ibliooicc

Description: If a function is integrable on an open interval, it is integrable on the corresponding closed interval. (Contributed by Glauco Siliprandi, 11-Dec-2019)

	Ref	Expression
Hypotheses	ibliooicc.1	\|- ( ph -> A e. RR )
	ibliooicc.2	\|- ( ph -> B e. RR )
	ibliooicc.3	\|- ( ph -> ( x e. ( A (,) B ) \|-> C ) e. L^1 )
	ibliooicc.4	\|- ( ( ph /\ x e. ( A [,] B ) ) -> C e. CC )
Assertion	ibliooicc	\|- ( ph -> ( x e. ( A [,] B ) \|-> C ) e. L^1 )

Proof

Step	Hyp	Ref	Expression
1		ibliooicc.1	\|- ( ph -> A e. RR )
2		ibliooicc.2	\|- ( ph -> B e. RR )
3		ibliooicc.3	\|- ( ph -> ( x e. ( A (,) B ) \|-> C ) e. L^1 )
4		ibliooicc.4	\|- ( ( ph /\ x e. ( A [,] B ) ) -> C e. CC )
5		ioossicc	\|- ( A (,) B ) C_ ( A [,] B )
6	5	a1i	\|- ( ph -> ( A (,) B ) C_ ( A [,] B ) )
7	1 2	iccssred	\|- ( ph -> ( A [,] B ) C_ RR )
8	1	rexrd	\|- ( ph -> A e. RR* )
9	2	rexrd	\|- ( ph -> B e. RR* )
10		icc0	\|- ( ( A e. RR* /\ B e. RR* ) -> ( ( A [,] B ) = (/) <-> B < A ) )
11	8 9 10	syl2anc	\|- ( ph -> ( ( A [,] B ) = (/) <-> B < A ) )
12	11	biimpar	\|- ( ( ph /\ B < A ) -> ( A [,] B ) = (/) )
13	12	difeq1d	\|- ( ( ph /\ B < A ) -> ( ( A [,] B ) \ ( A (,) B ) ) = ( (/) \ ( A (,) B ) ) )
14		0dif	\|- ( (/) \ ( A (,) B ) ) = (/)
15		0ss	\|- (/) C_ { A , B }
16	14 15	eqsstri	\|- ( (/) \ ( A (,) B ) ) C_ { A , B }
17	13 16	eqsstrdi	\|- ( ( ph /\ B < A ) -> ( ( A [,] B ) \ ( A (,) B ) ) C_ { A , B } )
18		ssid	\|- ( ( A [,] B ) \ ( A (,) B ) ) C_ ( ( A [,] B ) \ ( A (,) B ) )
19	8	adantr	\|- ( ( ph /\ A <_ B ) -> A e. RR* )
20	9	adantr	\|- ( ( ph /\ A <_ B ) -> B e. RR* )
21		simpr	\|- ( ( ph /\ A <_ B ) -> A <_ B )
22		iccdifioo	\|- ( ( A e. RR* /\ B e. RR* /\ A <_ B ) -> ( ( A [,] B ) \ ( A (,) B ) ) = { A , B } )
23	19 20 21 22	syl3anc	\|- ( ( ph /\ A <_ B ) -> ( ( A [,] B ) \ ( A (,) B ) ) = { A , B } )
24	18 23	sseqtrid	\|- ( ( ph /\ A <_ B ) -> ( ( A [,] B ) \ ( A (,) B ) ) C_ { A , B } )
25	17 24 2 1	ltlecasei	\|- ( ph -> ( ( A [,] B ) \ ( A (,) B ) ) C_ { A , B } )
26		prssi	\|- ( ( A e. RR /\ B e. RR ) -> { A , B } C_ RR )
27	1 2 26	syl2anc	\|- ( ph -> { A , B } C_ RR )
28		prfi	\|- { A , B } e. Fin
29		ovolfi	\|- ( ( { A , B } e. Fin /\ { A , B } C_ RR ) -> ( vol* ` { A , B } ) = 0 )
30	28 27 29	sylancr	\|- ( ph -> ( vol* ` { A , B } ) = 0 )
31		ovolssnul	\|- ( ( ( ( A [,] B ) \ ( A (,) B ) ) C_ { A , B } /\ { A , B } C_ RR /\ ( vol* ` { A , B } ) = 0 ) -> ( vol* ` ( ( A [,] B ) \ ( A (,) B ) ) ) = 0 )
32	25 27 30 31	syl3anc	\|- ( ph -> ( vol* ` ( ( A [,] B ) \ ( A (,) B ) ) ) = 0 )
33	6 7 32 4	itgss3	\|- ( ph -> ( ( ( x e. ( A (,) B ) \|-> C ) e. L^1 <-> ( x e. ( A [,] B ) \|-> C ) e. L^1 ) /\ S. ( A (,) B ) C _d x = S. ( A [,] B ) C _d x ) )
34	33	simpld	\|- ( ph -> ( ( x e. ( A (,) B ) \|-> C ) e. L^1 <-> ( x e. ( A [,] B ) \|-> C ) e. L^1 ) )
35	3 34	mpbid	\|- ( ph -> ( x e. ( A [,] B ) \|-> C ) e. L^1 )

Metamath Proof Explorer

Theorem ibliooicc

Proof