Page:Eddington A. Space Time and Gravitation. 1920.djvu/223

which gives the equation of the orbit in the usual form in particle dynamics. It differs from the equation of the Newtonian orbit by the small term ${\displaystyle 3mu^{2}}$ , which is easily shown to give the motion of perihelion.

The track of a ray of light is also obtained from this formula, since by the principle of equivalence it agrees with that of a material particle moving with the speed of light. This case is given by ${\displaystyle ds=0}$, and therefore ${\displaystyle h=\infty }$. The differentia] equation for the path of a light-ray is thus ${\displaystyle {\frac {d^{2}u}{d\theta ^{2}}}+u=3mu^{2}}$.

An approximate solution is ${\displaystyle u={\frac {\cos \theta }{R}}+{\frac {m}{R^{2}}}\left(\cos ^{2}\theta +2\sin ^{2}\theta \right)}$, neglecting the very small quantity ${\displaystyle m^{2}/R^{2}}$. Converting to Cartesian coordinates, this becomes ${\displaystyle x=R-{\frac {m}{R}}{\frac {x^{2}+2y^{2}}{\sqrt {\left(x^{2}+y^{2}\right)}}}}$.

The asymptotes of the light-track are found by taking ${\displaystyle y}$ very large compared with ${\displaystyle x}$, giving ${\displaystyle x=R\pm {\frac {2m}{R}}y}$ so that the angle between them is ${\displaystyle 4m/R}$.

Writing the line element in the form ${\displaystyle ds^{2}=-\left(1+a{\frac {m}{r}}+\ldots \right)dr^{2}-r^{2}\,d\theta ^{2}+\left(1+b{\frac {m}{r}}+c{\frac {m^{2}}{r^{2}}}+\ldots \right)dt^{2}}$, the approximate Newtonian attraction fixes ${\displaystyle b}$ equal to + 2; then the observed deflection of light fixes ${\displaystyle a}$ equal to − 2; and with these values the observed motion of Mercury fixes ${\displaystyle c}$ equal to 0.

To insert an arbitrary coefficient of ${\displaystyle r^{2}d\theta ^{2}}$ would merely vary the coordinate system. We cannot arrive at any intrinsically different kind of space-time in that way. Hence, within the limits of accuracy mentioned, the expression found by Einstein is completely determinable by observation.