Jacobi's elliptic functions

Theta functions

Jacobi's elliptic functions can be defined in terms of his theta functions. If we abbreviate as , and respectively as (the theta constants) then the modulus k is . If we set , we have

Since the Jacobi functions are defined in terms of , we need to invert this and find τ in terms of k. We start from , the complementary modulus. As a function of τ it is

Let us first define

If now we set and expand as a power series in q, we obtain

Reversion of series now gives

Since we may reduce to the case where the imaginary part of τ is greater than or equal to , we can assume the absolute value of q is less than or equal to ; for values this small the above series converges very rapidly and easily allows us to find the appropriate value for q.

Doubly-periodic functions

The three Jacobi elliptic functions are doubly periodic, meromorphic functions of z, whose periods are expressible in terms of τ and . If we set then the periods of sn are and , of cn are and , and of dn are and . If we call the periods of cn the lattice Λ, then both sn and dn are periodic with respect to Λ, but their full lattices of periods are larger (in each case, Λ is a subgroup of index 2).

The functions satisfy the two algebraic relations

From this we see that parametrizes an elliptic curve which is the intersection of the two quadrics defined by the above two equations. We now may define a group law for points on this curve by the addition formulas for the Jacobi functions

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