Side of Area Contained by Rational Straight Line and Third Apotome

Proof

 * Euclid-X-93.png

Let the area $AB$ be contained by the rational straight line $AC$ and the third apotome $AD$.

It is to be proved that the "side" of $AB$ is a second apotome of a medial straight line.

Let $DG$ be the annex of the third apotome $AD$.

Then, by definition:
 * $AG$ and $GD$ are rational straight lines which are commensurable in square only
 * neither $AG$ nor $DG$ is commensurable with the rational straight line $AC$
 * the square on the whole $AG$ is greater than the square on the annex $GD$ by the square on a straight line which is commensurable in length with $AG$.

Let there be applied to $AG$ a parallelogram equal to the fourth part of the square on $GD$ and deficient by a square figure.

From :
 * that parallelogram divides $AG$ into commensurable parts.

Let $DG$ be bisected at $E$.

Let the rectangle contained by $AF$ and $FG$ be applied to $AG$ which is equal to the square on $EG$ and deficient by a square figure.

Therefore $AF$ is commensurable with $FG$.

Through $E$, $F$ and $G$ let $EH$, $FI$ and $GK$ be drawn parallel to $AC$.

We have that $AF$ is commensurable with $FG$.

Therefore from :
 * $AG$ is commensurable with each of $AF$ and $FG$.

But $AG$ is rational and incommensurable in length with $AC$.

Therefore from :
 * each of the straight lines $AF$ and $FG$ is rational and incommensurable in length with $AC$.

Therefore from :
 * each of the rectangles $AI$ and $FK$ is medial.

We have that $DE$ is commensurable in length with $EG$.

Therefore from :
 * $DG$ is also commensurable in length with each of the straight lines $DE$ and $EG$.

But $DG$ is rational and incommensurable in length with $AC$.

Therefore from :
 * each of the straight lines $DE$ and $ED$ is rational and incommensurable in length with $AC$.

Therefore from :
 * each of the rectangles $DH$ and $EK$ is medial.

We have that $AG$ and $GD$ are commensurable in square only.

Therefore $AG$ is incommensurable in length with $GD$.

But:
 * $AG$ is commensurable in length with $AF$

and:
 * $DG$ is commensurable in length with $EG$

Therefore from :
 * $AF$ is incommensurable in length with $EG$.

But from :
 * $AF : EG = AI : EK$

Therefore from :
 * $AI$ is incommensurable with $EK$.

Let the square $LM$ be constructed equal to $AI$.

Let the square $NO$ be subtracted from $LM$ having the common angle $\angle LPM$ equal to $FK$.

Therefore from :
 * the squares $LM$ and $NO$ are about the same diameter.

Let $PR$ be the diameter of $LM$ and $NO$.

We have that the rectangle contained by $AF$ and $FG$ equals the square on $EG$.

Therefore from :
 * $AF : EG = EG : FG$

But we also have:
 * $AF : EG = AI : EK$

And from :
 * $EG : FG = EK : KF$

Therefore from :
 * $AI : EK = EK : FK$

Therefore $EK$ is a mean proportional between $AI$ and $FK$.

But from :
 * $MN$ is a mean proportional between $LM$ and $NO$.

We have that:
 * $AI$ equals the square $LM$

and:
 * $KF$ equals the square $NO$.

Therefore:
 * $MN = EK$

But:
 * $EK = DH$

and:
 * $MN = LO$

Therefore $DK$ equals the gnomon $UVW$ and $NO$.

But:
 * $AK$ equals the squares $LM$ and $NO$.

Therefore the remainder $AB$ equals $ST$.

But $ST$ is the square on $LN$.

Therefore the square on $LN$ equals $AB$.

Therefore $LN$ is the "side" of $AB$.

Now it is to be shown that $LN$ is a second apotome of a medial straight line.

We have that each of the rectangles $AI$ and $FK$ is medial.

Also:
 * $AI = LM$

and:
 * $FK = NO$

Therefore each of the squares $LM$ and $NO$, that is the squares on $LP$ and $PN$, is medial.

From:

and:

We have that:
 * $AI$ is commensurable with $FK$.

Therefore the square on $LP$ is incommensurable with the square on $PN$.

We have that $AI$ is incommensurable with $EK$.

Therefore $LM$ is incommensurable with $MN$.

That is, the square on $LP$ is incommensurable with the rectangle contained by $LP$ and $PN$.

So from:

and:

We have that:
 * $LP$ is incommensurable in length with $PN$.

Therefore $LP$ and $PN$ are medial straight lines which are commensurable in square only.

It now needs to be shoen that $LP$ and $PN$ contain] a [[Definition:Rational Area|rational rectangle.

We have that $EK$ is medial.

Also, that $EK$ equals the rectangle contained by $LP$ and $PN$.

Therefore the rectangle contained by $LP$ and $PN$ is medial

So $LP$ and $PN$ are medial straight lines which are commensurable in square only which contain a rational rectangle.

Therefore by definition $LN$ is a second apotome of a medial straight line.

But $LN$ is the "side" of the area $AB$.

Hence the result.