fdifsuppconst

Description: A function is a zero constant outside of its support. (Contributed by Thierry Arnoux, 22-Jun-2024)

		Ref	Expression
	Hypothesis	fdifsuppconst.1	\|- A = ( dom F \ ( F supp Z ) )
	Assertion	fdifsuppconst	\|- ( ( Fun F /\ F e. V /\ Z e. W ) -> ( F \|` A ) = ( A X. { Z } ) )

Proof

Step	Hyp	Ref	Expression
1		fdifsuppconst.1	\|- A = ( dom F \ ( F supp Z ) )
2		funfn	\|- ( Fun F <-> F Fn dom F )
3	2	biimpi	\|- ( Fun F -> F Fn dom F )
4	3	ad2antrr	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> F Fn dom F )
5		difssd	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> ( dom F \ ( F supp Z ) ) C_ dom F )
6	1 5	eqsstrid	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> A C_ dom F )
7	4 6	fnssresd	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> ( F \|` A ) Fn A )
8		fnconstg	\|- ( Z e. W -> ( A X. { Z } ) Fn A )
9	8	adantl	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> ( A X. { Z } ) Fn A )
10	4	adantr	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> F Fn dom F )
11		dmexg	\|- ( F e. V -> dom F e. _V )
12	11	ad3antlr	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> dom F e. _V )
13		simplr	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> Z e. W )
14	1	eleq2i	\|- ( x e. A <-> x e. ( dom F \ ( F supp Z ) ) )
15	14	biimpi	\|- ( x e. A -> x e. ( dom F \ ( F supp Z ) ) )
16	15	adantl	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> x e. ( dom F \ ( F supp Z ) ) )
17	10 12 13 16	fvdifsupp	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> ( F ` x ) = Z )
18		simpr	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> x e. A )
19	18	fvresd	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> ( ( F \|` A ) ` x ) = ( F ` x ) )
20		fvconst2g	\|- ( ( Z e. W /\ x e. A ) -> ( ( A X. { Z } ) ` x ) = Z )
21	20	adantll	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> ( ( A X. { Z } ) ` x ) = Z )
22	17 19 21	3eqtr4d	\|- ( ( ( ( Fun F /\ F e. V ) /\ Z e. W ) /\ x e. A ) -> ( ( F \|` A ) ` x ) = ( ( A X. { Z } ) ` x ) )
23	7 9 22	eqfnfvd	\|- ( ( ( Fun F /\ F e. V ) /\ Z e. W ) -> ( F \|` A ) = ( A X. { Z } ) )
24	23	3impa	\|- ( ( Fun F /\ F e. V /\ Z e. W ) -> ( F \|` A ) = ( A X. { Z } ) )

Metamath Proof Explorer

Theorem fdifsuppconst

Proof