# Root of Area contained by Rational Straight Line and Sixth Binomial

## Theorem

In the words of Euclid:

*If an area be contained by a rational straight line and the sixth binomial, the "side" of the area is the irrational straight line called the side of the sum of two medial areas.*

(*The Elements*: Book $\text{X}$: Proposition $59$)

## Proof

Let the rectangular area $ABCD$ be contained by the rational straight line $AB$ and the sixth binomial $AD$.

Let $E$ divide $AD$ into its terms such that $AE > ED$.

Let $E$ divide $AD$ into its terms such that $AE > ED$.

From Proposition $42$ of Book $\text{X} $: Binomial Straight Line is Divisible into Terms Uniquely this is possible at only one place.

By definition of binomial, $AE$ and $ED$ are rational straight lines which are commensurable in square only.

Thus $AE^2$ is greater than $ED^2$ by the square on a straight line which is commensurable with $AE$.

Let $ED$ be bisected at $F$.

- Let a parallelogram be applied to $AE$ equal to $EF^2$ and deficient by a square.

Let the rectangle contained by $AG$ and $GE$ equal to $EF^2$ be applied to $AE$.

By Proposition $17$ of Book $\text{X} $: Condition for Commensurability of Roots of Quadratic Equation:

- $AG$ is commensurable in length with $EG$.

Let $GH$, $EK$ and $FL$ be drawn from $G$, $E$ and $F$ parallel to $AB$ and $CD$.

Using Proposition $14$ of Book $\text{II} $: Construction of Square equal to Given Polygon:

- let the square $SN$ be constructed equal to the parallelogram $AH$

and:

- let the square $NQ$ be constructed equal to the parallelogram $GK$.

Let $SN$ and $NQ$ be placed so that $MN$ is in a straight line with $NO$.

Therefore $RN$ is also in a straight line with $NP$.

Let the parallelogram $SQ$ be completed.

- $SQ$ is a square.

We have that $AD$ is a third binomial straight line.

Therefore $AE$ and $ED$ are rational straight lines which are commensurable in square only.

We have that the rectangle contained by $AG$ and $GE$ is equal to $EF^2$.

Then by Proposition $17$ of Book $\text{VI} $: Rectangles Contained by Three Proportional Straight Lines:

- $AG : EF = EF : EG$

and so by Proposition $1$ of Book $\text{VI} $: Areas of Triangles and Parallelograms Proportional to Base:

- $AH : EL = EL : KG$

Therefore $EL$ is a mean proportional between $AH$ and $GK$.

But:

- $AH = SN$

and:

- $GK = NQ$

therefore $EL$ is a mean proportional between $SN$ and $NQ$.

- $MR$ is a mean proportional between $SN$ and $NQ$.

Therefore:

- $EL = MR$

and so:

- $EL = PO$

But:

- $AH + GK = SN + NQ$

Therefore:

- $AC = SQ$

That is:

- $AC$ is an area contained by a rational straight line $AB$ and the first binomial $AD$, while the side of the area $SQ$ is $MO$.

We have that $EA$ is incommensurable in length with $AB$.

Therefore $EA$ and $AB$ are rational straight lines which are commensurable in square only.

Therefore, by definition, $AK = MN^2 + NO^2$ is medial.

We have that:

- $ED$ is incommensurable in length with $AB = EK$

- $FE$ is incommensurable in length with $EK$.

Therefore $FE$ and $EK$ are rational straight lines which are commensurable in square only.

Therefore by definition:

- $EL = MR = MN \cdot NO$ is a medial area.

Since:

- $AE$ is incommensurable in length with $EF$

by:

and:

- Proposition $11$ of Book $\text{X} $: Commensurability of Elements of Proportional Magnitudes:
- $AK$ is incommensurable with $EL$.

But:

- $AK = MN^2 + NO^2$

and:

- $EL = MN \cdot NO$

Therefore:

- $MN^2 + NO^2$ is incommensurable with $MN \cdot NO$.

So by definition, $MO$ is the side of the sum of two medial areas.

$\blacksquare$

## Historical Note

This proof is Proposition $59$ of Book $\text{X}$ of Euclid's *The Elements*.

It is the converse of Proposition $65$: Square on Side of Sum of two Medial Area applied to Rational Straight Line.

## Sources

- 1926: Sir Thomas L. Heath:
*Euclid: The Thirteen Books of The Elements: Volume 3*(2nd ed.) ... (previous) ... (next): Book $\text{X}$. Propositions