Variety of perimeters with fixed area

From OER in Education
Revision as of 11:00, 28 March 2013 by JanetBlair (talk | contribs) (added rinfo)



Variety of perimeter with fixed area.png
Very visual and interactive and simple to understand.

Lesson idea. Geogebra has been used to produce

Resource details
Title Variety of perimeter with fixed area
Topic
Teaching approach
Learning Objectives
Format / structure

wiki page with downloadable .doc version

Subject
Age of students / grade
Table of contents
Additional Resources/material needed
Useful information
Related ORBIT Wiki Resources

This activity was a result of the ORBIT/Geogebra Competion which asked

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Files and resources to view and download
  • GeoGebra file:

File:.ggb

  • Guidance notes (.doc)
Acknowledgement

Janet Blair

License




Guidance notes


1) Overview

After learning the concepts of perimeters and areas, it is easy for students to think that figures with larger perimeters would also have larger areas, and vice versa. This applet helps teachers to explore with students the variety of the perimeters of a figure formed by several congruent squares touching side by side. Together with the complementary applet Variety of areas with fixed perimeter, teachers can clarify with students that a figure with a larger area may have a smaller perimeter, and areas and perimeters are two different concepts.


2) Learning Objective

  • Recognise that figures with the same areas could have different perimeters.
  • Recognise the strategy of minimizing the perimeters of figures with the same areas.


3) Teaching Approach

An enquiry teaching approach is expected. Students are asked to arrange 3 to 9 squares to form different figures and find their possible perimeters. Teacher then guide students to express their strategies of getting the largest and smallest perimeter with a certain number of squares.


4) Teacher’s Note

For each number of squares, ask students to record the possible perimeters in the table of the applet. Guide students to focus on the change of the perimeter when a square is dragged to a new position. Discuss with students the strategy of minimizing the perimeter, especially for 4 and 9 squares.