# Discrete relaxed Σ-decompositions
```agda
module foundation.discrete-relaxed-sigma-decompositions where
```
<details><summary>Imports</summary>
```agda
open import foundation.action-on-identifications-functions
open import foundation.contractible-types
open import foundation.dependent-pair-types
open import foundation.equivalences
open import foundation.relaxed-sigma-decompositions
open import foundation.type-arithmetic-dependent-pair-types
open import foundation.unit-type
open import foundation.universe-levels
open import foundation-core.equality-dependent-pair-types
open import foundation-core.function-types
open import foundation-core.identity-types
open import foundation-core.propositions
open import foundation-core.subtypes
```
</details>
## Definition
```agda
module _
{l1 : Level} (l2 : Level) (A : UU l1)
where
discrete-Relaxed-Σ-Decomposition :
Relaxed-Σ-Decomposition l1 l2 A
pr1 discrete-Relaxed-Σ-Decomposition = A
pr1 (pr2 discrete-Relaxed-Σ-Decomposition) a = raise-unit l2
pr2 (pr2 discrete-Relaxed-Σ-Decomposition) =
inv-equiv
( equiv-pr1
( λ _ →
is-contr-raise-unit))
module _
{l1 l2 l3 : Level} {A : UU l1}
(D : Relaxed-Σ-Decomposition l2 l3 A)
where
is-discrete-Prop-Relaxed-Σ-Decomposition : Prop (l2 ⊔ l3)
is-discrete-Prop-Relaxed-Σ-Decomposition =
Π-Prop
( indexing-type-Relaxed-Σ-Decomposition D)
( λ x → is-contr-Prop (cotype-Relaxed-Σ-Decomposition D x))
is-discrete-Relaxed-Σ-Decomposition :
UU (l2 ⊔ l3)
is-discrete-Relaxed-Σ-Decomposition =
type-Prop (is-discrete-Prop-Relaxed-Σ-Decomposition)
is-discrete-discrete-Relaxed-Σ-Decomposition :
{l1 l2 : Level} {A : UU l1} →
is-discrete-Relaxed-Σ-Decomposition (discrete-Relaxed-Σ-Decomposition l2 A)
is-discrete-discrete-Relaxed-Σ-Decomposition = λ x → is-contr-raise-unit
type-discrete-Relaxed-Σ-Decomposition :
{l1 l2 l3 : Level} {A : UU l1} → UU (l1 ⊔ lsuc l2 ⊔ lsuc l3)
type-discrete-Relaxed-Σ-Decomposition {l1} {l2} {l3} {A} =
type-subtype (is-discrete-Prop-Relaxed-Σ-Decomposition {l1} {l2} {l3} {A})
```
## Propositions
```agda
module _
{l1 l2 l3 l4 : Level} {A : UU l1}
(D : Relaxed-Σ-Decomposition l2 l3 A)
(is-discrete : is-discrete-Relaxed-Σ-Decomposition D)
where
equiv-discrete-is-discrete-Relaxed-Σ-Decomposition :
equiv-Relaxed-Σ-Decomposition D (discrete-Relaxed-Σ-Decomposition l4 A)
pr1 equiv-discrete-is-discrete-Relaxed-Σ-Decomposition =
( inv-equiv
( right-unit-law-Σ-is-contr is-discrete ∘e
matching-correspondence-Relaxed-Σ-Decomposition D))
pr1 (pr2 equiv-discrete-is-discrete-Relaxed-Σ-Decomposition) x =
( map-equiv (compute-raise-unit l4) ∘
terminal-map (cotype-Relaxed-Σ-Decomposition D x) ,
is-equiv-comp
( map-equiv (compute-raise-unit l4))
( terminal-map (cotype-Relaxed-Σ-Decomposition D x))
( is-equiv-terminal-map-is-contr (is-discrete x))
( is-equiv-map-equiv ( compute-raise-unit l4)))
pr2 (pr2 equiv-discrete-is-discrete-Relaxed-Σ-Decomposition) a =
eq-pair-Σ
( ap ( λ f → map-equiv f a)
( ( left-inverse-law-equiv
( equiv-pr1 is-discrete ∘e
matching-correspondence-Relaxed-Σ-Decomposition D)) ∙
( ( inv
( right-inverse-law-equiv
( equiv-pr1 ( λ _ → is-contr-raise-unit)))))))
( eq-is-contr is-contr-raise-unit)
is-contr-type-discrete-Relaxed-Σ-Decomposition :
{l1 l2 : Level} {A : UU l1} →
is-contr (type-discrete-Relaxed-Σ-Decomposition {l1} {l1} {l2} {A})
pr1 ( is-contr-type-discrete-Relaxed-Σ-Decomposition {l1} {l2} {A}) =
( discrete-Relaxed-Σ-Decomposition l2 A ,
is-discrete-discrete-Relaxed-Σ-Decomposition)
pr2 ( is-contr-type-discrete-Relaxed-Σ-Decomposition {l1} {l2} {A}) =
( λ x →
eq-type-subtype
( is-discrete-Prop-Relaxed-Σ-Decomposition)
( inv
( eq-equiv-Relaxed-Σ-Decomposition
( pr1 x)
( discrete-Relaxed-Σ-Decomposition l2 A)
( equiv-discrete-is-discrete-Relaxed-Σ-Decomposition
( pr1 x)
( pr2 x)))))
```