Proof of Nuprl Lemma : monad-of-Kleisli-adjunction

Step * 1 2 1 1 1 of Lemma monad-of-Kleisli-adjunction

1. C : SmallCategory
2. M : Monad(C)
3. x : cat-ob(C)@i
4. y : cat-ob(C)@i
5. f : cat-arrow(C) x y@i
⊢ (cat-comp(C) M(x) M(M(y)) M(y)
(cat-comp(C) M(x) M(y) M(M(y)) (monad-functor(M) x y f) (monad-functor(M) y M(y) monad-unit(M;y)))
monad-op(M;y))
= (monad-functor(M) x y f)
∈ (cat-arrow(C) M(x) M(y))
BY
{ (InstLemma `monad-equations` [⌜C⌝;⌜M⌝]⋅ THENA Auto) }

1
1. C : SmallCategory
2. M : Monad(C)
3. x : cat-ob(C)@i
4. y : cat-ob(C)@i
5. f : cat-arrow(C) x y@i
6. ∀[x:cat-ob(C)]

     ((((cat-comp(C) M(x) M(M(x)) M(x) monad-unit(M;M(x)) monad-op(M;x)) = (cat-id(C) M(x)) ∈ (cat-arrow(C) M(x) M(x)))

     ∧ ((cat-comp(C) M(x) M(M(x)) M(x) (monad-functor(M) x M(x) monad-unit(M;x)) monad-op(M;x))
       = (cat-id(C) M(x))
       ∈ (cat-arrow(C) M(x) M(x))))
     ∧ ((cat-comp(C) M(M(M(x))) M(M(x)) M(x) monad-op(M;M(x)) monad-op(M;x))

       = (cat-comp(C) M(M(M(x))) M(M(x)) M(x) (monad-functor(M) M(M(x)) M(x) monad-op(M;x)) monad-op(M;x))

       ∈ (cat-arrow(C) M(M(M(x))) M(x))))
⊢ (cat-comp(C) M(x) M(M(y)) M(y)
   (cat-comp(C) M(x) M(y) M(M(y)) (monad-functor(M) x y f) (monad-functor(M) y M(y) monad-unit(M;y)))
   monad-op(M;y))
= (monad-functor(M) x y f)
∈ (cat-arrow(C) M(x) M(y))

Latex:

Latex:
1. C : SmallCategory 2. M : Monad(C) 3. x : cat-ob(C)@i 4. y : cat-ob(C)@i 5. f : cat-arrow(C) x y@i \mvdash{} (cat-comp(C) M(x) M(M(y)) M(y) (cat-comp(C) M(x) M(y) M(M(y)) (monad-functor(M) x y f) (monad-functor(M) y M(y) monad-unit(M;y))) monad-op(M;y)) = (monad-functor(M) x y f) By Latex: (InstLemma `monad-equations` [\mkleeneopen{}C\mkleeneclose{};\mkleeneopen{}M\mkleeneclose{}]\mcdot{} THENA Auto) Home Index