# Why do initial algebras correspond to data and final coalgebras to codata?

If I understand correctly, we can model inductive data types as initial F-algebras and co-inductive data types as final F-coalgebras (for an appropriate endofunctor `F`) . I understand that according to Lambek's lemma the initial algebras (and final coalgebras) are fixed point solutions of the isomorphism `T ≅ F T`, but I don't see why the initial algebra is the least fixed point, while the final coalgebra is the greatest fixed point. (Is it obvious that the isomorphism `T ≅ F T` has a solution?)

Also I'm not really clear on how are inductive and co-inductive data types defined in type theory. Are there any recommended resources on this topic and maybe their relationship to category theory?

Thank you!

• In a poset category, an initial object is the bottom ("least"), and a final one is the top ("greatest"). So, by extension, it makes sense to call the initial algebra the least fixed point, etc. even if that's a little abuse, I think.
– chi
Aug 22, 2018 at 13:29
• @chi Thanks for the comment! Just to make sure I understand this correctly. One object is initial and the other is terminal, but they are leaving in different categories, right? The first one is initial in F-Alg(C), the second one is terminal in F-Coalg(C). I guess we cannot "compare" them, or it just doesn't matter? Aug 22, 2018 at 13:49
• Both are isomorphisms, though. We have `a: FA->A` and `b: B->FB`. So, in particular, `a^-1 : A->FA` is also a coalgebra and `b^-1: FB->B` is an algebra. Hence, we get an algebra-morphism `A->B` and a coalgebra morphism `A->B`. (They might be the same ones if we think of them as C-morphisms). So, we could say that A is "less" than B since there's a morphism between them in C. It is not a proper comparison since C is a category, not a poset, but there is some analogy. In a sense, a category is an extension of a preorder.
– chi
Aug 22, 2018 at 14:03

My understanding is that, in principle, there may be many solutions to the fixed point equation `T ≅ F T`. By Lambek's lemma, the initial algebra, if it exists, is one of those fixed points. In fact it's the least fixed point.