Quadrilaterals

962 /www/nrich/html/content/99/09/penta4/ 1 2011-02-01T00:00:01 <?xml version="1.0" encoding="UTF-8"?> <mdoxml version="1.0"> Quadrilaterals are shapes that have four straight sides. How many DIFFERENT quadrilaterals can be made by joining the dots on the circle? (There are eight evenly-spaced dots.) <mdo:image width="218" height="217" alt="quad" src="quad.gif"></mdo:image> Can you work out the angles of all your quadrilaterals? For a printable set of dotted circles to use with this resource <a href="http://nrich.maths.org/content/id/6676/8-Dot_noCentralPoint.pdf"> click here</a>. </mdoxml> <?xml version="1.0" encoding="UTF-8"?> <mdoxml version="1.0"> This problem can have more than one solution, depending on what you decide 'different' means. Thomas, Lydia and Bethan from Old Earth Primary School described a quadrilateral by the number of dots you move around the circle as you join its four corners. For example, a 1115 quadrilateral would look like this: <mdo:image height="217" width="218" src="quad1.gif" alt=""></mdo:image> They thought there were eight different possible quadrilaterals although they didn't explain exactly how they found them. This way of recording the quadrilaterals is very useful - a good idea! Here is the list of eight that Thomas, Lydia and Bethan found: trapezium -1115 trapezium -1214 trapezium -1232 kite -1133 rectangle -1313 square - 2222 other scalene quadrilaterals - 1223 and 1124 Some children at Breckland Middle School also worked on this problem. They said: We found ten solutions to this problem. To make sure there were no repeats, we cut them all out and compared them in pairs, then in tables and then as a class. Only one of each shape remained (reflections are allowed!). Here is a picture of the solutions they found: <mdo:image height="684" width="529" alt="" src="quadsol.gif"></mdo:image> It is interesting now to compare these two sets of solutions. Can you match Thomas, Lydia and Bethan's solutions to the pictures above? So, if we decide that 'different' means that one shape cannot fit on another, even if it is rotated, then there would be ten as children at Breckland have drawn. But, if we decide that reflections are the same too, then I think there are eight, as Thomas, Lydia and Bethan suggest. Here is a picture of the eight that Thomas, Lydia and Bethan found but I have drawn them in a particular order to make sure I didn't miss any out. Can you see what my system was? <mdo:image height="800" width="403" alt="" src="quadsol2.gif"></mdo:image> If we define 'different' in one of the ways above, the problem is quite manageable. Some of you made life very challenging by opening up the possibilities. Kerim, working at home, and Maiya, from Marist College, approached the problem differently. Kerim wrote: I figured this out by first labelling each point with a letter; A, B, C, D, E, F, G and H. I started listing the shapes possible with two points that were sitting close together. I started with H, A and found five combinations with H, A, B shapes; four combinations with H, A, C shapes; three combinations with H, A, D; two combinations with H, A, E and one combination with H, A, F. My shapes looked like this: HABC HABD HABF HABF HABG HACD HACE HACF HACG HADE HADF HADG HAEF HAEG HAFG This was my stage 1. For stage 2 I moved to another line that had points next to each other. A and B. My first set of combinations had only 4 possibilities because I had already created one of the other shapes in the first stage. I realised that I could follow the same pattern of each set of possibilities having one less shape. This looked like: ABCD ABCE ABCF ABCG ABDE ABDF ABDG ABEF ABEG ABFG At this point, I knew that it was unnecessary to list the shapes as I worked around the circle. I knew that the next stage would have one less set of combinations, and that the highest set would have one less than the highest number of possibilities in my last stage. I wrote down the numbers 3, 2, 1 for the next stage, and then 2 and 1 and finally just 1. I added the number of all of these possibilities together. I did it twice to make sure I didn't make a mistake. I had thirty five. So, Kerim found thirty-five quadrilaterals which all have two corners next to each other. She then began to think about quadrilaterals where none of the corners was immediately next to another on the circle. She says: I knew that I could also draw a square not using points next to each other. I had discovered this when I was first experimenting with the problem. I could make two different squares this way. I played around with the circle and could not come up with any more quadrilaterals that didn't have two points next each other. I added these 2 squares to my 35 and got 37. I sure hope I'm right. I offered my dad a dollar if he could come up with more, but he has not met my challenge! Thanks for the problem. It was fun to solve. Kerim has been very systematic in the way she has listed the quadrilaterals, which is very helpful. If you've had a go at this problem, how did you think about 'different' quadrilaterals? Do you agree with what Kerim has found? It is interesting that Kerim said she thought about the square because she'd played around with the problem to start with. It might be that using a combination of drawings and other ways of describing the quadrilaterals (eg using numbers or letters) works well for this problem. </mdoxml> <?xml version="1.0" encoding="UTF-8"?> <mdoxml version="1.0"><div class="embed"> <h2>Quadrilaterals</h2> Quadrilaterals are shapes that have four straight sides. How many DIFFERENT quadrilaterals can be made by joining the dots on the circle? (There are eight evenly-spaced dots.) <mdo:image alt="quad" height="217" src="quad.gif" width="218"></mdo:image> Can you work out the angles of all your quadrilaterals? For a printable set of dotted circles to use with this resource <a href="http://nrich.maths.org/content/id/6676/8-Dot_noCentralPoint.pdf">click here</a>. </div> <h3>Why do this problem?</h3> <div><a href="http://nrich.maths.org/public/viewer.php?obj_id=962&part=index">This problem</a> will help learners extend their knowledge of properties of quadrilaterals. It requires visualisation, a systematic approach and is a good context for generalisation and symbolic representation of findings.</div> <h3>Possible approach</h3> <div>To start with, you could pose the problem orally, asking children to imagine a circle with eight equally-spaced dots placed on its circumference. How many quadrilaterals do they think it might be possible to draw by joining four of the dots? Take a few suggestions and then ask how they think they could go about finding out.</div> <div>You could use <a href="http://nrich.maths.org/public/viewer.php?obj_id=2883&part=index">this interactivity</a> or draw an eight-point circle on the board. Invite them each to imagine a quadrilateral on this circle. How would they describe their quadrilateral to someone else? Let the class offer some suggestions e.g. by numbering the dots and describing a quadrilateral by the numbers at its vertices. Then return to the problem of the number of different quadrilaterals. Discuss ways in which they will be able to keep track of the quadrilaterals and how they will know they have them all. Some children may wish to draw quadrilaterals in a particular order, for example those with a side of $1$ first (i.e. adjacent pegs joined), then $2$ etc. Others may feel happy just to list the quadrilaterals as numbers. This sheet of <a href="/content/99/09/penta4/eightpeg.doc">blank eight-point circles</a> may be useful. Encourage children to work in small groups to find the total number.</div> <div>After a short time, you could stop the group and focus their attention on one of the quadrilaterals, using the interactivity. How could they work out the angles of this quadrilateral? At first it looks very difficult, but marking the centre of the circle with a dot (this can be done on the interactivity) makes it more accessible. Knowing the angles of each quadrilateral may help when it comes to checking there are no duplicates.</div> <div>After giving the class more time to work, bring them together to share findings and systems, using the interactivity to aid visualisation. You may also want to discuss the angles of each quadrilateral and, in particular, how pairs went about calculating these angles.</div> <div> </div> <div>You can read about one teacher's experience of using this task in the classroom on the <a href="http://www.ncetm.org.uk/resources/34135" target="_blank">NCETM website</a>.</div> <h3>Key questions</h3> <div>How do you know your quadrilaterals are all different?</div> <div>How do you know you have all the different quadrilaterals?</div> <h3>Possible extension</h3> <div>You could challenge pupils to think about whether they could predict the number of different quadrilaterals which are possible for different point circles. How would they go about finding out? (Here is a sheet of <a href="/content/99/09/penta4/ninepin.doc">nine-point circles</a> which may be useful.)</div> <h3>Possible support</h3> <div>Children could start by investigating the quadrilaterals on circles with smaller numbers of dots. These sheets might be useful: <a href="/content/99/09/penta4/fourpeg.doc">four peg</a>, <a href="/content/99/09/penta4/fivepeg.doc">five peg</a>, <a href="/content/99/09/penta4/sixpeg.doc">six peg</a>, <a href="/content/99/09/penta4/sevenpeg.doc">seven peg</a>.</div></mdoxml> <?xml version="1.0" encoding="UTF-8"?> <mdoxml version="1.0"> How will you record the quadrilaterals you've made? You might like to print off <a href="/content/99/09/penta4/eightpeg.doc">this sheet</a> to use. You could try drawing quadrilaterals which have a side made by joining two pegs next to each other. How many different quadrilaterals can you make in this way? How will you know when you've got them all? </mdoxml> <?xml version="1.0" encoding="UTF-8"?> <mdoxml version="1.0"> Jason (Lark Rise Lower School, UK) claims: There are 32 possible quadrilaterals. Did anyone else find this many? The number will depend on how you define 'different'. Ms Shiach, Lewis, Christopher, Sam and Jonathan (Roundwood Primary, UK) said: We initially thought there were a great many solutions but ended up with 6! <div class="editorial">Peter has found 8 quadrilaterals. He was very systematic about it, so he's confident that he found them all. Can you see what his system was?</div> <div style="text-align: center;"><mdo:image width="218" height="217" alt="Vertices 1, 2, 3, 4" src="quad1.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 3, 5" src="quad2.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 3, 6" src="quad3.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 4, 5" src="quad4.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 4, 6" src="quad5.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 4, 7" src="quad6.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 2, 5, 6" src="quad7.gif"></mdo:image><mdo:image width="218" height="217" alt="Vertices 1, 3, 5, 7" src="quad8.gif"></mdo:image></div> </mdoxml> 2 5 0 1 0 0 0 Quadrilaterals How many DIFFERENT quadrilaterals can be made by joining the dots on the 8-point circle? 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