* These intervals are of course to be such that within them the derivatives of F are finite and continuous.

* This statement requires some justification. If P be any point (at which the derivatives of F ₀ are finite and continuous) of a space for which x ₁, … x _n are Cartesian coordinates, we may determine a locus, L ₀ say, of the family (10), in which we regard m ₁, … m _n as continuously variable parameters, to pass through P. Allowing m ₁, … m _n to vary continuously from their values for L ₀, the locus represented by (10) will undergo a continuous displacement in the neighbourhood of P. In any such variation, however small, m ₁, … m _n simultaneously pass through rational values; thus, since m ₁, … m _n enter (10) only through their ratios, we can find a locus of the family for which m ₁, … m _n have integral values, to pass arbitrarily near P.

* Méthodes Nouvelles, § 87.

‡ Acta Math., xxx (1905), 305.Google Scholar

‡ Analytical Dynamics (2nd ed.), p. 385.Google Scholar

§ Phys. Zeit., xxiv (1923), 261Google Scholar.

∥ See, for example, Born, and Pauli, , Zeit. für Phys., x, 137, § 3.Google Scholar

* ‘Integrals of Systems of Ordinary Differential Equations,” p. 273, above.

* If the equations be taken in Poincaré's form (1), the special property of the value μ = 0 is that then the equations simplify in such a far-reaching manner that their solution becomes trivial; we thus reach the paradoxical conclusion that expansions in powers of μ are unsuitable for the precise reason which originally led to their adoption! In fact, as has been remarked by Poincaré, we get into unnecessary difficulties by taking too simple a first approximation; it is this same idea which underlies Gylden's contributions to Celestial Mechanics.

† See p. 281, above.