is being described.
A task which depends on members of the group noticing the needs of others and responding.
A simple visual exploration into halving and doubling.
How many tiles do we need to tile these patios?
Look at the mathematics that is all around us - this circular window is a wonderful example.
Have a good look at these images. Can you describe what is happening? There are plenty more images like this on NRICH's Exploring Squares CD.
An activity for high-attaining learners which involves making a new cylinder from a cardboard tube.
This article for teachers gives some food for thought when teaching ideas about area.
This article, written for teachers, discusses the merits of different kinds of resources: those which involve exploration and those which centre on calculation.
Nine squares with side lengths 1, 4, 7, 8, 9, 10, 14, 15, and 18 cm can be fitted together to form a rectangle. What are the dimensions of the rectangle?
Read about David Hilbert who proved that any polygon could be cut up into a certain number of pieces that could be put back together to form any other polygon of equal area.
If I use 12 green tiles to represent my lawn, how many different ways could I arrange them? How many border tiles would I need each time?
How would you move the bands on the pegboard to alter these shapes?