reconsider O = 0 , I = 1 as Point of I[01] by BORSUK_1:83, XXREAL_1:1;
let p1, p2, p3, p4 be Point of (TOP-REAL 2); :: thesis: for a, b, c, d being real number
for f, g being Function of I[01] ,(TOP-REAL 2) st a < b & c < d & p1 `2 = d & p2 `2 = d & p3 `2 = d & p4 `1 = b & a <= p1 `1 & p1 `1 < p2 `1 & p2 `1 < p3 `1 & p3 `1 <= b & c <= p4 `2 & p4 `2 <= d & f . 0 = p1 & f . 1 = p3 & g . 0 = p2 & g . 1 = p4 & f is continuous & f is one-to-one & g is continuous & g is one-to-one & rng f c= closed_inside_of_rectangle a,b,c,d & rng g c= closed_inside_of_rectangle a,b,c,d holds
rng f meets rng g
let a, b, c, d be real number ; :: thesis: for f, g being Function of I[01] ,(TOP-REAL 2) st a < b & c < d & p1 `2 = d & p2 `2 = d & p3 `2 = d & p4 `1 = b & a <= p1 `1 & p1 `1 < p2 `1 & p2 `1 < p3 `1 & p3 `1 <= b & c <= p4 `2 & p4 `2 <= d & f . 0 = p1 & f . 1 = p3 & g . 0 = p2 & g . 1 = p4 & f is continuous & f is one-to-one & g is continuous & g is one-to-one & rng f c= closed_inside_of_rectangle a,b,c,d & rng g c= closed_inside_of_rectangle a,b,c,d holds
rng f meets rng g
let f, g be Function of I[01] ,(TOP-REAL 2); :: thesis: ( a < b & c < d & p1 `2 = d & p2 `2 = d & p3 `2 = d & p4 `1 = b & a <= p1 `1 & p1 `1 < p2 `1 & p2 `1 < p3 `1 & p3 `1 <= b & c <= p4 `2 & p4 `2 <= d & f . 0 = p1 & f . 1 = p3 & g . 0 = p2 & g . 1 = p4 & f is continuous & f is one-to-one & g is continuous & g is one-to-one & rng f c= closed_inside_of_rectangle a,b,c,d & rng g c= closed_inside_of_rectangle a,b,c,d implies rng f meets rng g )
assume that
A1: a < b and
A2: c < d and
A3: p1 `2 = d and
A4: p2 `2 = d and
A5: p3 `2 = d and
A6: p4 `1 = b and
A7: a <= p1 `1 and
A8: p1 `1 < p2 `1 and
A9: p2 `1 < p3 `1 and
A10: p3 `1 <= b and
A11: c <= p4 `2 and
A12: p4 `2 <= d and
A13: f . 0 = p1 and
A14: f . 1 = p3 and
A15: g . 0 = p2 and
A16: g . 1 = p4 and
A17: ( f is continuous & f is one-to-one ) and
A18: ( g is continuous & g is one-to-one ) and
A19: rng f c= closed_inside_of_rectangle a,b,c,d and
A20: rng g c= closed_inside_of_rectangle a,b,c,d ; :: thesis: rng f meets rng g
set A = 2 / (b - a);
set B = - ((b + a) / (b - a));
set C = 2 / (d - c);
set D = - ((d + c) / (d - c));
set h = AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)));
reconsider f2 = (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) * f as Function of I[01] ,(TOP-REAL 2) ;
A21: p1 `1 < p3 `1 by A8, A9, XXREAL_0:2;
reconsider g2 = (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) * g as Function of I[01] ,(TOP-REAL 2) ;
A22: - 1 <= (g2 . I) `2 by A1, A2, A6, A11, A12, A16, Th63;
A23: (g2 . I) `1 = 1 by A1, A6, A16, Th56;
A24: (g2 . O) `2 = 1 by A2, A4, A15, Th55;
(f . I) `2 = d by A5, A14;
then A25: - 1 <= (f2 . O) `1 by A1, A7, A10, A13, A14, A21, Th62;
A26: ( g2 is continuous & g2 is one-to-one ) by A1, A2, A18, Th53;
consider x being Element of (rng f2) /\ (rng g2);
A27: dom f = the carrier of I[01] by FUNCT_2:def 1;
then A28: (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p3 = f2 . I by A14, FUNCT_1:23;
d - c > 0 by A2, XREAL_1:52;
then A29: 2 / (d - c) > 0 by XREAL_1:141;
b - a > 0 by A1, XREAL_1:52;
then A30: 2 / (b - a) > 0 by XREAL_1:141;
then A31: ((AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p1) `1 < ((AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p2) `1 by A8, A29, Th50;
(f . O) `2 = d by A3, A13;
then A32: (f2 . I) `1 <= 1 by A1, A7, A10, A13, A14, A21, Th62;
AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c))) is being_homeomorphism by A30, A29, Th50;
then A33: AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c))) is one-to-one by TOPS_2:def 5;
A34: rng f2 c= closed_inside_of_rectangle (- 1),1,(- 1),1 by A1, A2, A19, Th52;
A35: (f2 . I) `2 = 1 by A2, A5, A14, Th55;
A36: (f2 . O) `2 = 1 by A2, A3, A13, Th55;
A37: ( f2 is continuous & f2 is one-to-one ) by A1, A2, A17, Th53;
A38: rng g2 c= closed_inside_of_rectangle (- 1),1,(- 1),1 by A1, A2, A20, Th52;
A39: ((AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p2) `1 < ((AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p3) `1 by A9, A30, A29, Th50;
A40: (g2 . I) `2 <= 1 by A1, A2, A6, A11, A12, A16, Th63;
A41: dom g = the carrier of I[01] by FUNCT_2:def 1;
then A42: (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p2 = g2 . O by A15, FUNCT_1:23;
(AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . p1 = f2 . O by A13, A27, FUNCT_1:23;
then rng f2 meets rng g2 by A31, A39, A42, A28, A37, A36, A35, A25, A32, A34, A26, A24, A23, A22, A40, A38, Th35, JGRAPH_6:89;
then A43: (rng f2) /\ (rng g2) <> {} by XBOOLE_0:def 7;
then x in rng g2 by XBOOLE_0:def 4;
then consider z2 being set such that
A44: z2 in dom g2 and
A45: x = g2 . z2 by FUNCT_1:def 5;
A46: x = (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . (g . z2) by A41, A44, A45, FUNCT_1:23;
A47: g . z2 in rng g by A41, A44, FUNCT_1:def 5;
g . z2 in the carrier of (TOP-REAL 2) by A44, FUNCT_2:7;
then A48: g . z2 in dom (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) by FUNCT_2:def 1;
x in rng f2 by A43, XBOOLE_0:def 4;
then consider z1 being set such that
A49: z1 in dom f2 and
A50: x = f2 . z1 by FUNCT_1:def 5;
A51: f . z1 in rng f by A27, A49, FUNCT_1:def 5;
f . z1 in the carrier of (TOP-REAL 2) by A49, FUNCT_2:7;
then A52: f . z1 in dom (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) by FUNCT_2:def 1;
x = (AffineMap (2 / (b - a)),(- ((b + a) / (b - a))),(2 / (d - c)),(- ((d + c) / (d - c)))) . (f . z1) by A27, A49, A50, FUNCT_1:23;
then f . z1 = g . z2 by A46, A52, A48, A33, FUNCT_1:def 8;
hence rng f meets rng g by A51, A47, XBOOLE_0:3; :: thesis: verum