Nuprl Lemma : disjoint_increasing

Nuprl Lemma : disjoint_increasing_onto

∀[m,n,k:ℕ]. ∀[f:ℕn ⟶ ℕm]. ∀[g:ℕk ⟶ ℕm].
  (m = (n + k) ∈ ℕ) supposing
     ((∀j1:ℕn. ∀j2:ℕk.  (¬((f j1) = (g j2) ∈ ℤ))) and
     (∀i:ℕm. ((∃j:ℕn. (i = (f j) ∈ ℤ)) ∨ (∃j:ℕk. (i = (g j) ∈ ℤ)))) and
     increasing(g;k) and
     increasing(f;n))

Proof

Definitions occuring in Statement : increasing: increasing(f;k), int_seg: {i..j^-}, nat: ℕ, uimplies: b supposing a, uall: ∀[x:A]. B[x], all: ∀x:A. B[x], exists: ∃x:A. B[x], not: ¬A, or: P ∨ Q, apply: f a, function: x:A ⟶ B[x], add: n + m, natural_number: $n, int: ℤ, equal: s = t ∈ T
Definitions unfolded in proof : sq_stable: SqStable(P), bool: 𝔹, unit: Unit, it: ⋅, btrue: tt, ifthenelse: if b then t else f fi , bfalse: ff, bnot: ¬_bb, assert: ↑b, rev_implies: P ⇐ Q, iff: P ⇐⇒ Q, le: A ≤ B, subtract: n - m, sq_type: SQType(T), nat_plus: ℕ⁺, less_than: a < b, squash: ↓T, less_than': less_than'(a;b), true: True, guard: {T}, inject: Inj(A;B;f), pi1: fst(t), uiff: uiff(P;Q), lelt: i ≤ j < k, ge: i ≥ j , decidable: Dec(P), satisfiable_int_formula: satisfiable_int_formula(fmla), top: Top, and: P ∧ Q, uall: ∀[x:A]. B[x], member: t ∈ T, uimplies: b supposing a, all: ∀x:A. B[x], nat: ℕ, not: ¬A, implies: P ⇒ Q, subtype_rel: A ⊆r B, int_seg: {i..j^-}, so_lambda: λ₂x.t[x], so_apply: x[s], false: False, or: P ∨ Q, exists: ∃x:A. B[x], prop: ℙ
Lemmas referenced : le_antisymmetry, subtract_nat_wf, not-lt-2, mul-swap, int_seg_subtype, istype-false, equal_functionality_wrt_subtype_rel2, not-le-2, sq_stable__le, increasing_inj, equal-wf-base, le_int_wf, bnot_wf, uiff_transitivity, assert_functionality_wrt_uiff, bnot_of_lt_int, assert_of_le_int, lt_int_wf, eqtt_to_assert, assert_of_lt_int, eqff_to_assert, bool_cases_sqequal, bool_wf, bool_subtype_base, assert-bnot, iff_weakening_uiff, assert_wf, less_than_wf, add-is-int-iff, minus-one-mul-top, mul-associates, mul-distributes, le-add-cancel, le_weakening2, istype-sqequal, less_than_transitivity1, less_than_irreflexivity, add-commutes, add-associates, minus-add, minus-one-mul, add-swap, add-mul-special, two-mul, mul-distributes-right, zero-mul, zero-add, add-zero, one-mul, subtype_base_sq, add_functionality_wrt_le, le_reflexive, less-iff-le, omega-shadow, decidable__equal_int, intformeq_wf, int_formula_prop_eq_lemma, le_wf, add-member-int_seg1, int_seg_properties, subtract_wf, itermSubtract_wf, int_term_value_subtract_lemma, decidable__lt, intformless_wf, int_formula_prop_less_lemma, istype-less_than, inject_wf, injection_le, nat_properties, decidable__le, full-omega-unsat, intformand_wf, intformnot_wf, intformle_wf, itermConstant_wf, itermAdd_wf, itermVar_wf, int_formula_prop_and_lemma, int_formula_prop_not_lemma, int_formula_prop_le_lemma, int_term_value_constant_lemma, int_term_value_add_lemma, int_term_value_var_lemma, int_formula_prop_wf, istype-le, int_seg_wf, istype-int, set_subtype_base, lelt_wf, int_subtype_base, istype-void, increasing_wf, istype-nat
Rules used in proof : dependent_set_memberEquality, imageElimination, equalityElimination, promote_hyp, multiplyEquality, instantiate, cumulativity, minusEquality, imageMemberEquality, applyLambdaEquality, baseApply, baseClosed, Error :lambdaFormation_alt, productElimination, Error :dependent_set_memberEquality_alt, addEquality, dependent_functionElimination, unionElimination, approximateComputation, independent_functionElimination, Error :dependent_pairFormation_alt, int_eqEquality, voidElimination, independent_pairFormation, sqequalSubstitution, sqequalTransitivity, computationStep, sqequalReflexivity, Error :isect_memberFormation_alt, introduction, cut, hypothesis, sqequalRule, Error :functionIsType, Error :universeIsType, extract_by_obid, sqequalHypSubstitution, isectElimination, thin, natural_numberEquality, setElimination, rename, hypothesisEquality, Error :equalityIstype, applyEquality, intEquality, Error :lambdaEquality_alt, independent_isectElimination, sqequalBase, equalitySymmetry, Error :isect_memberEquality_alt, axiomEquality, Error :isectIsTypeImplies, Error :inhabitedIsType, Error :unionIsType, Error :productIsType, because_Cache, functionExtensionality, equalityTransitivity, closedConclusion

Latex:
\mforall{}[m,n,k:\mBbbN{}]. \mforall{}[f:\mBbbN{}n {}\mrightarrow{} \mBbbN{}m]. \mforall{}[g:\mBbbN{}k {}\mrightarrow{} \mBbbN{}m]. (m = (n + k)) supposing ((\mforall{}j1:\mBbbN{}n. \mforall{}j2:\mBbbN{}k. (\mneg{}((f j1) = (g j2)))) and (\mforall{}i:\mBbbN{}m. ((\mexists{}j:\mBbbN{}n. (i = (f j))) \mvee{} (\mexists{}j:\mBbbN{}k. (i = (g j))))) and increasing(g;k) and increasing(f;n)) Date html generated: 2019_06_20-PM-02_12_27 Last ObjectModification: 2019_06_20-PM-02_09_00 Theory : int_2 Home Index