df-qpa

Description: Define the completion of the p -adic rationals. Here we simply define it as the splitting field of a dense sequence of polynomials (using as the n -th set the collection of polynomials with degree less than n and with coefficients < ( p ^ n ) ). Krasner's lemma will then show that all monic polynomials have splitting fields isomorphic to a sufficiently close Eisenstein polynomial from the list, and unramified extensions are generated by the polynomial x ^ ( p ^ n ) - x , which is in the list. Thus, every finite extension of Qp is a subfield of this field extension, so it is algebraically closed. (Contributed by Mario Carneiro, 2-Dec-2014)

		Ref	Expression
	Assertion	df-qpa	$⊢ \overline{ℚ_{p}} = (p \in ℙ ⟼ ⦋ ℚ_{p} (p) / r ⦌ (r polySplitLim (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\})))$

Detailed syntax breakdown

Step	Hyp	Ref	Expression
0		cqpa	$class \overline{ℚ_{p}}$
1		vp	$setvar p$
2		cprime	$class ℙ$
3		cqp	$class ℚ_{p}$
4	1	cv	$setvar p$
5	4 3	cfv	$class ℚ_{p} (p)$
6		vr	$setvar r$
7	6	cv	$setvar r$
8		cpsl	$class polySplitLim$
9		vn	$setvar n$
10		cn	$class ℕ$
11		vf	$setvar f$
12		cpl1	$class {Poly}_{1}$
13	7 12	cfv	$class {Poly}_{1} (r)$
14		cdg1	$class \deg_{1}$
15	11	cv	$setvar f$
16	7 15 14	co	$class (r \deg_{1} f)$
17		cle	$class \leq$
18	9	cv	$setvar n$
19	16 18 17	wbr	$wff r \deg_{1} f \leq n$
20		vd	$setvar d$
21		cco1	$class {coe}_{1}$
22	15 21	cfv	$class {coe}_{1} (f)$
23	22	crn	$class ran {coe}_{1} (f)$
24	20	cv	$setvar d$
25	24	ccnv	$class d^{-1}$
26		cz	$class ℤ$
27		cc0	$class 0$
28	27	csn	$class \{0\}$
29	26 28	cdif	$class (ℤ ∖ \{0\})$
30	25 29	cima	$class d^{-1} [ℤ ∖ \{0\}]$
31		cfz	$class \dots$
32	27 18 31	co	$class (0 \dots n)$
33	30 32	wss	$wff d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n)$
34	33 20 23	wral	$wff \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n)$
35	19 34	wa	$wff (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))$
36	35 11 13	crab	$class \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\}$
37	9 10 36	cmpt	$class (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\})$
38	7 37 8	co	$class (r polySplitLim (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\}))$
39	6 5 38	csb	$class ⦋ ℚ_{p} (p) / r ⦌ (r polySplitLim (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\}))$
40	1 2 39	cmpt	$class (p \in ℙ ⟼ ⦋ ℚ_{p} (p) / r ⦌ (r polySplitLim (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\})))$
41	0 40	wceq	$wff \overline{ℚ_{p}} = (p \in ℙ ⟼ ⦋ ℚ_{p} (p) / r ⦌ (r polySplitLim (n \in ℕ ⟼ \{f \in {Poly}_{1} (r) \| (r \deg_{1} f \leq n \land \forall d \in ran {coe}_{1} (f) d^{-1} [ℤ ∖ \{0\}] \subseteq (0 \dots n))\})))$

Metamath Proof Explorer

Definition df-qpa

Detailed syntax breakdown