P l a n e   G e o m e t r y

An Adventure in Language and Logic

based on

# Book I.  Propositions 47 and 48

Proposition 47

PYTHAGORAS was a teacher and philosopher who lived some 250 years before Euclid, in the 6th century B.C. The theorem that bears his name is about an equality of non-congruent areas; specifically, the squares that are drawn on each side of a right triangle.

Thus if ABC is a right triangle with the right angle at A, then the square drawn on BC opposite the right angle, is equal to the two squares together drawn on CA, AB.

That is, if it takes one can of paint to paint the square on BC, then it will also take exactly one can to paint the other two squares.

That is how the sides of a right triangle are related -- by the squares drawn on them -- and we can illustrate it with numbers.

The square drawn on the side opposite the right angle, 25, is equal to the squares on the sides that make the right angle: 9 + 16.  Thus a triangle whose sides are 3-4-5 is right-angled.

That and other facts were known to many cultures long before Pythagoras, but credit has gone to him for being the first to prove the theorem. It is the culmination of Euclid's first Book.

PROPOSITION 47.  THEOREM

 In a right triangle the square drawn on the side opposite the right angleis equal to the squares drawn on the sides that make the right angle. Let ABC be a right triangle in which CAB is a right angle; then the square drawn on BC is equal to the two squares on CA, AB. On BC draw the square BDEC, and on BA, AC draw the squares GB, HC; (I. 46) through A draw AL parallel to BD or CE; and draw AD and FC. (The proof now shows that the square GB is equal to the rectangle BL, and that the square HC is equal to the remaining rectangle CL.  First, however, the proof demonstrates that triangles FBC, ABD are congruent and therefore equal. Next, the square GB and triangle FBC are on the same base FB and in the same parallels FB, GC; while parallelogram CL and triangle ABD are on the same base BD and in the same parallels BD, AL.) Then, since each of the angles BAG, BAC is a right angle, GA, CA upon meeting BA make the adjacent angles equal to two right angles; therefore AC is in a straight line with GA. (I. 14) For the same reason, BA is in a straight line with AH. And, since angle DBC is equal to angle FBA, because each is a right angle, to each of them add angle ABC; then the whole angle ABD is equal to the whole angle FBC. (Axiom 2) And since FB is equal to BA, and DB to BC, the two sides FB, BC are equal to the two sides AB, BD respectively; and we proved that angle FBC is equal to angle ABD; therefore triangle FBC is equal to triangle ABD. (S.A.S.)
 Furthermore, the parallelogram BL is double the triangle ABD, because they are on the same base BD and in the same parallels BD, AL. (I. 41) And the square GB is double the triangle FBC, because they are on the same base FB and in the same parallels FB, GC.
 But doubles of the equal triangles FBC, ABD are equal to one another. (I. 37, Problem 2.) Therefore the square GB is equal to the parallelogram BL.
 In the same way, by drawing AE, BK, we could show that the square HC is equal to the parallelogram CL. Therefore the whole square BDEC is equal to the two squares GB, HC. (Axiom 2) And the square BDEC is drawn on BC, and the squares GB, HC on BA, AC. Therefore the square drawn on BC is equal to the two squares on BA, AC. Therefore, in a right triangle etc.  Q.E.D.

The side opposite the right angle is called the hypotenuse
("hy-POT'n-yoos"); which literally means stretching under.

The above proof is Euclid's, not Pythagoras's. His proof is believed to have been based on the theory of proportions; Proposition VI. 31.

Now it is also a theorem that if BC is the diameter of a circle and A any point on the circumference, then angle BAC is always a right angle. (Proposition III. 31.) Therefore if we imagine the point A moving along the circumference, then at each point we will have a right angle. The square on BA will grow larger while the square on AC grows smaller, yet they continually adjust themselves so that together they equal the constant square on BC! That equality of areas is what makes Pythagoras's theorem so remarkable.

The converse

The hypothesis of Proposition 47 is that the triangle is right-angled; hence the converse, which is Proposition 48 and the last theorem of Book I, has for its conclusion that the triangle is right-angled. Here is the enunciation.

PROPOSITION 48.  THEOREM

 If the square drawn on one side of a triangle is equal to the squares drawn on the other two sides, then the angle contained by those two sides is a right angle.

It is this that informs us that if the sides of a triangle are 3-4-5 -- so that the squares on them are 9-16-25 -- then the triangle is right-angled. Whole-number sides such as these are called Pythagorean triples.

Pythagoras and the Pythagoreans

Pythagoras is remembered as the first to take mathematics seriously in relation to the world order. He taught that geometry and numbers should be studied with reverence, because we are entering into knowledge of the Divine. Mathematics is therefore more than just intellectual stimulation, and its relationship to the Universe is more than just coincidence.

Pythagoras was born on the Greek island of Samos. He left to found what we might call a religious sect in the city of Crotona in southern Italy, which was then part of greater Greece. His devotees were called Pythagoreans ("Pi-thag-o-REE-ans"), and many of them, both men and women, lived communally. They had their rituals and their dietary laws, and they made important contributions to the medicine and astronomy of their time. They were among the first to teach that the earth is round and that it revolves about the sun.

They also taught the continuity and reincarnation of life; and that through philosophy (literally, love of wisdom) there is purification and thus escape from the cycle of births. Hence they practiced equality between one another, and they showed compassion to all creatures, because we are all forms of One.

The Pythagoreans were the first to systematically investigate both arithmetic and geometry. Not only did they discover many theorems, but they gave an ethical and spiritual significance to each of the figures they drew. As a secret society, it must be said that they were extremely successful -- because not a word has survived! In this regard, Pythagoras is credited with discovering incommensurable magnitudes. (See Topic 10 of The Evolution of the Real Numbers.) They considered their doctrine of incommensurables their most esoteric teaching -- one of their members was treated as dead for having even spoken of it to an outsider. The significance they gave to it has never been revealed.

As a scientific researcher, Pythagoras discovered how musical harmonies depend on ratios of whole numbers. He found that we

hear the interval called an octave when the length of a vibrating string is halved, that is to say, when the length of the plucked string is to the whole string in the ratio 1:2 (Fig 1). We hear the interval called a perfect fifth (G above C) when two thirds of a string is plucked (Fig. 2), that is, when the stopped string is to the whole string in the ratio 2:3. And we hear a perfect fourth (F above C) when three fourths of the string is sounded (Fig. 3); and so on, for each interval in the musical scale.

In fact, Pythagoras taught that all things are known through number (not symbols for numbers). Or rather, "All things are assimilated to number." This means that just as one population becomes assimilated by another -- they become just like those others -- so all things are like numbers. In that likeness, all things meet and are intelligible.

Please "turn" the page and do some Problems.

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