Book I.

And if the angle BAD be equal to the opposite angle BCD, and the angle ABC to ADC; the opposite sides are equal; because, by prop. 32, book 1, all the angles of the quadrilateral figure ABCD are together equal to

A

D

four right angles, and the two angles

BAD, ADC are together equal to

the two angles BCD, ABC: where-
fore BAD, ADC are the half of all

the four angles; that is, BAD and B

C

ADC are equal to two right angles: and therefore AB, CD are parallels by prop. 28, B. 1. In the same manner AD, BC are parallels therefore ABCD is a parallelogram, and its opposite sides are equal by prop. 34, book 1.

PROP. VII. B. I.

There are two cases of this proposition, one of which is not in the Greek text, but is as necessary as the other: and that the case left out has been formerly in the text, appears plainly from this, that the second part of prop. 5, which is necessary to the demonstration of this case, can be of no use at all in the Elements, or anywhere else, but in this demonstration; because the second part of prop. 5 clearly follows from the first part, and prop. 13, book 1. This part must therefore have been added to prop. 5, upon account of some proposition betwixt the 5th and 13th, but none of these stand in need of it except the 7th proposition, on account of which it has been added: besides, the translation from the Arabic has this case explicitly demonstrated. And Proclus acknowledges, that the second part of prop. 5 was added upon account of prop. 7, but gives a ridiculous reason for it, " that it might afford an answer to objections "made against the 7th," as if the case of the 7th, which is left out, were, as he expressly makes it, an objection against the proposition itself. Whoever is curious, may read what Proclus says of this in his commentary on the 5th and 7th propositions; for it is not worth while to relate his trifles at full length.

It was thought proper to change the enunciation of this 7th prop, so as to preserve the very same meaning; the literal translation from the Greek being extremely harsh, and difficult to be understood by beginners.

PROP. XI. B. I.

A corollary is added to this proposition, which is necessary to Prop. 1, B. 11, and otherwise.

PROP. XX. and XXI. B. I.

Proclus, in his commentary, relates, that the Epicureans derided this proposition, as being manifest even to asses, and needing no demonstration; and his answer is, that though the truth of it be manifest to our senses, yet it is science which must give the reason why two sides of a triangle are greater than the third: but the right answer to this objection against this and the 21st, and some other plain propositions, is, that the number of axioms ought not to be increased without necessity, as it must be if these propositions be not demonstrated, Mons. Clairault, in the preface to his Elements of Geometry, published in French at Paris, ann. 1741, says, That Euclid has been at the pains to prove, that the two sides of a triangle which is included within another are together less than the two sides of the triangle which includes it; but he has forgot to add this condition, viz. that the triangles must be upon the same base; because, unless this be added, the sides of the included triangle may be greater than the sides of the triangle which includes it, in any ratio which is less than that of two to one, as Pappus Alexandrinus has demonstrated in prop. 3. B. 3. of his mathematical collections.

PROP. XXII. B. I.

Some authors blame Euclid, because he does not demonstrate that the two circles made use of in the construction of this problem must cut one another: but this is very plain from the determination he has given, viz. that any two of the straight lines DF, FG, GH must be great

er than the third: for who is so
dull, though only beginning to
learn the Elements, as not to per-
ceive that the circle described
from the centre F, at the distance-
FD, must meet FH betwixt F and,
H, because FD is less than FH;
and that, for the like reason, the circle described from the centre
G, at the distance GH, or GM, must meet DG betwixt D

DM

F G

H

Book I.

Book I. and G; and that these circles must meet one another, because
FD and GH are together greater

than FG? And this determina-
tion is easier to be understood
than that which Mr. Thomas
Simpson derives from it, and puts
instead of Euclid's, in the 49th
page of his Elements of Geome- D M

FG

H

try, that he may supply the omission he blames Euclid for; which determination is, that any of the three straight lines must be less than the sum, but greater than the difference of the other two: from this he shows the circles must meet one another, in one case; and says, that it may be proved after the same manner in any other case: but the straight line GM, which he bids take from GF, may be greater than it, as in the figure here annexed; in which case his demonstration must be changed into another.

PROP. XXIV. B. I.

To this is added, "of the two sides DE, DF, let DE be "that which is not greater than the other;" that is, take that side of the two DE, DF which is not greater than the other, in order to make with it the angle EDG

equal to BAC, because, without this
restriction, there might be three differ-
ent cases of the proposition, as Campa-
nus and others make.

Mr. Thomas Simpson, in p. 262 of
the second edition of his Elements of
Geometry, printed anno 1760, observes
in his notes, that it ought to have been
shown that the point F falls below the
line EG; this probably Euclid omitted
as it is very easy to perceive, that DG

E

D

being equal to DF, the point G is in the circumference of a circle described from the centre D, at the distance DF, and must be in that part of it which is above the straight line EF, because DG falls above DF, the angle EDG being greater than the angle EDF.

PROP. XXIX. B. I.

The proposition which is usually called the 5th postulate, or 11th axiom, by some the 12th, on which this 29th depends, has

given a great deal to do, both to ancient and modern geome- Book I. ters: it seems not to be properly placed among the axioms, as, indeed, it is not self-evident; but it may be demonstrated: thus

DEFINITION 1.

The distance of a point from a straight line, is the perpendicular drawn to it from the point.

DEF. 2.

One straight line is said to go nearer to, or further from, another straight line, when the distance of the points of the first from the other straight line become less or greater than they were; and two straight lines are said to keep the same distance from one another, when the distance of the points of one of them from the other is always the same.

AXIOM.

C

B

E

A straight line cannot first come nearer to another straight line, and then go further from it, before A it cuts it; and in like manner, a straight line cannot go further from anotherD straight line, and then come nearer to F it; nor can a straight line keep the

G

H

same distance from another straight line, and then come nearer to it, or go further from it; for a straight line keeps always the same direction.

D

F

B

C See the

E figure

H above:

For example, the straight line ABC cannot first come nearer to the straight line DE, as from the point A to the point B, and then, A from the point B to the point C, go further from the same DE: and in like manner, the straight line FGH cannot go further from DE, as from F to G, and then, from G to H, come nearer to the same DE: and so in the last case, as in fig. 2.

PROP. 1.

G

If two equal straight lines AC, BD, be each at right angles to the same straight line AB; if the points C, D be joined by the straight line CD, the straight line EF drawn from any point E in AB unto CD, at right angles to AB, shall be equal to AC, or BD.

If EF be not equal to AC, one of them must be greater than the other; let AC be the greater; then, because FE is

F

C

Ꭰ

F

Book I. less than CA, the straight line CFD is nearer to the straight line AB at the point F than at the point C, that is, CF comes nearer to AB from the point C to F: but because DB is greater than FE, the straight line CFD is further from AB at the point D than at F, that is, FD goes further from AB from F to D: therefore the straight line CFD first comes nearer to the straight line AB, and then goes further from it, before it cuts it; which is impossible. If FE be said to be greater than CA, or DB, the straight line CFD first goes further from the straight line AB, and then comes nearer to it; which is also impossible. Therefore FE is not unequal to AC, that is, it is equal to it.

PROP. 2.

A

E

B

a 4. 1.

b 8. 1.

If two equal straight lines AC, BD be each at right angles to the same straight line AB; the straight line CD which joins their extremities makes right angles with AC and BD.

F D

G

Join AD, BC; and because, in the triangles CAB, DBA, CA, AB are equal to DB, BA, and the angle CAB equal to the angle DBA; the base BC is equal a to the base AD: and in the triangles ACD, BDC, AC, CD are equal to BD, DC, and the base AD is equal to the base BC: therefore the angle ACD is C equalb to the angle BDC: from any point E in AB draw EF unto CD, at right angles to AB: therefore, by prop. 1, EF is equal to AC, or BD; wherefore, as has been just now shown, the angle ACF is equal to the angle EFC: in the same manner, the angle BDF is equal to the angle EFD; but the angles ACD, BDC are equal; therefore the angles EFC and EFD c10. def. 1. are equal, and right angles; wherefore also the angles ACD, BDC are right angles.

A

E B

COR. Hence, if two straight lines AB, CD be at right angles. to the same straight line AC, and if betwixt them a straight line BD be drawn at right angles to either of them, as to AB; then BD is equal to AC, and BDC is a right angle.

If AC be not equal to BD, take BG equal to AC, and join CG: therefore by this proposition, the angle ACG is a right angle; but ACD is also a right angle; wherefore the an