Modular lambda function
In mathematics, the elliptic modular lambda function λ(τ) is a highly symmetric holomorphic function on the complex upper half-plane. It is invariant under the fractional linear action of the congruence group Γ(2), and generates the function field of the corresponding quotient, i.e., it is a Hauptmodul for the modular curve X(2). Over any point τ, its value can be described as a cross ratio of the branch points of a ramified double cover of the projective line by the elliptic curve , where the map is defined as the quotient by the [−1] involution.
The q-expansion, where is the nome, is given by:
By symmetrizing the lambda function under the canonical action of the symmetric group S3 on X(2), and then normalizing suitably, one obtains a function on the upper half-plane that is invariant under the full modular group , and it is in fact Klein's modular j-invariant.
Modular properties
The function is invariant under the group generated by[1]
The generators of the modular group act by[2]
Consequently, the action of the modular group on is that of the anharmonic group, giving the six values of the cross-ratio:[3]
Other appearances
Other elliptic functions
It is the square of the Jacobi modulus,[4] that is, . In terms of the Dedekind eta function and theta functions,[4]
and,
In terms of the half-periods of Weierstrass's elliptic functions, let be a fundamental pair of periods with .
we have[4]
Since the three half-period values are distinct, this shows that λ does not take the value 0 or 1.[4]
The relation to the j-invariant is[6][7]
which is the j-invariant of the elliptic curve of Legendre form
Little Picard theorem
The lambda function is used in the original proof of the Little Picard theorem, that an entire non-constant function on the complex plane cannot omit more than one value. This theorem was proved by Picard in 1879.[8] Suppose if possible that f is entire and does not take the values 0 and 1. Since λ is holomorphic, it has a local holomorphic inverse ω defined away from 0,1,∞. Consider the function z → ω(f(z)). By the Monodromy theorem this is holomorphic and maps the complex plane C to the upper half plane. From this it is easy to construct a holomorphic function from C to the unit disc, which by Liouville's theorem must be constant.[9]
Moonshine
The function is the normalized Hauptmodul for the group , and its q-expansion , OEIS: A007248 where , is the graded character of any element in conjugacy class 4C of the monster group acting on the monster vertex algebra.
Footnotes
- Chandrasekharan (1985) p.115
- Chandrasekharan (1985) p.109
- Chandrasekharan (1985) p.110
- Chandrasekharan (1985) p.108
- Chandrasekharan (1985) p.63
- Chandrasekharan (1985) p.117
- Rankin (1977) pp.226–228
- Chandrasekharan (1985) p.121
- Chandrasekharan (1985) p.118
References
- Abramowitz, Milton; Stegun, Irene A., eds. (1972), Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables, New York: Dover Publications, ISBN 978-0-486-61272-0, Zbl 0543.33001
- Chandrasekharan, K. (1985), Elliptic Functions, Grundlehren der mathematischen Wissenschaften, 281, Springer-Verlag, pp. 108–121, ISBN 3-540-15295-4, Zbl 0575.33001
- Conway, John Horton; Norton, Simon (1979), "Monstrous moonshine", Bulletin of the London Mathematical Society, 11 (3): 308–339, doi:10.1112/blms/11.3.308, MR 0554399, Zbl 0424.20010
- Rankin, Robert A. (1977), Modular Forms and Functions, Cambridge University Press, ISBN 0-521-21212-X, Zbl 0376.10020
- Reinhardt, W. P.; Walker, P. L. (2010), "Elliptic Modular Function", in Olver, Frank W. J.; Lozier, Daniel M.; Boisvert, Ronald F.; Clark, Charles W. (eds.), NIST Handbook of Mathematical Functions, Cambridge University Press, ISBN 978-0-521-19225-5, MR 2723248