frgrncvvdeqlem3

Description: Lemma 3 for frgrncvvdeq . The unique neighbor of a vertex (expressed by a restricted iota) is the intersection of the corresponding neighborhoods. (Contributed by Alexander van der Vekens, 18-Dec-2017) (Revised by AV, 10-May-2021) (Proof shortened by AV, 12-Feb-2022)

	Ref	Expression
Hypotheses	frgrncvvdeq.v1	\|- V = ( Vtx ` G )
	frgrncvvdeq.e	\|- E = ( Edg ` G )
	frgrncvvdeq.nx	\|- D = ( G NeighbVtx X )
	frgrncvvdeq.ny	\|- N = ( G NeighbVtx Y )
	frgrncvvdeq.x	\|- ( ph -> X e. V )
	frgrncvvdeq.y	\|- ( ph -> Y e. V )
	frgrncvvdeq.ne	\|- ( ph -> X =/= Y )
	frgrncvvdeq.xy	\|- ( ph -> Y e/ D )
	frgrncvvdeq.f	\|- ( ph -> G e. FriendGraph )
	frgrncvvdeq.a	\|- A = ( x e. D \|-> ( iota_ y e. N { x , y } e. E ) )
Assertion	frgrncvvdeqlem3	\|- ( ( ph /\ x e. D ) -> { ( iota_ y e. N { x , y } e. E ) } = ( ( G NeighbVtx x ) i^i N ) )

Proof

Step	Hyp	Ref	Expression
1		frgrncvvdeq.v1	\|- V = ( Vtx ` G )
2		frgrncvvdeq.e	\|- E = ( Edg ` G )
3		frgrncvvdeq.nx	\|- D = ( G NeighbVtx X )
4		frgrncvvdeq.ny	\|- N = ( G NeighbVtx Y )
5		frgrncvvdeq.x	\|- ( ph -> X e. V )
6		frgrncvvdeq.y	\|- ( ph -> Y e. V )
7		frgrncvvdeq.ne	\|- ( ph -> X =/= Y )
8		frgrncvvdeq.xy	\|- ( ph -> Y e/ D )
9		frgrncvvdeq.f	\|- ( ph -> G e. FriendGraph )
10		frgrncvvdeq.a	\|- A = ( x e. D \|-> ( iota_ y e. N { x , y } e. E ) )
11	4	ineq2i	\|- ( ( G NeighbVtx x ) i^i N ) = ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) )
12	9	adantr	\|- ( ( ph /\ x e. D ) -> G e. FriendGraph )
13	3	eleq2i	\|- ( x e. D <-> x e. ( G NeighbVtx X ) )
14	1	nbgrisvtx	\|- ( x e. ( G NeighbVtx X ) -> x e. V )
15	14	a1i	\|- ( ph -> ( x e. ( G NeighbVtx X ) -> x e. V ) )
16	13 15	syl5bi	\|- ( ph -> ( x e. D -> x e. V ) )
17	16	imp	\|- ( ( ph /\ x e. D ) -> x e. V )
18	6	adantr	\|- ( ( ph /\ x e. D ) -> Y e. V )
19		elnelne2	\|- ( ( x e. D /\ Y e/ D ) -> x =/= Y )
20	8 19	sylan2	\|- ( ( x e. D /\ ph ) -> x =/= Y )
21	20	ancoms	\|- ( ( ph /\ x e. D ) -> x =/= Y )
22	17 18 21	3jca	\|- ( ( ph /\ x e. D ) -> ( x e. V /\ Y e. V /\ x =/= Y ) )
23	1 2	frcond3	\|- ( G e. FriendGraph -> ( ( x e. V /\ Y e. V /\ x =/= Y ) -> E. n e. V ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } ) )
24	12 22 23	sylc	\|- ( ( ph /\ x e. D ) -> E. n e. V ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } )
25		vex	\|- n e. _V
26		elinsn	\|- ( ( n e. _V /\ ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } ) -> ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) )
27	25 26	mpan	\|- ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } -> ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) )
28		frgrusgr	\|- ( G e. FriendGraph -> G e. USGraph )
29	2	nbusgreledg	\|- ( G e. USGraph -> ( n e. ( G NeighbVtx x ) <-> { n , x } e. E ) )
30		prcom	\|- { n , x } = { x , n }
31	30	eleq1i	\|- ( { n , x } e. E <-> { x , n } e. E )
32	29 31	bitrdi	\|- ( G e. USGraph -> ( n e. ( G NeighbVtx x ) <-> { x , n } e. E ) )
33	32	biimpd	\|- ( G e. USGraph -> ( n e. ( G NeighbVtx x ) -> { x , n } e. E ) )
34	9 28 33	3syl	\|- ( ph -> ( n e. ( G NeighbVtx x ) -> { x , n } e. E ) )
35	34	adantr	\|- ( ( ph /\ x e. D ) -> ( n e. ( G NeighbVtx x ) -> { x , n } e. E ) )
36	35	com12	\|- ( n e. ( G NeighbVtx x ) -> ( ( ph /\ x e. D ) -> { x , n } e. E ) )
37	36	adantr	\|- ( ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) -> ( ( ph /\ x e. D ) -> { x , n } e. E ) )
38	37	imp	\|- ( ( ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) /\ ( ph /\ x e. D ) ) -> { x , n } e. E )
39	4	eqcomi	\|- ( G NeighbVtx Y ) = N
40	39	eleq2i	\|- ( n e. ( G NeighbVtx Y ) <-> n e. N )
41	40	biimpi	\|- ( n e. ( G NeighbVtx Y ) -> n e. N )
42	41	adantl	\|- ( ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) -> n e. N )
43	1 2 3 4 5 6 7 8 9 10	frgrncvvdeqlem2	\|- ( ( ph /\ x e. D ) -> E! y e. N { x , y } e. E )
44		preq2	\|- ( y = n -> { x , y } = { x , n } )
45	44	eleq1d	\|- ( y = n -> ( { x , y } e. E <-> { x , n } e. E ) )
46	45	riota2	\|- ( ( n e. N /\ E! y e. N { x , y } e. E ) -> ( { x , n } e. E <-> ( iota_ y e. N { x , y } e. E ) = n ) )
47	42 43 46	syl2an	\|- ( ( ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) /\ ( ph /\ x e. D ) ) -> ( { x , n } e. E <-> ( iota_ y e. N { x , y } e. E ) = n ) )
48	38 47	mpbid	\|- ( ( ( n e. ( G NeighbVtx x ) /\ n e. ( G NeighbVtx Y ) ) /\ ( ph /\ x e. D ) ) -> ( iota_ y e. N { x , y } e. E ) = n )
49	27 48	sylan	\|- ( ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } /\ ( ph /\ x e. D ) ) -> ( iota_ y e. N { x , y } e. E ) = n )
50	49	eqcomd	\|- ( ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } /\ ( ph /\ x e. D ) ) -> n = ( iota_ y e. N { x , y } e. E ) )
51	50	sneqd	\|- ( ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } /\ ( ph /\ x e. D ) ) -> { n } = { ( iota_ y e. N { x , y } e. E ) } )
52		eqeq1	\|- ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } -> ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } <-> { n } = { ( iota_ y e. N { x , y } e. E ) } ) )
53	52	adantr	\|- ( ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } /\ ( ph /\ x e. D ) ) -> ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } <-> { n } = { ( iota_ y e. N { x , y } e. E ) } ) )
54	51 53	mpbird	\|- ( ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } /\ ( ph /\ x e. D ) ) -> ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } )
55	54	ex	\|- ( ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } -> ( ( ph /\ x e. D ) -> ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } ) )
56	55	rexlimivw	\|- ( E. n e. V ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { n } -> ( ( ph /\ x e. D ) -> ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } ) )
57	24 56	mpcom	\|- ( ( ph /\ x e. D ) -> ( ( G NeighbVtx x ) i^i ( G NeighbVtx Y ) ) = { ( iota_ y e. N { x , y } e. E ) } )
58	11 57	eqtr2id	\|- ( ( ph /\ x e. D ) -> { ( iota_ y e. N { x , y } e. E ) } = ( ( G NeighbVtx x ) i^i N ) )

Metamath Proof Explorer

Theorem frgrncvvdeqlem3

Proof