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What's going on?

The purpose of this activity is to engage students in using their number knowledge to understand and use an unfamiliar process.

A pyramid of dice.

Tags

  • AudienceKaiako
  • Curriculum Level2
  • Learning AreaMathematics and Statistics
  • Resource LanguageEnglish
  • Resource typeActivity
  • SeriesRich learning activities

About this resource

This activity assumes the students have experience in the following areas:

  • Knowing basic addition and subtraction facts.
  • Partitioning and regrouping numbers to make calculation easier.
  • Using fractions to represent parts of sets to the whole.
  • Finding fractions of whole numbers.

The problem is sufficiently open ended to allow the students freedom of choice in their approach. It may be scaffolded with guidance that leads to a solution, and/or the students might be given the opportunity to solve the problem independently.

The example responses at the end of the resource give an indication of the kind of response to expect from students who approach the problem in particular ways.

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    What's going on?

    Achievement objectives

    NA2-7: Generalise that whole numbers can be partitioned in many ways.

    NA2-8: Find rules for the next member in a sequential pattern.

    Required materials

    See Materials that come with this resource to download:

    • What's going on activity (.pdf)

    Activity

    A teacher showed her class an idea:

    An illustration of numbers showing 12 is broken up into three 4s and two 4s is equal to 2/3 or 8.

    and another example:

    An illustration of numbers showing 10 is broken up into five 2s and three 2s is equal to 3/5 or 6.
    • Can you make up one of your own?

    The following prompts illustrate how this activity can be structured around the phases of the Mathematics Investigation Cycle.

    Make sense

    Introduce the problem. Allow students time to read it and discuss in pairs or small groups.

    • Do I understand the situation? Explain how the examples were made?
    • What might be good numbers to choose? Why?
    • What are good fractions to use? Why?
    • Are there any numbers and fractions that you should not use? Why?

    Plan approach

    Discuss ideas about how to solve the problem. Emphasise that, in the planning phase, you want students to say how they would solve the problem, not to actually solve it.

    • What strategies will be useful to solve a problem like this?
    • What maths will be handy to create my own examples?
    • What fractions are good ones to get me started? Why are those fractions good?
    • Can I make a list of numbers to try first? How will I choose my numbers?
    • Do I need some tools to help me? Would a calculator or counters help?

    Take action

    Allow students time to work through their strategy and find a solution to the problem.

    • Am I clear what my examples should look like?
    • What is the same about the two examples the teacher gave us? What is different?
    • Can I find example just with numbers or do I need counters or a diagram to help me?
    • Are there some patterns I can use? What patterns will be useful?
    • Have I checked my examples? Can I prove they are correct?
    • Are my strategies the same as those others used?
    • Could I try using another person’s strategy to see if it better than mine?

    Convince yourself and others

    Allow students time to check their answers and then either have them pair share with other groups or ask for volunteers to share their solution with the class.

    • Have I got enough examples? How can I easily make more?
    • Which strategies were most efficient?
    • If I keep the number the same, can I make different examples with that number? How?
    • If I start with a fraction, how can I choose numbers that will work well? How?
    • Is there some maths that I need to solve problems like this? What is the maths? Where do I use that maths?

    Examples of work

     | 

    The student chooses number that they know are easily broken into equal parts. They list the equal parts then express a collection of parts as a fraction.

    Three examples showing numbers being broken up and expressing fractions.

    The student begins with a number and uses division to break it into equal parts. From the number of parts they chose a fraction with the same denominator and work out the fraction of the whole number using multiplication.

    An illustration of numbers showing 21 is broken up into three 7s and two 7s is equal to 2/3 or 14.

    The quality of the images on this page may vary depending on the device you are using.