These Thurston maps are NET maps for every choice of translation term.
They are primitive and have degree 4.
PURE MODULAR GROUP HURWITZ EQUIVALENCE CLASSES FOR TRANSLATIONS
{0,lambda1} {lambda2} {lambda1+lambda2}
Since no Thurston multiplier is 1, this modular group Hurwitz class
contains only finitely many Thurston equivalence classes.
The number of pure modular group Hurwitz classes
in this modular group Hurwitz class is 7.
The pullback map is constant: every curve has a trivial preimage.
The image of the pullback map is the intersection of the
geodesics (-1/1,0/1) and (-1/2,1/0).
Every NET map in this modular group Hurwitz class is rational.
FUNDAMENTAL GROUP WREATH RECURSIONS
When the translation term of the affine map is 0:
NewSphereMachine(
"a=<1,b*c,d*a*c,1>(2,3)",
"b=<1,1,d,1>(2,3)",
"c=<1,1,1,1>(1,2)(3,4)",
"d=(1,2)(3,4)",
"a*b*c*d");
When the translation term of the affine map is lambda1:
NewSphereMachine(
"a=<1,a^-1*c^-1,b^-1,1>(2,3)",
"b=<1,1,c,1>(2,3)",
"c=(1,2)(3,4)",
"d=(1,2)(3,4)",
"a*b*c*d");
When the translation term of the affine map is lambda2:
NewSphereMachine(
"a=<1,a,c^-1*b*c,1>(1,2)(3,4)",
"b=<1,1,1,1>(1,2)(3,4)",
"c=<1,1,d,1>(2,3)",
"d=<1,a*c,a^-1,1>(2,3)",
"a*b*c*d");
When the translation term of the affine map is lambda1+lambda2:
NewSphereMachine(
"a=<1,1,b,b^-1>(1,2)(3,4)",
"b=(1,2)(3,4)",
"c=<1,1,c,1>(2,3)",
"d=<1,d*a,a^-1,1>(2,3)",
"a*b*c*d");