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THE constructions used in Elementary Geometry, were effected, by the combination of straight lines and circles. Many problems, however, can be resolved, by the single application of the straight line or the circle; and such solutions are not only interesting, from the ingenuity and resources which they display, but may, in a variety of instances, be employed with manifest advantage. This Appendix is intended to exhibit a selection of Geometrical Problems, resolved by either of those methods singly. It is accordingly divided into Two Parts, corresponding to the rectilineal and the circular constructions.
PART I. '
Problems resolved by help of the Ruler, or by
PROP. I. PROB.
To bisect a given angle.
Let BAC be an angle, which it is required to bisect, by drawing only straight lines. In AB take any two points D and E, from AC cut off AF equal to AD and AG to AE, draw EF and DG, crossing in the point H. AH will bisect the angle BAC. For the triangles EAF and DAG, having the sides EA and AF equal by construc- - * * tion to GA and AD, and the contained angle DAG common to both, are equal (I. 3.), and consequently the angle AEF is equal to AGD. And since AE is equal to AG, and the part AD to AF, the remainder DE must be is equal to FG ; wherefore the triangles DEH and HGF, having the angle at E equal to that at G, the vertical angles at H equal, and also their opposite sides DE and FG, are equal (I.20.); and hence the side DH is equal to FH. Again, the sides AD and DH
are equal to AF and FH, and AH is common to the two triangles AHD and AHF, which are therefore equal (I.2.), and consequently the angle DAH is equal to FAH.
PROP. II. PROB.
To bisect a given finite straight line.
Let it be required to bisect AB, by a rectilineal construction. Draw AK diverging from AB, and make AC=CD=DE, join EB, and continue it beyond B till BF be equal to BE, and lastly join FC; which will bisect AB in the point G. For draw BH parallel to AE. And because BD evidently bi- IT sects the sides EC and EF of the triangle CEF, it is parallel to the base CF (VI. 1. cor. 2.); wherefore BDCH is a parallelogram, which has (I. 26.) its opposite sides BH and CD equal. But AC being parallel to BH, the angles GAC and GCA are equal to GBH and GHB, and the side AC, being made equal to CD, is hence equal to its corresponding interjacent side BH; whence the triangles AGC and BGH are equal (I. 20.), and therefore AG is equal to BG,
PROP. III. PROB.
Through a given point, to draw a line parallel to a given straight line.
Let it be required, by a rectilineal construction, to draw through C a straight line parallel to AB.
In AB take any two points D and F, join CD, which produce till DE be equal to it; c Gr again join E with the point F, N - 7 and continue this till FG be e- qual to EF: Then CG, being ATB F B joined, will be parallel to AB.
For, since AB or DF evidently bisects the sides EC and EG IC of the triangle CEG, it must be parallel to the base CG (VI. 1. cor. 2.).
PROP. IV. PROB.
From a point in a given straight line, to erect a perpendicular.
Let C be a given point, from which it is required, by help of straight lines merely, to erect a perpendicular to AB. In AB, having taken any point D, draw DE equal to DC and inclined to AB, join EC and produce it until CG be equal to CD or DE, make CF equal to CE, join FG
and produce this till GH be equal to GC: Then CH will be perpendicular to AB. For the triangles DCE and GCF, having the sides DC, CE equal to GC, CF, and the contained angles vertical at C, are equal (I. 3.); whence FG= CD : =CG=GH. The point G is therefore the centre of a semicircle which would pass through F, C, H, and consequently the angle FCH is a right angle (III. 19.), or CH is perpendicular to AB.
PROP. V. PROB.
To let fall a perpendicular upon a given straight line, from a point without it.
Let C be a given point, from which it is required, by a rectilineal construction, to let fall a perpendicular to AB. In AB take any point D, draw DF ob- II liquely, and make DE = DF= DG, join FE and produce it until
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