:: JGRAPH_3 semantic presentation
Lemma1:
for b1 being real number holds
(b1 ^2 ) + 1 > 0
Lemma2:
TOP-REAL 2 = TopSpaceMetr (Euclid 2)
by EUCLID:def 8;
Lemma3:
( dom proj1 = the carrier of (TOP-REAL 2) & dom proj2 = the carrier of (TOP-REAL 2) )
by FUNCT_2:def 1;
Lemma4:
for b1, b2 being complex number holds
not ( b1 ^2 = b2 ^2 & not b1 = b2 & not b1 = - b2 )
by SQUARE_1:109;
Lemma5:
for b1 being complex number holds
not ( b1 ^2 = 1 & not b1 = 1 & not b1 = - 1 )
by SQUARE_1:110;
Lemma6:
for b1 being real number holds
( 0 <= b1 & b1 <= 1 implies b1 ^2 <= b1 )
by SQUARE_1:111;
theorem Th1: :: JGRAPH_3:1
canceled;
theorem Th2: :: JGRAPH_3:2
canceled;
theorem Th3: :: JGRAPH_3:3
canceled;
theorem Th4: :: JGRAPH_3:4
canceled;
theorem Th5: :: JGRAPH_3:5
canceled;
theorem Th6: :: JGRAPH_3:6
canceled;
theorem Th7: :: JGRAPH_3:7
canceled;
theorem Th8: :: JGRAPH_3:8
canceled;
Lemma7:
for b1 being real number holds
( (b1 ^2 ) - 1 <= 0 implies ( - 1 <= b1 & b1 <= 1 ) )
by SQUARE_1:112;
Lemma8:
for b1, b2, b3 being real number holds
( ( b1 < b2 & b1 < b3 ) iff b1 < min b2,b3 )
by SQUARE_1:113;
Lemma9:
for b1 being real number holds
( 0 < b1 implies ( b1 / 3 < b1 & b1 / 4 < b1 ) )
by XREAL_1:223, XREAL_1:225;
Lemma10:
for b1 being real number holds
( ( b1 >= 1 implies sqrt b1 >= 1 ) & not ( b1 > 1 & not sqrt b1 > 1 ) )
by SQUARE_1:83, SQUARE_1:94, SQUARE_1:95;
theorem Th9: :: JGRAPH_3:9
theorem Th10: :: JGRAPH_3:10
theorem Th11: :: JGRAPH_3:11
theorem Th12: :: JGRAPH_3:12
theorem Th13: :: JGRAPH_3:13
definition
func Sq_Circ -> Function of the
carrier of
(TOP-REAL 2),the
carrier of
(TOP-REAL 2) means :
Def1:
:: JGRAPH_3:def 1
for b
1 being
Point of
(TOP-REAL 2) holds
( ( b
1 = 0.REAL 2 implies a
1 . b
1 = b
1 ) & ( ( ( b
1 `2 <= b
1 `1 &
- (b1 `1 ) <= b
1 `2 ) or ( b
1 `2 >= b
1 `1 & b
1 `2 <= - (b1 `1 ) ) ) & b
1 <> 0.REAL 2 implies a
1 . b
1 = |[((b1 `1 ) / (sqrt (1 + (((b1 `2 ) / (b1 `1 )) ^2 )))),((b1 `2 ) / (sqrt (1 + (((b1 `2 ) / (b1 `1 )) ^2 ))))]| ) & not ( not ( b
1 `2 <= b
1 `1 &
- (b1 `1 ) <= b
1 `2 ) & not ( b
1 `2 >= b
1 `1 & b
1 `2 <= - (b1 `1 ) ) & b
1 <> 0.REAL 2 & not a
1 . b
1 = |[((b1 `1 ) / (sqrt (1 + (((b1 `1 ) / (b1 `2 )) ^2 )))),((b1 `2 ) / (sqrt (1 + (((b1 `1 ) / (b1 `2 )) ^2 ))))]| ) );
existence
ex b1 being Function of the carrier of (TOP-REAL 2),the carrier of (TOP-REAL 2) st
for b2 being Point of (TOP-REAL 2) holds
( ( b2 = 0.REAL 2 implies b1 . b2 = b2 ) & ( ( ( b2 `2 <= b2 `1 & - (b2 `1 ) <= b2 `2 ) or ( b2 `2 >= b2 `1 & b2 `2 <= - (b2 `1 ) ) ) & b2 <> 0.REAL 2 implies b1 . b2 = |[((b2 `1 ) / (sqrt (1 + (((b2 `2 ) / (b2 `1 )) ^2 )))),((b2 `2 ) / (sqrt (1 + (((b2 `2 ) / (b2 `1 )) ^2 ))))]| ) & not ( not ( b2 `2 <= b2 `1 & - (b2 `1 ) <= b2 `2 ) & not ( b2 `2 >= b2 `1 & b2 `2 <= - (b2 `1 ) ) & b2 <> 0.REAL 2 & not b1 . b2 = |[((b2 `1 ) / (sqrt (1 + (((b2 `1 ) / (b2 `2 )) ^2 )))),((b2 `2 ) / (sqrt (1 + (((b2 `1 ) / (b2 `2 )) ^2 ))))]| ) )
uniqueness
for b1, b2 being Function of the carrier of (TOP-REAL 2),the carrier of (TOP-REAL 2) holds
( ( for b3 being Point of (TOP-REAL 2) holds
( ( b3 = 0.REAL 2 implies b1 . b3 = b3 ) & ( ( ( b3 `2 <= b3 `1 & - (b3 `1 ) <= b3 `2 ) or ( b3 `2 >= b3 `1 & b3 `2 <= - (b3 `1 ) ) ) & b3 <> 0.REAL 2 implies b1 . b3 = |[((b3 `1 ) / (sqrt (1 + (((b3 `2 ) / (b3 `1 )) ^2 )))),((b3 `2 ) / (sqrt (1 + (((b3 `2 ) / (b3 `1 )) ^2 ))))]| ) & not ( not ( b3 `2 <= b3 `1 & - (b3 `1 ) <= b3 `2 ) & not ( b3 `2 >= b3 `1 & b3 `2 <= - (b3 `1 ) ) & b3 <> 0.REAL 2 & not b1 . b3 = |[((b3 `1 ) / (sqrt (1 + (((b3 `1 ) / (b3 `2 )) ^2 )))),((b3 `2 ) / (sqrt (1 + (((b3 `1 ) / (b3 `2 )) ^2 ))))]| ) ) ) & ( for b3 being Point of (TOP-REAL 2) holds
( ( b3 = 0.REAL 2 implies b2 . b3 = b3 ) & ( ( ( b3 `2 <= b3 `1 & - (b3 `1 ) <= b3 `2 ) or ( b3 `2 >= b3 `1 & b3 `2 <= - (b3 `1 ) ) ) & b3 <> 0.REAL 2 implies b2 . b3 = |[((b3 `1 ) / (sqrt (1 + (((b3 `2 ) / (b3 `1 )) ^2 )))),((b3 `2 ) / (sqrt (1 + (((b3 `2 ) / (b3 `1 )) ^2 ))))]| ) & not ( not ( b3 `2 <= b3 `1 & - (b3 `1 ) <= b3 `2 ) & not ( b3 `2 >= b3 `1 & b3 `2 <= - (b3 `1 ) ) & b3 <> 0.REAL 2 & not b2 . b3 = |[((b3 `1 ) / (sqrt (1 + (((b3 `1 ) / (b3 `2 )) ^2 )))),((b3 `2 ) / (sqrt (1 + (((b3 `1 ) / (b3 `2 )) ^2 ))))]| ) ) ) implies b1 = b2 )
end;
:: deftheorem Def1 defines Sq_Circ JGRAPH_3:def 1 :
theorem Th14: :: JGRAPH_3:14
theorem Th15: :: JGRAPH_3:15
theorem Th16: :: JGRAPH_3:16
theorem Th17: :: JGRAPH_3:17
theorem Th18: :: JGRAPH_3:18
theorem Th19: :: JGRAPH_3:19
theorem Th20: :: JGRAPH_3:20
Lemma22:
for b1 being non empty Subset of (TOP-REAL 2)
for b2 being Point of ((TOP-REAL 2) | b1) holds (proj2 | b1) . b2 = proj2 . b2
Lemma23:
for b1 being non empty Subset of (TOP-REAL 2) holds
proj2 | b1 is continuous Function of ((TOP-REAL 2) | b1),R^1
Lemma24:
for b1 being non empty Subset of (TOP-REAL 2)
for b2 being Point of ((TOP-REAL 2) | b1) holds (proj1 | b1) . b2 = proj1 . b2
Lemma25:
for b1 being non empty Subset of (TOP-REAL 2) holds
proj1 | b1 is continuous Function of ((TOP-REAL 2) | b1),R^1
theorem Th21: :: JGRAPH_3:21
theorem Th22: :: JGRAPH_3:22
theorem Th23: :: JGRAPH_3:23
theorem Th24: :: JGRAPH_3:24
Lemma30:
( ( ( (1.REAL 2) `2 <= (1.REAL 2) `1 & - ((1.REAL 2) `1 ) <= (1.REAL 2) `2 ) or ( (1.REAL 2) `2 >= (1.REAL 2) `1 & (1.REAL 2) `2 <= - ((1.REAL 2) `1 ) ) ) & 1.REAL 2 <> 0.REAL 2 )
by JGRAPH_2:13, REVROT_1:19;
Lemma31:
for b1 being non empty Subset of (TOP-REAL 2) holds dom (proj2 * (Sq_Circ | b1)) = the carrier of ((TOP-REAL 2) | b1)
Lemma32:
for b1 being non empty Subset of (TOP-REAL 2) holds dom (proj1 * (Sq_Circ | b1)) = the carrier of ((TOP-REAL 2) | b1)
Lemma33:
the carrier of (TOP-REAL 2) \ {(0.REAL 2)} <> {}
by JGRAPH_2:19;
theorem Th25: :: JGRAPH_3:25
Lemma35:
( ( ( (1.REAL 2) `1 <= (1.REAL 2) `2 & - ((1.REAL 2) `2 ) <= (1.REAL 2) `1 ) or ( (1.REAL 2) `1 >= (1.REAL 2) `2 & (1.REAL 2) `1 <= - ((1.REAL 2) `2 ) ) ) & 1.REAL 2 <> 0.REAL 2 )
by JGRAPH_2:13, REVROT_1:19;
theorem Th26: :: JGRAPH_3:26
theorem Th27: :: JGRAPH_3:27
theorem Th28: :: JGRAPH_3:28
theorem Th29: :: JGRAPH_3:29
theorem Th30: :: JGRAPH_3:30
theorem Th31: :: JGRAPH_3:31
theorem Th32: :: JGRAPH_3:32
theorem Th33: :: JGRAPH_3:33
theorem Th34: :: JGRAPH_3:34
theorem Th35: :: JGRAPH_3:35
theorem Th36: :: JGRAPH_3:36
theorem Th37: :: JGRAPH_3:37
theorem Th38: :: JGRAPH_3:38
theorem Th39: :: JGRAPH_3:39
theorem Th40: :: JGRAPH_3:40
theorem Th41: :: JGRAPH_3:41
theorem Th42: :: JGRAPH_3:42
theorem Th43: :: JGRAPH_3:43
theorem Th44: :: JGRAPH_3:44
theorem Th45: :: JGRAPH_3:45
theorem Th46: :: JGRAPH_3:46
Lemma55:
for b1 being non empty Subset of (TOP-REAL 2) holds
proj2 * ((Sq_Circ " ) | b1) is Function of ((TOP-REAL 2) | b1),R^1
Lemma56:
for b1 being non empty Subset of (TOP-REAL 2) holds
proj1 * ((Sq_Circ " ) | b1) is Function of ((TOP-REAL 2) | b1),R^1
theorem Th47: :: JGRAPH_3:47
theorem Th48: :: JGRAPH_3:48
theorem Th49: :: JGRAPH_3:49
theorem Th50: :: JGRAPH_3:50
theorem Th51: :: JGRAPH_3:51
theorem Th52: :: JGRAPH_3:52
Lemma63:
Sq_Circ " is one-to-one
by FUNCT_1:62;
theorem Th53: :: JGRAPH_3:53
canceled;
theorem Th54: :: JGRAPH_3:54
E66:
now
let c
1 be
real number ;
assume
(c1 ^2 ) - 1
= 0
;
then
(c1 - 1) * (c1 + 1) = 0
;
then
( c
1 - 1
= 0 or c
1 + 1
= 0 )
by XCMPLX_1:6;
then
( c
1 = 0
+ 1 or c
1 + 1
= 0 )
;
then
( c
1 = 1 or c
1 = 0
- 1 )
;
hence
( c
1 = 1 or c
1 = - 1 )
;
end;
theorem Th55: :: JGRAPH_3:55