df-hdmap

Description: Define map from vectors to functionals in the closed kernel dual space. See hdmapfval description for more details. (Contributed by NM, 15-May-2015)

		Ref	Expression
	Assertion	df-hdmap	$⊢ HDMap = (k \in V ⟼ (w \in LHyp (k) ⟼ \{a \| \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))\}))$

Detailed syntax breakdown

Step	Hyp	Ref	Expression
0		chdma	$class HDMap$
1		vk	$setvar k$
2		cvv	$class V$
3		vw	$setvar w$
4		clh	$class LHyp$
5	1	cv	$setvar k$
6	5 4	cfv	$class LHyp (k)$
7		va	$setvar a$
8		cid	$class I$
9		cbs	$class Base$
10	5 9	cfv	$class {Base}_{k}$
11	8 10	cres	$class ({I ↾}_{{Base}_{k}})$
12		cltrn	$class LTrn$
13	5 12	cfv	$class LTrn (k)$
14	3	cv	$setvar w$
15	14 13	cfv	$class LTrn (k) (w)$
16	8 15	cres	$class ({I ↾}_{LTrn (k) (w)})$
17	11 16	cop	$class ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩$
18		ve	$setvar e$
19		cdvh	$class DVecH$
20	5 19	cfv	$class DVecH (k)$
21	14 20	cfv	$class DVecH (k) (w)$
22		vu	$setvar u$
23	22	cv	$setvar u$
24	23 9	cfv	$class {Base}_{u}$
25		vv	$setvar v$
26		chdma1	$class HDMap1$
27	5 26	cfv	$class HDMap1 (k)$
28	14 27	cfv	$class HDMap1 (k) (w)$
29		vi	$setvar i$
30	7	cv	$setvar a$
31		vt	$setvar t$
32	25	cv	$setvar v$
33		vy	$setvar y$
34		clcd	$class LCDual$
35	5 34	cfv	$class LCDual (k)$
36	14 35	cfv	$class LCDual (k) (w)$
37	36 9	cfv	$class {Base}_{LCDual (k) (w)}$
38		vz	$setvar z$
39	38	cv	$setvar z$
40		clspn	$class LSpan$
41	23 40	cfv	$class LSpan (u)$
42	18	cv	$setvar e$
43	42	csn	$class \{e\}$
44	43 41	cfv	$class LSpan (u) (\{e\})$
45	31	cv	$setvar t$
46	45	csn	$class \{t\}$
47	46 41	cfv	$class LSpan (u) (\{t\})$
48	44 47	cun	$class (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\}))$
49	39 48	wcel	$wff z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\}))$
50	49	wn	$wff \neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\}))$
51	33	cv	$setvar y$
52	29	cv	$setvar i$
53		chvm	$class HVMap$
54	5 53	cfv	$class HVMap (k)$
55	14 54	cfv	$class HVMap (k) (w)$
56	42 55	cfv	$class HVMap (k) (w) (e)$
57	42 56 39	cotp	$class ⟨e, HVMap (k) (w) (e), z⟩$
58	57 52	cfv	$class i (⟨e, HVMap (k) (w) (e), z⟩)$
59	39 58 45	cotp	$class ⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩$
60	59 52	cfv	$class i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩)$
61	51 60	wceq	$wff y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩)$
62	50 61	wi	$wff (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))$
63	62 38 32	wral	$wff \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))$
64	63 33 37	crio	$class (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩)))$
65	31 32 64	cmpt	$class (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
66	30 65	wcel	$wff a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
67	66 29 28	wsbc	$wff \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
68	67 25 24	wsbc	$wff \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
69	68 22 21	wsbc	$wff \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
70	69 18 17	wsbc	$wff \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))$
71	70 7	cab	$class \{a \| \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))\}$
72	3 6 71	cmpt	$class (w \in LHyp (k) ⟼ \{a \| \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))\})$
73	1 2 72	cmpt	$class (k \in V ⟼ (w \in LHyp (k) ⟼ \{a \| \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))\}))$
74	0 73	wceq	$wff HDMap = (k \in V ⟼ (w \in LHyp (k) ⟼ \{a \| \underset{˙}{[} ⟨{I ↾}_{{Base}_{k}}, {I ↾}_{LTrn (k) (w)}⟩ / e \underset{˙}{]} \underset{˙}{[} DVecH (k) (w) / u \underset{˙}{]} \underset{˙}{[} {Base}_{u} / v \underset{˙}{]} \underset{˙}{[} HDMap1 (k) (w) / i \underset{˙}{]} a \in (t \in v ⟼ (ι y \in {Base}_{LCDual (k) (w)} \| \forall z \in v (\neg z \in (LSpan (u) (\{e\}) \cup LSpan (u) (\{t\})) \to y = i (⟨z, i (⟨e, HVMap (k) (w) (e), z⟩), t⟩))))\}))$

Metamath Proof Explorer

Definition df-hdmap

Detailed syntax breakdown