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analytical expressions are fundamentally the same, and are easily derived from Proposition 17. Book II.: For

(n2 + 1)2————(n2—1)2= ( (n2 + 1) + (n2—1) ) ( (n2 + 1)—(n2—1))= 2n2x2=(2n)2. Or without having recourse to algebraical notation, since the square of the perpendicular is equivalent to the difference between the squares of the hypotenuse and of the base, it must, by Prop. 17. Book II. be equivalent to the rectangle under the sum and difference of the hypotenuse and base. Wherefore, if the perpendicular be an odd number, its square may be divided into two contiguous factors, the one even and the other odd. Thus, assuming the perpendicular equal to 3, its square 9 gives, by division, 4 and 5, for the base and hypotenuse; if the perpendicular be 5, the square 25 is parted into 12 and 13, for the corresponding base and hypotenuse; or if this perpendicular be denoted by 7, whose square is 49, the base and perpendicular must, by partition, be 24 and 25. Again, if the perpendicular be supposed to be an even number, its square may be divided into two adjacent factors, whose sum is the half and their difference 2. Thus, the perpendicular being 4, the half of its square, or 8, is split into -3 and 5, for the base and hypotenuse; if 6 be the perpendicular, the half of its square, or 18, is divided into 8 and 10, for the base and hypotenuse; and were 8 to represent the perpendicular, the half of its square, or 32, gives 15 and 17, for the corresponding base and perpendicular.

7. We may here introduce, from the Mathematical Collections of Pappus, an elegant extension of the famous Tenth Proposition.

In any triangle, rhomboids described on the two sides, are together equivalent to a rhomboid described on the base, and limited by these and by parallels to the line which joins the vertex with their point of concourse.

Let ADEB and BGFC be rhomboids described on the two sides AB and BC of the triangle ABC; produce the summits DE and FG to meet in H, join this point with the vertex B, to BH draw the parallels AK, CL, and join KL. It is obvious that AK and CL, being equal and parallel to BH, are

likewise equal and parallel to each other, and that the figure AKLC is a parallelogram or rhomboid.-This rhomboid is equivalent to the two rhomboids BD and BF.

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For produce HB to meet the base AC in I. And because the rhomboids KI and AH stand on the same base AK and between the same parallels, they are equivalent (II. 1. cor.); but the rhomboids AH and BD, standing on the same base AB and between the

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same parallels, are also equivalent. Whence KI is equivalent to BD. And in the same manner, it may be proved that LI is equivalent to BF. Consequently the whole rhomboid KC is equivalent to the two rhomboids BD and BF.

If the triangle ABC be right-angled at B, this theorem will pass into a case of the twenty-sixth of Book VI.; the rhomboid, described on the hypotenuse, being equivalent to the similar rhomboids described on the two sides. When these rhomboids become squares, the proposition becomes the same as the tenth; the only difference in the construction being, that a square AKOC (p. 52.) is constructed above the hypote nuse AC, instead of the square ADEC constructed below it.

8. From the proposition in the last article, an important theorem may be derived, which deserves a place in an ele mentary work :

In any triangle, the square described on the base is equivalent to the rectangles contained by the two sides and their segments intercepted from the base by perpendiculars let fall upon them from its opposite extremities.

Let the perpendiculars AP, CN be let fall from the points A, C upon the opposite sides BC and AB of the triangle ABC; the square of AC is equivalent to the rectangles contained by AB, AN, and by BC, CP.

For complete the rhomboids ADHB and CFHB, and let fall the perpendiculars BR and BS upon DH and FH.

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It is manifest, that the rhomboids AH and CH are equivalent to the square of AC. But the rhomboid AH is equivalent to the rectangle contained by AB and BR II.1. cor.). Comparing the triangles BHR and ACN; the angle BRH, being a right angle, is equal to ANC; and the two acute angles BHR and RBH, being together equal to a right angle, are equal to DAN and NAC; but DAB is equal to DHB (I. 26.), whence the angle RBH is equal to NAC. These triangles BHR and ACN, having thus two angles respectively equal, and the corresponding side BH in the one equal to AD or AC in the other, are therefore equal (I. 20.), and consequently the side BR is equal to AN. The rectangle AB and BR, which is equivalent to the rhomboid AH, is hence equivalent to the rectangle contained by AB and AN (II. 1. cor.).

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In the same manner, it may be demonstrated, by comparing the triangles BHS and PAC, that the rectangle under BC and BS, which is equivalent to the rhomboid CH, is equivalent to the rectangle contained by BC and CP. Wherefore the two rectangles of AB, AN and BC, CP are together equivalent to the square described on AC.

If the triangle ABC be right-angled at the vertex B, the perpendiculars CN and AP will evidently meet at the vertex, and consequently the rectangles AB, AN and BC, CP will become the squares of AB and BC. And hence the beautiful Proposition II. 10. is derived, being only a remarkable case of a much more general property.

9. Proposition tenth. It may be proper to notice likewise an extension of this beautiful proposition, which is easily demonstrated, after a similar mode, from the decomposition of the figure.

Equilateral triangles described on the sides of a right-angled triangle, are together equivalent to an equilateral triangle described on the hypotenuse.

Let ABC be a right-angled triangle, around which are constructed the equilateral triangles ADB, BEC and CFA; the triangles ADB and BEC are equivalent to CFA.

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For let fall the perpendiculars DG, BH and FI, and join CD, BF, CG, BI and HF. It is evident (I. 21.) that the, perpendiculars DG and FI bisect the bases AB and AC, and divide the triangles ADB and CFA into two equal triangles. But the angle DAB is equal to CAF, being angles of an equilateral triangle : add BAC to each, and the whole angle DAC is equal to BAF. But the containing sides DA and AC are respectively equal to BA and AF, and consequently (I. 3.) the triangle ADC is equal to ABF. Now the triangle ADC is composed of the three triangles ACG, ADG, and DCG, and the triangle ABF is composed of ABI, AFI, and FBI; but, since AB and AC are bisected in G and H, the triangles ACG and ABI are (II. 2.) halves of the original triangle ABC, and consequently equivalent to each other. Wherefore the remaining triangles ADG and DCG are together equivalent to AFI and FBI. But DG and CB being both perpendicular to AB, are (I. 22.) parallel; and, for the same reason, BH is parallel to FI. Whence (II. 1.) the triangle DCG is equivalent to DBG, and the triangle FBI equivalent to FHI; and therefore the triangles ADG and DBG, or the whole triangle ADB, must be equivalent to AFI and FHI, or the whole triangle AFH.—in like manner, it may be shown that the triangle BEC is equivalent to the triangle CFH; and consequently the equilateral triangles ADB and BEC are equivalent to AFH and CFH, which make up the whole triangle AFC.

This demonstration is the second of those given by the cele brated Italian geometer Torricelli, the favourite disciple of Galileo, and inventor of the barometer.

10. A useful proposition may be introduced here :

The square described on a straight line, is equivalent to the squares of the segments into which it is divided, and twice the rectangles contained by each pair of these segments.

The square of AB is equivalent to the squares of AC, of CD and of DB, with twice the rectangles of AC, CD, of AC, DB, and of CD, DB.

For make AE and EF equal to AC and CD draw EM, FL parallel to AB, and CH, DI parallel to AG.

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It is manifest that AO is the square of AC, OQ the square of CD, and QĶ the square of DB. Nor is it less obvious that the two rectangles CN and EP are contained by AC, CD, that the two rectangles NL and PI are contained by CD, DB, and that the two rectangles DM and FH are contained by AC, DB. But those squares and those double rectangles complete the whole square of AB. Wherefore the truth of the Proposition is established.

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Cor. Hence if a straight line be divided into three portions, the squares of the double segments AD, BC, together with twice the rectangle under the extreme segments AC, BD, are equivalent to the squares of the whole line AB and of the intermediate segment CD. For the squares FD, HM, together with the equal rectangles GP, NB, evidently fill up the whole square AB, with the repetition of the internal square OQ; that is, the squares of AD and BC, with twice the rectangle AC, DB, are equivalent to the squares of AB and CD.

11. Since rectangles correspond to numerical products, the properties of the sections of lines are easily derived from symbolical arithmetic or algebra;

1. In Prop. 14. let AC be denoted by a, and the segments of AB by b, c and d; then a(b+c+d)=ab+ac+ad.

2. In Prop. 15. let the two lines be denoted by a and b ; then (a+b)2=a+b2+2ab.

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