du 2 where A is the sum of squares of the constants. 2 By adding and subtracting u2 dt dt dx 2 + &c., this dx\ 2 + dt dt &c. } dx dt - (u· + v + √ + &c.)2 = A2. (6) 2B being the arbitrary constant arising in the integration. Substituting this expression in (6) and putting for u2 + v3 + x2 + &c., that equation becomes dr {2r2 (R + B) − A2} By differentiating (8) we find dR Eliminating from the first of equations (2) by means dr By means of these we obtain as a function of r, and r as a function of t+a, and therefore as a function of t + a. Then the equations (13) will give u, v, x, &c. in terms of t+a, ß, g, h, g, h, &c. A and B, the number of But there are rewhich reduce the In the first place, arbitrary constants being thus 2n +4. lations subsisting between the constants number of independent constants to 2n. the constant ẞ will only alter g1, h1, g2 h2, &c., and it may therefore be neglected, so that the number of arbitrary constants is reduced to 2n + 3. Again, since r2 = u2 + v2 + x2 + &c., we have by squaring and adding equations (13) 1 = cos2 (g) + sin2 (h) + 2 sin cos (gh). In order that this equation may subsist for all values of we must have the conditions Σ (*) = 1, Σ (h) = 1, Σ (gh) = 0. These three conditions reduce the number of arbitrary constants to 2n. It is to be observed that the integrals for determining t and are not independent: for if we assume a function CHAPTER VIII. SINGULAR SOLUTIONS OF DIFFERENTIAL EQUATIONS. By a singular solution of a differential equation, is meant a certain relation between the variables which satisfies the differential equation, but does not satisfy the general integral. Solutions of this kind have long attracted the attention of inathematicians, and the memoirs in which they are discussed are very numerous. Their existence was first pointed out by Taylor, in his Methodus Incrementorum, p. 27, and afterwards they were noticed by Clairaut, in the Mémoires de l'Académie des Sciences for 1734. But Euler, in the Mémoires de l'Académie de Berlin for 1756, was the first who considered the subject in its bearing on the general Theory of Integration; and in his Integral Calculus, Vol. 1. Sect. 2, Chap. IV., he gave a test for discovering whether a given solution be or be not included in the general integral. Lagrange, in the Mémoires de l'Académie de Berlin, and afterwards in his Théorie des Fonctions, and his Calcul des Fonctions, discussed the theory of these solutions, and shewed the connection between them and the general integral, and their relative geometric interpretations. Other points of the theory have been elucidated by Laplace (Mémoires de l'Académie des Sciences, 1772), Legendre (Ib. 1790), and Poisson, Journal de l'Ecole Polytechnique, Cahier x111. Having given a differential equation, to find its singular solutions if it have any. be a differential equation of the first order between x and y cleared of radicals and fractions, then if we represent the relations between x and y found by eliminating p between are singular solutions of U = 0, provided they satisfy that equation, and do not at the same time make d U dy = 0. We and eliminating p between this and the preceding equation, we find y2 - 4mx = 0, as the singular solution. dy (2) Let dx be the given equation. Then (v + y)3 — 4ay = 0 is the singular solution. 2 = 0, *Laplace, Mémoires de l'Académie, 1772. |