Weber modular function

In mathematics, the Weber modular functions are a family of three functions f, f1, and f2, studied by Heinrich Martin Weber. Let where τ is an element of the upper half-plane. Then the Weber functions are These are also the definitions in Duke's paper "Continued Fractions and Modular Functions". The function is the Dedekind eta function and should be interpreted as . The descriptions as quotients immediately imply The transformation τ → –1/τ fixes f and exchanges f1 and f2. So the 3-dimensional complex vector space with basis f, f1 and f2 is acted on by the group SL2(Z). Alternatively, let be the nome, The form of the infinite product has slightly changed. But since the eta quotients remain the same, then as long as the second uses the nome . The utility of the second form is to show connections and consistent notation with the Ramanujan G- and g-functions and the Jacobi theta functions, both of which conventionally uses the nome. Still employing the nome , define the Ramanujan G- and g-functions as The eta quotients make their connection to the first two Weber functions immediately apparent. In the nome, assume Then, Ramanujan found many relations between and which implies similar relations between and . For example, his identity, leads to For many values of n, Ramanujan also tabulated for odd n, and for even n. This automatically gives many explicit evaluations of and . For example, using , which are some of the square-free discriminants with class number 2, and one can easily get from these, as well as the more complicated examples found in Ramanujan's Notebooks. The argument of the classical Jacobi theta functions is traditionally the nome Dividing them by , and also noting that , then they are just squares of the Weber functions with even-subscript theta functions purposely listed first. Using the well-known Jacobi identity with even subscripts on the LHS, therefore, The three roots of the cubic equation where j(τ) is the j-function are given by .