Dubrovin [Lecture Notes in Math., Vol. 1620, Springer, Berlin, 1996, 120-348]
showed that the Chazy XII equation y′′′−2yy′′+3y′2=K(6y′−y2)2, K∈C, is equivalent to a projective-invariant equation for an affine
connection on a one-dimensional complex manifold with projective structure. By
exploiting this geometric connection it is shown that the Chazy XII solution,
for certain values of K, can be expressed as y=a1w1+a2w2+a3w3 where
wi solve the generalized Darboux-Halphen system. This relationship holds
only for certain values of the coefficients (a1,a2,a3) and the
Darboux-Halphen parameters (α,β,γ), which are enumerated in
Table 2. Consequently, the Chazy XII solution y(z) is parametrized by a
particular class of Schwarz triangle functions S(α,β,γ;z)
which are used to represent the solutions wi of the Darboux-Halphen system.
The paper only considers the case where α+β+γ<1. The associated
triangle functions are related among themselves via rational maps that are
derived from the classical algebraic transformations of hypergeometric
functions. The Chazy XII equation is also shown to be equivalent to a
Ramanujan-type differential system for a triple (P^,Q^,R^)