# Apartness relations ```agda module foundation.apartness-relations where ``` <details><summary>Imports</summary> ```agda open import foundation.binary-relations open import foundation.dependent-pair-types open import foundation.disjunction open import foundation.existential-quantification open import foundation.propositional-truncations open import foundation.universal-quantification open import foundation.universe-levels open import foundation-core.cartesian-product-types open import foundation-core.coproduct-types open import foundation-core.empty-types open import foundation-core.identity-types open import foundation-core.negation open import foundation-core.propositions ``` </details> ## Idea An **apartness relation** on a type `A` is a [relation](foundation.binary-relations.md) `R` which is - **Antireflexive:** For any `a : A` we have `¬ (R a a)` - **Symmetric:** For any `a b : A` we have `R a b → R b a` - **Cotransitive:** For any `a b c : A` we have `R a b → R a c ∨ R b c`. The idea of an apartness relation `R` is that `R a b` holds if you can positively establish a difference between `a` and `b`. For example, two subsets `A` and `B` of a type `X` are apart if we can find an element that is in the [symmetric difference](foundation.symmetric-difference.md) of `A` and `B`. ## Definitions ### Apartness relations ```agda module _ {l1 l2 : Level} {A : UU l1} (R : A → A → Prop l2) where is-antireflexive : UU (l1 ⊔ l2) is-antireflexive = (a : A) → ¬ (type-Prop (R a a)) is-consistent : UU (l1 ⊔ l2) is-consistent = (a b : A) → (a = b) → ¬ (type-Prop (R a b)) is-cotransitive-Prop : Prop (l1 ⊔ l2) is-cotransitive-Prop = ∀' A (λ a → ∀' A (λ b → ∀' A (λ c → R a b ⇒ (R a c ∨ R b c)))) is-cotransitive : UU (l1 ⊔ l2) is-cotransitive = type-Prop is-cotransitive-Prop is-apartness-relation : UU (l1 ⊔ l2) is-apartness-relation = ( is-antireflexive) × ( is-symmetric (λ x y → type-Prop (R x y))) × ( is-cotransitive) Apartness-Relation : {l1 : Level} (l2 : Level) (A : UU l1) → UU (l1 ⊔ lsuc l2) Apartness-Relation l2 A = Σ (Relation-Prop l2 A) (is-apartness-relation) module _ {l1 l2 : Level} {A : UU l1} (R : Apartness-Relation l2 A) where rel-Apartness-Relation : A → A → Prop l2 rel-Apartness-Relation = pr1 R apart-Apartness-Relation : A → A → UU l2 apart-Apartness-Relation x y = type-Prop (rel-Apartness-Relation x y) antirefl-Apartness-Relation : is-antireflexive rel-Apartness-Relation antirefl-Apartness-Relation = pr1 (pr2 R) consistent-Apartness-Relation : is-consistent rel-Apartness-Relation consistent-Apartness-Relation x .x refl = antirefl-Apartness-Relation x symmetric-Apartness-Relation : is-symmetric apart-Apartness-Relation symmetric-Apartness-Relation = pr1 (pr2 (pr2 R)) cotransitive-Apartness-Relation : is-cotransitive rel-Apartness-Relation cotransitive-Apartness-Relation = pr2 (pr2 (pr2 R)) ``` ### Types equipped with apartness relation ```agda Type-With-Apartness : (l1 l2 : Level) → UU (lsuc l1 ⊔ lsuc l2) Type-With-Apartness l1 l2 = Σ (UU l1) (Apartness-Relation l2) module _ {l1 l2 : Level} (A : Type-With-Apartness l1 l2) where type-Type-With-Apartness : UU l1 type-Type-With-Apartness = pr1 A apartness-relation-Type-With-Apartness : Apartness-Relation l2 type-Type-With-Apartness apartness-relation-Type-With-Apartness = pr2 A rel-apart-Type-With-Apartness : Relation-Prop l2 type-Type-With-Apartness rel-apart-Type-With-Apartness = rel-Apartness-Relation apartness-relation-Type-With-Apartness apart-Type-With-Apartness : (x y : type-Type-With-Apartness) → UU l2 apart-Type-With-Apartness = apart-Apartness-Relation apartness-relation-Type-With-Apartness antirefl-apart-Type-With-Apartness : is-antireflexive rel-apart-Type-With-Apartness antirefl-apart-Type-With-Apartness = antirefl-Apartness-Relation apartness-relation-Type-With-Apartness consistent-apart-Type-With-Apartness : is-consistent rel-apart-Type-With-Apartness consistent-apart-Type-With-Apartness = consistent-Apartness-Relation apartness-relation-Type-With-Apartness symmetric-apart-Type-With-Apartness : is-symmetric apart-Type-With-Apartness symmetric-apart-Type-With-Apartness = symmetric-Apartness-Relation apartness-relation-Type-With-Apartness cotransitive-apart-Type-With-Apartness : is-cotransitive rel-apart-Type-With-Apartness cotransitive-apart-Type-With-Apartness = cotransitive-Apartness-Relation apartness-relation-Type-With-Apartness ``` ### Apartness on the type of functions into a type with an apartness relation ```agda module _ {l1 l2 l3 : Level} (X : UU l1) (Y : Type-With-Apartness l2 l3) where rel-apart-function-into-Type-With-Apartness : Relation-Prop (l1 ⊔ l3) (X → type-Type-With-Apartness Y) rel-apart-function-into-Type-With-Apartness f g = ∃ X (λ x → rel-apart-Type-With-Apartness Y (f x) (g x)) apart-function-into-Type-With-Apartness : Relation (l1 ⊔ l3) (X → type-Type-With-Apartness Y) apart-function-into-Type-With-Apartness f g = type-Prop (rel-apart-function-into-Type-With-Apartness f g) is-prop-apart-function-into-Type-With-Apartness : (f g : X → type-Type-With-Apartness Y) → is-prop (apart-function-into-Type-With-Apartness f g) is-prop-apart-function-into-Type-With-Apartness f g = is-prop-type-Prop (rel-apart-function-into-Type-With-Apartness f g) ``` ## Properties ```agda module _ {l1 l2 l3 : Level} (X : UU l1) (Y : Type-With-Apartness l2 l3) where is-antireflexive-apart-function-into-Type-With-Apartness : is-antireflexive (rel-apart-function-into-Type-With-Apartness X Y) is-antireflexive-apart-function-into-Type-With-Apartness f H = apply-universal-property-trunc-Prop H ( empty-Prop) ( λ (x , a) → antirefl-apart-Type-With-Apartness Y (f x) a) is-symmetric-apart-function-into-Type-With-Apartness : is-symmetric (apart-function-into-Type-With-Apartness X Y) is-symmetric-apart-function-into-Type-With-Apartness f g H = apply-universal-property-trunc-Prop H ( rel-apart-function-into-Type-With-Apartness X Y g f) ( λ (x , a) → unit-trunc-Prop ( x , symmetric-apart-Type-With-Apartness Y (f x) (g x) a)) abstract is-cotransitive-apart-function-into-Type-With-Apartness : is-cotransitive (rel-apart-function-into-Type-With-Apartness X Y) is-cotransitive-apart-function-into-Type-With-Apartness f g h H = apply-universal-property-trunc-Prop H ( disjunction-Prop ( rel-apart-function-into-Type-With-Apartness X Y f h) ( rel-apart-function-into-Type-With-Apartness X Y g h)) ( λ (x , a) → apply-universal-property-trunc-Prop ( cotransitive-apart-Type-With-Apartness Y (f x) (g x) (h x) a) ( disjunction-Prop ( rel-apart-function-into-Type-With-Apartness X Y f h) ( rel-apart-function-into-Type-With-Apartness X Y g h)) ( λ where ( inl b) → inl-disjunction (intro-exists x b) ( inr b) → inr-disjunction (intro-exists x b))) exp-Type-With-Apartness : Type-With-Apartness (l1 ⊔ l2) (l1 ⊔ l3) pr1 exp-Type-With-Apartness = X → type-Type-With-Apartness Y pr1 (pr2 exp-Type-With-Apartness) = rel-apart-function-into-Type-With-Apartness X Y pr1 (pr2 (pr2 exp-Type-With-Apartness)) = is-antireflexive-apart-function-into-Type-With-Apartness pr1 (pr2 (pr2 (pr2 exp-Type-With-Apartness))) = is-symmetric-apart-function-into-Type-With-Apartness pr2 (pr2 (pr2 (pr2 exp-Type-With-Apartness))) = is-cotransitive-apart-function-into-Type-With-Apartness ``` ## References {{#bibliography}} {{#reference MRR88}}