isumgr

Description: The property of being an undirected multigraph. (Contributed by AV, 24-Nov-2020)

	Ref	Expression
Hypotheses	isumgr.v	\|- V = ( Vtx ` G )
	isumgr.e	\|- E = ( iEdg ` G )
Assertion	isumgr	\|- ( G e. U -> ( G e. UMGraph <-> E : dom E --> { x e. ( ~P V \ { (/) } ) \| ( # ` x ) = 2 } ) )

Proof

Step	Hyp	Ref	Expression
1		isumgr.v	\|- V = ( Vtx ` G )
2		isumgr.e	\|- E = ( iEdg ` G )
3		df-umgr	\|- UMGraph = { g \| [. ( Vtx ` g ) / v ]. [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } }
4	3	eleq2i	\|- ( G e. UMGraph <-> G e. { g \| [. ( Vtx ` g ) / v ]. [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } } )
5		fveq2	\|- ( h = G -> ( iEdg ` h ) = ( iEdg ` G ) )
6	5 2	eqtr4di	\|- ( h = G -> ( iEdg ` h ) = E )
7	5	dmeqd	\|- ( h = G -> dom ( iEdg ` h ) = dom ( iEdg ` G ) )
8	2	eqcomi	\|- ( iEdg ` G ) = E
9	8	dmeqi	\|- dom ( iEdg ` G ) = dom E
10	7 9	eqtrdi	\|- ( h = G -> dom ( iEdg ` h ) = dom E )
11		fveq2	\|- ( h = G -> ( Vtx ` h ) = ( Vtx ` G ) )
12	11 1	eqtr4di	\|- ( h = G -> ( Vtx ` h ) = V )
13	12	pweqd	\|- ( h = G -> ~P ( Vtx ` h ) = ~P V )
14	13	difeq1d	\|- ( h = G -> ( ~P ( Vtx ` h ) \ { (/) } ) = ( ~P V \ { (/) } ) )
15	14	rabeqdv	\|- ( h = G -> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } = { x e. ( ~P V \ { (/) } ) \| ( # ` x ) = 2 } )
16	6 10 15	feq123d	\|- ( h = G -> ( ( iEdg ` h ) : dom ( iEdg ` h ) --> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } <-> E : dom E --> { x e. ( ~P V \ { (/) } ) \| ( # ` x ) = 2 } ) )
17		fvexd	\|- ( g = h -> ( Vtx ` g ) e. _V )
18		fveq2	\|- ( g = h -> ( Vtx ` g ) = ( Vtx ` h ) )
19		fvexd	\|- ( ( g = h /\ v = ( Vtx ` h ) ) -> ( iEdg ` g ) e. _V )
20		fveq2	\|- ( g = h -> ( iEdg ` g ) = ( iEdg ` h ) )
21	20	adantr	\|- ( ( g = h /\ v = ( Vtx ` h ) ) -> ( iEdg ` g ) = ( iEdg ` h ) )
22		simpr	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> e = ( iEdg ` h ) )
23	22	dmeqd	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> dom e = dom ( iEdg ` h ) )
24		pweq	\|- ( v = ( Vtx ` h ) -> ~P v = ~P ( Vtx ` h ) )
25	24	ad2antlr	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> ~P v = ~P ( Vtx ` h ) )
26	25	difeq1d	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> ( ~P v \ { (/) } ) = ( ~P ( Vtx ` h ) \ { (/) } ) )
27	26	rabeqdv	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } = { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } )
28	22 23 27	feq123d	\|- ( ( ( g = h /\ v = ( Vtx ` h ) ) /\ e = ( iEdg ` h ) ) -> ( e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } <-> ( iEdg ` h ) : dom ( iEdg ` h ) --> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } ) )
29	19 21 28	sbcied2	\|- ( ( g = h /\ v = ( Vtx ` h ) ) -> ( [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } <-> ( iEdg ` h ) : dom ( iEdg ` h ) --> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } ) )
30	17 18 29	sbcied2	\|- ( g = h -> ( [. ( Vtx ` g ) / v ]. [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } <-> ( iEdg ` h ) : dom ( iEdg ` h ) --> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } ) )
31	30	cbvabv	\|- { g \| [. ( Vtx ` g ) / v ]. [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } } = { h \| ( iEdg ` h ) : dom ( iEdg ` h ) --> { x e. ( ~P ( Vtx ` h ) \ { (/) } ) \| ( # ` x ) = 2 } }
32	16 31	elab2g	\|- ( G e. U -> ( G e. { g \| [. ( Vtx ` g ) / v ]. [. ( iEdg ` g ) / e ]. e : dom e --> { x e. ( ~P v \ { (/) } ) \| ( # ` x ) = 2 } } <-> E : dom E --> { x e. ( ~P V \ { (/) } ) \| ( # ` x ) = 2 } ) )
33	4 32	syl5bb	\|- ( G e. U -> ( G e. UMGraph <-> E : dom E --> { x e. ( ~P V \ { (/) } ) \| ( # ` x ) = 2 } ) )

Metamath Proof Explorer

Theorem isumgr

Proof