defpred S₁[ Element of NAT ] means ( [$1,1] in Indices (GoB g) & ex i being Element of NAT st
( i in dom g & g /. i = (GoB g) * $1,1 ) );
set Y = { j where j is Element of NAT : S₁[j] } ;
1 <= width (GoB g) by GOBOARD7:35;
then consider i, j being Element of NAT such that
A70: ( i in dom g & [j,1] in Indices (GoB g) & g /. i = (GoB g) * j,1 ) by Th10;
A71: j in { j where j is Element of NAT : S₁[j] } by A70;
A72: { j where j is Element of NAT : S₁[j] } c= dom (GoB g)

let y be set ; :: according to TARSKI:def 3 :: thesis:
assume y in { j where j is Element of NAT : S₁[j] } ; :: thesis:
then ex j being Element of NAT st
( y = j & [j,1] in Indices (GoB g) & ex i being Element of NAT st
( i in dom g & g /. i = (GoB g) * j,1 ) ) ;
then [y,1] in [:(dom (GoB g)),(Seg (width (GoB g))):] by MATRIX_1:def 5;
hence y in dom (GoB g) by ZFMISC_1:106; :: thesis:

end;

{ j where j is Element of NAT : S₁[j] } is Subset of NAT from DOMAIN_1:sch 7();
then reconsider Y = { j where j is Element of NAT : S₁[j] } as non empty finite Subset of NAT by A71, A72;
reconsider i1 = max Y as Element of NAT by ORDINAL1:def 13;
i1 in Y by XXREAL_2:def 8;
then consider j being Element of NAT such that
A73: ( j = i1 & [j,1] in Indices (GoB g) & ex i being Element of NAT st
( i in dom g & g /. i = (GoB g) * j,1 ) ) ;
consider i being Element of NAT such that
A74: ( i in dom g & g /. i = (GoB g) * j,1 ) by A73;
( 1 <= i1 & i1 <= len (GoB g) & 1 <= 1 & 1 <= width (GoB g) ) by A73, MATRIX_1:39;
then A75: ((GoB g) * i1,1) `2 = ((GoB g) * 1,1) `2 by GOBOARD5:2;
then A76: ((GoB g) * i1,1) `2 = S-bound (L~ g) by Th40;
{ (q `1 ) where q is Point of (TOP-REAL 2) : ( q `2 = S-bound (L~ g) & q in L~ g ) } c= REAL

let X be set ; :: according to TARSKI:def 3 :: thesis:
assume X in { (q `1 ) where q is Point of (TOP-REAL 2) : ( q `2 = S-bound (L~ g) & q in L~ g ) } ; :: thesis:
then ex q being Point of (TOP-REAL 2) st
( X = q `1 & q `2 = S-bound (L~ g) & q in L~ g ) ;
hence X in REAL ; :: thesis:

end;

then reconsider B = { (q `1 ) where q is Point of (TOP-REAL 2) : ( q `2 = S-bound (L~ g) & q in L~ g ) } as Subset of REAL ;
set s1 = ((GoB g) * (len (GoB g)),1) `1 ;
for r being real number st r in B holds
((GoB g) * (len (GoB g)),1) `1 >= r

let r be real number ; :: thesis:
assume r in B ; :: thesis:
then consider q being Point of (TOP-REAL 2) such that
A77: ( r = q `1 & q `2 = S-bound (L~ g) & q in L~ g ) ;
1 <= width (GoB g) by GOBOARD7:35;
hence ((GoB g) * (len (GoB g)),1) `1 >= r by A77, Th34; :: thesis:

end;

then A78: B is bounded_above by SEQ_4:def 1;
A79: ( 1 <= i & i <= len g ) by A74, FINSEQ_3:27;

per cases by A79, XXREAL_0:1;

case i < len g ; :: thesis:

then i + 1 <= len g by NAT_1:13;
then g /. i in LSeg g,i by A79, TOPREAL1:27;
hence (GoB g) * i1,1 in L~ g by A73, A74, SPPOL_2:17; :: thesis:

end;

case i = len g ; :: thesis:

then g /. i in LSeg g,(i -' 1) by Lm9, Th3;
hence (GoB g) * i1,1 in L~ g by A73, A74, SPPOL_2:17; :: thesis:

end;

then ( ((GoB g) * i1,1) `2 = S-bound (L~ g) & (GoB g) * i1,1 in L~ g ) by A75, Th40;
then A80: ((GoB g) * i1,1) `1 in { (q `1 ) where q is Point of (TOP-REAL 2) : ( q `2 = S-bound (L~ g) & q in L~ g ) } ;
then A81: upper_bound B >= ((GoB g) * i1,1) `1 by A78, SEQ_4:def 4;
for r being real number st r in B holds
r <= ((GoB g) * i1,1) `1

let r be real number ; :: thesis:
assume r in B ; :: thesis:
then consider q being Point of (TOP-REAL 2) such that
A82: ( r = q `1 & q `2 = S-bound (L~ g) & q in L~ g ) ;
thus r <= ((GoB g) * i1,1) `1 by A82, Lm7; :: thesis:

end;

then upper_bound B <= ((GoB g) * i1,1) `1 by A80, SEQ_4:62;
then ((GoB g) * i1,1) `1 = upper_bound B by A81, XXREAL_0:1
.= sup (proj1 | (S-most (L~ g))) by Th18 ;
hence ex b₁ being Element of NAT st
( [b₁,1] in Indices (GoB g) & (GoB g) * b₁,1 = S-max (L~ g) ) by A73, A76, EUCLID:57; :: thesis: