Poster

Can they be equal?

This poster is based on the problem Can They Be Equal?.

The poster is available as a PDF, or the image below can be clicked on to enlarge it.

Canonical solution

Using whole numbers only: 3 by 6 and 4 by 4

Using fractions: Any two numbers $a$ and $b$ where $a\gt2$ and $b = \frac{2a}{a-2}$

Why?

Geometrically

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Can They Be Equal? Poster
Each square along the edges accounts for one unit of perimeter, except for the four corner squares. They account for two units of perimeter but only one unit of area. This means the perimeter is 4 more than the area. There will have to be 4 squares in the middle that will only be counted for the area and not the perimeter.

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Can They Be Equal? Poster

There are only two ways to make a rectangle using 4 squares.

These make 4 by 4 or 3 by 6 rectangles.

This extends to fractions if the sides of the red rectangle aren't whole numbers, but any two numbers which multiply to 4.

Algebraically

Sides $a$ and $b$

Perimeter: $2a+2b$

Area: $ab$

$2a+2b = ab$

Factorising to get whole number solutions:

$ab - 2a-2b = 0$

$(a-2)(b-2) = \underbrace{ab-2a-2b}_0+4 \therefore (a-2)(b-2)=4$

(This fits with the geometry above because the sides of the red rectangle are $a-2$ and $b-2$)

Whole number solutions: $a-2$ and $b-2$ are $1$ and $3$ or $2$ and $2$

$\therefore a$ and $b$ are $3$ and $6$ or $4$ and $4$

Other solutions: Find any two numbers which multiply to give $4$ and add $2$ to each of them

Rearranging to get infinitely many solutions

$\begin{align}ab-2b &= 2a\\

\Rightarrow b(a-2)&=2a\\

\Rightarrow b&=\frac{2a}{a-2}\end{align}$

$a$ and $b$ need to be positive $\therefore a\gt2.$ Infinitely many solutions.