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the centre f, at the distance of one of these five, shall pass through the extremities of the other four, and touch the straight lines a b, bc, cd, de, ea, because the angles at the points g, h, k, l, m are right angles; and that a straight line drawn from the extremity of the diameter of a circle at right angles to it, touches (iii. 16) the circle; therefore each of the straight lines ab, bc, cd, de, ea touches the circle: wherefore it is inscribed in the pentagon abcde. Which was to be done.

PROPOSITION XIV.-PROBLEM.

To describe a circle about a given equilateral and equiangular pentagon. LET abcde be the given equilateral and equiangular pentagon; it is required to describe a circle about it.

Bisect (i. 9) the angles bcd, cde by the straight lines cf, fd, and from the point f, in which they meet, draw the straight lines fb, fa, fe, to the points b, a, e. It may be demonstrated

in the same manner as in the preceding proposition, that the angles cba, bae, aed are bisected by the straight lines fb, fa, fe. And because the angle bed is equal to the angle b cde, and that fcd is the half of the angle bcd, and cdf the half of cde; the angle fcd is equal to fdc; wherefore the side cf is equal (i. 6) to the side fd. In like manner, it may be demonstrated that fb, fa, fe are each of them equal to fc, or fd. Therefore the five straight lines fa, fb, fc, fd, fe are equal to one another; and the circle described from the centre f, at the distance of one of them, shall pass through the extremities of the other four, and be described about the equilateral and equiangular pentagon a bcde. Which was to be done.

d

PROPOSITION XV.-PROBLEM.

To inscribe an equilateral and equiangular hexagon in a given circle. LET abcdef be the given circle; it is required to inscribe an equilateral and equiangular hexagon in it.

Find the centre g of the circle abcdef, and draw the diameter agd; and from d as a centre, at the distance dg, describe the circle egch, join eg, cg, and produce them to the points b, f; and join ab, bc, cd, de, ef, fa. The hexagon abcdef is equilateral and equiangular.

Because g is the centre of the circle abcdef, ge is equal to g d. And because d is the centre of the circle egch, de is equal to dg; wherefore ge is equal to ed, and the triangle egd is equilateral; and therefore its three angles egd, gde, deg are equal to one another, be

d

cause the angles at the base of an isosceles triangle are equal (i. 5); and the three angles of a triangle are equal (i. 32) to two right angles; therefore the angle egd is the third part of two right angles. In the same manner it may be demonstrated that the angle dgc is also the third part of two right angles. And because the straight line gc makes with eb the adjacent angles egc, cgb equal (i. 13) to two right angles; the remaining angle cgb is the third part of two right angles: therefore the angles egd dgc, cgb are equal to one another. And to these are equal (i. 15) the vertical opposite angles bga, agffge, therefore the six angles egd, dgc, cgb, bga, agf, fge are equal to one another. But equal angles stand upon equal (iii. 26) circumferences; therefore the six circumferences ab, bc, cd, de, ef, fa are equal to one another. And equal circumferences are subtended by equal (iii. 29) straight lines; therefore the six straight lines are equal to one another, and the hexagon abcdef is equilateral. It is also equiangular; for, since the circumference af is equal to ed, to each of these add the circumference abcd; therefore the whole circumference fabcd shall be equal to the whole edeba. And the angle fed stands upon the circumference fabcd, and the angle a fe upon edcba; therefore the angle a fe is equal to fed. In the same manner, it may be demonstrated that the other angles of the hexagon abcdef are each of them equal to the angle a fe or fed: therefore the hexagon is equianglar; and it is equilateral, as was shewn; and it is inscribed in the given circle abcdef. Which was to be done.

h

COR. From this it is manifest, that the side of the hexagon is equal to the straight line from the centre, that is, to the semidiameter of the circle.

And if through the points a, b, c, d, e, f there be drawn straight lines touching the circle, an equilateral and equiangular hexagon shall be described about it, which may be demonstrated from what has been said of the pentagon; and likewise a circle may be inscribed in a given equilateral and equiangular hexagon, and circumscribed about it, by a method like to that used for the pentagon.

PROPOSITION XVI.—PROBLEM.

To inscribe an equilateral and equiangular quindecagon in a given circle. LEt abcd be the given circle; it is required to inscribe an equilateral and equiangular quindecagon in the circle abcd.

Let ac be the side of an equilateral triangle inscribed (ii. 4) in the circle, and ab the side of an equilateral and equiangular pentagon inscribed (iv. 11) in the same; therefore, of such equal parts as the whole circumference abcdf contains fifteen, the circumference a bc, being the

a

third part of the whole, contains five; and the circumference ab, which is the fifth part of the whole, contains three; therefore bc their difference contains two of the same parts. Bisect (iii. 30) be in e; therefore be, ec are, each of them, the fifteenth part of the whole circumference abcd. Therefore, if the straight lines be, e c be drawn, and straight lines equal to them be placed round (i. 4) b in the whole circle, an equilateral and equiangular quindecagon shall be inscribed in it. Which was to be done.

And in the same manner as was done in the pentagon, if, through the points of division made by inscribing the quindecagon, straight lines be drawn touching the circle, an equilateral and equiangular

e

d

quindecagon shall be described about it. And, likewise, as in the pentagon, a circle may be inscribed in a given equilateral and equiangular quindecagon, and circumscribed about it.

EXERCISES ON BOOK IV.

SECT. I.-PROBLEMS.

1. Given a line and two points, to describe a circle that shall pass through the points and touch the line.

2. Given a circle, to inscribe in it three equal circles which shall touch it and each other.

3. Given a circle, to inscribe in it four equal circles which shall touch it and each other.

4. Given a circle, to describe six other circles, each of which shall be equal to the given circle and be in contact with it and each other.

5. Given a quadrant of a circle, to inscribe a circle in it.

6. Given two circles, to draw a line that shall be a tangent to both. 7. Given a finite straight line, to describe on it an equilateral and equiangular decagon.

8. Given a line and a circle, to draw a tangent to the circle parallel to the line.

SECT. II.-THEOREMS.

9. If the three angles of a triangle be bisected, the bisecting lines shall meet in the same point.

10. If a circle be inscribed in a triangle, the rectangle contained by. the radius of the circle and the sum of the three sides of the triangles is double of the triangle.

11. If an equilateral triangle be described about a circle, the straight lines which join the points of contact of the circle and the triangle contain another equilateral triangle, each of which is equal to one half of a side of the other triangle.

12. If a square be inscribed in a circle, it shall be double the square of the radius of the circle.

BOOK V.

DEFINITIONS.

I. A LESS magnitude is said to be a part of a greater magnitude, when the less measures the greater; that is, when the less is contained a certain number of times exactly in the greater.

II. A greater magnitude is said to be a multiple of a less, when the greater is measured by the less; that is, when the greater contains the less a certain number of times exactly.

III. Ratio is a mutual relation of two magnitudes of the same kind to one another, in respect of quantity.

IV. Magnitudes are said to have a ratio to one another, when the less can be multiplied so as to exceed the other.

V. The first of four magnitudes is said to have the same ratio to the second which the third has to the fourth, when any equimultiples whatsoever of the first and third being taken, and any equimultiples whatsoever of the second and fourth; if the multiple of the first be less than that of the second, the multiple of the third is also less than that of the fourth; or, if the multiple of the first be equal to that of the second, the multiple of the third is also equal to that of the fourth; or, if the multiple of the first be greater than that of the second, the multiple of the third is also greater than that of the fourth.

VI. Magnitudes which have the same ratio are called proportionals. N. B. When four magnitudes are proportionals, it is usually expressed by saying, the first is to the second, as the third to the fourth.

VII. When of the equimultiples of four magnitudes (taken as in the fifth definition), the multiple of the first is greater than that of the second, but the multiple of the third is not greater than the multiple of the fourth; then the first is said to have to the second a greater ratio than the third magnitude has to the fourth; and, on the contrary, the third is said to have to the fourth a less ratio than the first has to the second.

VIII. Analogy, or proportion, is the similitude of ratios.
IX. Proportion consists in three terms at least.

X. When three magnitudes are proportionals, the first is said to have to the third the duplicate ratio of that which it has to the second.

XI. When four magnitudes are continual proportionals, the first is said to have to the fourth the triplicate ratio of that which it has to the second, and so on, quadruplicate, &c. increasing the denomination still by unity, in any number of proportionals.

Definition a, to wit, of compound ratio.

When there are any number of magnitudes of the same kind, the first is said to have to the last of them the ratio compounded of the ratio which the first has to the second, and of the ratio which the second has to the

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