efrlimOLD

Description: Obsolete version of efrlim as of 19-Apr-2025. (Contributed by Mario Carneiro, 1-Mar-2015) (Proof modification is discouraged.) (New usage is discouraged.)

		Ref	Expression
	Hypothesis	efrlimOLD.1	\|- S = ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) )
	Assertion	efrlimOLD	\|- ( A e. CC -> ( k e. RR+ \|-> ( ( 1 + ( A / k ) ) ^c k ) ) ~~>r ( exp ` A ) )

Proof

Step	Hyp	Ref	Expression
1		efrlimOLD.1	\|- S = ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) )
2		rge0ssre	\|- ( 0 [,) +oo ) C_ RR
3		ax-resscn	\|- RR C_ CC
4	2 3	sstri	\|- ( 0 [,) +oo ) C_ CC
5	4	sseli	\|- ( x e. ( 0 [,) +oo ) -> x e. CC )
6		simpll	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> A e. CC )
7		1cnd	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> 1 e. CC )
8		simplr	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> x e. CC )
9		ax-1ne0	\|- 1 =/= 0
10	9	a1i	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> 1 =/= 0 )
11		simpr	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> -. x = 0 )
12	11	neqned	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> x =/= 0 )
13	6 7 8 10 12	divdiv2d	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( A / ( 1 / x ) ) = ( ( A x. x ) / 1 ) )
14		mulcl	\|- ( ( A e. CC /\ x e. CC ) -> ( A x. x ) e. CC )
15	14	adantr	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( A x. x ) e. CC )
16	15	div1d	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( ( A x. x ) / 1 ) = ( A x. x ) )
17	13 16	eqtrd	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( A / ( 1 / x ) ) = ( A x. x ) )
18	17	oveq2d	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( 1 + ( A / ( 1 / x ) ) ) = ( 1 + ( A x. x ) ) )
19	18	oveq1d	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) = ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) )
20	19	ifeq2da	\|- ( ( A e. CC /\ x e. CC ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) = if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) )
21	5 20	sylan2	\|- ( ( A e. CC /\ x e. ( 0 [,) +oo ) ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) = if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) )
22	21	mpteq2dva	\|- ( A e. CC -> ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) ) = ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) )
23		resmpt	\|- ( ( 0 [,) +oo ) C_ CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` ( 0 [,) +oo ) ) = ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) )
24	4 23	ax-mp	\|- ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` ( 0 [,) +oo ) ) = ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) )
25	22 24	eqtr4di	\|- ( A e. CC -> ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) ) = ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` ( 0 [,) +oo ) ) )
26		0e0icopnf	\|- 0 e. ( 0 [,) +oo )
27	26	a1i	\|- ( A e. CC -> 0 e. ( 0 [,) +oo ) )
28		eqeq2	\|- ( ( exp ` ( A x. 1 ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) -> ( if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. 1 ) ) <-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) ) )
29		eqeq2	\|- ( ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) -> ( if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) <-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) ) )
30		cnxmet	\|- ( abs o. - ) e. ( *Met ` CC )
31		0cnd	\|- ( A e. CC -> 0 e. CC )
32		abscl	\|- ( A e. CC -> ( abs ` A ) e. RR )
33		peano2re	\|- ( ( abs ` A ) e. RR -> ( ( abs ` A ) + 1 ) e. RR )
34	32 33	syl	\|- ( A e. CC -> ( ( abs ` A ) + 1 ) e. RR )
35		0red	\|- ( A e. CC -> 0 e. RR )
36		absge0	\|- ( A e. CC -> 0 <_ ( abs ` A ) )
37	32	ltp1d	\|- ( A e. CC -> ( abs ` A ) < ( ( abs ` A ) + 1 ) )
38	35 32 34 36 37	lelttrd	\|- ( A e. CC -> 0 < ( ( abs ` A ) + 1 ) )
39	34 38	elrpd	\|- ( A e. CC -> ( ( abs ` A ) + 1 ) e. RR+ )
40	39	rpreccld	\|- ( A e. CC -> ( 1 / ( ( abs ` A ) + 1 ) ) e. RR+ )
41	40	rpxrd	\|- ( A e. CC -> ( 1 / ( ( abs ` A ) + 1 ) ) e. RR* )
42		blssm	\|- ( ( ( abs o. - ) e. ( Met ` CC ) /\ 0 e. CC /\ ( 1 / ( ( abs ` A ) + 1 ) ) e. RR ) -> ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) C_ CC )
43	30 31 41 42	mp3an2i	\|- ( A e. CC -> ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) C_ CC )
44	1 43	eqsstrid	\|- ( A e. CC -> S C_ CC )
45	44	sselda	\|- ( ( A e. CC /\ x e. S ) -> x e. CC )
46		mul0or	\|- ( ( A e. CC /\ x e. CC ) -> ( ( A x. x ) = 0 <-> ( A = 0 \/ x = 0 ) ) )
47	45 46	syldan	\|- ( ( A e. CC /\ x e. S ) -> ( ( A x. x ) = 0 <-> ( A = 0 \/ x = 0 ) ) )
48	47	biimpa	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A x. x ) = 0 ) -> ( A = 0 \/ x = 0 ) )
49	8 12	reccld	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( 1 / x ) e. CC )
50	45 49	syldanl	\|- ( ( ( A e. CC /\ x e. S ) /\ -. x = 0 ) -> ( 1 / x ) e. CC )
51	50	adantlr	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( 1 / x ) e. CC )
52	51	1cxpd	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( 1 ^c ( 1 / x ) ) = 1 )
53		simplr	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> A = 0 )
54	53	oveq1d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( A x. x ) = ( 0 x. x ) )
55	45	ad2antrr	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> x e. CC )
56	55	mul02d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( 0 x. x ) = 0 )
57	54 56	eqtrd	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( A x. x ) = 0 )
58	57	oveq2d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( 1 + ( A x. x ) ) = ( 1 + 0 ) )
59		1p0e1	\|- ( 1 + 0 ) = 1
60	58 59	eqtrdi	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( 1 + ( A x. x ) ) = 1 )
61	60	oveq1d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) = ( 1 ^c ( 1 / x ) ) )
62	53	fveq2d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( exp ` A ) = ( exp ` 0 ) )
63		ef0	\|- ( exp ` 0 ) = 1
64	62 63	eqtrdi	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( exp ` A ) = 1 )
65	52 61 64	3eqtr4d	\|- ( ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) /\ -. x = 0 ) -> ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) = ( exp ` A ) )
66	65	ifeq2da	\|- ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = if ( x = 0 , ( exp ` A ) , ( exp ` A ) ) )
67		ifid	\|- if ( x = 0 , ( exp ` A ) , ( exp ` A ) ) = ( exp ` A )
68	66 67	eqtrdi	\|- ( ( ( A e. CC /\ x e. S ) /\ A = 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` A ) )
69		iftrue	\|- ( x = 0 -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` A ) )
70	69	adantl	\|- ( ( ( A e. CC /\ x e. S ) /\ x = 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` A ) )
71	68 70	jaodan	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A = 0 \/ x = 0 ) ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` A ) )
72		mulrid	\|- ( A e. CC -> ( A x. 1 ) = A )
73	72	ad2antrr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A = 0 \/ x = 0 ) ) -> ( A x. 1 ) = A )
74	73	fveq2d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A = 0 \/ x = 0 ) ) -> ( exp ` ( A x. 1 ) ) = ( exp ` A ) )
75	71 74	eqtr4d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A = 0 \/ x = 0 ) ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. 1 ) ) )
76	48 75	syldan	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A x. x ) = 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. 1 ) ) )
77		mulne0b	\|- ( ( A e. CC /\ x e. CC ) -> ( ( A =/= 0 /\ x =/= 0 ) <-> ( A x. x ) =/= 0 ) )
78	45 77	syldan	\|- ( ( A e. CC /\ x e. S ) -> ( ( A =/= 0 /\ x =/= 0 ) <-> ( A x. x ) =/= 0 ) )
79		df-ne	\|- ( ( A x. x ) =/= 0 <-> -. ( A x. x ) = 0 )
80	78 79	bitrdi	\|- ( ( A e. CC /\ x e. S ) -> ( ( A =/= 0 /\ x =/= 0 ) <-> -. ( A x. x ) = 0 ) )
81		simprr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> x =/= 0 )
82	81	neneqd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> -. x = 0 )
83	82	iffalsed	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) )
84		ax-1cn	\|- 1 e. CC
85	45 14	syldan	\|- ( ( A e. CC /\ x e. S ) -> ( A x. x ) e. CC )
86		addcl	\|- ( ( 1 e. CC /\ ( A x. x ) e. CC ) -> ( 1 + ( A x. x ) ) e. CC )
87	84 85 86	sylancr	\|- ( ( A e. CC /\ x e. S ) -> ( 1 + ( A x. x ) ) e. CC )
88	87	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( 1 + ( A x. x ) ) e. CC )
89		eqid	\|- ( 1 ( ball ` ( abs o. - ) ) 1 ) = ( 1 ( ball ` ( abs o. - ) ) 1 )
90	89	dvlog2lem	\|- ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ ( CC \ ( -oo (,] 0 ) )
91		eqid	\|- ( CC \ ( -oo (,] 0 ) ) = ( CC \ ( -oo (,] 0 ) )
92	91	logdmss	\|- ( CC \ ( -oo (,] 0 ) ) C_ ( CC \ { 0 } )
93	90 92	sstri	\|- ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ ( CC \ { 0 } )
94		eqid	\|- ( abs o. - ) = ( abs o. - )
95	94	cnmetdval	\|- ( ( ( 1 + ( A x. x ) ) e. CC /\ 1 e. CC ) -> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) = ( abs ` ( ( 1 + ( A x. x ) ) - 1 ) ) )
96	87 84 95	sylancl	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) = ( abs ` ( ( 1 + ( A x. x ) ) - 1 ) ) )
97		pncan2	\|- ( ( 1 e. CC /\ ( A x. x ) e. CC ) -> ( ( 1 + ( A x. x ) ) - 1 ) = ( A x. x ) )
98	84 85 97	sylancr	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) - 1 ) = ( A x. x ) )
99	98	fveq2d	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( ( 1 + ( A x. x ) ) - 1 ) ) = ( abs ` ( A x. x ) ) )
100	96 99	eqtrd	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) = ( abs ` ( A x. x ) ) )
101	85	abscld	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( A x. x ) ) e. RR )
102	34	adantr	\|- ( ( A e. CC /\ x e. S ) -> ( ( abs ` A ) + 1 ) e. RR )
103	45	abscld	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` x ) e. RR )
104	102 103	remulcld	\|- ( ( A e. CC /\ x e. S ) -> ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) e. RR )
105		1red	\|- ( ( A e. CC /\ x e. S ) -> 1 e. RR )
106		absmul	\|- ( ( A e. CC /\ x e. CC ) -> ( abs ` ( A x. x ) ) = ( ( abs ` A ) x. ( abs ` x ) ) )
107	45 106	syldan	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( A x. x ) ) = ( ( abs ` A ) x. ( abs ` x ) ) )
108	32	adantr	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` A ) e. RR )
109	108 33	syl	\|- ( ( A e. CC /\ x e. S ) -> ( ( abs ` A ) + 1 ) e. RR )
110	45	absge0d	\|- ( ( A e. CC /\ x e. S ) -> 0 <_ ( abs ` x ) )
111	108	lep1d	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` A ) <_ ( ( abs ` A ) + 1 ) )
112	108 109 103 110 111	lemul1ad	\|- ( ( A e. CC /\ x e. S ) -> ( ( abs ` A ) x. ( abs ` x ) ) <_ ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) )
113	107 112	eqbrtrd	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( A x. x ) ) <_ ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) )
114		0cn	\|- 0 e. CC
115	94	cnmetdval	\|- ( ( x e. CC /\ 0 e. CC ) -> ( x ( abs o. - ) 0 ) = ( abs ` ( x - 0 ) ) )
116	45 114 115	sylancl	\|- ( ( A e. CC /\ x e. S ) -> ( x ( abs o. - ) 0 ) = ( abs ` ( x - 0 ) ) )
117	45	subid1d	\|- ( ( A e. CC /\ x e. S ) -> ( x - 0 ) = x )
118	117	fveq2d	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( x - 0 ) ) = ( abs ` x ) )
119	116 118	eqtrd	\|- ( ( A e. CC /\ x e. S ) -> ( x ( abs o. - ) 0 ) = ( abs ` x ) )
120		simpr	\|- ( ( A e. CC /\ x e. S ) -> x e. S )
121	120 1	eleqtrdi	\|- ( ( A e. CC /\ x e. S ) -> x e. ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) )
122	30	a1i	\|- ( ( A e. CC /\ x e. S ) -> ( abs o. - ) e. ( *Met ` CC ) )
123	41	adantr	\|- ( ( A e. CC /\ x e. S ) -> ( 1 / ( ( abs ` A ) + 1 ) ) e. RR* )
124		0cnd	\|- ( ( A e. CC /\ x e. S ) -> 0 e. CC )
125		elbl3	\|- ( ( ( ( abs o. - ) e. ( Met ` CC ) /\ ( 1 / ( ( abs ` A ) + 1 ) ) e. RR ) /\ ( 0 e. CC /\ x e. CC ) ) -> ( x e. ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) <-> ( x ( abs o. - ) 0 ) < ( 1 / ( ( abs ` A ) + 1 ) ) ) )
126	122 123 124 45 125	syl22anc	\|- ( ( A e. CC /\ x e. S ) -> ( x e. ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) <-> ( x ( abs o. - ) 0 ) < ( 1 / ( ( abs ` A ) + 1 ) ) ) )
127	121 126	mpbid	\|- ( ( A e. CC /\ x e. S ) -> ( x ( abs o. - ) 0 ) < ( 1 / ( ( abs ` A ) + 1 ) ) )
128	119 127	eqbrtrrd	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` x ) < ( 1 / ( ( abs ` A ) + 1 ) ) )
129	38	adantr	\|- ( ( A e. CC /\ x e. S ) -> 0 < ( ( abs ` A ) + 1 ) )
130		ltmuldiv2	\|- ( ( ( abs ` x ) e. RR /\ 1 e. RR /\ ( ( ( abs ` A ) + 1 ) e. RR /\ 0 < ( ( abs ` A ) + 1 ) ) ) -> ( ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) < 1 <-> ( abs ` x ) < ( 1 / ( ( abs ` A ) + 1 ) ) ) )
131	103 105 109 129 130	syl112anc	\|- ( ( A e. CC /\ x e. S ) -> ( ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) < 1 <-> ( abs ` x ) < ( 1 / ( ( abs ` A ) + 1 ) ) ) )
132	128 131	mpbird	\|- ( ( A e. CC /\ x e. S ) -> ( ( ( abs ` A ) + 1 ) x. ( abs ` x ) ) < 1 )
133	101 104 105 113 132	lelttrd	\|- ( ( A e. CC /\ x e. S ) -> ( abs ` ( A x. x ) ) < 1 )
134	100 133	eqbrtrd	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) < 1 )
135		1rp	\|- 1 e. RR+
136		rpxr	\|- ( 1 e. RR+ -> 1 e. RR* )
137	135 136	mp1i	\|- ( ( A e. CC /\ x e. S ) -> 1 e. RR* )
138		1cnd	\|- ( ( A e. CC /\ x e. S ) -> 1 e. CC )
139		elbl3	\|- ( ( ( ( abs o. - ) e. ( Met ` CC ) /\ 1 e. RR ) /\ ( 1 e. CC /\ ( 1 + ( A x. x ) ) e. CC ) ) -> ( ( 1 + ( A x. x ) ) e. ( 1 ( ball ` ( abs o. - ) ) 1 ) <-> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) < 1 ) )
140	122 137 138 87 139	syl22anc	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) e. ( 1 ( ball ` ( abs o. - ) ) 1 ) <-> ( ( 1 + ( A x. x ) ) ( abs o. - ) 1 ) < 1 ) )
141	134 140	mpbird	\|- ( ( A e. CC /\ x e. S ) -> ( 1 + ( A x. x ) ) e. ( 1 ( ball ` ( abs o. - ) ) 1 ) )
142	93 141	sselid	\|- ( ( A e. CC /\ x e. S ) -> ( 1 + ( A x. x ) ) e. ( CC \ { 0 } ) )
143		eldifsni	\|- ( ( 1 + ( A x. x ) ) e. ( CC \ { 0 } ) -> ( 1 + ( A x. x ) ) =/= 0 )
144	142 143	syl	\|- ( ( A e. CC /\ x e. S ) -> ( 1 + ( A x. x ) ) =/= 0 )
145	144	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( 1 + ( A x. x ) ) =/= 0 )
146	45	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> x e. CC )
147	146 81	reccld	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( 1 / x ) e. CC )
148	88 145 147	cxpefd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) = ( exp ` ( ( 1 / x ) x. ( log ` ( 1 + ( A x. x ) ) ) ) ) )
149	87 144	logcld	\|- ( ( A e. CC /\ x e. S ) -> ( log ` ( 1 + ( A x. x ) ) ) e. CC )
150	149	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( log ` ( 1 + ( A x. x ) ) ) e. CC )
151	147 150	mulcomd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( 1 / x ) x. ( log ` ( 1 + ( A x. x ) ) ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) x. ( 1 / x ) ) )
152		simpll	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> A e. CC )
153		simprl	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> A =/= 0 )
154	152 153	dividd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( A / A ) = 1 )
155	154	oveq1d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( A / A ) / x ) = ( 1 / x ) )
156	152 152 146 153 81	divdiv1d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( A / A ) / x ) = ( A / ( A x. x ) ) )
157	155 156	eqtr3d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( 1 / x ) = ( A / ( A x. x ) ) )
158	157	oveq2d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( log ` ( 1 + ( A x. x ) ) ) x. ( 1 / x ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) x. ( A / ( A x. x ) ) ) )
159	85	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( A x. x ) e. CC )
160	78	biimpa	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( A x. x ) =/= 0 )
161	150 152 159 160	div12d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( log ` ( 1 + ( A x. x ) ) ) x. ( A / ( A x. x ) ) ) = ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) )
162	151 158 161	3eqtrd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( ( 1 / x ) x. ( log ` ( 1 + ( A x. x ) ) ) ) = ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) )
163	162	fveq2d	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> ( exp ` ( ( 1 / x ) x. ( log ` ( 1 + ( A x. x ) ) ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
164	83 148 163	3eqtrd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A =/= 0 /\ x =/= 0 ) ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
165	164	ex	\|- ( ( A e. CC /\ x e. S ) -> ( ( A =/= 0 /\ x =/= 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
166	80 165	sylbird	\|- ( ( A e. CC /\ x e. S ) -> ( -. ( A x. x ) = 0 -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
167	166	imp	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
168	28 29 76 167	ifbothda	\|- ( ( A e. CC /\ x e. S ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
169	168	mpteq2dva	\|- ( A e. CC -> ( x e. S \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) = ( x e. S \|-> if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) ) )
170	44	resmptd	\|- ( A e. CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` S ) = ( x e. S \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) )
171		1cnd	\|- ( ( ( A e. CC /\ x e. S ) /\ ( A x. x ) = 0 ) -> 1 e. CC )
172	149	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> ( log ` ( 1 + ( A x. x ) ) ) e. CC )
173	85	adantr	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> ( A x. x ) e. CC )
174		simpr	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> -. ( A x. x ) = 0 )
175	174	neqned	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> ( A x. x ) =/= 0 )
176	172 173 175	divcld	\|- ( ( ( A e. CC /\ x e. S ) /\ -. ( A x. x ) = 0 ) -> ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) e. CC )
177	171 176	ifclda	\|- ( ( A e. CC /\ x e. S ) -> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) e. CC )
178		eqidd	\|- ( A e. CC -> ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) = ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
179		eqidd	\|- ( A e. CC -> ( y e. CC \|-> ( exp ` ( A x. y ) ) ) = ( y e. CC \|-> ( exp ` ( A x. y ) ) ) )
180		oveq2	\|- ( y = if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) -> ( A x. y ) = ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
181	180	fveq2d	\|- ( y = if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) -> ( exp ` ( A x. y ) ) = ( exp ` ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
182		oveq2	\|- ( if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) = 1 -> ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) = ( A x. 1 ) )
183	182	fveq2d	\|- ( if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) = 1 -> ( exp ` ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) = ( exp ` ( A x. 1 ) ) )
184		oveq2	\|- ( if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) -> ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) = ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) )
185	184	fveq2d	\|- ( if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) -> ( exp ` ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) = ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
186	183 185	ifsb	\|- ( exp ` ( A x. if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
187	181 186	eqtrdi	\|- ( y = if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) -> ( exp ` ( A x. y ) ) = if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
188	177 178 179 187	fmptco	\|- ( A e. CC -> ( ( y e. CC \|-> ( exp ` ( A x. y ) ) ) o. ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) = ( x e. S \|-> if ( ( A x. x ) = 0 , ( exp ` ( A x. 1 ) ) , ( exp ` ( A x. ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) ) )
189	169 170 188	3eqtr4d	\|- ( A e. CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` S ) = ( ( y e. CC \|-> ( exp ` ( A x. y ) ) ) o. ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) )
190		eqidd	\|- ( A e. CC -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) = ( x e. S \|-> ( 1 + ( A x. x ) ) ) )
191		eqidd	\|- ( A e. CC -> ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) = ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) )
192		eqeq1	\|- ( y = ( 1 + ( A x. x ) ) -> ( y = 1 <-> ( 1 + ( A x. x ) ) = 1 ) )
193		fveq2	\|- ( y = ( 1 + ( A x. x ) ) -> ( log ` y ) = ( log ` ( 1 + ( A x. x ) ) ) )
194		oveq1	\|- ( y = ( 1 + ( A x. x ) ) -> ( y - 1 ) = ( ( 1 + ( A x. x ) ) - 1 ) )
195	193 194	oveq12d	\|- ( y = ( 1 + ( A x. x ) ) -> ( ( log ` y ) / ( y - 1 ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) )
196	192 195	ifbieq2d	\|- ( y = ( 1 + ( A x. x ) ) -> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) = if ( ( 1 + ( A x. x ) ) = 1 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) ) )
197	141 190 191 196	fmptco	\|- ( A e. CC -> ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) o. ( x e. S \|-> ( 1 + ( A x. x ) ) ) ) = ( x e. S \|-> if ( ( 1 + ( A x. x ) ) = 1 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) ) ) )
198	59	eqeq2i	\|- ( ( 1 + ( A x. x ) ) = ( 1 + 0 ) <-> ( 1 + ( A x. x ) ) = 1 )
199	138 85 124	addcand	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) = ( 1 + 0 ) <-> ( A x. x ) = 0 ) )
200	198 199	bitr3id	\|- ( ( A e. CC /\ x e. S ) -> ( ( 1 + ( A x. x ) ) = 1 <-> ( A x. x ) = 0 ) )
201	98	oveq2d	\|- ( ( A e. CC /\ x e. S ) -> ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) = ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) )
202	200 201	ifbieq2d	\|- ( ( A e. CC /\ x e. S ) -> if ( ( 1 + ( A x. x ) ) = 1 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) ) = if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) )
203	202	mpteq2dva	\|- ( A e. CC -> ( x e. S \|-> if ( ( 1 + ( A x. x ) ) = 1 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( ( 1 + ( A x. x ) ) - 1 ) ) ) ) = ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
204	197 203	eqtrd	\|- ( A e. CC -> ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) o. ( x e. S \|-> ( 1 + ( A x. x ) ) ) ) = ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) )
205		eqid	\|- ( ( TopOpen ` CCfld ) \|`t S ) = ( ( TopOpen ` CCfld ) \|`t S )
206		eqid	\|- ( TopOpen ` CCfld ) = ( TopOpen ` CCfld )
207	206	cnfldtopon	\|- ( TopOpen ` CCfld ) e. ( TopOn ` CC )
208	207	a1i	\|- ( A e. CC -> ( TopOpen ` CCfld ) e. ( TopOn ` CC ) )
209		1cnd	\|- ( A e. CC -> 1 e. CC )
210	208 208 209	cnmptc	\|- ( A e. CC -> ( x e. CC \|-> 1 ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
211		id	\|- ( A e. CC -> A e. CC )
212	208 208 211	cnmptc	\|- ( A e. CC -> ( x e. CC \|-> A ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
213	208	cnmptid	\|- ( A e. CC -> ( x e. CC \|-> x ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
214	206	mulcn	\|- x. e. ( ( ( TopOpen ` CCfld ) tX ( TopOpen ` CCfld ) ) Cn ( TopOpen ` CCfld ) )
215	214	a1i	\|- ( A e. CC -> x. e. ( ( ( TopOpen ` CCfld ) tX ( TopOpen ` CCfld ) ) Cn ( TopOpen ` CCfld ) ) )
216	208 212 213 215	cnmpt12f	\|- ( A e. CC -> ( x e. CC \|-> ( A x. x ) ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
217	206	addcn	\|- + e. ( ( ( TopOpen ` CCfld ) tX ( TopOpen ` CCfld ) ) Cn ( TopOpen ` CCfld ) )
218	217	a1i	\|- ( A e. CC -> + e. ( ( ( TopOpen ` CCfld ) tX ( TopOpen ` CCfld ) ) Cn ( TopOpen ` CCfld ) ) )
219	208 210 216 218	cnmpt12f	\|- ( A e. CC -> ( x e. CC \|-> ( 1 + ( A x. x ) ) ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
220	205 208 44 219	cnmpt1res	\|- ( A e. CC -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( TopOpen ` CCfld ) ) )
221	141	fmpttd	\|- ( A e. CC -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) : S --> ( 1 ( ball ` ( abs o. - ) ) 1 ) )
222	221	frnd	\|- ( A e. CC -> ran ( x e. S \|-> ( 1 + ( A x. x ) ) ) C_ ( 1 ( ball ` ( abs o. - ) ) 1 ) )
223		difss	\|- ( CC \ { 0 } ) C_ CC
224	93 223	sstri	\|- ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ CC
225	224	a1i	\|- ( A e. CC -> ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ CC )
226		cnrest2	\|- ( ( ( TopOpen ` CCfld ) e. ( TopOn ` CC ) /\ ran ( x e. S \|-> ( 1 + ( A x. x ) ) ) C_ ( 1 ( ball ` ( abs o. - ) ) 1 ) /\ ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ CC ) -> ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( TopOpen ` CCfld ) ) <-> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ) )
227	207 222 225 226	mp3an2i	\|- ( A e. CC -> ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( TopOpen ` CCfld ) ) <-> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ) )
228	220 227	mpbid	\|- ( A e. CC -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) )
229		blcntr	\|- ( ( ( abs o. - ) e. ( *Met ` CC ) /\ 0 e. CC /\ ( 1 / ( ( abs ` A ) + 1 ) ) e. RR+ ) -> 0 e. ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) )
230	30 31 40 229	mp3an2i	\|- ( A e. CC -> 0 e. ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) )
231	230 1	eleqtrrdi	\|- ( A e. CC -> 0 e. S )
232		resttopon	\|- ( ( ( TopOpen ` CCfld ) e. ( TopOn ` CC ) /\ S C_ CC ) -> ( ( TopOpen ` CCfld ) \|`t S ) e. ( TopOn ` S ) )
233	207 44 232	sylancr	\|- ( A e. CC -> ( ( TopOpen ` CCfld ) \|`t S ) e. ( TopOn ` S ) )
234		toponuni	\|- ( ( ( TopOpen ` CCfld ) \|`t S ) e. ( TopOn ` S ) -> S = U. ( ( TopOpen ` CCfld ) \|`t S ) )
235	233 234	syl	\|- ( A e. CC -> S = U. ( ( TopOpen ` CCfld ) \|`t S ) )
236	231 235	eleqtrd	\|- ( A e. CC -> 0 e. U. ( ( TopOpen ` CCfld ) \|`t S ) )
237		eqid	\|- U. ( ( TopOpen ` CCfld ) \|`t S ) = U. ( ( TopOpen ` CCfld ) \|`t S )
238	237	cncnpi	\|- ( ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( TopOpen ` CCfld ) \|`t S ) Cn ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) /\ 0 e. U. ( ( TopOpen ` CCfld ) \|`t S ) ) -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 0 ) )
239	228 236 238	syl2anc	\|- ( A e. CC -> ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 0 ) )
240		cnelprrecn	\|- CC e. { RR , CC }
241		logf1o	\|- log : ( CC \ { 0 } ) -1-1-onto-> ran log
242		f1of	\|- ( log : ( CC \ { 0 } ) -1-1-onto-> ran log -> log : ( CC \ { 0 } ) --> ran log )
243	241 242	ax-mp	\|- log : ( CC \ { 0 } ) --> ran log
244		logrncn	\|- ( x e. ran log -> x e. CC )
245	244	ssriv	\|- ran log C_ CC
246		fss	\|- ( ( log : ( CC \ { 0 } ) --> ran log /\ ran log C_ CC ) -> log : ( CC \ { 0 } ) --> CC )
247	243 245 246	mp2an	\|- log : ( CC \ { 0 } ) --> CC
248		fssres	\|- ( ( log : ( CC \ { 0 } ) --> CC /\ ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ ( CC \ { 0 } ) ) -> ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) : ( 1 ( ball ` ( abs o. - ) ) 1 ) --> CC )
249	247 93 248	mp2an	\|- ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) : ( 1 ( ball ` ( abs o. - ) ) 1 ) --> CC
250		blcntr	\|- ( ( ( abs o. - ) e. ( *Met ` CC ) /\ 1 e. CC /\ 1 e. RR+ ) -> 1 e. ( 1 ( ball ` ( abs o. - ) ) 1 ) )
251	30 84 135 250	mp3an	\|- 1 e. ( 1 ( ball ` ( abs o. - ) ) 1 )
252		ovex	\|- ( 1 / y ) e. _V
253	89	dvlog2	\|- ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) = ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) )
254	252 253	dmmpti	\|- dom ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) = ( 1 ( ball ` ( abs o. - ) ) 1 )
255	251 254	eleqtrri	\|- 1 e. dom ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) )
256		eqid	\|- ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) = ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) )
257	253	fveq1i	\|- ( ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 1 ) = ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) ) ` 1 )
258		oveq2	\|- ( y = 1 -> ( 1 / y ) = ( 1 / 1 ) )
259		1div1e1	\|- ( 1 / 1 ) = 1
260	258 259	eqtrdi	\|- ( y = 1 -> ( 1 / y ) = 1 )
261		eqid	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) ) = ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) )
262		1ex	\|- 1 e. _V
263	260 261 262	fvmpt	\|- ( 1 e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) ) ` 1 ) = 1 )
264	251 263	ax-mp	\|- ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> ( 1 / y ) ) ` 1 ) = 1
265	257 264	eqtr2i	\|- 1 = ( ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 1 )
266	265	a1i	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> 1 = ( ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 1 ) )
267		fvres	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) = ( log ` y ) )
268		fvres	\|- ( 1 e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) = ( log ` 1 ) )
269	251 268	mp1i	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) = ( log ` 1 ) )
270		log1	\|- ( log ` 1 ) = 0
271	269 270	eqtrdi	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) = 0 )
272	267 271	oveq12d	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) - ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) ) = ( ( log ` y ) - 0 ) )
273	93	sseli	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> y e. ( CC \ { 0 } ) )
274		eldifsn	\|- ( y e. ( CC \ { 0 } ) <-> ( y e. CC /\ y =/= 0 ) )
275	273 274	sylib	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( y e. CC /\ y =/= 0 ) )
276		logcl	\|- ( ( y e. CC /\ y =/= 0 ) -> ( log ` y ) e. CC )
277	275 276	syl	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( log ` y ) e. CC )
278	277	subid1d	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log ` y ) - 0 ) = ( log ` y ) )
279	272 278	eqtr2d	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( log ` y ) = ( ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) - ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) ) )
280	279	oveq1d	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> ( ( log ` y ) / ( y - 1 ) ) = ( ( ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) - ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) ) / ( y - 1 ) ) )
281	266 280	ifeq12d	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) -> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) = if ( y = 1 , ( ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 1 ) , ( ( ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) - ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) ) / ( y - 1 ) ) ) )
282	281	mpteq2ia	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) = ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , ( ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 1 ) , ( ( ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` y ) - ( ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ` 1 ) ) / ( y - 1 ) ) ) )
283	256 206 282	dvcnp	\|- ( ( ( CC e. { RR , CC } /\ ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) : ( 1 ( ball ` ( abs o. - ) ) 1 ) --> CC /\ ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ CC ) /\ 1 e. dom ( CC _D ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ) -> ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` 1 ) )
284	255 283	mpan2	\|- ( ( CC e. { RR , CC } /\ ( log \|` ( 1 ( ball ` ( abs o. - ) ) 1 ) ) : ( 1 ( ball ` ( abs o. - ) ) 1 ) --> CC /\ ( 1 ( ball ` ( abs o. - ) ) 1 ) C_ CC ) -> ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` 1 ) )
285	240 249 224 284	mp3an	\|- ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` 1 )
286		oveq2	\|- ( x = 0 -> ( A x. x ) = ( A x. 0 ) )
287	286	oveq2d	\|- ( x = 0 -> ( 1 + ( A x. x ) ) = ( 1 + ( A x. 0 ) ) )
288		eqid	\|- ( x e. S \|-> ( 1 + ( A x. x ) ) ) = ( x e. S \|-> ( 1 + ( A x. x ) ) )
289		ovex	\|- ( 1 + ( A x. 0 ) ) e. _V
290	287 288 289	fvmpt	\|- ( 0 e. S -> ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) = ( 1 + ( A x. 0 ) ) )
291	231 290	syl	\|- ( A e. CC -> ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) = ( 1 + ( A x. 0 ) ) )
292		mul01	\|- ( A e. CC -> ( A x. 0 ) = 0 )
293	292	oveq2d	\|- ( A e. CC -> ( 1 + ( A x. 0 ) ) = ( 1 + 0 ) )
294	293 59	eqtrdi	\|- ( A e. CC -> ( 1 + ( A x. 0 ) ) = 1 )
295	291 294	eqtrd	\|- ( A e. CC -> ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) = 1 )
296	295	fveq2d	\|- ( A e. CC -> ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) ) = ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` 1 ) )
297	285 296	eleqtrrid	\|- ( A e. CC -> ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) ) )
298		cnpco	\|- ( ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) ) ` 0 ) /\ ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 1 ( ball ` ( abs o. - ) ) 1 ) ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> ( 1 + ( A x. x ) ) ) ` 0 ) ) ) -> ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) o. ( x e. S \|-> ( 1 + ( A x. x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
299	239 297 298	syl2anc	\|- ( A e. CC -> ( ( y e. ( 1 ( ball ` ( abs o. - ) ) 1 ) \|-> if ( y = 1 , 1 , ( ( log ` y ) / ( y - 1 ) ) ) ) o. ( x e. S \|-> ( 1 + ( A x. x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
300	204 299	eqeltrrd	\|- ( A e. CC -> ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
301	208 208 211	cnmptc	\|- ( A e. CC -> ( y e. CC \|-> A ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
302	208	cnmptid	\|- ( A e. CC -> ( y e. CC \|-> y ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
303	208 301 302 215	cnmpt12f	\|- ( A e. CC -> ( y e. CC \|-> ( A x. y ) ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
304		efcn	\|- exp e. ( CC -cn-> CC )
305	206	cncfcn1	\|- ( CC -cn-> CC ) = ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) )
306	304 305	eleqtri	\|- exp e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) )
307	306	a1i	\|- ( A e. CC -> exp e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
308	208 303 307	cnmpt11f	\|- ( A e. CC -> ( y e. CC \|-> ( exp ` ( A x. y ) ) ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) )
309	177	fmpttd	\|- ( A e. CC -> ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) : S --> CC )
310	309 231	ffvelcdmd	\|- ( A e. CC -> ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ` 0 ) e. CC )
311		unicntop	\|- CC = U. ( TopOpen ` CCfld )
312	311	cncnpi	\|- ( ( ( y e. CC \|-> ( exp ` ( A x. y ) ) ) e. ( ( TopOpen ` CCfld ) Cn ( TopOpen ` CCfld ) ) /\ ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ` 0 ) e. CC ) -> ( y e. CC \|-> ( exp ` ( A x. y ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ` 0 ) ) )
313	308 310 312	syl2anc	\|- ( A e. CC -> ( y e. CC \|-> ( exp ` ( A x. y ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ` 0 ) ) )
314		cnpco	\|- ( ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) /\ ( y e. CC \|-> ( exp ` ( A x. y ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` ( ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ` 0 ) ) ) -> ( ( y e. CC \|-> ( exp ` ( A x. y ) ) ) o. ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
315	300 313 314	syl2anc	\|- ( A e. CC -> ( ( y e. CC \|-> ( exp ` ( A x. y ) ) ) o. ( x e. S \|-> if ( ( A x. x ) = 0 , 1 , ( ( log ` ( 1 + ( A x. x ) ) ) / ( A x. x ) ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
316	189 315	eqeltrd	\|- ( A e. CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` S ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
317	206	cnfldtop	\|- ( TopOpen ` CCfld ) e. Top
318	317	a1i	\|- ( A e. CC -> ( TopOpen ` CCfld ) e. Top )
319	206	cnfldtopn	\|- ( TopOpen ` CCfld ) = ( MetOpen ` ( abs o. - ) )
320	319	blopn	\|- ( ( ( abs o. - ) e. ( Met ` CC ) /\ 0 e. CC /\ ( 1 / ( ( abs ` A ) + 1 ) ) e. RR ) -> ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) e. ( TopOpen ` CCfld ) )
321	30 31 41 320	mp3an2i	\|- ( A e. CC -> ( 0 ( ball ` ( abs o. - ) ) ( 1 / ( ( abs ` A ) + 1 ) ) ) e. ( TopOpen ` CCfld ) )
322	1 321	eqeltrid	\|- ( A e. CC -> S e. ( TopOpen ` CCfld ) )
323		isopn3i	\|- ( ( ( TopOpen ` CCfld ) e. Top /\ S e. ( TopOpen ` CCfld ) ) -> ( ( int ` ( TopOpen ` CCfld ) ) ` S ) = S )
324	317 322 323	sylancr	\|- ( A e. CC -> ( ( int ` ( TopOpen ` CCfld ) ) ` S ) = S )
325	231 324	eleqtrrd	\|- ( A e. CC -> 0 e. ( ( int ` ( TopOpen ` CCfld ) ) ` S ) )
326		efcl	\|- ( A e. CC -> ( exp ` A ) e. CC )
327	326	ad2antrr	\|- ( ( ( A e. CC /\ x e. CC ) /\ x = 0 ) -> ( exp ` A ) e. CC )
328	84 15 86	sylancr	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( 1 + ( A x. x ) ) e. CC )
329	328 49	cxpcld	\|- ( ( ( A e. CC /\ x e. CC ) /\ -. x = 0 ) -> ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) e. CC )
330	327 329	ifclda	\|- ( ( A e. CC /\ x e. CC ) -> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) e. CC )
331	330	fmpttd	\|- ( A e. CC -> ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) : CC --> CC )
332	311 311	cnprest	\|- ( ( ( ( TopOpen ` CCfld ) e. Top /\ S C_ CC ) /\ ( 0 e. ( ( int ` ( TopOpen ` CCfld ) ) ` S ) /\ ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) : CC --> CC ) ) -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` 0 ) <-> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` S ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) ) )
333	318 44 325 331 332	syl22anc	\|- ( A e. CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` 0 ) <-> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` S ) e. ( ( ( ( TopOpen ` CCfld ) \|`t S ) CnP ( TopOpen ` CCfld ) ) ` 0 ) ) )
334	316 333	mpbird	\|- ( A e. CC -> ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
335	311	cnpresti	\|- ( ( ( 0 [,) +oo ) C_ CC /\ 0 e. ( 0 [,) +oo ) /\ ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( TopOpen ` CCfld ) CnP ( TopOpen ` CCfld ) ) ` 0 ) ) -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` ( 0 [,) +oo ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
336	4 27 334 335	mp3an2i	\|- ( A e. CC -> ( ( x e. CC \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A x. x ) ) ^c ( 1 / x ) ) ) ) \|` ( 0 [,) +oo ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
337	25 336	eqeltrd	\|- ( A e. CC -> ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) ) CnP ( TopOpen ` CCfld ) ) ` 0 ) )
338		simpl	\|- ( ( A e. CC /\ k e. RR+ ) -> A e. CC )
339		rpcn	\|- ( k e. RR+ -> k e. CC )
340	339	adantl	\|- ( ( A e. CC /\ k e. RR+ ) -> k e. CC )
341		rpne0	\|- ( k e. RR+ -> k =/= 0 )
342	341	adantl	\|- ( ( A e. CC /\ k e. RR+ ) -> k =/= 0 )
343	338 340 342	divcld	\|- ( ( A e. CC /\ k e. RR+ ) -> ( A / k ) e. CC )
344		addcl	\|- ( ( 1 e. CC /\ ( A / k ) e. CC ) -> ( 1 + ( A / k ) ) e. CC )
345	84 343 344	sylancr	\|- ( ( A e. CC /\ k e. RR+ ) -> ( 1 + ( A / k ) ) e. CC )
346	345 340	cxpcld	\|- ( ( A e. CC /\ k e. RR+ ) -> ( ( 1 + ( A / k ) ) ^c k ) e. CC )
347		oveq2	\|- ( k = ( 1 / x ) -> ( A / k ) = ( A / ( 1 / x ) ) )
348	347	oveq2d	\|- ( k = ( 1 / x ) -> ( 1 + ( A / k ) ) = ( 1 + ( A / ( 1 / x ) ) ) )
349		id	\|- ( k = ( 1 / x ) -> k = ( 1 / x ) )
350	348 349	oveq12d	\|- ( k = ( 1 / x ) -> ( ( 1 + ( A / k ) ) ^c k ) = ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) )
351		eqid	\|- ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) ) = ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) )
352	326 346 350 206 351	rlimcnp3	\|- ( A e. CC -> ( ( k e. RR+ \|-> ( ( 1 + ( A / k ) ) ^c k ) ) ~~>r ( exp ` A ) <-> ( x e. ( 0 [,) +oo ) \|-> if ( x = 0 , ( exp ` A ) , ( ( 1 + ( A / ( 1 / x ) ) ) ^c ( 1 / x ) ) ) ) e. ( ( ( ( TopOpen ` CCfld ) \|`t ( 0 [,) +oo ) ) CnP ( TopOpen ` CCfld ) ) ` 0 ) ) )
353	337 352	mpbird	\|- ( A e. CC -> ( k e. RR+ \|-> ( ( 1 + ( A / k ) ) ^c k ) ) ~~>r ( exp ` A ) )

Metamath Proof Explorer

Theorem efrlimOLD

Proof