author | haftmann |
Sat, 08 Sep 2018 08:09:07 +0000 | |
changeset 68940 | 25b431feb2e9 |
parent 68611 | 4bc4b5c0ccfc |
child 70365 | 4df0628e8545 |
permissions | -rw-r--r-- |
63467 | 1 |
(* Title: HOL/NthRoot.thy |
2 |
Author: Jacques D. Fleuriot, 1998 |
|
3 |
Author: Lawrence C Paulson, 2004 |
|
12196 | 4 |
*) |
5 |
||
60758 | 6 |
section \<open>Nth Roots of Real Numbers\<close> |
14324 | 7 |
|
15131 | 8 |
theory NthRoot |
65552
f533820e7248
theories "GCD" and "Binomial" are already included in "Main": this avoids improper imports in applications;
wenzelm
parents:
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diff
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|
9 |
imports Deriv |
15131 | 10 |
begin |
14324 | 11 |
|
63467 | 12 |
|
60758 | 13 |
subsection \<open>Existence of Nth Root\<close> |
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14 |
|
60758 | 15 |
text \<open>Existence follows from the Intermediate Value Theorem\<close> |
14324 | 16 |
|
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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diff
changeset
|
17 |
lemma realpow_pos_nth: |
63467 | 18 |
fixes a :: real |
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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diff
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|
19 |
assumes n: "0 < n" |
63467 | 20 |
and a: "0 < a" |
21 |
shows "\<exists>r>0. r ^ n = a" |
|
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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diff
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|
22 |
proof - |
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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diff
changeset
|
23 |
have "\<exists>r\<ge>0. r \<le> (max 1 a) \<and> r ^ n = a" |
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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diff
changeset
|
24 |
proof (rule IVT) |
63467 | 25 |
show "0 ^ n \<le> a" |
26 |
using n a by (simp add: power_0_left) |
|
27 |
show "0 \<le> max 1 a" |
|
28 |
by simp |
|
29 |
from n have n1: "1 \<le> n" |
|
30 |
by simp |
|
31 |
have "a \<le> max 1 a ^ 1" |
|
32 |
by simp |
|
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
22968
diff
changeset
|
33 |
also have "max 1 a ^ 1 \<le> max 1 a ^ n" |
63467 | 34 |
using n1 by (rule power_increasing) simp |
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
22968
diff
changeset
|
35 |
finally show "a \<le> max 1 a ^ n" . |
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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changeset
|
36 |
show "\<forall>r. 0 \<le> r \<and> r \<le> max 1 a \<longrightarrow> isCont (\<lambda>x. x ^ n) r" |
44289 | 37 |
by simp |
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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|
38 |
qed |
63467 | 39 |
then obtain r where r: "0 \<le> r \<and> r ^ n = a" |
40 |
by fast |
|
41 |
with n a have "r \<noteq> 0" |
|
42 |
by (auto simp add: power_0_left) |
|
43 |
with r have "0 < r \<and> r ^ n = a" |
|
44 |
by simp |
|
45 |
then show ?thesis .. |
|
23009
01c295dd4a36
Prove existence of nth roots using Intermediate Value Theorem
huffman
parents:
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|
46 |
qed |
14325 | 47 |
|
23047 | 48 |
(* Used by Integration/RealRandVar.thy in AFP *) |
49 |
lemma realpow_pos_nth2: "(0::real) < a \<Longrightarrow> \<exists>r>0. r ^ Suc n = a" |
|
63467 | 50 |
by (blast intro: realpow_pos_nth) |
23047 | 51 |
|
63467 | 52 |
text \<open>Uniqueness of nth positive root.\<close> |
53 |
lemma realpow_pos_nth_unique: "0 < n \<Longrightarrow> 0 < a \<Longrightarrow> \<exists>!r. 0 < r \<and> r ^ n = a" for a :: real |
|
54 |
by (auto intro!: realpow_pos_nth simp: power_eq_iff_eq_base) |
|
14324 | 55 |
|
56 |
||
60758 | 57 |
subsection \<open>Nth Root\<close> |
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58 |
|
63467 | 59 |
text \<open> |
60 |
We define roots of negative reals such that \<open>root n (- x) = - root n x\<close>. |
|
61 |
This allows us to omit side conditions from many theorems. |
|
62 |
\<close> |
|
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63 |
|
63467 | 64 |
lemma inj_sgn_power: |
65 |
assumes "0 < n" |
|
66 |
shows "inj (\<lambda>y. sgn y * \<bar>y\<bar>^n :: real)" |
|
67 |
(is "inj ?f") |
|
51483
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modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
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|
68 |
proof (rule injI) |
63467 | 69 |
have x: "(0 < a \<and> b < 0) \<or> (a < 0 \<and> 0 < b) \<Longrightarrow> a \<noteq> b" for a b :: real |
70 |
by auto |
|
71 |
fix x y |
|
72 |
assume "?f x = ?f y" |
|
73 |
with power_eq_iff_eq_base[of n "\<bar>x\<bar>" "\<bar>y\<bar>"] \<open>0 < n\<close> show "x = y" |
|
51483
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modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
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changeset
|
74 |
by (cases rule: linorder_cases[of 0 x, case_product linorder_cases[of 0 y]]) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
75 |
(simp_all add: x) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
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diff
changeset
|
76 |
qed |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
77 |
|
63467 | 78 |
lemma sgn_power_injE: |
79 |
"sgn a * \<bar>a\<bar> ^ n = x \<Longrightarrow> x = sgn b * \<bar>b\<bar> ^ n \<Longrightarrow> 0 < n \<Longrightarrow> a = b" |
|
80 |
for a b :: real |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
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changeset
|
81 |
using inj_sgn_power[THEN injD, of n a b] by simp |
dc39d69774bb
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hoelzl
parents:
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|
82 |
|
63467 | 83 |
definition root :: "nat \<Rightarrow> real \<Rightarrow> real" |
84 |
where "root n x = (if n = 0 then 0 else the_inv (\<lambda>y. sgn y * \<bar>y\<bar>^n) x)" |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
85 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
86 |
lemma root_0 [simp]: "root 0 x = 0" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
87 |
by (simp add: root_def) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
88 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
89 |
lemma root_sgn_power: "0 < n \<Longrightarrow> root n (sgn y * \<bar>y\<bar>^n) = y" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
90 |
using the_inv_f_f[OF inj_sgn_power] by (simp add: root_def) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
91 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
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diff
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|
92 |
lemma sgn_power_root: |
63467 | 93 |
assumes "0 < n" |
94 |
shows "sgn (root n x) * \<bar>(root n x)\<bar>^n = x" |
|
95 |
(is "?f (root n x) = x") |
|
96 |
proof (cases "x = 0") |
|
97 |
case True |
|
98 |
with assms root_sgn_power[of n 0] show ?thesis |
|
99 |
by simp |
|
100 |
next |
|
101 |
case False |
|
102 |
with realpow_pos_nth[OF \<open>0 < n\<close>, of "\<bar>x\<bar>"] |
|
103 |
obtain r where "0 < r" "r ^ n = \<bar>x\<bar>" |
|
104 |
by auto |
|
60758 | 105 |
with \<open>x \<noteq> 0\<close> have S: "x \<in> range ?f" |
51483
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modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
106 |
by (intro image_eqI[of _ _ "sgn x * r"]) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
107 |
(auto simp: abs_mult sgn_mult power_mult_distrib abs_sgn_eq mult_sgn_abs) |
60758 | 108 |
from \<open>0 < n\<close> f_the_inv_into_f[OF inj_sgn_power[OF \<open>0 < n\<close>] this] show ?thesis |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
109 |
by (simp add: root_def) |
63467 | 110 |
qed |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
111 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
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diff
changeset
|
112 |
lemma split_root: "P (root n x) \<longleftrightarrow> (n = 0 \<longrightarrow> P 0) \<and> (0 < n \<longrightarrow> (\<forall>y. sgn y * \<bar>y\<bar>^n = x \<longrightarrow> P y))" |
63558 | 113 |
proof (cases "n = 0") |
114 |
case True |
|
115 |
then show ?thesis by simp |
|
116 |
next |
|
117 |
case False |
|
118 |
then show ?thesis |
|
119 |
by simp (metis root_sgn_power sgn_power_root) |
|
120 |
qed |
|
20687
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huffman
parents:
20515
diff
changeset
|
121 |
|
22956
617140080e6a
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huffman
parents:
22943
diff
changeset
|
122 |
lemma real_root_zero [simp]: "root n 0 = 0" |
51483
dc39d69774bb
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hoelzl
parents:
51478
diff
changeset
|
123 |
by (simp split: split_root add: sgn_zero_iff) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
124 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
125 |
lemma real_root_minus: "root n (- x) = - root n x" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
126 |
by (clarsimp split: split_root elim!: sgn_power_injE simp: sgn_minus) |
22956
617140080e6a
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huffman
parents:
22943
diff
changeset
|
127 |
|
63467 | 128 |
lemma real_root_less_mono: "0 < n \<Longrightarrow> x < y \<Longrightarrow> root n x < root n y" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
129 |
proof (clarsimp split: split_root) |
63467 | 130 |
have *: "0 < b \<Longrightarrow> a < 0 \<Longrightarrow> \<not> a > b" for a b :: real |
131 |
by auto |
|
132 |
fix a b :: real |
|
133 |
assume "0 < n" "sgn a * \<bar>a\<bar> ^ n < sgn b * \<bar>b\<bar> ^ n" |
|
134 |
then show "a < b" |
|
135 |
using power_less_imp_less_base[of a n b] |
|
136 |
power_less_imp_less_base[of "- b" n "- a"] |
|
137 |
by (simp add: sgn_real_def * [of "a ^ n" "- ((- b) ^ n)"] |
|
138 |
split: if_split_asm) |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
139 |
qed |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
140 |
|
63467 | 141 |
lemma real_root_gt_zero: "0 < n \<Longrightarrow> 0 < x \<Longrightarrow> 0 < root n x" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
142 |
using real_root_less_mono[of n 0 x] by simp |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
143 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
144 |
lemma real_root_ge_zero: "0 \<le> x \<Longrightarrow> 0 \<le> root n x" |
63467 | 145 |
using real_root_gt_zero[of n x] |
146 |
by (cases "n = 0") (auto simp add: le_less) |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
147 |
|
63467 | 148 |
lemma real_root_pow_pos: "0 < n \<Longrightarrow> 0 < x \<Longrightarrow> root n x ^ n = x" (* TODO: rename *) |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
149 |
using sgn_power_root[of n x] real_root_gt_zero[of n x] by simp |
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
150 |
|
63467 | 151 |
lemma real_root_pow_pos2 [simp]: "0 < n \<Longrightarrow> 0 \<le> x \<Longrightarrow> root n x ^ n = x" (* TODO: rename *) |
152 |
by (auto simp add: order_le_less real_root_pow_pos) |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
153 |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
154 |
lemma sgn_root: "0 < n \<Longrightarrow> sgn (root n x) = sgn x" |
60867 | 155 |
by (auto split: split_root simp: sgn_real_def) |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
156 |
|
23046 | 157 |
lemma odd_real_root_pow: "odd n \<Longrightarrow> root n x ^ n = x" |
63467 | 158 |
using sgn_power_root[of n x] |
159 |
by (simp add: odd_pos sgn_real_def split: if_split_asm) |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
160 |
|
63467 | 161 |
lemma real_root_power_cancel: "0 < n \<Longrightarrow> 0 \<le> x \<Longrightarrow> root n (x ^ n) = x" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
162 |
using root_sgn_power[of n x] by (auto simp add: le_less power_0_left) |
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
163 |
|
23046 | 164 |
lemma odd_real_root_power_cancel: "odd n \<Longrightarrow> root n (x ^ n) = x" |
63467 | 165 |
using root_sgn_power[of n x] |
166 |
by (simp add: odd_pos sgn_real_def power_0_left split: if_split_asm) |
|
23046 | 167 |
|
63467 | 168 |
lemma real_root_pos_unique: "0 < n \<Longrightarrow> 0 \<le> y \<Longrightarrow> y ^ n = x \<Longrightarrow> root n x = y" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
169 |
using root_sgn_power[of n y] by (auto simp add: le_less power_0_left) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
170 |
|
63467 | 171 |
lemma odd_real_root_unique: "odd n \<Longrightarrow> y ^ n = x \<Longrightarrow> root n x = y" |
172 |
by (erule subst, rule odd_real_root_power_cancel) |
|
23046 | 173 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
174 |
lemma real_root_one [simp]: "0 < n \<Longrightarrow> root n 1 = 1" |
63467 | 175 |
by (simp add: real_root_pos_unique) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
176 |
|
63467 | 177 |
text \<open>Root function is strictly monotonic, hence injective.\<close> |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
178 |
|
63467 | 179 |
lemma real_root_le_mono: "0 < n \<Longrightarrow> x \<le> y \<Longrightarrow> root n x \<le> root n y" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
180 |
by (auto simp add: order_le_less real_root_less_mono) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
181 |
|
63467 | 182 |
lemma real_root_less_iff [simp]: "0 < n \<Longrightarrow> root n x < root n y \<longleftrightarrow> x < y" |
63558 | 183 |
by (cases "x < y") (simp_all add: real_root_less_mono linorder_not_less real_root_le_mono) |
22721
d9be18bd7a28
moved root and sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
22630
diff
changeset
|
184 |
|
63467 | 185 |
lemma real_root_le_iff [simp]: "0 < n \<Longrightarrow> root n x \<le> root n y \<longleftrightarrow> x \<le> y" |
63558 | 186 |
by (cases "x \<le> y") (simp_all add: real_root_le_mono linorder_not_le real_root_less_mono) |
22721
d9be18bd7a28
moved root and sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
22630
diff
changeset
|
187 |
|
63467 | 188 |
lemma real_root_eq_iff [simp]: "0 < n \<Longrightarrow> root n x = root n y \<longleftrightarrow> x = y" |
189 |
by (simp add: order_eq_iff) |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
190 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
191 |
lemmas real_root_gt_0_iff [simp] = real_root_less_iff [where x=0, simplified] |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
192 |
lemmas real_root_lt_0_iff [simp] = real_root_less_iff [where y=0, simplified] |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
193 |
lemmas real_root_ge_0_iff [simp] = real_root_le_iff [where x=0, simplified] |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
194 |
lemmas real_root_le_0_iff [simp] = real_root_le_iff [where y=0, simplified] |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
195 |
lemmas real_root_eq_0_iff [simp] = real_root_eq_iff [where y=0, simplified] |
22721
d9be18bd7a28
moved root and sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
22630
diff
changeset
|
196 |
|
63467 | 197 |
lemma real_root_gt_1_iff [simp]: "0 < n \<Longrightarrow> 1 < root n y \<longleftrightarrow> 1 < y" |
198 |
using real_root_less_iff [where x=1] by simp |
|
23257 | 199 |
|
63467 | 200 |
lemma real_root_lt_1_iff [simp]: "0 < n \<Longrightarrow> root n x < 1 \<longleftrightarrow> x < 1" |
201 |
using real_root_less_iff [where y=1] by simp |
|
202 |
||
203 |
lemma real_root_ge_1_iff [simp]: "0 < n \<Longrightarrow> 1 \<le> root n y \<longleftrightarrow> 1 \<le> y" |
|
204 |
using real_root_le_iff [where x=1] by simp |
|
23257 | 205 |
|
63467 | 206 |
lemma real_root_le_1_iff [simp]: "0 < n \<Longrightarrow> root n x \<le> 1 \<longleftrightarrow> x \<le> 1" |
207 |
using real_root_le_iff [where y=1] by simp |
|
23257 | 208 |
|
63467 | 209 |
lemma real_root_eq_1_iff [simp]: "0 < n \<Longrightarrow> root n x = 1 \<longleftrightarrow> x = 1" |
210 |
using real_root_eq_iff [where y=1] by simp |
|
23257 | 211 |
|
212 |
||
63467 | 213 |
text \<open>Roots of multiplication and division.\<close> |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
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diff
changeset
|
214 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
215 |
lemma real_root_mult: "root n (x * y) = root n x * root n y" |
63467 | 216 |
by (auto split: split_root elim!: sgn_power_injE |
217 |
simp: sgn_mult abs_mult power_mult_distrib) |
|
51483
dc39d69774bb
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hoelzl
parents:
51478
diff
changeset
|
218 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
219 |
lemma real_root_inverse: "root n (inverse x) = inverse (root n x)" |
63467 | 220 |
by (auto split: split_root elim!: sgn_power_injE |
66815 | 221 |
simp: power_inverse) |
51483
dc39d69774bb
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hoelzl
parents:
51478
diff
changeset
|
222 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
223 |
lemma real_root_divide: "root n (x / y) = root n x / root n y" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
224 |
by (simp add: divide_inverse real_root_mult real_root_inverse) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
225 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
226 |
lemma real_root_abs: "0 < n \<Longrightarrow> root n \<bar>x\<bar> = \<bar>root n x\<bar>" |
dc39d69774bb
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hoelzl
parents:
51478
diff
changeset
|
227 |
by (simp add: abs_if real_root_minus) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
228 |
|
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
229 |
lemma real_root_power: "0 < n \<Longrightarrow> root n (x ^ k) = root n x ^ k" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
230 |
by (induct k) (simp_all add: real_root_mult) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
231 |
|
63467 | 232 |
|
233 |
text \<open>Roots of roots.\<close> |
|
23257 | 234 |
|
235 |
lemma real_root_Suc_0 [simp]: "root (Suc 0) x = x" |
|
63467 | 236 |
by (simp add: odd_real_root_unique) |
23257 | 237 |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
238 |
lemma real_root_mult_exp: "root (m * n) x = root m (root n x)" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
239 |
by (auto split: split_root elim!: sgn_power_injE |
63467 | 240 |
simp: sgn_zero_iff sgn_mult power_mult[symmetric] |
241 |
abs_mult power_mult_distrib abs_sgn_eq) |
|
23257 | 242 |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
243 |
lemma real_root_commute: "root m (root n x) = root n (root m x)" |
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57275
diff
changeset
|
244 |
by (simp add: real_root_mult_exp [symmetric] mult.commute) |
23257 | 245 |
|
63467 | 246 |
|
247 |
text \<open>Monotonicity in first argument.\<close> |
|
23257 | 248 |
|
63558 | 249 |
lemma real_root_strict_decreasing: |
250 |
assumes "0 < n" "n < N" "1 < x" |
|
251 |
shows "root N x < root n x" |
|
252 |
proof - |
|
253 |
from assms have "root n (root N x) ^ n < root N (root n x) ^ N" |
|
254 |
by (simp add: real_root_commute power_strict_increasing del: real_root_pow_pos2) |
|
255 |
with assms show ?thesis by simp |
|
256 |
qed |
|
23257 | 257 |
|
63558 | 258 |
lemma real_root_strict_increasing: |
259 |
assumes "0 < n" "n < N" "0 < x" "x < 1" |
|
260 |
shows "root n x < root N x" |
|
261 |
proof - |
|
262 |
from assms have "root N (root n x) ^ N < root n (root N x) ^ n" |
|
263 |
by (simp add: real_root_commute power_strict_decreasing del: real_root_pow_pos2) |
|
264 |
with assms show ?thesis by simp |
|
265 |
qed |
|
23257 | 266 |
|
63467 | 267 |
lemma real_root_decreasing: "0 < n \<Longrightarrow> n < N \<Longrightarrow> 1 \<le> x \<Longrightarrow> root N x \<le> root n x" |
268 |
by (auto simp add: order_le_less real_root_strict_decreasing) |
|
23257 | 269 |
|
63467 | 270 |
lemma real_root_increasing: "0 < n \<Longrightarrow> n < N \<Longrightarrow> 0 \<le> x \<Longrightarrow> x \<le> 1 \<Longrightarrow> root n x \<le> root N x" |
271 |
by (auto simp add: order_le_less real_root_strict_increasing) |
|
23257 | 272 |
|
63467 | 273 |
|
274 |
text \<open>Continuity and derivatives.\<close> |
|
23042
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add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
275 |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
276 |
lemma isCont_real_root: "isCont (root n) x" |
63467 | 277 |
proof (cases "n > 0") |
278 |
case True |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
279 |
let ?f = "\<lambda>y::real. sgn y * \<bar>y\<bar>^n" |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
280 |
have "continuous_on ({0..} \<union> {.. 0}) (\<lambda>x. if 0 < x then x ^ n else - ((-x) ^ n) :: real)" |
63467 | 281 |
using True by (intro continuous_on_If continuous_intros) auto |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
282 |
then have "continuous_on UNIV ?f" |
63467 | 283 |
by (rule continuous_on_cong[THEN iffD1, rotated 2]) (auto simp: not_less le_less True) |
284 |
then have [simp]: "isCont ?f x" for x |
|
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
285 |
by (simp add: continuous_on_eq_continuous_at) |
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
286 |
have "isCont (root n) (?f (root n x))" |
63467 | 287 |
by (rule isCont_inverse_function [where f="?f" and d=1]) (auto simp: root_sgn_power True) |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
288 |
then show ?thesis |
63467 | 289 |
by (simp add: sgn_power_root True) |
290 |
next |
|
291 |
case False |
|
292 |
then show ?thesis |
|
293 |
by (simp add: root_def[abs_def]) |
|
294 |
qed |
|
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
295 |
|
63467 | 296 |
lemma tendsto_real_root [tendsto_intros]: |
61973 | 297 |
"(f \<longlongrightarrow> x) F \<Longrightarrow> ((\<lambda>x. root n (f x)) \<longlongrightarrow> root n x) F" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
298 |
using isCont_tendsto_compose[OF isCont_real_root, of f x F] . |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
299 |
|
63467 | 300 |
lemma continuous_real_root [continuous_intros]: |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
301 |
"continuous F f \<Longrightarrow> continuous F (\<lambda>x. root n (f x))" |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
302 |
unfolding continuous_def by (rule tendsto_real_root) |
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
303 |
|
63467 | 304 |
lemma continuous_on_real_root [continuous_intros]: |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
305 |
"continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. root n (f x))" |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
306 |
unfolding continuous_on_def by (auto intro: tendsto_real_root) |
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
307 |
|
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
308 |
lemma DERIV_real_root: |
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
309 |
assumes n: "0 < n" |
63467 | 310 |
and x: "0 < x" |
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
311 |
shows "DERIV (root n) x :> inverse (real n * root n x ^ (n - Suc 0))" |
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
312 |
proof (rule DERIV_inverse_function) |
63467 | 313 |
show "0 < x" |
314 |
using x . |
|
315 |
show "x < x + 1" |
|
316 |
by simp |
|
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
317 |
show "DERIV (\<lambda>x. x ^ n) (root n x) :> real n * root n x ^ (n - Suc 0)" |
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
318 |
by (rule DERIV_pow) |
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
319 |
show "real n * root n x ^ (n - Suc 0) \<noteq> 0" |
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
320 |
using n x by simp |
63467 | 321 |
show "isCont (root n) x" |
322 |
by (rule isCont_real_root) |
|
68611 | 323 |
qed (use n in auto) |
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
324 |
|
23046 | 325 |
lemma DERIV_odd_real_root: |
326 |
assumes n: "odd n" |
|
63467 | 327 |
and x: "x \<noteq> 0" |
23046 | 328 |
shows "DERIV (root n) x :> inverse (real n * root n x ^ (n - Suc 0))" |
329 |
proof (rule DERIV_inverse_function) |
|
68611 | 330 |
show "x - 1 < x" "x < x + 1" |
331 |
by auto |
|
23046 | 332 |
show "DERIV (\<lambda>x. x ^ n) (root n x) :> real n * root n x ^ (n - Suc 0)" |
333 |
by (rule DERIV_pow) |
|
334 |
show "real n * root n x ^ (n - Suc 0) \<noteq> 0" |
|
335 |
using odd_pos [OF n] x by simp |
|
63467 | 336 |
show "isCont (root n) x" |
337 |
by (rule isCont_real_root) |
|
68611 | 338 |
qed (use n odd_real_root_pow in auto) |
23046 | 339 |
|
31880 | 340 |
lemma DERIV_even_real_root: |
63467 | 341 |
assumes n: "0 < n" |
342 |
and "even n" |
|
343 |
and x: "x < 0" |
|
31880 | 344 |
shows "DERIV (root n) x :> inverse (- real n * root n x ^ (n - Suc 0))" |
345 |
proof (rule DERIV_inverse_function) |
|
63467 | 346 |
show "x - 1 < x" |
347 |
by simp |
|
348 |
show "x < 0" |
|
349 |
using x . |
|
68611 | 350 |
show "- (root n y ^ n) = y" if "x - 1 < y" and "y < 0" for y |
351 |
proof - |
|
352 |
have "root n (-y) ^ n = -y" |
|
353 |
using that \<open>0 < n\<close> by simp |
|
60758 | 354 |
with real_root_minus and \<open>even n\<close> |
31880 | 355 |
show "- (root n y ^ n) = y" by simp |
356 |
qed |
|
357 |
show "DERIV (\<lambda>x. - (x ^ n)) (root n x) :> - real n * root n x ^ (n - Suc 0)" |
|
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
358 |
by (auto intro!: derivative_eq_intros) |
31880 | 359 |
show "- real n * root n x ^ (n - Suc 0) \<noteq> 0" |
360 |
using n x by simp |
|
63467 | 361 |
show "isCont (root n) x" |
362 |
by (rule isCont_real_root) |
|
363 |
qed |
|
31880 | 364 |
|
365 |
lemma DERIV_real_root_generic: |
|
63558 | 366 |
assumes "0 < n" |
367 |
and "x \<noteq> 0" |
|
368 |
and "even n \<Longrightarrow> 0 < x \<Longrightarrow> D = inverse (real n * root n x ^ (n - Suc 0))" |
|
369 |
and "even n \<Longrightarrow> x < 0 \<Longrightarrow> D = - inverse (real n * root n x ^ (n - Suc 0))" |
|
49753 | 370 |
and "odd n \<Longrightarrow> D = inverse (real n * root n x ^ (n - Suc 0))" |
31880 | 371 |
shows "DERIV (root n) x :> D" |
63467 | 372 |
using assms |
63558 | 373 |
by (cases "even n", cases "0 < x") |
374 |
(auto intro: DERIV_real_root[THEN DERIV_cong] |
|
375 |
DERIV_odd_real_root[THEN DERIV_cong] |
|
376 |
DERIV_even_real_root[THEN DERIV_cong]) |
|
31880 | 377 |
|
63467 | 378 |
|
60758 | 379 |
subsection \<open>Square Root\<close> |
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
380 |
|
63467 | 381 |
definition sqrt :: "real \<Rightarrow> real" |
382 |
where "sqrt = root 2" |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
383 |
|
63467 | 384 |
lemma pos2: "0 < (2::nat)" |
385 |
by simp |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
386 |
|
63467 | 387 |
lemma real_sqrt_unique: "y\<^sup>2 = x \<Longrightarrow> 0 \<le> y \<Longrightarrow> sqrt x = y" |
388 |
unfolding sqrt_def by (rule real_root_pos_unique [OF pos2]) |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
389 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
390 |
lemma real_sqrt_abs [simp]: "sqrt (x\<^sup>2) = \<bar>x\<bar>" |
63467 | 391 |
apply (rule real_sqrt_unique) |
63558 | 392 |
apply (rule power2_abs) |
63467 | 393 |
apply (rule abs_ge_zero) |
394 |
done |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
395 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
396 |
lemma real_sqrt_pow2 [simp]: "0 \<le> x \<Longrightarrow> (sqrt x)\<^sup>2 = x" |
63467 | 397 |
unfolding sqrt_def by (rule real_root_pow_pos2 [OF pos2]) |
22856 | 398 |
|
63558 | 399 |
lemma real_sqrt_pow2_iff [simp]: "(sqrt x)\<^sup>2 = x \<longleftrightarrow> 0 \<le> x" |
63467 | 400 |
apply (rule iffI) |
63558 | 401 |
apply (erule subst) |
402 |
apply (rule zero_le_power2) |
|
63467 | 403 |
apply (erule real_sqrt_pow2) |
404 |
done |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
405 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
406 |
lemma real_sqrt_zero [simp]: "sqrt 0 = 0" |
63467 | 407 |
unfolding sqrt_def by (rule real_root_zero) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
408 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
409 |
lemma real_sqrt_one [simp]: "sqrt 1 = 1" |
63467 | 410 |
unfolding sqrt_def by (rule real_root_one [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
411 |
|
56889
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
412 |
lemma real_sqrt_four [simp]: "sqrt 4 = 2" |
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
413 |
using real_sqrt_abs[of 2] by simp |
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
414 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
415 |
lemma real_sqrt_minus: "sqrt (- x) = - sqrt x" |
63467 | 416 |
unfolding sqrt_def by (rule real_root_minus) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
417 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
418 |
lemma real_sqrt_mult: "sqrt (x * y) = sqrt x * sqrt y" |
63467 | 419 |
unfolding sqrt_def by (rule real_root_mult) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
420 |
|
56889
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
421 |
lemma real_sqrt_mult_self[simp]: "sqrt a * sqrt a = \<bar>a\<bar>" |
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
422 |
using real_sqrt_abs[of a] unfolding power2_eq_square real_sqrt_mult . |
48a745e1bde7
avoid the Complex constructor, use the more natural Re/Im view; moved csqrt to Complex.
hoelzl
parents:
56536
diff
changeset
|
423 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
424 |
lemma real_sqrt_inverse: "sqrt (inverse x) = inverse (sqrt x)" |
63467 | 425 |
unfolding sqrt_def by (rule real_root_inverse) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
426 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
427 |
lemma real_sqrt_divide: "sqrt (x / y) = sqrt x / sqrt y" |
63467 | 428 |
unfolding sqrt_def by (rule real_root_divide) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
429 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
430 |
lemma real_sqrt_power: "sqrt (x ^ k) = sqrt x ^ k" |
63467 | 431 |
unfolding sqrt_def by (rule real_root_power [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
432 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
433 |
lemma real_sqrt_gt_zero: "0 < x \<Longrightarrow> 0 < sqrt x" |
63467 | 434 |
unfolding sqrt_def by (rule real_root_gt_zero [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
435 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
436 |
lemma real_sqrt_ge_zero: "0 \<le> x \<Longrightarrow> 0 \<le> sqrt x" |
63467 | 437 |
unfolding sqrt_def by (rule real_root_ge_zero) |
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
438 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
439 |
lemma real_sqrt_less_mono: "x < y \<Longrightarrow> sqrt x < sqrt y" |
63467 | 440 |
unfolding sqrt_def by (rule real_root_less_mono [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
441 |
|
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
442 |
lemma real_sqrt_le_mono: "x \<le> y \<Longrightarrow> sqrt x \<le> sqrt y" |
63467 | 443 |
unfolding sqrt_def by (rule real_root_le_mono [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
444 |
|
63558 | 445 |
lemma real_sqrt_less_iff [simp]: "sqrt x < sqrt y \<longleftrightarrow> x < y" |
63467 | 446 |
unfolding sqrt_def by (rule real_root_less_iff [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
447 |
|
63558 | 448 |
lemma real_sqrt_le_iff [simp]: "sqrt x \<le> sqrt y \<longleftrightarrow> x \<le> y" |
63467 | 449 |
unfolding sqrt_def by (rule real_root_le_iff [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
450 |
|
63558 | 451 |
lemma real_sqrt_eq_iff [simp]: "sqrt x = sqrt y \<longleftrightarrow> x = y" |
63467 | 452 |
unfolding sqrt_def by (rule real_root_eq_iff [OF pos2]) |
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
453 |
|
62381
a6479cb85944
New and revised material for (multivariate) analysis
paulson <lp15@cam.ac.uk>
parents:
62347
diff
changeset
|
454 |
lemma real_less_lsqrt: "0 \<le> x \<Longrightarrow> 0 \<le> y \<Longrightarrow> x < y\<^sup>2 \<Longrightarrow> sqrt x < y" |
a6479cb85944
New and revised material for (multivariate) analysis
paulson <lp15@cam.ac.uk>
parents:
62347
diff
changeset
|
455 |
using real_sqrt_less_iff[of x "y\<^sup>2"] by simp |
a6479cb85944
New and revised material for (multivariate) analysis
paulson <lp15@cam.ac.uk>
parents:
62347
diff
changeset
|
456 |
|
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
457 |
lemma real_le_lsqrt: "0 \<le> x \<Longrightarrow> 0 \<le> y \<Longrightarrow> x \<le> y\<^sup>2 \<Longrightarrow> sqrt x \<le> y" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
458 |
using real_sqrt_le_iff[of x "y\<^sup>2"] by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
459 |
|
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
460 |
lemma real_le_rsqrt: "x\<^sup>2 \<le> y \<Longrightarrow> x \<le> sqrt y" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
461 |
using real_sqrt_le_mono[of "x\<^sup>2" y] by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
462 |
|
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
463 |
lemma real_less_rsqrt: "x\<^sup>2 < y \<Longrightarrow> x < sqrt y" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
464 |
using real_sqrt_less_mono[of "x\<^sup>2" y] by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
465 |
|
65552
f533820e7248
theories "GCD" and "Binomial" are already included in "Main": this avoids improper imports in applications;
wenzelm
parents:
64267
diff
changeset
|
466 |
lemma real_sqrt_power_even: |
63721 | 467 |
assumes "even n" "x \<ge> 0" |
468 |
shows "sqrt x ^ n = x ^ (n div 2)" |
|
469 |
proof - |
|
470 |
from assms obtain k where "n = 2*k" by (auto elim!: evenE) |
|
471 |
with assms show ?thesis by (simp add: power_mult) |
|
472 |
qed |
|
473 |
||
63467 | 474 |
lemma sqrt_le_D: "sqrt x \<le> y \<Longrightarrow> x \<le> y\<^sup>2" |
62131
1baed43f453e
nonneg_Reals, nonpos_Reals, Cauchy integral formula, etc.
paulson
parents:
61973
diff
changeset
|
475 |
by (meson not_le real_less_rsqrt) |
1baed43f453e
nonneg_Reals, nonpos_Reals, Cauchy integral formula, etc.
paulson
parents:
61973
diff
changeset
|
476 |
|
67685
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
477 |
lemma sqrt_ge_absD: "\<bar>x\<bar> \<le> sqrt y \<Longrightarrow> x\<^sup>2 \<le> y" |
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
478 |
using real_sqrt_le_iff[of "x\<^sup>2"] by simp |
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
479 |
|
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
480 |
lemma sqrt_even_pow2: |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
481 |
assumes n: "even n" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
482 |
shows "sqrt (2 ^ n) = 2 ^ (n div 2)" |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
483 |
proof - |
58709
efdc6c533bd3
prefer generic elimination rules for even/odd over specialized unfold rules for nat
haftmann
parents:
57514
diff
changeset
|
484 |
from n obtain m where m: "n = 2 * m" .. |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
485 |
from m have "sqrt (2 ^ n) = sqrt ((2 ^ m)\<^sup>2)" |
57512
cc97b347b301
reduced name variants for assoc and commute on plus and mult
haftmann
parents:
57275
diff
changeset
|
486 |
by (simp only: power_mult[symmetric] mult.commute) |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
487 |
then show ?thesis |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
488 |
using m by simp |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
489 |
qed |
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
490 |
|
53594 | 491 |
lemmas real_sqrt_gt_0_iff [simp] = real_sqrt_less_iff [where x=0, unfolded real_sqrt_zero] |
492 |
lemmas real_sqrt_lt_0_iff [simp] = real_sqrt_less_iff [where y=0, unfolded real_sqrt_zero] |
|
493 |
lemmas real_sqrt_ge_0_iff [simp] = real_sqrt_le_iff [where x=0, unfolded real_sqrt_zero] |
|
494 |
lemmas real_sqrt_le_0_iff [simp] = real_sqrt_le_iff [where y=0, unfolded real_sqrt_zero] |
|
495 |
lemmas real_sqrt_eq_0_iff [simp] = real_sqrt_eq_iff [where y=0, unfolded real_sqrt_zero] |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
496 |
|
53594 | 497 |
lemmas real_sqrt_gt_1_iff [simp] = real_sqrt_less_iff [where x=1, unfolded real_sqrt_one] |
498 |
lemmas real_sqrt_lt_1_iff [simp] = real_sqrt_less_iff [where y=1, unfolded real_sqrt_one] |
|
499 |
lemmas real_sqrt_ge_1_iff [simp] = real_sqrt_le_iff [where x=1, unfolded real_sqrt_one] |
|
500 |
lemmas real_sqrt_le_1_iff [simp] = real_sqrt_le_iff [where y=1, unfolded real_sqrt_one] |
|
501 |
lemmas real_sqrt_eq_1_iff [simp] = real_sqrt_eq_iff [where y=1, unfolded real_sqrt_one] |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
502 |
|
60615
e5fa1d5d3952
Useful lemmas. The theorem concerning swapping the variables in a double integral.
paulson <lp15@cam.ac.uk>
parents:
60141
diff
changeset
|
503 |
lemma sqrt_add_le_add_sqrt: |
e5fa1d5d3952
Useful lemmas. The theorem concerning swapping the variables in a double integral.
paulson <lp15@cam.ac.uk>
parents:
60141
diff
changeset
|
504 |
assumes "0 \<le> x" "0 \<le> y" |
e5fa1d5d3952
Useful lemmas. The theorem concerning swapping the variables in a double integral.
paulson <lp15@cam.ac.uk>
parents:
60141
diff
changeset
|
505 |
shows "sqrt (x + y) \<le> sqrt x + sqrt y" |
63467 | 506 |
by (rule power2_le_imp_le) (simp_all add: power2_sum assms) |
60615
e5fa1d5d3952
Useful lemmas. The theorem concerning swapping the variables in a double integral.
paulson <lp15@cam.ac.uk>
parents:
60141
diff
changeset
|
507 |
|
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
508 |
lemma isCont_real_sqrt: "isCont sqrt x" |
63467 | 509 |
unfolding sqrt_def by (rule isCont_real_root) |
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
510 |
|
63467 | 511 |
lemma tendsto_real_sqrt [tendsto_intros]: |
61973 | 512 |
"(f \<longlongrightarrow> x) F \<Longrightarrow> ((\<lambda>x. sqrt (f x)) \<longlongrightarrow> sqrt x) F" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
513 |
unfolding sqrt_def by (rule tendsto_real_root) |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
514 |
|
63467 | 515 |
lemma continuous_real_sqrt [continuous_intros]: |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
516 |
"continuous F f \<Longrightarrow> continuous F (\<lambda>x. sqrt (f x))" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
517 |
unfolding sqrt_def by (rule continuous_real_root) |
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
518 |
|
63467 | 519 |
lemma continuous_on_real_sqrt [continuous_intros]: |
57155 | 520 |
"continuous_on s f \<Longrightarrow> continuous_on s (\<lambda>x. sqrt (f x))" |
51483
dc39d69774bb
modernized definition of root: use the_inv, handle positive and negative case uniformly, and 0-th root is constant 0
hoelzl
parents:
51478
diff
changeset
|
521 |
unfolding sqrt_def by (rule continuous_on_real_root) |
51478
270b21f3ae0a
move continuous and continuous_on to the HOL image; isCont is an abbreviation for continuous (at x) (isCont is now restricted to a T2 space)
hoelzl
parents:
49962
diff
changeset
|
522 |
|
31880 | 523 |
lemma DERIV_real_sqrt_generic: |
524 |
assumes "x \<noteq> 0" |
|
63467 | 525 |
and "x > 0 \<Longrightarrow> D = inverse (sqrt x) / 2" |
526 |
and "x < 0 \<Longrightarrow> D = - inverse (sqrt x) / 2" |
|
31880 | 527 |
shows "DERIV sqrt x :> D" |
528 |
using assms unfolding sqrt_def |
|
529 |
by (auto intro!: DERIV_real_root_generic) |
|
530 |
||
63467 | 531 |
lemma DERIV_real_sqrt: "0 < x \<Longrightarrow> DERIV sqrt x :> inverse (sqrt x) / 2" |
31880 | 532 |
using DERIV_real_sqrt_generic by simp |
533 |
||
534 |
declare |
|
56381
0556204bc230
merged DERIV_intros, has_derivative_intros into derivative_intros
hoelzl
parents:
56371
diff
changeset
|
535 |
DERIV_real_sqrt_generic[THEN DERIV_chain2, derivative_intros] |
0556204bc230
merged DERIV_intros, has_derivative_intros into derivative_intros
hoelzl
parents:
56371
diff
changeset
|
536 |
DERIV_real_root_generic[THEN DERIV_chain2, derivative_intros] |
23042
492514b39956
add lemmas about continuity and derivatives of roots
huffman
parents:
23009
diff
changeset
|
537 |
|
67685
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
538 |
lemmas has_derivative_real_sqrt[derivative_intros] = DERIV_real_sqrt[THEN DERIV_compose_FDERIV] |
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
539 |
|
63558 | 540 |
lemma not_real_square_gt_zero [simp]: "\<not> 0 < x * x \<longleftrightarrow> x = 0" |
541 |
for x :: real |
|
63467 | 542 |
apply auto |
63558 | 543 |
using linorder_less_linear [where x = x and y = 0] |
63467 | 544 |
apply (simp add: zero_less_mult_iff) |
545 |
done |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
546 |
|
63467 | 547 |
lemma real_sqrt_abs2 [simp]: "sqrt (x * x) = \<bar>x\<bar>" |
548 |
apply (subst power2_eq_square [symmetric]) |
|
549 |
apply (rule real_sqrt_abs) |
|
550 |
done |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
551 |
|
63467 | 552 |
lemma real_inv_sqrt_pow2: "0 < x \<Longrightarrow> (inverse (sqrt x))\<^sup>2 = inverse x" |
553 |
by (simp add: power_inverse) |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
554 |
|
63467 | 555 |
lemma real_sqrt_eq_zero_cancel: "0 \<le> x \<Longrightarrow> sqrt x = 0 \<Longrightarrow> x = 0" |
556 |
by simp |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
557 |
|
63467 | 558 |
lemma real_sqrt_ge_one: "1 \<le> x \<Longrightarrow> 1 \<le> sqrt x" |
559 |
by simp |
|
20687
fedb901be392
move root and sqrt stuff from Transcendental to NthRoot
huffman
parents:
20515
diff
changeset
|
560 |
|
22443 | 561 |
lemma sqrt_divide_self_eq: |
562 |
assumes nneg: "0 \<le> x" |
|
563 |
shows "sqrt x / x = inverse (sqrt x)" |
|
63467 | 564 |
proof (cases "x = 0") |
565 |
case True |
|
566 |
then show ?thesis by simp |
|
22443 | 567 |
next |
63467 | 568 |
case False |
569 |
then have pos: "0 < x" |
|
570 |
using nneg by arith |
|
22443 | 571 |
show ?thesis |
63467 | 572 |
proof (rule right_inverse_eq [THEN iffD1, symmetric]) |
573 |
show "sqrt x / x \<noteq> 0" |
|
574 |
by (simp add: divide_inverse nneg False) |
|
22443 | 575 |
show "inverse (sqrt x) / (sqrt x / x) = 1" |
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
576 |
by (simp add: divide_inverse mult.assoc [symmetric] |
63467 | 577 |
power2_eq_square [symmetric] real_inv_sqrt_pow2 pos False) |
22443 | 578 |
qed |
579 |
qed |
|
580 |
||
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
581 |
lemma real_div_sqrt: "0 \<le> x \<Longrightarrow> x / sqrt x = sqrt x" |
63558 | 582 |
by (cases "x = 0") (simp_all add: sqrt_divide_self_eq [of x] field_simps) |
54413
88a036a95967
add finite_select_induct; move generic lemmas from MV_Analysis/Linear_Algebra to the HOL image
hoelzl
parents:
53594
diff
changeset
|
583 |
|
63558 | 584 |
lemma real_divide_square_eq [simp]: "(r * a) / (r * r) = a / r" |
585 |
for a r :: real |
|
586 |
by (cases "r = 0") (simp_all add: divide_inverse ac_simps) |
|
22721
d9be18bd7a28
moved root and sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
22630
diff
changeset
|
587 |
|
63467 | 588 |
lemma lemma_real_divide_sqrt_less: "0 < u \<Longrightarrow> u / sqrt 2 < u" |
589 |
by (simp add: divide_less_eq) |
|
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
590 |
|
63558 | 591 |
lemma four_x_squared: "4 * x\<^sup>2 = (2 * x)\<^sup>2" |
592 |
for x :: real |
|
63467 | 593 |
by (simp add: power2_eq_square) |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
594 |
|
57275
0ddb5b755cdc
moved lemmas from the proof of the Central Limit Theorem by Jeremy Avigad and Luke Serafin
hoelzl
parents:
57155
diff
changeset
|
595 |
lemma sqrt_at_top: "LIM x at_top. sqrt x :: real :> at_top" |
0ddb5b755cdc
moved lemmas from the proof of the Central Limit Theorem by Jeremy Avigad and Luke Serafin
hoelzl
parents:
57155
diff
changeset
|
596 |
by (rule filterlim_at_top_at_top[where Q="\<lambda>x. True" and P="\<lambda>x. 0 < x" and g="power2"]) |
0ddb5b755cdc
moved lemmas from the proof of the Central Limit Theorem by Jeremy Avigad and Luke Serafin
hoelzl
parents:
57155
diff
changeset
|
597 |
(auto intro: eventually_gt_at_top) |
0ddb5b755cdc
moved lemmas from the proof of the Central Limit Theorem by Jeremy Avigad and Luke Serafin
hoelzl
parents:
57155
diff
changeset
|
598 |
|
63467 | 599 |
|
60758 | 600 |
subsection \<open>Square Root of Sum of Squares\<close> |
22856 | 601 |
|
63558 | 602 |
lemma sum_squares_bound: "2 * x * y \<le> x\<^sup>2 + y\<^sup>2" |
603 |
for x y :: "'a::linordered_field" |
|
55967 | 604 |
proof - |
63467 | 605 |
have "(x - y)\<^sup>2 = x * x - 2 * x * y + y * y" |
55967 | 606 |
by algebra |
63467 | 607 |
then have "0 \<le> x\<^sup>2 - 2 * x * y + y\<^sup>2" |
55967 | 608 |
by (metis sum_power2_ge_zero zero_le_double_add_iff_zero_le_single_add power2_eq_square) |
609 |
then show ?thesis |
|
610 |
by arith |
|
611 |
qed |
|
22856 | 612 |
|
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
613 |
lemma arith_geo_mean: |
63467 | 614 |
fixes u :: "'a::linordered_field" |
615 |
assumes "u\<^sup>2 = x * y" "x \<ge> 0" "y \<ge> 0" |
|
616 |
shows "u \<le> (x + y)/2" |
|
617 |
apply (rule power2_le_imp_le) |
|
618 |
using sum_squares_bound assms |
|
619 |
apply (auto simp: zero_le_mult_iff) |
|
620 |
apply (auto simp: algebra_simps power2_eq_square) |
|
621 |
done |
|
55967 | 622 |
|
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
623 |
lemma arith_geo_mean_sqrt: |
63558 | 624 |
fixes x :: real |
625 |
assumes "x \<ge> 0" "y \<ge> 0" |
|
626 |
shows "sqrt (x * y) \<le> (x + y)/2" |
|
55967 | 627 |
apply (rule arith_geo_mean) |
628 |
using assms |
|
629 |
apply (auto simp: zero_le_mult_iff) |
|
630 |
done |
|
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
631 |
|
63558 | 632 |
lemma real_sqrt_sum_squares_mult_ge_zero [simp]: "0 \<le> sqrt ((x\<^sup>2 + y\<^sup>2) * (xa\<^sup>2 + ya\<^sup>2))" |
55967 | 633 |
by (metis real_sqrt_ge_0_iff split_mult_pos_le sum_power2_ge_zero) |
22856 | 634 |
|
635 |
lemma real_sqrt_sum_squares_mult_squared_eq [simp]: |
|
63467 | 636 |
"(sqrt ((x\<^sup>2 + y\<^sup>2) * (xa\<^sup>2 + ya\<^sup>2)))\<^sup>2 = (x\<^sup>2 + y\<^sup>2) * (xa\<^sup>2 + ya\<^sup>2)" |
44320 | 637 |
by (simp add: zero_le_mult_iff) |
22856 | 638 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
639 |
lemma real_sqrt_sum_squares_eq_cancel: "sqrt (x\<^sup>2 + y\<^sup>2) = x \<Longrightarrow> y = 0" |
63467 | 640 |
by (drule arg_cong [where f = "\<lambda>x. x\<^sup>2"]) simp |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
641 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
642 |
lemma real_sqrt_sum_squares_eq_cancel2: "sqrt (x\<^sup>2 + y\<^sup>2) = y \<Longrightarrow> x = 0" |
63467 | 643 |
by (drule arg_cong [where f = "\<lambda>x. x\<^sup>2"]) simp |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
644 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
645 |
lemma real_sqrt_sum_squares_ge1 [simp]: "x \<le> sqrt (x\<^sup>2 + y\<^sup>2)" |
63467 | 646 |
by (rule power2_le_imp_le) simp_all |
22856 | 647 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
648 |
lemma real_sqrt_sum_squares_ge2 [simp]: "y \<le> sqrt (x\<^sup>2 + y\<^sup>2)" |
63467 | 649 |
by (rule power2_le_imp_le) simp_all |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
650 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
651 |
lemma real_sqrt_ge_abs1 [simp]: "\<bar>x\<bar> \<le> sqrt (x\<^sup>2 + y\<^sup>2)" |
63467 | 652 |
by (rule power2_le_imp_le) simp_all |
22856 | 653 |
|
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
654 |
lemma real_sqrt_ge_abs2 [simp]: "\<bar>y\<bar> \<le> sqrt (x\<^sup>2 + y\<^sup>2)" |
63467 | 655 |
by (rule power2_le_imp_le) simp_all |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
656 |
|
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
657 |
lemma le_real_sqrt_sumsq [simp]: "x \<le> sqrt (x * x + y * y)" |
63467 | 658 |
by (simp add: power2_eq_square [symmetric]) |
23049
11607c283074
moved sqrt lemmas from Transcendental.thy to NthRoot.thy
huffman
parents:
23047
diff
changeset
|
659 |
|
67685
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
660 |
lemma sqrt_sum_squares_le_sum: |
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
661 |
"\<lbrakk>0 \<le> x; 0 \<le> y\<rbrakk> \<Longrightarrow> sqrt (x\<^sup>2 + y\<^sup>2) \<le> x + y" |
68465
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
662 |
by (rule power2_le_imp_le) (simp_all add: power2_sum) |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
663 |
|
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
664 |
lemma L2_set_mult_ineq_lemma: |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
665 |
fixes a b c d :: real |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
666 |
shows "2 * (a * c) * (b * d) \<le> a\<^sup>2 * d\<^sup>2 + b\<^sup>2 * c\<^sup>2" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
667 |
proof - |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
668 |
have "0 \<le> (a * d - b * c)\<^sup>2" by simp |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
669 |
also have "\<dots> = a\<^sup>2 * d\<^sup>2 + b\<^sup>2 * c\<^sup>2 - 2 * (a * d) * (b * c)" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
670 |
by (simp only: power2_diff power_mult_distrib) |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
671 |
also have "\<dots> = a\<^sup>2 * d\<^sup>2 + b\<^sup>2 * c\<^sup>2 - 2 * (a * c) * (b * d)" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
672 |
by simp |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
673 |
finally show "2 * (a * c) * (b * d) \<le> a\<^sup>2 * d\<^sup>2 + b\<^sup>2 * c\<^sup>2" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
674 |
by simp |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
675 |
qed |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
676 |
|
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
677 |
lemma sqrt_sum_squares_le_sum_abs: "sqrt (x\<^sup>2 + y\<^sup>2) \<le> \<bar>x\<bar> + \<bar>y\<bar>" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
678 |
by (rule power2_le_imp_le) (simp_all add: power2_sum) |
67685
bdff8bf0a75b
moved theorems from AFP/Affine_Arithmetic and AFP/Ordinary_Differential_Equations
immler
parents:
66815
diff
changeset
|
679 |
|
22858 | 680 |
lemma real_sqrt_sum_squares_triangle_ineq: |
53015
a1119cf551e8
standardized symbols via "isabelle update_sub_sup", excluding src/Pure and src/Tools/WWW_Find;
wenzelm
parents:
51483
diff
changeset
|
681 |
"sqrt ((a + c)\<^sup>2 + (b + d)\<^sup>2) \<le> sqrt (a\<^sup>2 + b\<^sup>2) + sqrt (c\<^sup>2 + d\<^sup>2)" |
68465
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
682 |
proof - |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
683 |
have "(a * c + b * d) \<le> (sqrt (a\<^sup>2 + b\<^sup>2) * sqrt (c\<^sup>2 + d\<^sup>2))" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
684 |
by (rule power2_le_imp_le) (simp_all add: power2_sum power_mult_distrib ring_distribs L2_set_mult_ineq_lemma add.commute) |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
685 |
then have "(a + c)\<^sup>2 + (b + d)\<^sup>2 \<le> (sqrt (a\<^sup>2 + b\<^sup>2) + sqrt (c\<^sup>2 + d\<^sup>2))\<^sup>2" |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
686 |
by (simp add: power2_sum) |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
687 |
then show ?thesis |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
688 |
by (auto intro: power2_le_imp_le) |
e699ca8e22b7
New material in support of quaternions
paulson <lp15@cam.ac.uk>
parents:
68077
diff
changeset
|
689 |
qed |
22858 | 690 |
|
63467 | 691 |
lemma real_sqrt_sum_squares_less: "\<bar>x\<bar> < u / sqrt 2 \<Longrightarrow> \<bar>y\<bar> < u / sqrt 2 \<Longrightarrow> sqrt (x\<^sup>2 + y\<^sup>2) < u" |
692 |
apply (rule power2_less_imp_less) |
|
63558 | 693 |
apply simp |
694 |
apply (drule power_strict_mono [OF _ abs_ge_zero pos2]) |
|
695 |
apply (drule power_strict_mono [OF _ abs_ge_zero pos2]) |
|
696 |
apply (simp add: power_divide) |
|
63467 | 697 |
apply (drule order_le_less_trans [OF abs_ge_zero]) |
698 |
apply (simp add: zero_less_divide_iff) |
|
699 |
done |
|
23122 | 700 |
|
59741
5b762cd73a8e
Lots of new material on complex-valued functions. Modified simplification of (x/n)^k
paulson <lp15@cam.ac.uk>
parents:
58889
diff
changeset
|
701 |
lemma sqrt2_less_2: "sqrt 2 < (2::real)" |
63467 | 702 |
by (metis not_less not_less_iff_gr_or_eq numeral_less_iff real_sqrt_four |
703 |
real_sqrt_le_iff semiring_norm(75) semiring_norm(78) semiring_norm(85)) |
|
59741
5b762cd73a8e
Lots of new material on complex-valued functions. Modified simplification of (x/n)^k
paulson <lp15@cam.ac.uk>
parents:
58889
diff
changeset
|
704 |
|
64122 | 705 |
lemma sqrt_sum_squares_half_less: |
706 |
"x < u/2 \<Longrightarrow> y < u/2 \<Longrightarrow> 0 \<le> x \<Longrightarrow> 0 \<le> y \<Longrightarrow> sqrt (x\<^sup>2 + y\<^sup>2) < u" |
|
59741
5b762cd73a8e
Lots of new material on complex-valued functions. Modified simplification of (x/n)^k
paulson <lp15@cam.ac.uk>
parents:
58889
diff
changeset
|
707 |
apply (rule real_sqrt_sum_squares_less) |
63558 | 708 |
apply (auto simp add: abs_if field_simps) |
709 |
apply (rule le_less_trans [where y = "x*2"]) |
|
64122 | 710 |
using less_eq_real_def sqrt2_less_2 apply force |
63558 | 711 |
apply assumption |
59741
5b762cd73a8e
Lots of new material on complex-valued functions. Modified simplification of (x/n)^k
paulson <lp15@cam.ac.uk>
parents:
58889
diff
changeset
|
712 |
apply (rule le_less_trans [where y = "y*2"]) |
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
713 |
using less_eq_real_def sqrt2_less_2 mult_le_cancel_left |
63558 | 714 |
apply auto |
59741
5b762cd73a8e
Lots of new material on complex-valued functions. Modified simplification of (x/n)^k
paulson <lp15@cam.ac.uk>
parents:
58889
diff
changeset
|
715 |
done |
61609
77b453bd616f
Coercion "real" now has type nat => real only and is no longer overloaded. Type class "real_of" is gone. Many duplicate theorems removed.
paulson <lp15@cam.ac.uk>
parents:
60867
diff
changeset
|
716 |
|
61969 | 717 |
lemma LIMSEQ_root: "(\<lambda>n. root n n) \<longlonglongrightarrow> 1" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
718 |
proof - |
63040 | 719 |
define x where "x n = root n n - 1" for n |
61969 | 720 |
have "x \<longlonglongrightarrow> sqrt 0" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
721 |
proof (rule tendsto_sandwich[OF _ _ tendsto_const]) |
61969 | 722 |
show "(\<lambda>x. sqrt (2 / x)) \<longlonglongrightarrow> sqrt 0" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
723 |
by (intro tendsto_intros tendsto_divide_0[OF tendsto_const] filterlim_mono[OF filterlim_real_sequentially]) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
724 |
(simp_all add: at_infinity_eq_at_top_bot) |
63467 | 725 |
have "x n \<le> sqrt (2 / real n)" if "2 < n" for n :: nat |
726 |
proof - |
|
727 |
have "1 + (real (n - 1) * n) / 2 * (x n)\<^sup>2 = 1 + of_nat (n choose 2) * (x n)\<^sup>2" |
|
66815 | 728 |
by (auto simp add: choose_two field_char_0_class.of_nat_div mod_eq_0_iff_dvd) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
729 |
also have "\<dots> \<le> (\<Sum>k\<in>{0, 2}. of_nat (n choose k) * x n^k)" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
730 |
by (simp add: x_def) |
68077
ee8c13ae81e9
Some tidying up (mostly regarding summations from 0)
paulson <lp15@cam.ac.uk>
parents:
67685
diff
changeset
|
731 |
also have "\<dots> \<le> (\<Sum>k\<le>n. of_nat (n choose k) * x n^k)" |
63467 | 732 |
using \<open>2 < n\<close> |
64267 | 733 |
by (intro sum_mono2) (auto intro!: mult_nonneg_nonneg zero_le_power simp: x_def le_diff_eq) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
734 |
also have "\<dots> = (x n + 1) ^ n" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
735 |
by (simp add: binomial_ring) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
736 |
also have "\<dots> = n" |
60758 | 737 |
using \<open>2 < n\<close> by (simp add: x_def) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
738 |
finally have "real (n - 1) * (real n / 2 * (x n)\<^sup>2) \<le> real (n - 1) * 1" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
739 |
by simp |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
740 |
then have "(x n)\<^sup>2 \<le> 2 / real n" |
60758 | 741 |
using \<open>2 < n\<close> unfolding mult_le_cancel_left by (simp add: field_simps) |
63467 | 742 |
from real_sqrt_le_mono[OF this] show ?thesis |
743 |
by simp |
|
744 |
qed |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
745 |
then show "eventually (\<lambda>n. x n \<le> sqrt (2 / real n)) sequentially" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
746 |
by (auto intro!: exI[of _ 3] simp: eventually_sequentially) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
747 |
show "eventually (\<lambda>n. sqrt 0 \<le> x n) sequentially" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
748 |
by (auto intro!: exI[of _ 1] simp: eventually_sequentially le_diff_eq x_def) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
749 |
qed |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
750 |
from tendsto_add[OF this tendsto_const[of 1]] show ?thesis |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
751 |
by (simp add: x_def) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
752 |
qed |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
753 |
|
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
754 |
lemma LIMSEQ_root_const: |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
755 |
assumes "0 < c" |
61969 | 756 |
shows "(\<lambda>n. root n c) \<longlonglongrightarrow> 1" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
757 |
proof - |
63467 | 758 |
have ge_1: "(\<lambda>n. root n c) \<longlonglongrightarrow> 1" if "1 \<le> c" for c :: real |
759 |
proof - |
|
63040 | 760 |
define x where "x n = root n c - 1" for n |
61969 | 761 |
have "x \<longlonglongrightarrow> 0" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
762 |
proof (rule tendsto_sandwich[OF _ _ tendsto_const]) |
61969 | 763 |
show "(\<lambda>n. c / n) \<longlonglongrightarrow> 0" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
764 |
by (intro tendsto_divide_0[OF tendsto_const] filterlim_mono[OF filterlim_real_sequentially]) |
63467 | 765 |
(simp_all add: at_infinity_eq_at_top_bot) |
766 |
have "x n \<le> c / n" if "1 < n" for n :: nat |
|
767 |
proof - |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
768 |
have "1 + x n * n = 1 + of_nat (n choose 1) * x n^1" |
63417
c184ec919c70
more lemmas to emphasize {0::nat..(<)n} as canonical representation of intervals on nat
haftmann
parents:
63367
diff
changeset
|
769 |
by (simp add: choose_one) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
770 |
also have "\<dots> \<le> (\<Sum>k\<in>{0, 1}. of_nat (n choose k) * x n^k)" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
771 |
by (simp add: x_def) |
68077
ee8c13ae81e9
Some tidying up (mostly regarding summations from 0)
paulson <lp15@cam.ac.uk>
parents:
67685
diff
changeset
|
772 |
also have "\<dots> \<le> (\<Sum>k\<le>n. of_nat (n choose k) * x n^k)" |
63467 | 773 |
using \<open>1 < n\<close> \<open>1 \<le> c\<close> |
64267 | 774 |
by (intro sum_mono2) |
63467 | 775 |
(auto intro!: mult_nonneg_nonneg zero_le_power simp: x_def le_diff_eq) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
776 |
also have "\<dots> = (x n + 1) ^ n" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
777 |
by (simp add: binomial_ring) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
778 |
also have "\<dots> = c" |
60758 | 779 |
using \<open>1 < n\<close> \<open>1 \<le> c\<close> by (simp add: x_def) |
63467 | 780 |
finally show ?thesis |
781 |
using \<open>1 \<le> c\<close> \<open>1 < n\<close> by (simp add: field_simps) |
|
782 |
qed |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
783 |
then show "eventually (\<lambda>n. x n \<le> c / n) sequentially" |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
784 |
by (auto intro!: exI[of _ 3] simp: eventually_sequentially) |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
785 |
show "eventually (\<lambda>n. 0 \<le> x n) sequentially" |
63467 | 786 |
using \<open>1 \<le> c\<close> |
787 |
by (auto intro!: exI[of _ 1] simp: eventually_sequentially le_diff_eq x_def) |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
788 |
qed |
63467 | 789 |
from tendsto_add[OF this tendsto_const[of 1]] show ?thesis |
790 |
by (simp add: x_def) |
|
791 |
qed |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
792 |
show ?thesis |
63467 | 793 |
proof (cases "1 \<le> c") |
794 |
case True |
|
795 |
with ge_1 show ?thesis by blast |
|
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
796 |
next |
63467 | 797 |
case False |
60758 | 798 |
with \<open>0 < c\<close> have "1 \<le> 1 / c" |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
799 |
by simp |
61969 | 800 |
then have "(\<lambda>n. 1 / root n (1 / c)) \<longlonglongrightarrow> 1 / 1" |
60758 | 801 |
by (intro tendsto_divide tendsto_const ge_1 \<open>1 \<le> 1 / c\<close> one_neq_zero) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
802 |
then show ?thesis |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
803 |
by (rule filterlim_cong[THEN iffD1, rotated 3]) |
63467 | 804 |
(auto intro!: exI[of _ 1] simp: eventually_sequentially real_root_divide) |
60141
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
805 |
qed |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
806 |
qed |
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
807 |
|
833adf7db7d8
New material, mostly about limits. Consolidation.
paulson <lp15@cam.ac.uk>
parents:
59741
diff
changeset
|
808 |
|
22956
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
809 |
text "Legacy theorem names:" |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
810 |
lemmas real_root_pos2 = real_root_power_cancel |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
811 |
lemmas real_root_pos_pos = real_root_gt_zero [THEN order_less_imp_le] |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
812 |
lemmas real_root_pos_pos_le = real_root_ge_zero |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
813 |
lemmas real_sqrt_eq_zero_cancel_iff = real_sqrt_eq_0_iff |
617140080e6a
define roots of negative reals so that many lemmas no longer require side conditions; simplification solves more goals than previously
huffman
parents:
22943
diff
changeset
|
814 |
|
14324 | 815 |
end |