frgrogt3nreg

Description: If a finite friendship graph has an order greater than 3, it cannot be k-regular for any k . (Contributed by Alexander van der Vekens, 9-Oct-2018) (Revised by AV, 4-Jun-2021)

		Ref	Expression
	Hypothesis	frgrreggt1.v	\|- V = ( Vtx ` G )
	Assertion	frgrogt3nreg	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> A. k e. NN0 -. G RegUSGraph k )

Proof

Step	Hyp	Ref	Expression
1		frgrreggt1.v	\|- V = ( Vtx ` G )
2		simp1	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> G e. FriendGraph )
3		simp2	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> V e. Fin )
4		hashcl	\|- ( V e. Fin -> ( # ` V ) e. NN0 )
5		0red	\|- ( ( # ` V ) e. NN0 -> 0 e. RR )
6		3re	\|- 3 e. RR
7	6	a1i	\|- ( ( # ` V ) e. NN0 -> 3 e. RR )
8		nn0re	\|- ( ( # ` V ) e. NN0 -> ( # ` V ) e. RR )
9	5 7 8	3jca	\|- ( ( # ` V ) e. NN0 -> ( 0 e. RR /\ 3 e. RR /\ ( # ` V ) e. RR ) )
10	9	adantr	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( 0 e. RR /\ 3 e. RR /\ ( # ` V ) e. RR ) )
11		3pos	\|- 0 < 3
12	11	a1i	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 0 < 3 )
13		simpr	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 3 < ( # ` V ) )
14		lttr	\|- ( ( 0 e. RR /\ 3 e. RR /\ ( # ` V ) e. RR ) -> ( ( 0 < 3 /\ 3 < ( # ` V ) ) -> 0 < ( # ` V ) ) )
15	14	imp	\|- ( ( ( 0 e. RR /\ 3 e. RR /\ ( # ` V ) e. RR ) /\ ( 0 < 3 /\ 3 < ( # ` V ) ) ) -> 0 < ( # ` V ) )
16	10 12 13 15	syl12anc	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 0 < ( # ` V ) )
17	16	ex	\|- ( ( # ` V ) e. NN0 -> ( 3 < ( # ` V ) -> 0 < ( # ` V ) ) )
18		ltne	\|- ( ( 0 e. RR /\ 0 < ( # ` V ) ) -> ( # ` V ) =/= 0 )
19	5 17 18	syl6an	\|- ( ( # ` V ) e. NN0 -> ( 3 < ( # ` V ) -> ( # ` V ) =/= 0 ) )
20		hasheq0	\|- ( V e. Fin -> ( ( # ` V ) = 0 <-> V = (/) ) )
21	20	necon3bid	\|- ( V e. Fin -> ( ( # ` V ) =/= 0 <-> V =/= (/) ) )
22	21	biimpcd	\|- ( ( # ` V ) =/= 0 -> ( V e. Fin -> V =/= (/) ) )
23	19 22	syl6	\|- ( ( # ` V ) e. NN0 -> ( 3 < ( # ` V ) -> ( V e. Fin -> V =/= (/) ) ) )
24	23	com23	\|- ( ( # ` V ) e. NN0 -> ( V e. Fin -> ( 3 < ( # ` V ) -> V =/= (/) ) ) )
25	4 24	mpcom	\|- ( V e. Fin -> ( 3 < ( # ` V ) -> V =/= (/) ) )
26	25	a1i	\|- ( G e. FriendGraph -> ( V e. Fin -> ( 3 < ( # ` V ) -> V =/= (/) ) ) )
27	26	3imp	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> V =/= (/) )
28	2 3 27	3jca	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> ( G e. FriendGraph /\ V e. Fin /\ V =/= (/) ) )
29	28	ad2antrl	\|- ( ( G RegUSGraph k /\ ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) ) -> ( G e. FriendGraph /\ V e. Fin /\ V =/= (/) ) )
30		simpl	\|- ( ( G RegUSGraph k /\ ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) ) -> G RegUSGraph k )
31	1	frgrregord13	\|- ( ( ( G e. FriendGraph /\ V e. Fin /\ V =/= (/) ) /\ G RegUSGraph k ) -> ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) )
32	29 30 31	syl2anc	\|- ( ( G RegUSGraph k /\ ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) ) -> ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) )
33		1red	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 1 e. RR )
34	6	a1i	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 3 e. RR )
35	8	adantr	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( # ` V ) e. RR )
36		1lt3	\|- 1 < 3
37	36	a1i	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 1 < 3 )
38	33 34 35 37 13	lttrd	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> 1 < ( # ` V ) )
39	33 38	gtned	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( # ` V ) =/= 1 )
40		eqneqall	\|- ( ( # ` V ) = 1 -> ( ( # ` V ) =/= 1 -> -. G RegUSGraph k ) )
41	39 40	syl5com	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( ( # ` V ) = 1 -> -. G RegUSGraph k ) )
42		ltne	\|- ( ( 3 e. RR /\ 3 < ( # ` V ) ) -> ( # ` V ) =/= 3 )
43	7 42	sylan	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( # ` V ) =/= 3 )
44		eqneqall	\|- ( ( # ` V ) = 3 -> ( ( # ` V ) =/= 3 -> -. G RegUSGraph k ) )
45	43 44	syl5com	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( ( # ` V ) = 3 -> -. G RegUSGraph k ) )
46	41 45	jaod	\|- ( ( ( # ` V ) e. NN0 /\ 3 < ( # ` V ) ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) )
47	46	ex	\|- ( ( # ` V ) e. NN0 -> ( 3 < ( # ` V ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) ) )
48	4 47	syl	\|- ( V e. Fin -> ( 3 < ( # ` V ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) ) )
49	48	a1i	\|- ( G e. FriendGraph -> ( V e. Fin -> ( 3 < ( # ` V ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) ) ) )
50	49	3imp	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) )
51	50	ad2antrl	\|- ( ( G RegUSGraph k /\ ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) ) -> ( ( ( # ` V ) = 1 \/ ( # ` V ) = 3 ) -> -. G RegUSGraph k ) )
52	32 51	mpd	\|- ( ( G RegUSGraph k /\ ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) ) -> -. G RegUSGraph k )
53	52	ex	\|- ( G RegUSGraph k -> ( ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) -> -. G RegUSGraph k ) )
54		ax-1	\|- ( -. G RegUSGraph k -> ( ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) -> -. G RegUSGraph k ) )
55	53 54	pm2.61i	\|- ( ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) /\ k e. NN0 ) -> -. G RegUSGraph k )
56	55	ralrimiva	\|- ( ( G e. FriendGraph /\ V e. Fin /\ 3 < ( # ` V ) ) -> A. k e. NN0 -. G RegUSGraph k )

Metamath Proof Explorer

Theorem frgrogt3nreg

Proof