Nuprl Lemma : Cauchy-Schwarz1-strict-iff

n:ℕ. ∀x,y:ℕ1 ⟶ ℝ.
  (∃i,j:ℕ1. x[j] y[i] ≠ x[i] y[j]
  ⇐⇒ {x[i] y[i] 0≤i≤n} * Σ{x[i] y[i] 0≤i≤n}) < {x[i] x[i] 0≤i≤n} * Σ{y[i] y[i] 0≤i≤n}))


Proof



Definitions occuring in Statement :  rsum: Σ{x[k] n≤k≤m} rneq: x ≠ y rless: x < y rmul: b real: int_seg: {i..j-} nat: so_apply: x[s] all: x:A. B[x] exists: x:A. B[x] iff: ⇐⇒ Q function: x:A ⟶ B[x] add: m natural_number: $n
Definitions unfolded in proof :  all: x:A. B[x] member: t ∈ T iff: ⇐⇒ Q and: P ∧ Q implies:  Q prop: uall: [x:A]. B[x] nat: so_lambda: λ2x.t[x] so_apply: x[s] rev_implies:  Q less_than: a < b squash: T less_than': less_than'(a;b) true: True uimplies: supposing a uiff: uiff(P;Q) req_int_terms: t1 ≡ t2 false: False not: ¬A top: Top int_seg: {i..j-} lelt: i ≤ j < k guard: {T} rless: x < y sq_exists: x:{A| B[x]} nat_plus: + ge: i ≥  decidable: Dec(P) or: P ∨ Q satisfiable_int_formula: satisfiable_int_formula(fmla) exists: x:A. B[x] le: A ≤ B pointwise-req: x[k] y[k] for k ∈ [n,m] rev_uimplies: rev_uimplies(P;Q) pointwise-rleq: x[k] ≤ y[k] for k ∈ [n,m] rneq: x ≠ y
Lemmas referenced :  Cauchy-Schwarz1-strict exists_wf int_seg_wf rneq_wf rmul_wf rmul_preserves_rless rsum_wf int-to-real_wf rless-int rless_functionality rmul_comm rless_wf real_wf nat_wf radd_wf itermSubtract_wf itermAdd_wf itermMultiply_wf itermVar_wf itermConstant_wf req-iff-rsub-is-0 req_weakening real_polynomial_null real_term_value_sub_lemma real_term_value_add_lemma real_term_value_mul_lemma real_term_value_var_lemma real_term_value_const_lemma int_seg_properties nat_plus_properties nat_properties decidable__lt full-omega-unsat intformand_wf intformnot_wf intformless_wf intformle_wf int_formula_prop_and_lemma int_formula_prop_not_lemma int_formula_prop_less_lemma int_term_value_var_lemma int_term_value_add_lemma int_term_value_constant_lemma int_formula_prop_le_lemma int_formula_prop_wf lelt_wf le_wf rmul_functionality rsum_product radd_functionality req_transitivity req_inversion rsum_linearity2 rsum_functionality2 rsum_linearity1 rless-implies-rless rsub_wf rsum_linearity-rsub rsum_functionality rnexp_wf false_wf req_functionality rnexp2 rsum-of-nonneg-positive-iff rsum_nonneg rnexp2-nonneg equal_wf rneq-iff-rabs rabs_wf rabs-positive-iff rmul-is-positive
Rules used in proof :  cut introduction extract_by_obid sqequalSubstitution sqequalTransitivity computationStep sqequalReflexivity lambdaFormation hypothesis sqequalHypSubstitution dependent_functionElimination thin hypothesisEquality independent_pairFormation independent_functionElimination isectElimination natural_numberEquality addEquality setElimination rename because_Cache sqequalRule lambdaEquality applyEquality functionExtensionality productElimination imageMemberEquality baseClosed independent_isectElimination functionEquality addLevel impliesFunctionality approximateComputation int_eqEquality intEquality isect_memberEquality voidElimination voidEquality dependent_set_memberEquality unionElimination dependent_pairFormation equalityTransitivity equalitySymmetry inrFormation inlFormation
Latex:
\mforall{}n:\mBbbN{}.  \mforall{}x,y:\mBbbN{}n  +  1  {}\mrightarrow{}  \mBbbR{}.
    (\mexists{}i,j:\mBbbN{}n  +  1.  x[j]  *  y[i]  \mneq{}  x[i]  *  y[j]
    \mLeftarrow{}{}\mRightarrow{}  (\mSigma{}\{x[i]  *  y[i]  |  0\mleq{}i\mleq{}n\}  *  \mSigma{}\{x[i]  *  y[i]  |  0\mleq{}i\mleq{}n\})  <  (\mSigma{}\{x[i]  *  x[i]  |  0\mleq{}i\mleq{}n\}
            *  \mSigma{}\{y[i]  *  y[i]  |  0\mleq{}i\mleq{}n\}))


Date html generated: 2017_10_03-AM-09_04_29
Last ObjectModification: 2017_06_19-PM-03_54_47

Theory : reals


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