Nuprl Lemma : csm-pres-c1

∀[G:j⊢]. ∀[phi:{G ⊢ _:𝔽}]. ∀[A,T:{G.𝕀 ⊢ _}]. ∀[f:{G.𝕀 ⊢ _:(T ⟶ A)}]. ∀[t:{G.𝕀, (phi)p ⊢ _:T}].

∀[t0:{G ⊢ _:(T)[0(𝕀)][phi |⟶ t[0]]}]. ∀[cA:G.𝕀 ⊢ Compositon(A)]. ∀[H:j⊢]. ∀[s:H j⟶ G].

  ((pres-c1(G;phi;f;t;t0;cA))s
  = pres-c1(H;(phi)s;(f)s+;(t)s+;(t0)s;(cA)s+)
  ∈ {H ⊢ _:((A)s+)[1(𝕀)][(phi)s |⟶ app((f)s+; (t)s+)[1]]})

Proof

Definitions occuring in Statement : pres-c1: pres-c1(G;phi;f;t;t0;cA), csm-comp-structure: (cA)tau, composition-structure: Gamma ⊢ Compositon(A), partial-term-1: u[1], partial-term-0: u[0], constrained-cubical-term: {Gamma ⊢ _:A[phi |⟶ t]}, context-subset: Gamma, phi, face-type: 𝔽, interval-1: 1(𝕀), interval-0: 0(𝕀), interval-type: 𝕀, cubical-app: app(w; u), cubical-fun: (A ⟶ B), csm+: tau+, csm-id-adjoin: [u], cc-fst: p, cube-context-adjoin: X.A, csm-ap-term: (t)s, cubical-term: {X ⊢ _:A}, csm-ap-type: (AF)s, cubical-type: {X ⊢ _}, cube_set_map: A ⟶ B, cubical_set: CubicalSet, uall: ∀[x:A]. B[x], equal: s = t ∈ T
Definitions unfolded in proof : uall: ∀[x:A]. B[x], member: t ∈ T, composition-structure: Gamma ⊢ Compositon(A), squash: ↓T, subtype_rel: A ⊆r B, constrained-cubical-term: {Gamma ⊢ _:A[phi |⟶ t]}, uimplies: b supposing a, csm+: tau+, csm-comp: G o F, cubical-type: {X ⊢ _}, interval-1: 1(𝕀), csm-id-adjoin: [u], csm-ap-type: (AF)s, interval-type: 𝕀, csm-ap: (s)x, csm-id: 1(X), csm-adjoin: (s;u), cc-snd: q, cc-fst: p, constant-cubical-type: (X), pi2: snd(t), compose: f o g, pi1: fst(t), prop: ℙ, true: True, partial-term-1: u[1], csm-ap-term: (t)s, pres-c1: pres-c1(G;phi;f;t;t0;cA), all: ∀x:A. B[x], implies: P ⇒ Q, partial-term-0: u[0], interval-0: 0(𝕀)
Lemmas referenced : pres-c1_wf, context-subset-term-subtype, cube-context-adjoin_wf, interval-type_wf, cubical-fun_wf, csm-ap-term_wf, face-type_wf, csm-face-type, cc-fst_wf_interval, cubical-app_wf_fun, context-subset_wf, thin-context-subset, cubical-fun-subset, subset-cubical-term, context-subset-is-subset, csm-ap-type_wf, cubical_set_cumulativity-i-j, csm+_wf_interval, cube_set_map_cumulativity-i-j, csm-id-adjoin_wf-interval-1, cube_set_map_wf, composition-structure_wf, constrained-cubical-term_wf, csm-id-adjoin_wf-interval-0, cubical-type-cumulativity2, partial-term-0_wf, istype-cubical-term, cubical-type_wf, cubical_set_wf, context-subset-map, equal_wf, squash_wf, true_wf, istype-universe, csm-id-adjoin_wf, interval-1_wf, csm-context-subset-subtype2, cubical-term-eqcd, csm-cubical-app, csm-comp_term, context-adjoin-subset4, csm-cubical-fun, interval-0_wf, csm+_wf, subtype_rel-equal, cubical-term_wf, csm-interval-type
Rules used in proof : cut, introduction, extract_by_obid, sqequalSubstitution, sqequalTransitivity, computationStep, sqequalReflexivity, isect_memberFormation_alt, hypothesis, sqequalHypSubstitution, isectElimination, thin, hypothesisEquality, applyLambdaEquality, setElimination, rename, sqequalRule, imageMemberEquality, baseClosed, imageElimination, equalityTransitivity, equalitySymmetry, applyEquality, instantiate, Error :memTop, because_Cache, dependent_set_memberEquality_alt, equalityIstype, inhabitedIsType, independent_isectElimination, universeIsType, productElimination, hyp_replacement, lambdaEquality_alt, universeEquality, natural_numberEquality, dependent_functionElimination, independent_functionElimination, cumulativity, lambdaFormation_alt

Latex:
\mforall{}[G:j\mvdash{}]. \mforall{}[phi:\{G \mvdash{} \_:\mBbbF{}\}]. \mforall{}[A,T:\{G.\mBbbI{} \mvdash{} \_\}]. \mforall{}[f:\{G.\mBbbI{} \mvdash{} \_:(T {}\mrightarrow{} A)\}]. \mforall{}[t:\{G.\mBbbI{}, (phi)p \mvdash{} \_:T\}]. \mforall{}[t0:\{G \mvdash{} \_:(T)[0(\mBbbI{})][phi |{}\mrightarrow{} t[0]]\}]. \mforall{}[cA:G.\mBbbI{} \mvdash{} Compositon(A)]. \mforall{}[H:j\mvdash{}]. \mforall{}[s:H j{}\mrightarrow{} G]. ((pres-c1(G;phi;f;t;t0;cA))s = pres-c1(H;(phi)s;(f)s+;(t)s+;(t0)s;(cA)s+)) Date html generated: 2020_05_20-PM-05_25_55 Last ObjectModification: 2020_04_21-PM-02_58_28 Theory : cubical!type!theory Home Index