let i1 be Element of NAT ; :: thesis: for p being Point of (TOP-REAL 2)
for Y being non empty finite Subset of NAT
for h being non constant standard special_circular_sequence st p `1 = E-bound (L~ h) & p in L~ h & Y = { j where j is Element of NAT : ( [(len (GoB h)),j] in Indices (GoB h) & ex i being Element of NAT st
( i in dom h & h /. i = (GoB h) * (len (GoB h)),j ) ) } & i1 = max Y holds
((GoB h) * (len (GoB h)),i1) `2 >= p `2
let p be Point of (TOP-REAL 2); :: thesis: for Y being non empty finite Subset of NAT
for h being non constant standard special_circular_sequence st p `1 = E-bound (L~ h) & p in L~ h & Y = { j where j is Element of NAT : ( [(len (GoB h)),j] in Indices (GoB h) & ex i being Element of NAT st
( i in dom h & h /. i = (GoB h) * (len (GoB h)),j ) ) } & i1 = max Y holds
((GoB h) * (len (GoB h)),i1) `2 >= p `2
let Y be non empty finite Subset of NAT ; :: thesis: for h being non constant standard special_circular_sequence st p `1 = E-bound (L~ h) & p in L~ h & Y = { j where j is Element of NAT : ( [(len (GoB h)),j] in Indices (GoB h) & ex i being Element of NAT st
( i in dom h & h /. i = (GoB h) * (len (GoB h)),j ) ) } & i1 = max Y holds
((GoB h) * (len (GoB h)),i1) `2 >= p `2
let h be non constant standard special_circular_sequence; :: thesis: ( p `1 = E-bound (L~ h) & p in L~ h & Y = { j where j is Element of NAT : ( [(len (GoB h)),j] in Indices (GoB h) & ex i being Element of NAT st
( i in dom h & h /. i = (GoB h) * (len (GoB h)),j ) ) } & i1 = max Y implies ((GoB h) * (len (GoB h)),i1) `2 >= p `2 )
A1: 1 <= len (GoB h) by GOBOARD7:34;
assume A2: ( p `1 = E-bound (L~ h) & p in L~ h & Y = { j where j is Element of NAT : ( [(len (GoB h)),j] in Indices (GoB h) & ex i being Element of NAT st
( i in dom h & h /. i = (GoB h) * (len (GoB h)),j ) ) } & i1 = max Y ) ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then consider i being Element of NAT such that
A3: 1 <= i and
A4: i + 1 <= len h and
A5: p in LSeg (h /. i),(h /. (i + 1)) by SPPOL_2:14;
A6: 1 <= i + 1 by A3, XREAL_1:147;
i <= i + 1 by NAT_1:11;
then A7: i <= len h by A4, XXREAL_0:2;
A8: p `1 = ((GoB h) * (len (GoB h)),1) `1 by A2, Th41;
A9: 1 <= width (GoB h) by GOBOARD7:35;
now
per cases ( LSeg h,i is vertical or LSeg h,i is horizontal ) by SPPOL_1:41;
case LSeg h,i is vertical ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then LSeg (h /. i),(h /. (i + 1)) is vertical by A3, A4, TOPREAL1:def 5;
then A10: (h /. i) `1 = (h /. (i + 1)) `1 by SPPOL_1:37;
then A11: p `1 = (h /. i) `1 by A5, GOBOARD7:5;
A12: p `1 = (h /. (i + 1)) `1 by A5, A10, GOBOARD7:5;
now
per cases ( (h /. i) `2 >= (h /. (i + 1)) `2 or (h /. i) `2 < (h /. (i + 1)) `2 ) ;
case (h /. i) `2 >= (h /. (i + 1)) `2 ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then A13: (h /. i) `2 >= p `2 by A5, TOPREAL1:10;
((GoB h) * (len (GoB h)),i1) `2 >= (h /. i) `2 by A2, A8, A1, A3, A7, A11, Th46;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 by A13, XXREAL_0:2; :: thesis: verum
end;
case (h /. i) `2 < (h /. (i + 1)) `2 ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then A14: (h /. (i + 1)) `2 >= p `2 by A5, TOPREAL1:10;
((GoB h) * (len (GoB h)),i1) `2 >= (h /. (i + 1)) `2 by A2, A8, A1, A4, A6, A12, Th46;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 by A14, XXREAL_0:2; :: thesis: verum
end;
end;
end;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 ; :: thesis: verum
end;
case LSeg h,i is horizontal ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then LSeg (h /. i),(h /. (i + 1)) is horizontal by A3, A4, TOPREAL1:def 5;
then A15: (h /. i) `2 = (h /. (i + 1)) `2 by SPPOL_1:36;
then A16: p `2 = (h /. i) `2 by A5, GOBOARD7:6;
A17: p `2 = (h /. (i + 1)) `2 by A5, A15, GOBOARD7:6;
now
per cases ( (h /. i) `1 >= (h /. (i + 1)) `1 or (h /. i) `1 < (h /. (i + 1)) `1 ) ;
case (h /. i) `1 >= (h /. (i + 1)) `1 ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then A18: (h /. i) `1 >= ((GoB h) * (len (GoB h)),1) `1 by A8, A5, TOPREAL1:9;
(h /. i) `1 <= ((GoB h) * (len (GoB h)),1) `1 by A9, A3, A7, Th7;
then (h /. i) `1 = ((GoB h) * (len (GoB h)),1) `1 by A18, XXREAL_0:1;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 by A2, A1, A3, A7, A16, Th46; :: thesis: verum
end;
case (h /. i) `1 < (h /. (i + 1)) `1 ; :: thesis: ((GoB h) * (len (GoB h)),i1) `2 >= p `2
then A19: (h /. (i + 1)) `1 >= ((GoB h) * (len (GoB h)),1) `1 by A8, A5, TOPREAL1:9;
(h /. (i + 1)) `1 <= ((GoB h) * (len (GoB h)),1) `1 by A9, A4, A6, Th7;
then (h /. (i + 1)) `1 = ((GoB h) * (len (GoB h)),1) `1 by A19, XXREAL_0:1;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 by A2, A1, A4, A6, A17, Th46; :: thesis: verum
end;
end;
end;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 ; :: thesis: verum
end;
end;
end;
hence ((GoB h) * (len (GoB h)),i1) `2 >= p `2 ; :: thesis: verum