# Propositional maps ```agda module foundation.propositional-maps where open import foundation-core.propositional-maps public ``` <details><summary>Imports</summary> ```agda open import foundation.dependent-pair-types open import foundation.embeddings open import foundation.logical-equivalences open import foundation.truncated-maps open import foundation.universe-levels open import foundation-core.equivalences open import foundation-core.function-types open import foundation-core.homotopies open import foundation-core.propositions open import foundation-core.truncation-levels ``` </details> ## Properties ### Being a propositional map is a property ```agda module _ {l1 l2 : Level} {A : UU l1} {B : UU l2} where is-prop-is-prop-map : (f : A → B) → is-prop (is-prop-map f) is-prop-is-prop-map f = is-prop-is-trunc-map neg-one-𝕋 f is-prop-map-Prop : (A → B) → Prop (l1 ⊔ l2) pr1 (is-prop-map-Prop f) = is-prop-map f pr2 (is-prop-map-Prop f) = is-prop-is-prop-map f ``` ### Being a propositional map is equivalent to being an embedding ```agda module _ {l1 l2 : Level} {A : UU l1} {B : UU l2} where equiv-is-emb-is-prop-map : (f : A → B) → is-prop-map f ≃ is-emb f equiv-is-emb-is-prop-map f = equiv-iff ( is-prop-map-Prop f) ( is-emb-Prop f) ( is-emb-is-prop-map) ( is-prop-map-is-emb) equiv-is-prop-map-is-emb : (f : A → B) → is-emb f ≃ is-prop-map f equiv-is-prop-map-is-emb f = equiv-iff ( is-emb-Prop f) ( is-prop-map-Prop f) ( is-prop-map-is-emb) ( is-emb-is-prop-map) ``` ### Propositional maps are closed under homotopies ```agda module _ {l1 l2 : Level} {A : UU l1} {B : UU l2} {f g : A → B} (H : f ~ g) where is-prop-map-htpy : is-prop-map g → is-prop-map f is-prop-map-htpy = is-trunc-map-htpy neg-one-𝕋 H ``` ### Propositional maps are closed under composition ```agda module _ {l1 l2 l3 : Level} {A : UU l1} {B : UU l2} {X : UU l3} (g : B → X) (h : A → B) where is-prop-map-comp : is-prop-map g → is-prop-map h → is-prop-map (g ∘ h) is-prop-map-comp = is-trunc-map-comp neg-one-𝕋 g h comp-prop-map : {l1 l2 l3 : Level} {A : UU l1} {B : UU l2} {X : UU l3} (g : prop-map B X) (h : prop-map A B) → prop-map A X pr1 (comp-prop-map g h) = pr1 g ∘ pr1 h pr2 (comp-prop-map g h) = is-prop-map-comp (pr1 g) (pr1 h) (pr2 g) (pr2 h) ``` ### In a commuting triangle `f ~ g ∘ h`, if `g` and `h` are propositional maps, then `f` is a propositional map ```agda module _ {l1 l2 l3 : Level} {A : UU l1} {B : UU l2} {X : UU l3} (f : A → X) (g : B → X) (h : A → B) (H : f ~ (g ∘ h)) where is-prop-map-left-map-triangle : is-prop-map g → is-prop-map h → is-prop-map f is-prop-map-left-map-triangle = is-trunc-map-left-map-triangle neg-one-𝕋 f g h H ``` ### In a commuting triangle `f ~ g ∘ h`, if `f` and `g` are propositional maps, then `h` is a propositional map ```agda module _ {l1 l2 l3 : Level} {A : UU l1} {B : UU l2} {X : UU l3} (f : A → X) (g : B → X) (h : A → B) (H : f ~ (g ∘ h)) where is-prop-map-top-map-triangle : is-prop-map g → is-prop-map f → is-prop-map h is-prop-map-top-map-triangle = is-trunc-map-top-map-triangle neg-one-𝕋 f g h H ``` ### If a composite `g ∘ h` and its left factor `g` are propositional maps, then its right factor `h` is a propositional map ```agda module _ {l1 l2 l3 : Level} {A : UU l1} {B : UU l2} {X : UU l3} (g : B → X) (h : A → B) where is-prop-map-right-factor : is-prop-map g → is-prop-map (g ∘ h) → is-prop-map h is-prop-map-right-factor = is-trunc-map-right-factor neg-one-𝕋 g h ``` ### A `-1`-truncated map is `k+1`-truncated ```agda abstract is-trunc-map-is-prop-map : {l1 l2 : Level} (k : 𝕋) {A : UU l1} {B : UU l2} {f : A → B} → is-prop-map f → is-trunc-map (succ-𝕋 k) f is-trunc-map-is-prop-map neg-two-𝕋 H = H is-trunc-map-is-prop-map (succ-𝕋 k) H = is-trunc-map-succ-is-trunc-map (succ-𝕋 k) (is-trunc-map-is-prop-map k H) ```