frlmpwfi

Description: Formal linear combinations over Z/2Z are equivalent to finite subsets. MOVABLE (Contributed by Stefan O'Rear, 10-Jul-2015) (Proof shortened by AV, 14-Jun-2020)

	Ref	Expression
Hypotheses	frlmpwfi.r	$⊢ R = ℤ / 2 ℤ$
	frlmpwfi.y	$⊢ Y = R freeLMod I$
	frlmpwfi.b	$⊢ B = {Base}_{Y}$
Assertion	frlmpwfi	$⊢ I \in V \to B \approx (𝒫 I \cap Fin)$

Proof

Step	Hyp	Ref	Expression
1		frlmpwfi.r	$⊢ R = ℤ / 2 ℤ$
2		frlmpwfi.y	$⊢ Y = R freeLMod I$
3		frlmpwfi.b	$⊢ B = {Base}_{Y}$
4	1	fvexi	$⊢ R \in V$
5		eqid	$⊢ {Base}_{R} = {Base}_{R}$
6		eqid	$⊢ 0_{R} = 0_{R}$
7		eqid	$⊢ \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\} = \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\}$
8	2 5 6 7	frlmbas	$⊢ (R \in V \land I \in V) \to \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\} = {Base}_{Y}$
9	4 8	mpan	$⊢ I \in V \to \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\} = {Base}_{Y}$
10	9 3	eqtr4di	$⊢ I \in V \to \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\} = B$
11		eqid	$⊢ \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\} = \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\}$
12		enrefg	$⊢ I \in V \to I \approx I$
13		2nn	$⊢ 2 \in ℕ$
14	1 5	znhash	$⊢ 2 \in ℕ \to \|{Base}_{R}\| = 2$
15	13 14	ax-mp	$⊢ \|{Base}_{R}\| = 2$
16		hash2	$⊢ \|2_{𝑜}\| = 2$
17	15 16	eqtr4i	$⊢ \|{Base}_{R}\| = \|2_{𝑜}\|$
18		2nn0	$⊢ 2 \in ℕ_{0}$
19	15 18	eqeltri	$⊢ \|{Base}_{R}\| \in ℕ_{0}$
20		fvex	$⊢ {Base}_{R} \in V$
21		hashclb	$⊢ {Base}_{R} \in V \to ({Base}_{R} \in Fin \leftrightarrow \|{Base}_{R}\| \in ℕ_{0})$
22	20 21	ax-mp	$⊢ {Base}_{R} \in Fin \leftrightarrow \|{Base}_{R}\| \in ℕ_{0}$
23	19 22	mpbir	$⊢ {Base}_{R} \in Fin$
24		2onn	$⊢ 2_{𝑜} \in ω$
25		nnfi	$⊢ 2_{𝑜} \in ω \to 2_{𝑜} \in Fin$
26	24 25	ax-mp	$⊢ 2_{𝑜} \in Fin$
27		hashen	$⊢ ({Base}_{R} \in Fin \land 2_{𝑜} \in Fin) \to (\|{Base}_{R}\| = \|2_{𝑜}\| \leftrightarrow {Base}_{R} \approx 2_{𝑜})$
28	23 26 27	mp2an	$⊢ \|{Base}_{R}\| = \|2_{𝑜}\| \leftrightarrow {Base}_{R} \approx 2_{𝑜}$
29	17 28	mpbi	$⊢ {Base}_{R} \approx 2_{𝑜}$
30	29	a1i	$⊢ I \in V \to {Base}_{R} \approx 2_{𝑜}$
31	1	zncrng	$⊢ 2 \in ℕ_{0} \to R \in CRing$
32		crngring	$⊢ R \in CRing \to R \in Ring$
33	18 31 32	mp2b	$⊢ R \in Ring$
34	5 6	ring0cl	$⊢ R \in Ring \to 0_{R} \in {Base}_{R}$
35	33 34	mp1i	$⊢ I \in V \to 0_{R} \in {Base}_{R}$
36		2on0	$⊢ 2_{𝑜} \neq \emptyset$
37		2on	$⊢ 2_{𝑜} \in On$
38		on0eln0	$⊢ 2_{𝑜} \in On \to (\emptyset \in 2_{𝑜} \leftrightarrow 2_{𝑜} \neq \emptyset)$
39	37 38	ax-mp	$⊢ \emptyset \in 2_{𝑜} \leftrightarrow 2_{𝑜} \neq \emptyset$
40	36 39	mpbir	$⊢ \emptyset \in 2_{𝑜}$
41	40	a1i	$⊢ I \in V \to \emptyset \in 2_{𝑜}$
42	7 11 12 30 35 41	mapfien2	$⊢ I \in V \to \{x \in ({Base}_{R}^{I}) \| {finSupp}_{0_{R}} (x)\} \approx \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\}$
43	10 42	eqbrtrrd	$⊢ I \in V \to B \approx \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\}$
44	11	pwfi2en	$⊢ I \in V \to \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\} \approx (𝒫 I \cap Fin)$
45		entr	$⊢ (B \approx \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\} \land \{x \in ({2_{𝑜}}^{I}) \| {finSupp}_{\emptyset} (x)\} \approx (𝒫 I \cap Fin)) \to B \approx (𝒫 I \cap Fin)$
46	43 44 45	syl2anc	$⊢ I \in V \to B \approx (𝒫 I \cap Fin)$

Metamath Proof Explorer

Theorem frlmpwfi

Proof