let i, j, k be Nat; for f being FinSequence of the carrier of (TOP-REAL 2)
for G being Go-board st f is_sequence_on G & LSeg ((G * (i,j)),(G * (i,k))) meets L~ f & [i,j] in Indices G & [i,k] in Indices G & j <= k holds
ex n being Nat st
( j <= n & n <= k & (G * (i,n)) `2 = lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) )
let f be FinSequence of the carrier of (TOP-REAL 2); for G being Go-board st f is_sequence_on G & LSeg ((G * (i,j)),(G * (i,k))) meets L~ f & [i,j] in Indices G & [i,k] in Indices G & j <= k holds
ex n being Nat st
( j <= n & n <= k & (G * (i,n)) `2 = lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) )
let G be Go-board; ( f is_sequence_on G & LSeg ((G * (i,j)),(G * (i,k))) meets L~ f & [i,j] in Indices G & [i,k] in Indices G & j <= k implies ex n being Nat st
( j <= n & n <= k & (G * (i,n)) `2 = lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) ) )
set X = (LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f);
assume that
A1:
f is_sequence_on G
and
A2:
LSeg ((G * (i,j)),(G * (i,k))) meets L~ f
and
A3:
[i,j] in Indices G
and
A4:
[i,k] in Indices G
and
A5:
j <= k
; ex n being Nat st
( j <= n & n <= k & (G * (i,n)) `2 = lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) )
A6:
( 1 <= i & i <= len G )
by A3, MATRIX_0:32;
ex x being object st
( x in LSeg ((G * (i,j)),(G * (i,k))) & x in L~ f )
by A2, XBOOLE_0:3;
then reconsider X1 = (LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f) as non empty compact Subset of (TOP-REAL 2) by XBOOLE_0:def 4;
consider p being object such that
A7:
p in S-most X1
by XBOOLE_0:def 1;
reconsider p = p as Point of (TOP-REAL 2) by A7;
A8:
p in (LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f)
by A7, XBOOLE_0:def 4;
then A9:
p in LSeg ((G * (i,j)),(G * (i,k)))
by XBOOLE_0:def 4;
proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f)) = (proj2 | ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))
by RELAT_1:129;
then A10: lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) =
lower_bound ((proj2 | ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) .: ([#] ((TOP-REAL 2) | ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f)))))
by PRE_TOPC:def 5
.=
S-bound ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))
;
A11:
1 <= k
by A4, MATRIX_0:32;
A12: p `2 =
(S-min ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) `2
by A7, PSCOMP_1:55
.=
lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f)))
by A10, EUCLID:52
;
A13:
( 1 <= i & i <= len G )
by A3, MATRIX_0:32;
A14:
1 <= j
by A3, MATRIX_0:32;
A15:
k <= width G
by A4, MATRIX_0:32;
then A16:
(G * (i,j)) `2 <= (G * (i,k)) `2
by A5, A6, A14, SPRECT_3:12;
then A17:
(G * (i,j)) `2 <= p `2
by A9, TOPREAL1:4;
A18:
p `2 <= (G * (i,k)) `2
by A9, A16, TOPREAL1:4;
A19:
j <= width G
by A3, MATRIX_0:32;
then A20: (G * (i,j)) `1 =
(G * (i,1)) `1
by A6, A14, GOBOARD5:2
.=
(G * (i,k)) `1
by A13, A11, A15, GOBOARD5:2
;
p in L~ f
by A8, XBOOLE_0:def 4;
then
p in union { (LSeg (f,k1)) where k1 is Nat : ( 1 <= k1 & k1 + 1 <= len f ) }
by TOPREAL1:def 4;
then consider Y being set such that
A21:
p in Y
and
A22:
Y in { (LSeg (f,k1)) where k1 is Nat : ( 1 <= k1 & k1 + 1 <= len f ) }
by TARSKI:def 4;
consider i1 being Nat such that
A23:
Y = LSeg (f,i1)
and
A24:
1 <= i1
and
A25:
i1 + 1 <= len f
by A22;
A26:
p in LSeg ((f /. i1),(f /. (i1 + 1)))
by A21, A23, A24, A25, TOPREAL1:def 3;
1 < i1 + 1
by A24, NAT_1:13;
then
i1 + 1 in Seg (len f)
by A25, FINSEQ_1:1;
then A27:
i1 + 1 in dom f
by FINSEQ_1:def 3;
then consider io, jo being Nat such that
A28:
[io,jo] in Indices G
and
A29:
f /. (i1 + 1) = G * (io,jo)
by A1, GOBOARD1:def 9;
A30:
( 1 <= io & io <= len G )
by A28, MATRIX_0:32;
A31:
1 <= jo
by A28, MATRIX_0:32;
i1 <= len f
by A25, NAT_1:13;
then
i1 in Seg (len f)
by A24, FINSEQ_1:1;
then A32:
i1 in dom f
by FINSEQ_1:def 3;
then consider i0, j0 being Nat such that
A33:
[i0,j0] in Indices G
and
A34:
f /. i1 = G * (i0,j0)
by A1, GOBOARD1:def 9;
A35:
( 1 <= i0 & i0 <= len G )
by A33, MATRIX_0:32;
A36:
1 <= j0
by A33, MATRIX_0:32;
A37:
j0 <= width G
by A33, MATRIX_0:32;
A38:
jo <= width G
by A28, MATRIX_0:32;
A39:
f is special
by A1, A32, JORDAN8:4, RELAT_1:38;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )
proof
per cases
( (f /. i1) `1 = (f /. (i1 + 1)) `1 or (f /. i1) `2 = (f /. (i1 + 1)) `2 )
by A24, A25, A39, TOPREAL1:def 5;
suppose A40:
(f /. i1) `1 = (f /. (i1 + 1)) `1
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )(G * (io,j)) `1 =
(G * (io,1)) `1
by A14, A19, A30, GOBOARD5:2
.=
(G * (io,jo)) `1
by A30, A31, A38, GOBOARD5:2
.=
p `1
by A26, A29, A40, GOBOARD7:5
.=
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
;
then
(
io <= i &
io >= i )
by A6, A14, A19, A30, GOBOARD5:3;
then A41:
i = io
by XXREAL_0:1;
(G * (i0,j)) `1 =
(G * (i0,1)) `1
by A14, A19, A35, GOBOARD5:2
.=
(G * (i0,j0)) `1
by A35, A36, A37, GOBOARD5:2
.=
p `1
by A26, A34, A40, GOBOARD7:5
.=
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
;
then
(
i0 <= i &
i0 >= i )
by A6, A14, A19, A35, GOBOARD5:3;
then A42:
i = i0
by XXREAL_0:1;
thus
ex
n being
Nat st
(
j <= n &
n <= k &
G * (
i,
n)
= p )
verumproof
per cases
( (f /. i1) `2 <= (f /. (i1 + 1)) `2 or (f /. i1) `2 > (f /. (i1 + 1)) `2 )
;
suppose A43:
(f /. i1) `2 <= (f /. (i1 + 1)) `2
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )thus
ex
n being
Nat st
(
j <= n &
n <= k &
G * (
i,
n)
= p )
verumproof
per cases
( f /. i1 in LSeg ((G * (i,j)),(G * (i,k))) or not f /. i1 in LSeg ((G * (i,j)),(G * (i,k))) )
;
suppose A44:
f /. i1 in LSeg (
(G * (i,j)),
(G * (i,k)))
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )
1
+ 1
<= i1 + 1
by A24, XREAL_1:6;
then
f /. i1 in L~ f
by A25, A32, GOBOARD1:1, XXREAL_0:2;
then
f /. i1 in X1
by A44, XBOOLE_0:def 4;
then A45:
p `2 <= (f /. i1) `2
by A10, A12, PSCOMP_1:24;
take n =
j0;
( j <= n & n <= k & G * (i,n) = p )A46:
p in LSeg (
(G * (i,j)),
(G * (i,k)))
by A8, XBOOLE_0:def 4;
p `2 >= (f /. i1) `2
by A26, A43, TOPREAL1:4;
then
p `2 = (f /. i1) `2
by A45, XXREAL_0:1;
then A47:
p `2 =
(G * (1,j0)) `2
by A34, A35, A36, A37, GOBOARD5:1
.=
(G * (i,n)) `2
by A6, A36, A37, GOBOARD5:1
;
A48:
(G * (i,j)) `2 <= (G * (i,k)) `2
by A5, A6, A14, A15, SPRECT_3:12;
then
(G * (i,j)) `2 <= (G * (i,n)) `2
by A46, A47, TOPREAL1:4;
hence
j <= n
by A6, A19, A36, GOBOARD5:4;
( n <= k & G * (i,n) = p )
(G * (i,n)) `2 <= (G * (i,k)) `2
by A46, A47, A48, TOPREAL1:4;
hence
n <= k
by A13, A11, A37, GOBOARD5:4;
G * (i,n) = pp `1 =
(G * (i,j)) `1
by A20, A46, GOBOARD7:5
.=
(G * (i,1)) `1
by A6, A14, A19, GOBOARD5:2
.=
(G * (i,n)) `1
by A6, A36, A37, GOBOARD5:2
;
hence
G * (
i,
n)
= p
by A47, TOPREAL3:6;
verum suppose A49:
not
f /. i1 in LSeg (
(G * (i,j)),
(G * (i,k)))
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )A50:
(f /. i1) `1 =
p `1
by A26, A40, GOBOARD7:5
.=
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
;
thus
ex
n being
Nat st
(
j <= n &
n <= k &
G * (
i,
n)
= p )
verumproof
per cases
( (f /. i1) `2 < (G * (i,j)) `2 or (f /. i1) `2 > (G * (i,k)) `2 )
by A20, A49, A50, GOBOARD7:7;
suppose A51:
(f /. i1) `2 < (G * (i,j)) `2
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )
p `2 <= (G * (io,jo)) `2
by A26, A29, A43, TOPREAL1:4;
then
p `2 <= (G * (1,jo)) `2
by A30, A31, A38, GOBOARD5:1;
then
p `2 <= (G * (i,jo)) `2
by A6, A31, A38, GOBOARD5:1;
then
(G * (i,j)) `2 <= (G * (i,jo)) `2
by A17, XXREAL_0:2;
then A52:
j <= jo
by A6, A19, A31, GOBOARD5:4;
|.(i0 - io).| + |.(j0 - jo).| = 1
by A1, A32, A27, A33, A34, A28, A29, GOBOARD1:def 9;
then
0 + |.(j0 - jo).| = 1
by A42, A41, ABSVALUE:2;
then A53:
|.(- (j0 - jo)).| = 1
by COMPLEX1:52;
j0 <= jo + 0
by A34, A29, A35, A37, A31, A42, A41, A43, GOBOARD5:4;
then
j0 - jo <= 0
by XREAL_1:20;
then
jo - j0 = 1
by A53, ABSVALUE:def 1;
then A54:
j0 + 1
= jo + 0
;
(
(G * (i,j0)) `2 < (G * (i,j)) `2 &
j0 <= j )
by A34, A6, A14, A37, A42, A51, GOBOARD5:4;
then
j0 < j
by XXREAL_0:1;
then
jo <= j
by A54, NAT_1:13;
then A55:
j = jo
by A52, XXREAL_0:1;
take n =
jo;
( j <= n & n <= k & G * (i,n) = p )A56:
p `1 =
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
.=
(G * (i,1)) `1
by A6, A14, A19, GOBOARD5:2
.=
(G * (i,n)) `1
by A6, A31, A38, GOBOARD5:2
;
p `2 <= (G * (io,jo)) `2
by A26, A29, A43, TOPREAL1:4;
then
p `2 <= (G * (1,jo)) `2
by A30, A31, A38, GOBOARD5:1;
then
p `2 <= (G * (i,jo)) `2
by A6, A31, A38, GOBOARD5:1;
then
p `2 = (G * (i,j)) `2
by A17, A55, XXREAL_0:1;
hence
(
j <= n &
n <= k &
G * (
i,
n)
= p )
by A5, A55, A56, TOPREAL3:6;
verum end;
end; end;
end; end; suppose A58:
(f /. i1) `2 > (f /. (i1 + 1)) `2
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )thus
ex
n being
Nat st
(
j <= n &
n <= k &
G * (
i,
n)
= p )
verumproof
per cases
( f /. (i1 + 1) in LSeg ((G * (i,j)),(G * (i,k))) or not f /. (i1 + 1) in LSeg ((G * (i,j)),(G * (i,k))) )
;
suppose A59:
f /. (i1 + 1) in LSeg (
(G * (i,j)),
(G * (i,k)))
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )
1
+ 1
<= i1 + 1
by A24, XREAL_1:6;
then
f /. (i1 + 1) in L~ f
by A25, A27, GOBOARD1:1, XXREAL_0:2;
then
f /. (i1 + 1) in X1
by A59, XBOOLE_0:def 4;
then A60:
p `2 <= (f /. (i1 + 1)) `2
by A10, A12, PSCOMP_1:24;
take n =
jo;
( j <= n & n <= k & G * (i,n) = p )A61:
p in LSeg (
(G * (i,j)),
(G * (i,k)))
by A8, XBOOLE_0:def 4;
p `2 >= (f /. (i1 + 1)) `2
by A26, A58, TOPREAL1:4;
then
p `2 = (f /. (i1 + 1)) `2
by A60, XXREAL_0:1;
then A62:
p `2 =
(G * (1,jo)) `2
by A29, A30, A31, A38, GOBOARD5:1
.=
(G * (i,n)) `2
by A6, A31, A38, GOBOARD5:1
;
A63:
(G * (i,j)) `2 <= (G * (i,k)) `2
by A5, A6, A14, A15, SPRECT_3:12;
then
(G * (i,j)) `2 <= (G * (i,n)) `2
by A61, A62, TOPREAL1:4;
hence
j <= n
by A6, A19, A31, GOBOARD5:4;
( n <= k & G * (i,n) = p )
(G * (i,n)) `2 <= (G * (i,k)) `2
by A61, A62, A63, TOPREAL1:4;
hence
n <= k
by A13, A11, A38, GOBOARD5:4;
G * (i,n) = pp `1 =
(G * (i,j)) `1
by A20, A61, GOBOARD7:5
.=
(G * (i,1)) `1
by A6, A14, A19, GOBOARD5:2
.=
(G * (i,n)) `1
by A6, A31, A38, GOBOARD5:2
;
hence
G * (
i,
n)
= p
by A62, TOPREAL3:6;
verum suppose A64:
not
f /. (i1 + 1) in LSeg (
(G * (i,j)),
(G * (i,k)))
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )A65:
(f /. (i1 + 1)) `1 =
p `1
by A26, A40, GOBOARD7:5
.=
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
;
thus
ex
n being
Nat st
(
j <= n &
n <= k &
G * (
i,
n)
= p )
verumproof
per cases
( (f /. (i1 + 1)) `2 < (G * (i,j)) `2 or (f /. (i1 + 1)) `2 > (G * (i,k)) `2 )
by A20, A64, A65, GOBOARD7:7;
suppose A66:
(f /. (i1 + 1)) `2 < (G * (i,j)) `2
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )
p `2 <= (G * (i0,j0)) `2
by A26, A34, A58, TOPREAL1:4;
then
p `2 <= (G * (1,j0)) `2
by A35, A36, A37, GOBOARD5:1;
then
p `2 <= (G * (i,j0)) `2
by A6, A36, A37, GOBOARD5:1;
then
(G * (i,j)) `2 <= (G * (i,j0)) `2
by A17, XXREAL_0:2;
then A67:
j <= j0
by A6, A19, A36, GOBOARD5:4;
jo <= j0 + 0
by A34, A29, A35, A36, A38, A42, A41, A58, GOBOARD5:4;
then
jo - j0 <= 0
by XREAL_1:20;
then A68:
- (jo - j0) >= - 0
;
|.(i0 - io).| + |.(j0 - jo).| = 1
by A1, A32, A27, A33, A34, A28, A29, GOBOARD1:def 9;
then
0 + |.(j0 - jo).| = 1
by A42, A41, ABSVALUE:2;
then
j0 - jo = 1
by A68, ABSVALUE:def 1;
then A69:
jo + 1
= j0 - 0
;
(
(G * (i,jo)) `2 < (G * (i,j)) `2 &
jo <= j )
by A29, A6, A14, A38, A41, A66, GOBOARD5:4;
then
jo < j
by XXREAL_0:1;
then
j0 <= j
by A69, NAT_1:13;
then A70:
j = j0
by A67, XXREAL_0:1;
take n =
j0;
( j <= n & n <= k & G * (i,n) = p )A71:
p `1 =
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
.=
(G * (i,1)) `1
by A6, A14, A19, GOBOARD5:2
.=
(G * (i,n)) `1
by A6, A36, A37, GOBOARD5:2
;
p `2 <= (G * (i0,j0)) `2
by A26, A34, A58, TOPREAL1:4;
then
p `2 <= (G * (1,j0)) `2
by A35, A36, A37, GOBOARD5:1;
then
p `2 <= (G * (i,j0)) `2
by A6, A36, A37, GOBOARD5:1;
then
p `2 = (G * (i,j)) `2
by A17, A70, XXREAL_0:1;
hence
(
j <= n &
n <= k &
G * (
i,
n)
= p )
by A5, A70, A71, TOPREAL3:6;
verum end;
end; end;
end; end;
end; end; suppose A73:
(f /. i1) `2 = (f /. (i1 + 1)) `2
;
ex n being Nat st
( j <= n & n <= k & G * (i,n) = p )take n =
j0;
( j <= n & n <= k & G * (i,n) = p )
p `2 = (f /. i1) `2
by A26, A73, GOBOARD7:6;
then A74:
p `2 =
(G * (1,j0)) `2
by A34, A35, A36, A37, GOBOARD5:1
.=
(G * (i,n)) `2
by A6, A36, A37, GOBOARD5:1
;
A75:
(G * (i,j)) `2 <= (G * (i,k)) `2
by A5, A6, A14, A15, SPRECT_3:12;
then
(G * (i,j)) `2 <= (G * (i,n)) `2
by A9, A74, TOPREAL1:4;
hence
j <= n
by A6, A19, A36, GOBOARD5:4;
( n <= k & G * (i,n) = p )
(G * (i,n)) `2 <= (G * (i,k)) `2
by A9, A74, A75, TOPREAL1:4;
hence
n <= k
by A13, A11, A37, GOBOARD5:4;
G * (i,n) = pp `1 =
(G * (i,j)) `1
by A20, A9, GOBOARD7:5
.=
(G * (i,1)) `1
by A6, A14, A19, GOBOARD5:2
.=
(G * (i,n)) `1
by A6, A36, A37, GOBOARD5:2
;
hence
G * (
i,
n)
= p
by A74, TOPREAL3:6;
verum end;
end;
hence
ex n being Nat st
( j <= n & n <= k & (G * (i,n)) `2 = lower_bound (proj2 .: ((LSeg ((G * (i,j)),(G * (i,k)))) /\ (L~ f))) )
by A12; verum