I have a partially-defined operator (`disj_union`

below) on sets that I would like to lift to a quotient type (`natq`

). Morally, I think this *should* be ok, because it is always possible to find in the equivalence class *some* representative for which the operator is defined [*]. However, I cannot complete the proof that the lifted definition preserves the equivalence, because `disj_union`

is only partially defined. In my theory file below, I propose one way I have found to define my `disj_union`

operator, but I don't like it because it features lots of `abs`

and `Rep`

functions, and I think it would be hard to work with (right?).

What is a good way to define this kind of thing using quotients in Isabelle?

```
theory My_Theory imports
"~~/src/HOL/Library/Quotient_Set"
begin
(* A ∪-operator that is defined only on disjoint operands. *)
definition "X ∩ Y = {} ⟹ disj_union X Y ≡ X ∪ Y"
(* Two sets are equivalent if they have the same cardinality. *)
definition "card_eq X Y ≡ finite X ∧ finite Y ∧ card X = card Y"
(* Quotient sets of naturals by this equivalence. *)
quotient_type natq = "nat set" / partial: card_eq
proof (intro part_equivpI)
show "∃x. card_eq x x" by (metis card_eq_def finite.emptyI)
show "symp card_eq" by (metis card_eq_def symp_def)
show "transp card_eq" by (metis card_eq_def transp_def)
qed
(* I want to lift my disj_union operator to the natq type.
But I cannot complete the proof, because disj_union is
only partially defined. *)
lift_definition natq_add :: "natq ⇒ natq ⇒ natq"
is "disj_union"
oops
(* Here is another attempt to define natq_add. I think it
is correct, but it looks hard to prove things about,
because it uses abstraction and representation functions
explicitly. *)
definition natq_add :: "natq ⇒ natq ⇒ natq"
where "natq_add X Y ≡
let (X',Y') = SOME (X',Y').
X' ∈ Rep_natq X ∧ Y' ∈ Rep_natq Y ∧ X' ∩ Y' = {}
in abs_natq (disj_union X' Y')"
end
```

[*] This is a little bit like how capture-avoiding substitution is only defined on the condition that bound variables do not clash; a condition that can always be satisfied by renaming to another representative in the alpha-equivalence class.