# Tight apartness relations ```agda module foundation.tight-apartness-relations where ``` <details><summary>Imports</summary> ```agda open import foundation.apartness-relations open import foundation.binary-relations open import foundation.dependent-pair-types open import foundation.function-extensionality open import foundation.propositional-truncations open import foundation.universe-levels open import foundation-core.cartesian-product-types open import foundation-core.identity-types open import foundation-core.negation open import foundation-core.propositions ``` </details> ## Idea A [relation](foundation.binary-relations.md) `R` is said to be **tight** if for every `x y : A` we have `¬ (R x y) → (x = y)`. ## Definition ```agda module _ {l1 l2 : Level} {A : UU l1} (R : A → A → Prop l2) where is-tight : UU (l1 ⊔ l2) is-tight = (x y : A) → ¬ (type-Prop (R x y)) → x = y is-tight-apartness-relation : UU (l1 ⊔ l2) is-tight-apartness-relation = is-apartness-relation R × is-tight is-tight-Apartness-Relation : {l1 l2 : Level} {A : UU l1} (R : Apartness-Relation l2 A) → UU (l1 ⊔ l2) is-tight-Apartness-Relation R = is-tight (rel-Apartness-Relation R) Tight-Apartness-Relation : {l1 : Level} (l2 : Level) (A : UU l1) → UU (l1 ⊔ lsuc l2) Tight-Apartness-Relation l2 A = Σ (Apartness-Relation l2 A) (is-tight-Apartness-Relation) module _ {l1 l2 : Level} {A : UU l1} (R : Tight-Apartness-Relation l2 A) where apartness-relation-Tight-Apartness-Relation : Apartness-Relation l2 A apartness-relation-Tight-Apartness-Relation = pr1 R is-tight-apartness-relation-Tight-Apartness-Relation : is-tight-Apartness-Relation apartness-relation-Tight-Apartness-Relation is-tight-apartness-relation-Tight-Apartness-Relation = pr2 R ``` ### Types with tight apartness ```agda Type-With-Tight-Apartness : (l1 l2 : Level) → UU (lsuc l1 ⊔ lsuc l2) Type-With-Tight-Apartness l1 l2 = Σ ( Type-With-Apartness l1 l2) ( λ X → is-tight (rel-apart-Type-With-Apartness X)) module _ {l1 l2 : Level} (X : Type-With-Tight-Apartness l1 l2) where type-with-apartness-Type-With-Tight-Apartness : Type-With-Apartness l1 l2 type-with-apartness-Type-With-Tight-Apartness = pr1 X type-Type-With-Tight-Apartness : UU l1 type-Type-With-Tight-Apartness = type-Type-With-Apartness type-with-apartness-Type-With-Tight-Apartness rel-apart-Type-With-Tight-Apartness : Relation-Prop l2 type-Type-With-Tight-Apartness rel-apart-Type-With-Tight-Apartness = rel-apart-Type-With-Apartness type-with-apartness-Type-With-Tight-Apartness apart-Type-With-Tight-Apartness : Relation l2 type-Type-With-Tight-Apartness apart-Type-With-Tight-Apartness = apart-Type-With-Apartness type-with-apartness-Type-With-Tight-Apartness is-tight-apart-Type-With-Tight-Apartness : is-tight rel-apart-Type-With-Tight-Apartness is-tight-apart-Type-With-Tight-Apartness = pr2 X ``` ## Properties ### The apartness relation of functions into a type with tight apartness is tight ```agda is-tight-apartness-function-into-Type-With-Tight-Apartness : {l1 l2 l3 : Level} {X : UU l1} (Y : Type-With-Tight-Apartness l2 l3) → is-tight ( rel-apart-function-into-Type-With-Apartness X ( type-with-apartness-Type-With-Tight-Apartness Y)) is-tight-apartness-function-into-Type-With-Tight-Apartness Y f g H = eq-htpy ( λ x → is-tight-apart-Type-With-Tight-Apartness Y ( f x) ( g x) ( λ u → H ( unit-trunc-Prop (x , u)))) exp-Type-With-Tight-Apartness : {l1 l2 l3 : Level} (X : UU l1) → Type-With-Tight-Apartness l2 l3 → Type-With-Tight-Apartness (l1 ⊔ l2) (l1 ⊔ l3) pr1 (exp-Type-With-Tight-Apartness X Y) = exp-Type-With-Apartness X (type-with-apartness-Type-With-Tight-Apartness Y) pr2 (exp-Type-With-Tight-Apartness X Y) = is-tight-apartness-function-into-Type-With-Tight-Apartness Y ``` ## References {{#bibliography}} {{#reference MRR88}}