Equation of the center

::\beta=\frac{1}{e}\left(1-\sqrt{1-e^2}\right). The result is in radians. The Bessel functions can be expanded in powers of *x* by, :J_n(x) = \frac{1}{n!}\left(\frac{x}{2}\right)^n\sum_{m=0}^\infty(-1)^m\frac{\left(\frac{x}{2}\right)^{2m}}{m!\prod_{k=1}^m (n+k)} and *β**m* by, :\beta^m = \left(\frac{e}{2}\right)^m\left[1+m\sum_{n=1}^\infty\frac{(2n+m-1)!}{n!(n+m)!}\left(\frac{e}{2}\right)^{2n}\right]. Substituting and reducing, the equation for *ν* becomes (truncated at order *e*7), :\begin{align} \nu \approx M &+ \left(2e - \frac{1}{4}e^3 + \frac{5}{96}e^5 + \frac{107}{4608}e^7\right) \sin M\\ &{}+ \left(\frac{5}{4}e^2 - \frac{11}{24}e^4 + \frac{17}{192}e^6\right) \sin 2 M\\ &{}+ \left(\frac{13}{12}e^3 - \frac{43}{64}e^5 + \frac{95}{512}e^7\right) \sin 3 M\\ &{}+ \left(\frac{103}{96}e^4 - \frac{451}{480}e^6\right) \sin 4 M\\ &{}+ \left(\frac{1097}{960}e^5 - \frac{5957}{4608}e^7\right) \sin 5 M\\ &{}+ \frac{1223}{960}e^6\sin6M + \frac{47273}{32256}e^7\sin7M + \cdots \end{align} and by the definition, moving *M* to the left-hand side, gives an approximation for the equation of the center. However, it is not a good approximation when *e* is high (see graph). If the coefficients are calculated from the Bessel functions then the approximation is much better when going up to the same frequency (such as \sin7M). This formula is sometimes presented in terms of powers of *e* with coefficients in functions of sin *M* (here truncated at order *e*6), :\begin{align} \nu = M &{}+ 2e \sin M + \frac{5}{4}e^2\sin 2M\\ &{}+ \frac{e^3}{12}(13\sin 3M - 3\sin M)\\ &{}+ \frac{e^4}{96}(103\sin 4M - 44\sin 2M)\\ &{}+ \frac{e^5}{960}(1097\sin 5M - 645\sin 3M + 50\sin M)\\ &{}+ \frac{e^6}{960}(1223\sin 6M - 902\sin 4M + 85\sin 2M)+ \cdots \end{align} which is similar to the above form. This presentation, when not truncated, contains the same infinite set of terms, but implies a different order of adding them up. Because of this, for small *e*, the series converges rapidly but if *e* exceeds the "Laplace limit" of 0.6627... then it diverges for all values of *M* (other than multiples of π), a fact discovered by Francesco Carlini and Pierre-Simon Laplace. ## Examples The equation of the center attains its maximum when the eccentric anomaly is \pi/2, the true anomaly is \pi/2+\operatorname{arcsin}e, the mean anomaly is \pi/2-e, and the equation of the center is e+\operatorname{arcsin}e. Here are some examples: ::data[format=table] | Orbital eccentricity | True value | Maximum equation of the center (series truncated as shown) | *e*7 | *e*3 | *e*2 | Venus | Earth | Saturn | Mars | Mercury | |---|---|---|---|---|---|---|---|---|---|---| | editor-last = Seidelmann | editor-first = P. Kenneth | editor2-last = Urban | editor2-first = Sean E. | title = Explanatory Supplement to the Astronomical Almanac | publisher = University Science Books, Mill Valley, CA | year = 2013 | isbn = 978-1-891389-85-6 | edition=3rd | page=338 | | | 0.006777 | 0.7766° | 0.7766° | 0.7766° | 0.7766° | | | | | | | | 0.01671 | 1.915° | 1.915° | 1.915° | 1.915° | | | | | | | | 0.05386 | 6.173° | 6.174° | 6.174° | 6.186° | | | | | | | | 0.09339 | 10.71° | 10.71° | 10.71° | 10.77° | | | | | | | | 0.2056 | 23.64° | 23.68° | 23.77° | 23.28° | | | | | | | :: ## References ## References 1. Vallado, David A. (2001). p. 80 2. Brouwer, Dirk; Clemence, Gerald M. (1961). p. 77. 3. Brouwer, Dirk; Clemence, Gerald M. (1961). p. 62. 4. Brouwer, Dirk; Clemence, Gerald M. (1961). p. 68. 5. Smart, W. M. (1953). p. 32. 6. Moulton, Forest Ray (1914). pp. 171–172. ::callout[type=info title="Wikipedia Source"] This article was imported from [Wikipedia](https://en.wikipedia.org/wiki/Equation_of_the_center) and is available under the [Creative Commons Attribution-ShareAlike 4.0 License](https://creativecommons.org/licenses/by-sa/4.0/). Content has been adapted to SurfDoc format. Original contributors can be found on the [article history page](https://en.wikipedia.org/wiki/Equation_of_the_center?action=history). ::