Nuprl Lemma : isr-rep_int_constraint

Nuprl Lemma : isr-rep_int_constraint_step

∀[f:IntConstraints ⟶ IntConstraints]. ∀[p:IntConstraints].
  (unsat(p)) supposing
     ((↑isr(rep_int_constraint_step(f;p))) and
     ((∀p:IntConstraints
         (0 < dim(p)
         ⇒

 (dim(f p) < dim(p) ∨ ((dim(f p) = dim(p) ∈ ℤ) ∧ num-eq-constraints(f p) < num-eq-constraints(p)))))

∧ (∀p:IntConstraints. (unsat(f p) ⇒ unsat(p)))))

Proof

Definitions occuring in Statement : rep_int_constraint_step: rep_int_constraint_step(f;p), num-eq-constraints: num-eq-constraints(p), int-problem-dimension: dim(p), unsat-int-problem: unsat(p), int-constraint-problem: IntConstraints, assert: ↑b, isr: isr(x), less_than: a < b, uimplies: b supposing a, uall: ∀[x:A]. B[x], all: ∀x:A. B[x], implies: P ⇒ Q, or: P ∨ Q, and: P ∧ Q, apply: f a, function: x:A ⟶ B[x], natural_number: $n, int: ℤ, equal: s = t ∈ T
Definitions unfolded in proof : uall: ∀[x:A]. B[x], member: t ∈ T, uimplies: b supposing a, and: P ∧ Q, all: ∀x:A. B[x], nat: ℕ, implies: P ⇒ Q, false: False, ge: i ≥ j , guard: {T}, prop: ℙ, unsat-int-problem: unsat(p), not: ¬A, so_lambda: λ₂x.t[x], subtype_rel: A ⊆r B, so_apply: x[s], decidable: Dec(P), or: P ∨ Q, iff: P ⇐⇒ Q, rev_implies: P ⇐ Q, uiff: uiff(P;Q), subtract: n - m, top: Top, le: A ≤ B, less_than': less_than'(a;b), true: True, sq_stable: SqStable(P), squash: ↓T, exists: ∃x:A. B[x], nat_plus: ℕ⁺, less_than: a < b, int-constraint-problem: IntConstraints, rep_int_constraint_step: rep_int_constraint_step(f;p), callbyvalueall: callbyvalueall, unit: Unit, has-value: (a)↓, has-valueall: has-valueall(a), bool: 𝔹, it: ⋅, btrue: tt, bfalse: ff, sq_type: SQType(T), bnot: ¬_bb, ifthenelse: if b then t else f fi , assert: ↑b, isr: isr(x), satisfies-int-constraint-problem: xs |= p
Lemmas referenced : nat_properties, less_than_transitivity1, less_than_irreflexivity, ge_wf, less_than_wf, satisfies-int-constraint-problem_wf, list_wf, assert_wf, isr_wf, tunion_wf, nat_wf, equal-wf-base-T, unit_wf2, rep_int_constraint_step_wf, int-constraint-problem_wf, int-problem-dimension_wf, decidable__le, subtract_wf, false_wf, not-ge-2, less-iff-le, condition-implies-le, minus-one-mul, zero-add, minus-one-mul-top, minus-add, minus-minus, add-associates, add-swap, add-commutes, add_functionality_wrt_le, add-zero, le-add-cancel, add_nat_wf, le_wf, sq_stable__le, equal_wf, decidable__lt, not-lt-2, add-mul-special, zero-mul, all_wf, or_wf, num-eq-constraints_wf, unsat-int-problem_wf, subtype_rel-equal, base_wf, le_weakening, le_reflexive, one-mul, two-mul, mul-distributes-right, minus-zero, omega-shadow, list_subtype_base, int_subtype_base, equal-wf-T-base, evalall-reduce, union-valueall-type, tunion-valueall-type, product-valueall-type, list-valueall-type, set-valueall-type, int-valueall-type, equal-valueall-type, valueall-type-has-valueall, lt_int_wf, bool_wf, eqtt_to_assert, assert_of_lt_int, top_wf, eqff_to_assert, bool_cases_sqequal, subtype_base_sq, bool_subtype_base, assert-bnot, less_than_transitivity2, true_wf
Rules used in proof : sqequalSubstitution, sqequalTransitivity, computationStep, sqequalReflexivity, isect_memberFormation, introduction, cut, sqequalHypSubstitution, productElimination, thin, lambdaFormation, extract_by_obid, isectElimination, hypothesisEquality, hypothesis, setElimination, rename, intWeakElimination, natural_numberEquality, independent_isectElimination, independent_functionElimination, voidElimination, sqequalRule, lambdaEquality, dependent_functionElimination, intEquality, productEquality, setEquality, baseApply, closedConclusion, baseClosed, applyEquality, because_Cache, addEquality, functionExtensionality, unionElimination, independent_pairFormation, minusEquality, isect_memberEquality, voidEquality, dependent_set_memberEquality, imageMemberEquality, imageElimination, equalityTransitivity, equalitySymmetry, multiplyEquality, functionEquality, dependent_pairFormation, sqequalIntensionalEquality, applyLambdaEquality, promote_hyp, addLevel, levelHypothesis, callbyvalueReduce, equalityElimination, lessCases, sqequalAxiom, instantiate, cumulativity

Latex:
\mforall{}[f:IntConstraints {}\mrightarrow{} IntConstraints]. \mforall{}[p:IntConstraints]. (unsat(p)) supposing ((\muparrow{}isr(rep\_int\_constraint\_step(f;p))) and ((\mforall{}p:IntConstraints (0 < dim(p) {}\mRightarrow{} (dim(f p) < dim(p) \mvee{} ((dim(f p) = dim(p)) \mwedge{} num-eq-constraints(f p) < num-eq-constraints(p))))) \mwedge{} (\mforall{}p:IntConstraints. (unsat(f p) {}\mRightarrow{} unsat(p))))) Date html generated: 2017_04_14-AM-09_10_59 Last ObjectModification: 2017_02_27-PM-03_48_31 Theory : omega Home Index