now :: thesis: for Seqts1, Seqts2 being Subset of (S -sequents) st Seqts1 c= Seqts2 holds
(R#3a S) . Seqts1 c= (R#3a S) . Seqts2
let Seqts1, Seqts2 be Subset of (S -sequents); :: thesis: ( Seqts1 c= Seqts2 implies (R#3a S) . Seqts1 c= (R#3a S) . Seqts2 )
set X = Seqts1;
set Y = Seqts2;
assume A2: Seqts1 c= Seqts2 ; :: thesis: (R#3a S) . Seqts1 c= (R#3a S) . Seqts2
set R = R#3a S;
set Q = S -sequents ;
now :: thesis: for x being set st x in (R#3a S) . Seqts1 holds
x in (R#3a S) . Seqts2
let x be set ; :: thesis: ( x in (R#3a S) . Seqts1 implies x in (R#3a S) . Seqts2 )
assume A3: x in (R#3a S) . Seqts1 ; :: thesis: x in (R#3a S) . Seqts2
reconsider seqt = x as Element of S -sequents by A3;
[Seqts1,seqt] in P#3a S by A3, Lm29;
then seqt Rule3a Seqts1 by Def34;
then consider t, t1, t2 being termal string of S, xx being set such that
A4: ( xx in Seqts1 & seqt `1 = (xx `1) \/ {((<*(TheEqSymbOf S)*> ^ t1) ^ t2)} & xx `2 = (<*(TheEqSymbOf S)*> ^ t) ^ t1 & seqt `2 = (<*(TheEqSymbOf S)*> ^ t) ^ t2 ) by Def21;
seqt Rule3a Seqts2 by Def21, A4, A2;
then [Seqts2,seqt] in P#3a S by Def34;
hence x in (R#3a S) . Seqts2 by Lm26; :: thesis: verum
end;
hence (R#3a S) . Seqts1 c= (R#3a S) . Seqts2 by TARSKI:def 3; :: thesis: verum
end;
hence for b1 being Rule of S st b1 = R#3a S holds
b1 is isotone by Def9; :: thesis: verum