Return to Mathematics IndexArea, Arithmetic and Algebra

Larry Freeman Kenwood Academy

5015 South Blackstone Avenue

Chicago IL 60615

(312) 535-1409Objectives:

To show how area of rectangles and squares can motivate the learning of

multiplication rules for certain binomials, specifically:

(x + y)^{2}= x^{2}+ 2xy + y^{2}

(x + y)(x - y) = x^{2}- y^{2}To show those teaching upper-grade math and high school first year math how their students can perform arithmetic based on these identities. To show by paper folding several applications of the "distributive law" of multiplication over addition/subtraction.Materials:

Cardboard demonstration set for the teacher (with magnetic tape backing) and

printed sets of squares and rectangles for students to examine and re-arrange at

their desks. Prepare packets of pre-cut squares and rectangles, one for each

student.

Student materials should be prepared on centimeter-ruled paper; two cm = one

unit. (In this fashion, area can be checked by simply counting squares). The

entire square will measure 16 x 16 units, with heavy horizontal and vertical

lines partitioning it into an 8 x 8, 4 x 4, and two 8 x 4 rectangles. All

measurements start from the lower-left hand corner of the large square. Enter

dimensions on every edge; in the interior of each rectangle should appear

"Area = ______________ square units".

Two of each square will be needed for each student packet: one left whole and

one cut along the heavy lines into the four rectangles. The teacher will need a

similar set of materials, very much enlarged and made of heavier paper

("tagboard" is ideal). In addition, prepare a set of the four cut rectangles

very much enlarged. They must be on heavier still cardboard and backed with

magnetic strip material to adhere to typical metallic base chalkboards. The

teacher's uncut square should be pre-folded along the heavy vertical and

horizontal lines.Strategy:

Review the area formula for a rectangle. Immediately have students remove the

four small rectangles and arrange them to form a large square. How many

different arrangements can they find -- rotations and reflections are

"different" in this case? Sketch each arrangement in a student's notebook.

Find the area of every large square by adding up areas of the four components.

Encourage students to confirm this identity:

(a + b)^{2}= a^{2}+ 2ab + b^{2}[a = 8 and b = 4]Challenge: Using as many of the small pieces as needed, ask students to create

a rectangle whose measurements are 8 x 16. Sketch the arrangement they

discovered, and, as before, try to discover and sketch as many different

arrangements as possible. Calculate the total area by adding the components.

The student will note that all but the small square were used in the second

rectangle:

So 8 X 16 = 128 which also equals 12^{2}- 4^{2}[144 - 16 = 128].

The teacher should duplicate these arrangements with the large magnetized

rectangles on the chalkboard. The algebraic identity here demonstrated is:

(x - y)(x + y) = x^{2}- y^{2}. [Here x = 12 and y = 4].Second challenge: Have students take the larger square from their packet and

fold it along the vertical line. The left side is now a rectangle whose

measurements are 8 x 12. But it consists of two rectangles: 4 x 8 and 8 x 8.

Thus they have shown that 8 X 12 = 8 X 4 + 8 X 8. So they have proved that

8 X 12 = 8(4 + 8) [an illustration of the distributive law]Third challenge: With new teacher-made packets -- identical to the originalsexceptthat variable names replace numerals for dimensions. Another difference:

These paper rectangles should not have centimeter ruling. Now the student

should follow every step above using variables instead of numerals. The writing

of the appropriate identities is left as an exercise for the teacher; answers

available from the writer.Performance Assessment:

While students are working on this project, either individually or in pairs, the

teacher circulates, assesses performance visually and gives hints, commendations

or other encouragements (via adroit questions). Later, notebooks themselves

will be graded for completeness and accuracy. Ultimately knowledge will be

"assessed" via customary pencil and paper tests. [Ruth Mitchell-type global

assessment techniques do not seem cost effective for this unit.]References and credits:

This unit was inspired by a conference table discussion with Porter Johnson. In

fact none of these techniques is really new; they are frequently re-discovered

in many different places at widely different times by creative teachers inspired

to improve textbook versions of "the method."Multicultural Dimensions:

Geometry is not the exclusive possession of any culture in any historical era

ancient or modern. All peoples who had concerns with land and its measurement

or with calendars developed appropriate geometrical principles. Similarly with

arithmetic: Counting and rudimentary computing were known to all peoples,

ancient or modern, no matter what geographical location. None was limited by

"culture" in matters of commerce; rather our current awareness or ignorance is

a function of the available historical record and its readability. It is

pointless to try to ascribe primacy or originality to any cultural group.

Algebra was a European inheritance which came most directly from the

Mediterranean Moorish (Muslim/Islamic) civilizations. They, in turn certainly

drew from the ancient Greek, Hindu and African civilizations. Every

civilization refines and improves what it inherits.