rpnnen1

Description: One half of rpnnen , where we show an injection from the real numbers to sequences of rational numbers. Specifically, we map a real number x to the sequence ( Fx ) : NN --> QQ (see rpnnen1lem6 ) such that ( ( Fx )k ) is the largest rational number with denominator k that is strictly less than x . In this manner, we get a monotonically increasing sequence that converges to x , and since each sequence converges to a unique real number, this mapping from reals to sequences of rational numbers is injective. Note: The NN and QQ existence hypotheses provide for use with either nnex and qex , or nnexALT and qexALT . The proof should not be modified to use any of those 4 theorems. (Contributed by Mario Carneiro, 13-May-2013) (Revised by Mario Carneiro, 16-Jun-2013) (Revised by NM, 15-Aug-2021) (Proof modification is discouraged.)

	Ref	Expression
Hypotheses	rpnnen1.n	$⊢ ℕ \in V$
	rpnnen1.q	$⊢ ℚ \in V$
Assertion	rpnnen1	$⊢ ℝ ≼ (ℚ^{ℕ})$

Proof

Step	Hyp	Ref	Expression
1		rpnnen1.n	$⊢ ℕ \in V$
2		rpnnen1.q	$⊢ ℚ \in V$
3		oveq1	$⊢ m = n \to \frac{m}{k} = \frac{n}{k}$
4	3	breq1d	$⊢ m = n \to (\frac{m}{k} < x \leftrightarrow \frac{n}{k} < x)$
5	4	cbvrabv	$⊢ \{m \in ℤ \| \frac{m}{k} < x\} = \{n \in ℤ \| \frac{n}{k} < x\}$
6		oveq2	$⊢ j = k \to \frac{m}{j} = \frac{m}{k}$
7	6	breq1d	$⊢ j = k \to (\frac{m}{j} < y \leftrightarrow \frac{m}{k} < y)$
8	7	rabbidv	$⊢ j = k \to \{m \in ℤ \| \frac{m}{j} < y\} = \{m \in ℤ \| \frac{m}{k} < y\}$
9	8	supeq1d	$⊢ j = k \to sup (\{m \in ℤ \| \frac{m}{j} < y\} ℝ <) = sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <)$
10		id	$⊢ j = k \to j = k$
11	9 10	oveq12d	$⊢ j = k \to \frac{sup (\{m \in ℤ \| \frac{m}{j} < y\} ℝ <)}{j} = \frac{sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <)}{k}$
12	11	cbvmptv	$⊢ (j \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{j} < y\} ℝ <)}{j}) = (k \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <)}{k})$
13		breq2	$⊢ y = x \to (\frac{m}{k} < y \leftrightarrow \frac{m}{k} < x)$
14	13	rabbidv	$⊢ y = x \to \{m \in ℤ \| \frac{m}{k} < y\} = \{m \in ℤ \| \frac{m}{k} < x\}$
15	14	supeq1d	$⊢ y = x \to sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <) = sup (\{m \in ℤ \| \frac{m}{k} < x\} ℝ <)$
16	15	oveq1d	$⊢ y = x \to \frac{sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <)}{k} = \frac{sup (\{m \in ℤ \| \frac{m}{k} < x\} ℝ <)}{k}$
17	16	mpteq2dv	$⊢ y = x \to (k \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{k} < y\} ℝ <)}{k}) = (k \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{k} < x\} ℝ <)}{k})$
18	12 17	eqtrid	$⊢ y = x \to (j \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{j} < y\} ℝ <)}{j}) = (k \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{k} < x\} ℝ <)}{k})$
19	18	cbvmptv	$⊢ (y \in ℝ ⟼ (j \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{j} < y\} ℝ <)}{j})) = (x \in ℝ ⟼ (k \in ℕ ⟼ \frac{sup (\{m \in ℤ \| \frac{m}{k} < x\} ℝ <)}{k}))$
20	5 19 1 2	rpnnen1lem6	$⊢ ℝ ≼ (ℚ^{ℕ})$

Metamath Proof Explorer

Theorem rpnnen1

Proof