What are definitions of ellipticity?

Ellipticity seems to have many definitions. So far, I'm aware of three. Are there other definitions of ellipticity that you know of, and if so, where did you encounter them?

The three definitions that I'm listing all have that $a \geq b$.

Definition 1: $$ \varepsilon = \frac{a-b}{a} = 1 - \frac{b}{a}. $$ This definition comes from my "Dictionary of Physics and Mathematics" from McGraw-Hill.

Definition 2: $$ \varepsilon = \sqrt{\frac{a^2-b^2}{a^2}} = \sqrt{1 - \frac{b^2}{a^2}}. $$ This definition comes from . As a side note, the Wolfram page on ellipticity also defines something called flattening that is equivalent to my definition 1.

Definition 3: $$ \varepsilon = \frac{a^2-b^2}{a^2+b^2}. $$

I've done a light search for information on definition three, but I have not turned up anything in the literature.

1 Answer

There are several definitions of ellipticity (also called eccentricity), though they aren't different things quite so much as different measurements of divergence from perfect circularity:

• Your first definition is the first (or "primary") flattening f, which is equal to the versine of the angle [ref. 1];
• Your second definition is the first (or "primary") eccentricity ε, which is equal to the sine of the angle [ref. 1];
• Your third definition is the third eccentricity ε'', the trigonometric identity of which is ambiguous [ref. 1].

Within the context above, there are two other measures of flattening and one other of eccentricity [ref. 1]:

• The second flattening, f ' = (a-b)/b, is the exsecant of the angle;
• The third flattening, f '' = (a-b)/(a+b), is the havertan (half of the versed tangent) of the angle;
• The second eccentricity, ε' = (a²-b²)/b², is the tangent of the angle.

There exists at least one extension of these two sets (a rather hard-to-find item, it seems), a fourth degree of flattening and of eccentricity, respectively [ref. 2, pp. 2-3]:

• This fourth flattening, μ₀ = (a²-b²)/b²,
  • note that this would be f ''', in the established Western convention;
• This fourth eccentricity, e₀ = $\surd$((a²-b²)/ab),
  • note that this would be ε''', in the established Western convention.

The first 3 flattenings follow a general pattern of 2sin²(θ/2)/[denom.], wherein the denominator in each case is {1, 1-numer., 2-numer.}; I haven't yet checked to see if the 4th flattening follows suit with {3-numer.}. The first 3 eccentricities follow a rather similar pattern of sin²(θ)/[denom.], wherein the denominator in each case is also {1, 1-numer., 2-numer.}. I have not yet checked to see if the denominators continue in like manner, with {4-numer., ..., n-numer.,...}.

You might also note that the first four denominators are {a, b, (a+b)*0.5, ab^0.5}. Whether this pattern continues to a fifth degree via tetration of 0.5, much less higher orders of hyperoperation (of 0.5, I expect), I don't yet know.

If I find data regarding the denominators' pattern, and/or that of the increasing hyperoperation, then I will return with the update(s).

References:

1. • "Geometry of the Earth ellipsoid", Vladimir Nikolaevich Gan'shin, Moscow, 1967