should be a line greater than AI. By similar reasoning it may be shown that the fourth term cannot be less than AI; it is then equal to AI; therefore rectangular parallelopipeds of the same base are to each other as their altitudes. Fig. 213. Fig. 213. THEOREM. 403. Two rectangular parallelopipeds AG, AK (fig. 213), which have the same altitude AE, are to each other as their bases ABCD, AMNO. Demonstration. Having placed the two solids the one by the side of the other, as represented in the figure, produce the plane ONKL, till it meet the plane DCGH in PQ, and a third parallelopiped AQ will be obtained, which may be compared with each of the parallelopipeds AG, AK. The two solids AG, AQ, having the same base AEHD are to each other as their altitudes AB, AO; also the two solids AQ, AK, having the same base AOLE, are to each other as their altitudes AD, AM. Thus we have the two proportions solid AG solid AQ:: AB: AO, solid AQ solid AK:: AD: AM. Multiplying the two proportions in order and omitting in the result the common multiplier solid AQ we shall have solid AG solid AK :: AB × AD: AO × AM. But AB × AD represents the base ABCD and AO × AM represents the base AMNO; therefore two rectangular parallelopipeds of the same altitude are to each other as their bases. THEOREM. 404. Any two rectangular parallelopipeds are to each other as the products of their bases by their altitudes, or as the products of their three dimensions. Demonstration. Having placed the two solids AG, AZ (fig. 213), in such a manner that their surfaces may have a common angle BAE, produce the planes necessary to form the third parallelopiped AK of the same altitude with the parallelopiped AG, we shall have, by the preceding proposition, solid AG solid AK :: ABCD: AMNO, But the two parallelopipeds AK, AZ, which have the same base have solid AK: solid AZ :: AE : AX. Multiplying these two proportions in order and omitting in the result the common multiplier solid AK, we obtain solid AG : solid AZ :: ABCD × AE : AMNO × AX. In the place of the bases ABCD, AMNO, we can substitute AB × AD, AO × AM, which will give : solid AG solid AZ:: AB × AD × AE: AO × AM × AX. Therefore any two rectangular parallelopipeds are to each other as the products of their bases by their altitudes, or as the products of their three dimensions. 405. Scholium. Hence we may take for the measure of a rectangular parallelopiped the product of its base by its altitude, or the product of its three dimensions. It is on this principle that we estimate all other solids. In order to understand this measure it is necessary to recollect that by the product of two or several lines is meant the product of the numbers which represent these lines, and these numbers depend upon the linear unit, which may be taken at pleasure; the product therefore of the three dimensions of a parallelopiped is a number which of itself has no meaning, and which would be different according as one or another linear unit is used. But if, in like manner, the three dimensions of another parallelopiped are multiplied together, by estimating them according to the same linear unit, the two products would be to each other as the two parallelopipeds and would give an idea of their relative magnitude. The magnitude of a solid, its volume, or its extension, constitutes what is called its solidity; and the word solidity is employed particularly to denote the measure of a solid; thus we say that the solidity of a rectangular parallelopiped is equal to the product of its base by its altitude, or the product of its three dimensions. The three dimensions of a cube being equal to each other, if the side is 1, the solidity will be 1 × 1 × 1, or 1 ; if the side is † Content is often employed by English writers to denote both solid and superficial measures. The word solidity, though most commonly used, is exceptionable, as it is likely to suggest to the mind of the student the idea of resistance. The term volume has been adopted by some as preferable to solidity. 2, the solidity will be 2 x 2 x 2, or 8; if the side is 3, the solidity will be 3 × 3 × 3, or 27, and so on; thus, the sides of cubes being as the numbers 1, 2, 3, &c., the cubes themselves, or their solidities, are as the numbers 1, 8, 27, &c. Hence the origin of what in arithmetic is called the cube of a number; it is the product arising from three factors, which are each equal to this number. If it were proposed to make a cube double of a given cube, it would be necessary that the side of the cube sought should be to the side of the given cube as the cube root of 2 is to 1. Now it is easy to find, by a geometrical construction, the square root of 2; but we cannot, in this way, find the cube root of this number, at least by the simple operations of elementary geometry, which consist in employing only straight lines, two points of which are known, and circles whose centres and radii are determined. On account of this difficulty, the problem of the duplication of the cube was celebrated among the ancient geometers, as also that of the trisection of an angle, which is nearly of the same character. But the solutions, of which problems of this kind are susceptible, have long been known; and, although less simple than the constructions of elementary geometry, they are not less exact or less rigorous. THEOREM. 406. The solidity of a parallelopiped, and in general of any prism whatever, is equal to the product of its base by its altitude. Demonstration. 1. A parallelopiped of whatever kind is equivalent to a rectangular parallelopiped having the same altitude and an equivalent base (401). But the solidity of this last is equal to the product of its base by its altitude (405); therefore the solidity of the first is also equal to the product of its base by its altitude. 2. Every triangular prism is half of a parallelopiped, so constructed as to have the same altitude and a base twice as great (397). Now the solidity of this last is equal to the product of its base by its altitude (405); therefore the solidity of the triangular prism is equal to the product of its base, half of that of the parallelopiped, by its altitude. 3. A prism of whatever kind may be divided into as many triangular prisms of the same altitude, as there are triangles in the polygon taken for a base. But the solidity of each triangular prism is equal to the product of its base by its altitude; and, since the altitude is the same in each, it follows that the sum of all the partial prisms is equal to the sum of all the triangles, taken for bases, multiplied by the common altitude. Therefore the solidity of a prism of whatever kind is equal to the product of its base by its altitude. 407. Corollary. If we compare two prisms, which have the same altitude, the products of the bases by the altitudes will be as the bases; therefore two prisms of the same altitude are to each other as their bases; for a similar reason, two prisms of the same base are to each other as their altitudes. LEMMA. 408. If a pyramid S-ABCDE (fig. 214) is cut by a plane a b d, Fig. 214. parallel to the base, 1. The sides SA, SB, SC,..... and the altitude SO, will be divided proportionally in a, b, c,..... and o; 2. The section abcde will be a polygon similar to the base ABCDE. Demonstration. The planes ABC, abc, being parallel, their intersections AB, ab, by a third plane SAB, will be parallel (340); consequently the triangles SAB, Sa b, are similar, and SA: Sa:: SB: Sb; and so on; therefore the sides SA, SB, SC, &c., are cut proportionally at a, b, c, &c. The altitude SO is cut in the same proportion at the point 0; for BO and bo are parallel (340), and consequently SO: So:: SB: Sb (196). 2. Since a b is parallel to AB, bc to BC, cd to CD, &c., the angle abc ABC, the angle b c d = BCD, and so on. Moreover, on account of the similar triangles SAB, Sab, AB: ab:: SB: Sb; and, on account of the similar triangles SBC, Sbc, BC: bc:: CD: cd, in like manner, 409. Corollary. Let S-ABCDE, S-XYZ, be two pyramids that have a common vertex, and whose altitudes are the same, or whose bases are situated in the same plane; if these pyramids be cut by a plane parallel to their bases, the sections abcde, xyz, thus formed, will be to each other as the bases ABCDE, XYZ. For, the polygons ABCDE, abcde, being similar, their surfaces are as the squares of their homologous sides AB, ab; but AB: ab:: SA: Sa, consequently -2 --2 ABCDE: a b c d e :: SA: Sa. For the same reason, XYZ : x y z :: SX : S x. SA: Sa:: SX: Sx, But, since a b c d e, x y z, are in the same plane, whence ABCDE: abcde:: XYZ: xyz; therefore the sections a b c d e, xyz, are to each other as their bases ABCDE, XYZ. Fig. 215. LEMMA. 410. Let S-ABC (fig. 215), be a triangular pyramid, of which S is the vertex and ABC the base; if the sides SA, SB, SC, AB, AC, BC, be bisected at the points D, E, F, G, H, I, and through these points the straight lines DE, EF, DF, EG, FH, EI, GI, GH, be drawn; we say that the pyramid S-ABC may be considered as composed of two prisms AGH-FDE, EGI-CFH, equivalent to each other, and two equal pyramids S-DEF, E-GBI. Demonstration. It follows from the construction, that ED is parallel to BA, and GE to AS (199); hence the figure ADEG is a parallelogram. For the same reason, the figure ADFH is also a parallelogram; consequently the straight lines AD, GE, HF, are equal and parallel; therefore the solid AGH-FDE is a prism (346). . It may be shown, in like manner, that the two figures EFCI, CIGH, are parallelograms, and that thus the straight lines EF, IC, GH, are equal and parallel; therefore the solid EGI-CFH is |