Join CD; then, in the case in which the C D . vertex of each of the triangles is without the other triangle, because AC is equal to AD, the angle ACD is equal (5. 1.) to the angle ADC: but the angle ACD is greater than the angle BCD; therefore the angle ADC is greater also than BCD; much more then is the angle BDC greater than the angle BCD. Again, because CB is equal to DB, the angle BDC is equal (5. 1.) to the angle BCD; but Ā B it has been demonstrated to be greater than it; which is impossible. But if one of the vertices, as D, be within the other triangle ACB; produce AC, AD to E, F; there E fore, because AC is equal to AD in the triangle ACD, the angles ECD, FDC upon the other side of the base CD are equal (5. 1.) to one another, but the angle ECD is greater than the angle BCD; wherefore the angle FDC is likewise greater than BCD ; D much more then is the angle BDC greater than the angle BCD. Again because CB is equal to DB, the angle BDC is equal (5. 1.) to the angle BDC; but BCD has been proved to be greater than the same BCD ; A B which is impossible. The case in which the vertex of one triangle is upon a side of the other, needs no demonstration. Therefore upon the same base, and on the same side of it, there cannot be two triangles that have their sides which are terminated in one extremity of the base equal to one another, and likewise those which are terminated in the other extremity. Q. E. D. PROP. VIII. THEOR. If two triangles have two sides of the one equal to two sides of the other, each to each, and have likewise their bases equal; the angle which is contained by the two sides of the one shall be equal to the angle contained by the two sides equal to them, of the other. Let ABC, DEF be A D G two triangles, having the two sides AB, AC, equal to the two sides DE, DF, each to each, viz: AB to DE, and AC to DF; and also the base BC equal to the base EF. The angle BAC is equal to B СЕ the angle EDF. For, if the triangle ABC be applied to DEF, so that the point B be on E, and the straight line BC upon EF; the point C shall also coincide with the point F. Because BC is equal to EF; therefore BC coinciding with EF, BA and AC shall coincide with ED and DF; for, if the base BC coincides with the base EF, but the sides BA, CA do not coincide with the sides ED, FD but have a different situation, as EG, FG; then upon the same base EF, and upon the same side of it, there can be two triangles that have their sides which are terminated in one extremity of the base equal to one another, and likewise their sides terminated in the other extremity ; but this is impossible; (7. 1.) therefore, if the base BC coincides with the base EF, the sides BA, AC cannot but coincide with the sides, ED, DF; wherefore likewise the angle BAC coincides with the angle EDF, and is equal (8. Ax.) to it. Therefore, if two triangles, &c. Q. E. D. PROP. IX. PROB. To bisect a given rectilineal angle, that is, to divide it into two equal angles. Let BAC be the given rectilineal angle, it is required to bisect it. Take any point D in AB, and from AC cut (3. 1.) off AE equal to AD; join DE, and upon it describe (1. 1.) A an equilateral triangle DEF; then join AF; the straight line AF bisects the angle BAC. Because AD is equal to AE, and AF is common to the two triangles DAF, EAF; D the two sides DA, AF, are equal to the two sides, EA, AF each to each ; and the base DF is equal to the base EF; therefore the angle DAF is equal (8. 1.) to the angle EAF; wherefore the given rectilineal angle BAC is F bisected by the straight line, AF, which was B С to be done. E. PROP. X. PROB. To bisect a given finite straight line, that is, to divide it into two equal parts. Let AB be the given straight line: it is required to divide it into two equal parts. Describe (1. 1.) upon it an equilateral triangle ABC, and bisecť (9. 1.) the angle ACB by the straight line CD. AB is cut into two equal parts in the point D. Because AC is equal to CB, and CD com. С mon to the two triangles ACD, BCD; the two sides AC, CD are equal to BC, CD, each to each ; and the angle ACD is equal to the angle BCD; therefore the base. AD is equal to the base (4. 1.) DB and the straight line AB is divided into two equal parts in the point D. Which was to be done. D B PROP. XI. PROB. To draw a straight line at right angles to a given straight line, from a given point in the same. Let AB be a given straight line, and C a point given in it: it is required to draw a straight line from the point C at right angles to AB.* Take any point D in AC, and (3. 1.) make CE equal to CD, and upon DE describe (1. 1.) the equilateral F triangle, DFE, and join FC; the straight line FC drawn from the given point C is at right angles to the given straight line AB. Because DC is equal to CE, and FC common to the two triangles DCF, ECF; the two sides, DC, CF, are equal A D С to the two EC, CF, each to each; and B the base DF is equal to the base EF; therefore the angle DCF is equal (8. 1.) to the angle ECF ; and they are adjacent angles. But, when the adjacent angles which one straight line makes with another straight line are equal to one another, each of them is called a right (10. Def. 1.) angle; therefore each of the angles DCF, ECF, is a right angle. Wherefore, from the given point C, in the given straight line AB, FC has been drawn at right angles to AB. Which was to be done. . Cor. By help of this oblem, it may be demonstrated, that two straight lines cannot have a common segment. If it be possible, let the two straight lines ABC, ABD have the segment AB common to both of them. From the point B draw BE at right angles to AB; and because ABC is a straight line, the angle CBE is equal (10. Def. 1.) to the E angle EBA ; in the same manner, because ABD is a straight line, the angle DBE is equal to the angle EBA ; wherefore the angle DBE is equal to the angle CBE, the less to the greater; which is impossible; -D therefore two straight lines cannot have a common segment. A С Hh See Note. PROP. XII. PROB. To draw a straight line perpendicular to a given straight line of an unlimited length, from a given point without it. Let AB be the given straight line, which may be produced to any length both ways, and let C be a point without it. It is required to draw a straight line per C pendicular to AB from the point C. Take any point D upon the other side of AB, and from the centre C, at the distance, CD, describe (3. Post) the circle FDG meeting AB in F, G; H and, bisect (10. 1.) FG in H, and join A G B CF, CH, CG; the straight line CH, D drawn from the given point C, is perpendicular to the given straight line AB. Because FH is equal to HG, and HC, common to the two triangles FHC, GHC, the two sides FH, HC are equal to the two GH, HC, each to each; and the base CF is equal (15 Def. 1.) to the base CG; therefore the angle CHF is equal (8. 1.) to the angle CHG; and they are adjacent angles; but when a straight line standing on a straight line makes the adjacent angles equal to one another, each of them is a right angle, and the straight line which stands upon the other is called a perpendicular to it; therefore from the given point C a perpendicular CH has been drawn to the given straight line AB. Which was to be done. PROP. XIII. THEOR. The angles which one straight line makes with another upon the one side of it, are either two right angles, or are together equal to two right angles. Let the straight line AB make with CD, upon one side of it, the angles CBA, ABD; these are either two right angles, or are together equal to two right angles. For, if the angle CBA be equal to ABD, each of them is a right A A E D С (def. 10.) angle; but, if not, from the point B draw BE at right angles (11. 1.) to CD; therefore the angles CBE, EBD, are two right angles; (def. 10.) and because CBE is equal to the two angles CBA, ABE, together, add the angle EBD to each of these equals; therefore the angles CBE, EBD are (2 Ax.) equal to the three angles CBA, ABE, EBD. Again, because the angle DBA is equal to the two angles DBE, EBA, add to these equals the angle ABC; therefore the angles DBA, ABC are equal to the three angles DBE, EBA, ABC; but the angles CBE, EBD have been demonstrated to be equal to the same three angles ; and things that are equal to the same are equal (1. Ax.) to one another; therefore the angles CBE, EBD are equal to the angles DBA, ABC: but CBE EBD are two right angles : therefore DBA, ABC are together equal to two right angles. Wherefore, when a straight line, &c. Q. E. D. PROP. XIV. THEOR. If, at a point in a straight line, two other straight lines, upon the opposite sides of it, make the adjacent angles together equal to two right angles, these two straight lines shall be in one and the same straight line. At the point B in the straight line A AB, let the two straight lines BC, BD upon the opposite sides of AB make the adjacent angles ABC, ABD equal together to two right angles, BD is in the same straight line with CB. For, if BD be not in the same E straight line with CB, let BE be in the same straight line with it; there с B fore, because the straight line AB makes angles with the straight line CBE, upon one side of it, the angles ABC, ABE are together equal (13. 1.) to two right angles ; but the angles ABC, ABD are likewise together equal to two right angles; therefore the angles CBA, ABE are equal to the angles CBA, ABD : take away the common angle ABC, the remaining angle ABE is equal (3. Ax.) to the remaining angle ABD, the less to the greater, which is impossible; therefore BE is not in the same straight line with BC. And, in like mapner, it may be demonstrated that no other can be in the same straight line with it but BD, which therefore is in the same straight line with CB. Wherefore, if at a point, &c. Q. E. D. PROP. XV. THEOR. IF 'two straight lines cut one another, the vertical or opposite angles shall be equal. Let the two straight lines AB, CD cut one another in the point E; the angle AEC shall be equal to the angle DEB, and CEB to AED. |