dvmptresicc

Description: Derivative of a function restricted to a closed interval. (Contributed by Glauco Siliprandi, 11-Dec-2019)

	Ref	Expression
Hypotheses	dvmptresicc.f	$⊢ F = (x \in ℂ ⟼ A)$
	dvmptresicc.a	$⊢ (φ \land x \in ℂ) \to A \in ℂ$
	dvmptresicc.fdv	$⊢ φ \to ℂ D F = (x \in ℂ ⟼ B)$
	dvmptresicc.b	$⊢ (φ \land x \in ℂ) \to B \in ℂ$
	dvmptresicc.c	$⊢ φ \to C \in ℝ$
	dvmptresicc.d	$⊢ φ \to D \in ℝ$
Assertion	dvmptresicc	$⊢ φ \to \frac{d (x \in [C, D]⟼ A)}{d_{ℝ} x} = (x \in (C, D) ⟼ B)$

Proof

Step	Hyp	Ref	Expression
1		dvmptresicc.f	$⊢ F = (x \in ℂ ⟼ A)$
2		dvmptresicc.a	$⊢ (φ \land x \in ℂ) \to A \in ℂ$
3		dvmptresicc.fdv	$⊢ φ \to ℂ D F = (x \in ℂ ⟼ B)$
4		dvmptresicc.b	$⊢ (φ \land x \in ℂ) \to B \in ℂ$
5		dvmptresicc.c	$⊢ φ \to C \in ℝ$
6		dvmptresicc.d	$⊢ φ \to D \in ℝ$
7	1	reseq1i	$⊢ {F ↾}_{[C, D]} = {(x \in ℂ ⟼ A) ↾}_{[C, D]}$
8	5 6	iccssred	$⊢ φ \to [C, D] \subseteq ℝ$
9		ax-resscn	$⊢ ℝ \subseteq ℂ$
10	9	a1i	$⊢ φ \to ℝ \subseteq ℂ$
11	8 10	sstrd	$⊢ φ \to [C, D] \subseteq ℂ$
12	11	resmptd	$⊢ φ \to {(x \in ℂ ⟼ A) ↾}_{[C, D]} = (x \in [C, D] ⟼ A)$
13	7 12	syl5eq	$⊢ φ \to {F ↾}_{[C, D]} = (x \in [C, D] ⟼ A)$
14	13	oveq2d	$⊢ φ \to ℝ D ({F ↾}_{[C, D]}) = \frac{d (x \in [C, D]⟼ A)}{d_{ℝ} x}$
15	8	resabs1d	$⊢ φ \to {({F ↾}_{ℝ}) ↾}_{[C, D]} = {F ↾}_{[C, D]}$
16	15	eqcomd	$⊢ φ \to {F ↾}_{[C, D]} = {({F ↾}_{ℝ}) ↾}_{[C, D]}$
17	16	oveq2d	$⊢ φ \to ℝ D ({F ↾}_{[C, D]}) = ℝ D ({({F ↾}_{ℝ}) ↾}_{[C, D]})$
18	2 1	fmptd	$⊢ φ \to F : ℂ ⟶ ℂ$
19	18 10	fssresd	$⊢ φ \to ({F ↾}_{ℝ}) : ℝ ⟶ ℂ$
20		ssidd	$⊢ φ \to ℝ \subseteq ℝ$
21		eqid	$⊢ TopOpen (ℂ_{fld}) = TopOpen (ℂ_{fld})$
22	21	tgioo2	$⊢ topGen (ran (.)) = TopOpen (ℂ_{fld}) ↾_{𝑡} ℝ$
23	21 22	dvres	$⊢ ((ℝ \subseteq ℂ \land ({F ↾}_{ℝ}) : ℝ ⟶ ℂ) \land (ℝ \subseteq ℝ \land [C, D] \subseteq ℝ)) \to ℝ D ({({F ↾}_{ℝ}) ↾}_{[C, D]}) = {{({F ↾}_{ℝ})}_{ℝ}^{'} ↾}_{int (topGen (ran (.))) ([C, D])}$
24	10 19 20 8 23	syl22anc	$⊢ φ \to ℝ D ({({F ↾}_{ℝ}) ↾}_{[C, D]}) = {{({F ↾}_{ℝ})}_{ℝ}^{'} ↾}_{int (topGen (ran (.))) ([C, D])}$
25		reelprrecn	$⊢ ℝ \in \{ℝ, ℂ\}$
26	25	a1i	$⊢ φ \to ℝ \in \{ℝ, ℂ\}$
27		ssidd	$⊢ φ \to ℂ \subseteq ℂ$
28	3	dmeqd	$⊢ φ \to dom F_{ℂ}^{'} = dom (x \in ℂ ⟼ B)$
29	4	ralrimiva	$⊢ φ \to \forall x \in ℂ B \in ℂ$
30		dmmptg	$⊢ \forall x \in ℂ B \in ℂ \to dom (x \in ℂ ⟼ B) = ℂ$
31	29 30	syl	$⊢ φ \to dom (x \in ℂ ⟼ B) = ℂ$
32	28 31	eqtr2d	$⊢ φ \to ℂ = dom F_{ℂ}^{'}$
33	10 32	sseqtrd	$⊢ φ \to ℝ \subseteq dom F_{ℂ}^{'}$
34		dvres3	$⊢ ((ℝ \in \{ℝ, ℂ\} \land F : ℂ ⟶ ℂ) \land (ℂ \subseteq ℂ \land ℝ \subseteq dom F_{ℂ}^{'})) \to ℝ D ({F ↾}_{ℝ}) = {F_{ℂ}^{'} ↾}_{ℝ}$
35	26 18 27 33 34	syl22anc	$⊢ φ \to ℝ D ({F ↾}_{ℝ}) = {F_{ℂ}^{'} ↾}_{ℝ}$
36		iccntr	$⊢ (C \in ℝ \land D \in ℝ) \to int (topGen (ran (.))) ([C, D]) = (C, D)$
37	5 6 36	syl2anc	$⊢ φ \to int (topGen (ran (.))) ([C, D]) = (C, D)$
38	35 37	reseq12d	$⊢ φ \to {{({F ↾}_{ℝ})}_{ℝ}^{'} ↾}_{int (topGen (ran (.))) ([C, D])} = {({F_{ℂ}^{'} ↾}_{ℝ}) ↾}_{(C, D)}$
39		ioossre	$⊢ (C, D) \subseteq ℝ$
40		resabs1	$⊢ (C, D) \subseteq ℝ \to {({F_{ℂ}^{'} ↾}_{ℝ}) ↾}_{(C, D)} = {F_{ℂ}^{'} ↾}_{(C, D)}$
41	39 40	mp1i	$⊢ φ \to {({F_{ℂ}^{'} ↾}_{ℝ}) ↾}_{(C, D)} = {F_{ℂ}^{'} ↾}_{(C, D)}$
42	3	reseq1d	$⊢ φ \to {F_{ℂ}^{'} ↾}_{(C, D)} = {(x \in ℂ ⟼ B) ↾}_{(C, D)}$
43		ioosscn	$⊢ (C, D) \subseteq ℂ$
44		resmpt	$⊢ (C, D) \subseteq ℂ \to {(x \in ℂ ⟼ B) ↾}_{(C, D)} = (x \in (C, D) ⟼ B)$
45	43 44	mp1i	$⊢ φ \to {(x \in ℂ ⟼ B) ↾}_{(C, D)} = (x \in (C, D) ⟼ B)$
46	42 45	eqtrd	$⊢ φ \to {F_{ℂ}^{'} ↾}_{(C, D)} = (x \in (C, D) ⟼ B)$
47	38 41 46	3eqtrd	$⊢ φ \to {{({F ↾}_{ℝ})}_{ℝ}^{'} ↾}_{int (topGen (ran (.))) ([C, D])} = (x \in (C, D) ⟼ B)$
48	17 24 47	3eqtrd	$⊢ φ \to ℝ D ({F ↾}_{[C, D]}) = (x \in (C, D) ⟼ B)$
49	14 48	eqtr3d	$⊢ φ \to \frac{d (x \in [C, D]⟼ A)}{d_{ℝ} x} = (x \in (C, D) ⟼ B)$

Metamath Proof Explorer

Theorem dvmptresicc

Proof