dvcnsqrt

Description: Derivative of square root function. (Contributed by Brendan Leahy, 18-Dec-2018)

		Ref	Expression
	Hypothesis	dvcncxp1.d	\|- D = ( CC \ ( -oo (,] 0 ) )
	Assertion	dvcnsqrt	\|- ( CC _D ( x e. D \|-> ( sqrt ` x ) ) ) = ( x e. D \|-> ( 1 / ( 2 x. ( sqrt ` x ) ) ) )

Proof

Step	Hyp	Ref	Expression
1		dvcncxp1.d	\|- D = ( CC \ ( -oo (,] 0 ) )
2		halfcn	\|- ( 1 / 2 ) e. CC
3	1	dvcncxp1	\|- ( ( 1 / 2 ) e. CC -> ( CC _D ( x e. D \|-> ( x ^c ( 1 / 2 ) ) ) ) = ( x e. D \|-> ( ( 1 / 2 ) x. ( x ^c ( ( 1 / 2 ) - 1 ) ) ) ) )
4	2 3	ax-mp	\|- ( CC _D ( x e. D \|-> ( x ^c ( 1 / 2 ) ) ) ) = ( x e. D \|-> ( ( 1 / 2 ) x. ( x ^c ( ( 1 / 2 ) - 1 ) ) ) )
5		difss	\|- ( CC \ ( -oo (,] 0 ) ) C_ CC
6	1 5	eqsstri	\|- D C_ CC
7	6	sseli	\|- ( x e. D -> x e. CC )
8		cxpsqrt	\|- ( x e. CC -> ( x ^c ( 1 / 2 ) ) = ( sqrt ` x ) )
9	7 8	syl	\|- ( x e. D -> ( x ^c ( 1 / 2 ) ) = ( sqrt ` x ) )
10	9	mpteq2ia	\|- ( x e. D \|-> ( x ^c ( 1 / 2 ) ) ) = ( x e. D \|-> ( sqrt ` x ) )
11	10	oveq2i	\|- ( CC _D ( x e. D \|-> ( x ^c ( 1 / 2 ) ) ) ) = ( CC _D ( x e. D \|-> ( sqrt ` x ) ) )
12		1p0e1	\|- ( 1 + 0 ) = 1
13		ax-1cn	\|- 1 e. CC
14		2halves	\|- ( 1 e. CC -> ( ( 1 / 2 ) + ( 1 / 2 ) ) = 1 )
15	13 14	ax-mp	\|- ( ( 1 / 2 ) + ( 1 / 2 ) ) = 1
16	12 15	eqtr4i	\|- ( 1 + 0 ) = ( ( 1 / 2 ) + ( 1 / 2 ) )
17		0cn	\|- 0 e. CC
18		addsubeq4	\|- ( ( ( 1 e. CC /\ 0 e. CC ) /\ ( ( 1 / 2 ) e. CC /\ ( 1 / 2 ) e. CC ) ) -> ( ( 1 + 0 ) = ( ( 1 / 2 ) + ( 1 / 2 ) ) <-> ( ( 1 / 2 ) - 1 ) = ( 0 - ( 1 / 2 ) ) ) )
19	13 17 2 2 18	mp4an	\|- ( ( 1 + 0 ) = ( ( 1 / 2 ) + ( 1 / 2 ) ) <-> ( ( 1 / 2 ) - 1 ) = ( 0 - ( 1 / 2 ) ) )
20	16 19	mpbi	\|- ( ( 1 / 2 ) - 1 ) = ( 0 - ( 1 / 2 ) )
21		df-neg	\|- -u ( 1 / 2 ) = ( 0 - ( 1 / 2 ) )
22	20 21	eqtr4i	\|- ( ( 1 / 2 ) - 1 ) = -u ( 1 / 2 )
23	22	oveq2i	\|- ( x ^c ( ( 1 / 2 ) - 1 ) ) = ( x ^c -u ( 1 / 2 ) )
24	1	logdmn0	\|- ( x e. D -> x =/= 0 )
25	2	a1i	\|- ( x e. D -> ( 1 / 2 ) e. CC )
26	7 24 25	cxpnegd	\|- ( x e. D -> ( x ^c -u ( 1 / 2 ) ) = ( 1 / ( x ^c ( 1 / 2 ) ) ) )
27	23 26	eqtrid	\|- ( x e. D -> ( x ^c ( ( 1 / 2 ) - 1 ) ) = ( 1 / ( x ^c ( 1 / 2 ) ) ) )
28	9	oveq2d	\|- ( x e. D -> ( 1 / ( x ^c ( 1 / 2 ) ) ) = ( 1 / ( sqrt ` x ) ) )
29	27 28	eqtrd	\|- ( x e. D -> ( x ^c ( ( 1 / 2 ) - 1 ) ) = ( 1 / ( sqrt ` x ) ) )
30	29	oveq2d	\|- ( x e. D -> ( ( 1 / 2 ) x. ( x ^c ( ( 1 / 2 ) - 1 ) ) ) = ( ( 1 / 2 ) x. ( 1 / ( sqrt ` x ) ) ) )
31		1cnd	\|- ( x e. D -> 1 e. CC )
32		2cnd	\|- ( x e. D -> 2 e. CC )
33	7	sqrtcld	\|- ( x e. D -> ( sqrt ` x ) e. CC )
34		2ne0	\|- 2 =/= 0
35	34	a1i	\|- ( x e. D -> 2 =/= 0 )
36	7	adantr	\|- ( ( x e. D /\ ( sqrt ` x ) = 0 ) -> x e. CC )
37		simpr	\|- ( ( x e. D /\ ( sqrt ` x ) = 0 ) -> ( sqrt ` x ) = 0 )
38	36 37	sqr00d	\|- ( ( x e. D /\ ( sqrt ` x ) = 0 ) -> x = 0 )
39	38	ex	\|- ( x e. D -> ( ( sqrt ` x ) = 0 -> x = 0 ) )
40	39	necon3d	\|- ( x e. D -> ( x =/= 0 -> ( sqrt ` x ) =/= 0 ) )
41	24 40	mpd	\|- ( x e. D -> ( sqrt ` x ) =/= 0 )
42	31 32 31 33 35 41	divmuldivd	\|- ( x e. D -> ( ( 1 / 2 ) x. ( 1 / ( sqrt ` x ) ) ) = ( ( 1 x. 1 ) / ( 2 x. ( sqrt ` x ) ) ) )
43		1t1e1	\|- ( 1 x. 1 ) = 1
44	43	oveq1i	\|- ( ( 1 x. 1 ) / ( 2 x. ( sqrt ` x ) ) ) = ( 1 / ( 2 x. ( sqrt ` x ) ) )
45	42 44	eqtrdi	\|- ( x e. D -> ( ( 1 / 2 ) x. ( 1 / ( sqrt ` x ) ) ) = ( 1 / ( 2 x. ( sqrt ` x ) ) ) )
46	30 45	eqtrd	\|- ( x e. D -> ( ( 1 / 2 ) x. ( x ^c ( ( 1 / 2 ) - 1 ) ) ) = ( 1 / ( 2 x. ( sqrt ` x ) ) ) )
47	46	mpteq2ia	\|- ( x e. D \|-> ( ( 1 / 2 ) x. ( x ^c ( ( 1 / 2 ) - 1 ) ) ) ) = ( x e. D \|-> ( 1 / ( 2 x. ( sqrt ` x ) ) ) )
48	4 11 47	3eqtr3i	\|- ( CC _D ( x e. D \|-> ( sqrt ` x ) ) ) = ( x e. D \|-> ( 1 / ( 2 x. ( sqrt ` x ) ) ) )

Metamath Proof Explorer

Theorem dvcnsqrt

Proof