axsegconlem7

Description: Lemma for axsegcon . Show that a particular ratio of distances is in the closed unit interval. (Contributed by Scott Fenton, 18-Sep-2013)

	Ref	Expression
Hypotheses	axsegconlem2.1	$⊢ S = \sum_{p = 1}^{N} {(A (p) - B (p))}^{2}$
	axsegconlem7.2	$⊢ T = \sum_{p = 1}^{N} {(C (p) - D (p))}^{2}$
Assertion	axsegconlem7	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to \frac{\sqrt{S}}{\sqrt{S} + \sqrt{T}} \in [0, 1]$

Proof

Step	Hyp	Ref	Expression
1		axsegconlem2.1	$⊢ S = \sum_{p = 1}^{N} {(A (p) - B (p))}^{2}$
2		axsegconlem7.2	$⊢ T = \sum_{p = 1}^{N} {(C (p) - D (p))}^{2}$
3	2	axsegconlem5	$⊢ (C \in 𝔼 (N) \land D \in 𝔼 (N)) \to 0 \leq \sqrt{T}$
4	3	adantl	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to 0 \leq \sqrt{T}$
5	1	axsegconlem4	$⊢ (A \in 𝔼 (N) \land B \in 𝔼 (N)) \to \sqrt{S} \in ℝ$
6	5	3adant3	$⊢ (A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \to \sqrt{S} \in ℝ$
7	2	axsegconlem4	$⊢ (C \in 𝔼 (N) \land D \in 𝔼 (N)) \to \sqrt{T} \in ℝ$
8		addge01	$⊢ (\sqrt{S} \in ℝ \land \sqrt{T} \in ℝ) \to (0 \leq \sqrt{T} \leftrightarrow \sqrt{S} \leq \sqrt{S} + \sqrt{T})$
9	6 7 8	syl2an	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to (0 \leq \sqrt{T} \leftrightarrow \sqrt{S} \leq \sqrt{S} + \sqrt{T})$
10	4 9	mpbid	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to \sqrt{S} \leq \sqrt{S} + \sqrt{T}$
11	6	adantr	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to \sqrt{S} \in ℝ$
12	1	axsegconlem5	$⊢ (A \in 𝔼 (N) \land B \in 𝔼 (N)) \to 0 \leq \sqrt{S}$
13	12	3adant3	$⊢ (A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \to 0 \leq \sqrt{S}$
14	13	adantr	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to 0 \leq \sqrt{S}$
15		readdcl	$⊢ (\sqrt{S} \in ℝ \land \sqrt{T} \in ℝ) \to \sqrt{S} + \sqrt{T} \in ℝ$
16	6 7 15	syl2an	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to \sqrt{S} + \sqrt{T} \in ℝ$
17		0red	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to 0 \in ℝ$
18	1	axsegconlem6	$⊢ (A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \to 0 < \sqrt{S}$
19	18	adantr	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to 0 < \sqrt{S}$
20	17 11 16 19 10	ltletrd	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to 0 < \sqrt{S} + \sqrt{T}$
21		divelunit	$⊢ ((\sqrt{S} \in ℝ \land 0 \leq \sqrt{S}) \land (\sqrt{S} + \sqrt{T} \in ℝ \land 0 < \sqrt{S} + \sqrt{T})) \to (\frac{\sqrt{S}}{\sqrt{S} + \sqrt{T}} \in [0, 1] \leftrightarrow \sqrt{S} \leq \sqrt{S} + \sqrt{T})$
22	11 14 16 20 21	syl22anc	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to (\frac{\sqrt{S}}{\sqrt{S} + \sqrt{T}} \in [0, 1] \leftrightarrow \sqrt{S} \leq \sqrt{S} + \sqrt{T})$
23	10 22	mpbird	$⊢ ((A \in 𝔼 (N) \land B \in 𝔼 (N) \land A \neq B) \land (C \in 𝔼 (N) \land D \in 𝔼 (N))) \to \frac{\sqrt{S}}{\sqrt{S} + \sqrt{T}} \in [0, 1]$

Metamath Proof Explorer

Theorem axsegconlem7

Proof