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SSL Commutative_Ring_Ex.thy
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(* Title: HOL/Decision_Procs/ex/Commutative_Ring_Ex.thy
Author: Bernhard Haeupler, Stefan Berghofer *) section \<open>Some examples demonstrating the ring and field methods\<close> theory Commutative_Ring_Ex imports "../Reflective_Field" begin lemma "4 * (x::int) ^ 5 * y ^ 3 * x ^ 2 * 3 + x * z + 3 ^ 5 = 12 * x ^ 7 * y ^ 3 by ring lemma (in cring) assumes "x \ shows "\ \<guillemotleft>12\<guillemotright> \<otimes> x [^] (7::nat) \<otimes> y [^] (3::nat) \<oplus> z \<oti by ring lemma "((x::int) + y) ^ 2 = x ^ 2 + y ^ 2 + 2 * x * y" by ring lemma (in cring) assumes "x \ shows "(x \ by ring lemma "((x::int) + y) ^ 3 = x ^ 3 + y ^ 3 + 3 * x ^ 2 * y + 3 * y ^ 2 * x" by ring lemma (in cring) assumes "x \ shows "(x \ x [^] (3::nat) \<oplus> y [^] (3::nat) \<oplus> \<guillemotleft>3\<guillemotright> \<otimes> x [^] (2: by ring lemma "((x::int) - y) ^ 3 = x ^ 3 + 3 * x * y ^ 2 + (- 3) * y * x ^ 2 - y ^ 3" by ring lemma (in cring) assumes "x \ shows "(x \ x [^] (3::nat) \<oplus> \<guillemotleft>3\<guillemotright> \<otimes> x \<otimes> y [^] (2::nat) \<oplu by ring lemma "((x::int) - y) ^ 2 = x ^ 2 + y ^ 2 - 2 * x * y" by ring lemma (in cring) assumes "x \ shows "(x \ by ring lemma " ((a::int) + b + c) ^ 2 = a ^ 2 + b ^ 2 + c ^ 2 + 2 * a * b + 2 * b * c + by ring lemma (in cring) assumes "a \ shows " (a \ a [^] (2::nat) \<oplus> b [^] (2::nat) \<oplus> c [^] (2::nat) \<oplus> \<guillemotleft>2\<guillemotr by ring lemma "((a::int) - b - c) ^ 2 = a ^ 2 + b ^ 2 + c ^ 2 - 2 * a * b + 2 * b * c - 2 by ring lemma (in cring) assumes "a \ shows "(a \ a [^] (2::nat) \<oplus> b [^] (2::nat) \<oplus> c [^] (2::nat) \<ominus> \<guillemotleft>2\<guillemot by ring lemma "(a::int) * b + a * c = a * (b + c)" by ring lemma (in cring) assumes "a \ shows "a \ by ring lemma "(a::int) ^ 2 - b ^ 2 = (a - b) * (a + b)" by ring lemma (in cring) assumes "a \ shows "a [^] (2::nat) \ by ring lemma "(a::int) ^ 3 - b ^ 3 = (a - b) * (a ^ 2 + a * b + b ^ 2)" by ring lemma (in cring) assumes "a \ shows "a [^] (3::nat) \ by ring lemma "(a::int) ^ 3 + b ^ 3 = (a + b) * (a ^ 2 - a * b + b ^ 2)" by ring lemma (in cring) assumes "a \ shows "a [^] (3::nat) \ by ring lemma "(a::int) ^ 4 - b ^ 4 = (a - b) * (a + b) * (a ^ 2 + b ^ 2)" by ring lemma (in cring) assumes "a \ shows "a [^] (4::nat) \ by ring lemma "(a::int) ^ 10 - b ^ 10 = (a - b) * (a ^ 9 + a ^ 8 * b + a ^ 7 * b ^ 2 + a ^ 6 * b ^ 3 + a ^ 5 * b ^ 4 + a ^ 4 * b ^ 5 + a ^ 3 * b ^ 6 + a ^ 2 * b ^ 7 + a * b ^ 8 + b ^ 9)" by ring lemma (in cring) assumes "a \ shows "a [^] (10::nat) \ (a \<ominus> b) \<otimes> (a [^] (9::nat) \<oplus> a [^] (8::nat) \<otimes> b \<oplus> a [^] (7::nat) \<otim a [^] (6::nat) \<otimes> b [^] (3::nat) \<oplus> a [^] (5::nat) \<otimes> b [^] (4::nat) \<oplus> a [^] (4::nat) \<otimes> b [^] (5::nat) \<oplus> a [^] (3::nat) \<otimes> b [^] (6::nat) \<oplus> a [^] (2::nat) \<otimes> b [^] (7::nat) \<oplus> a \<otimes> b [^] (8::nat) \<oplus> b [^] (9::nat))" by ring lemma "(x::'a::field) \ by field lemma (in field) assumes "x \ shows "x \ by field end ¤ Diese beiden folgenden Angebotsgruppen bietet das Unternehmen0.13Angebot Wie Sie bei der Firma Beratungs- und Dienstleistungen beauftragen können ¤*Eine klare Vorstellung vom Zielzustand |
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2026-03-28