let e be epsilon Ordinal; ex a being Ordinal st e = 1 -Veblen a
set U = Tarski-Class (e \/ omega);
A1:
omega in Tarski-Class (e \/ omega)
by Th57;
( 0-element_of (Tarski-Class (e \/ omega)) = 0 & 1-element_of (Tarski-Class (e \/ omega)) = 1 )
;
then reconsider f = ((Tarski-Class (e \/ omega)) -Veblen) . 0, g = ((Tarski-Class (e \/ omega)) -Veblen) . 1 as normal Ordinal-Sequence of (Tarski-Class (e \/ omega)) by A1, Th62;
A2: g =
criticals ((Tarski-Class (e \/ omega)) exp omega)
by Th74
.=
criticals f
by Def15
;
A3: f . e =
0 -Veblen e
.=
exp (omega,e)
by Th68
.=
e
by ORDINAL5:def 5
;
A4:
dom f = On (Tarski-Class (e \/ omega))
by FUNCT_2:def 1;
( e c= e \/ omega & e \/ omega in Tarski-Class (e \/ omega) )
by CLASSES1:2, XBOOLE_1:7;
then A5:
e in Tarski-Class (e \/ omega)
by CLASSES1:def 1;
then
e in On (Tarski-Class (e \/ omega))
by ORDINAL1:def 9;
then
e is_a_fixpoint_of f
by A3, A4;
then consider a being Ordinal such that
A6:
( a in dom (criticals f) & e = (criticals f) . a )
by Th33;
take
a
; e = 1 -Veblen a
set W = Tarski-Class (a \/ omega);
A7:
( a c= a \/ omega & a \/ omega in Tarski-Class (a \/ omega) )
by CLASSES1:2, XBOOLE_1:7;
a c= e
by A6, ORDINAL4:10;
then
( omega in Tarski-Class (a \/ omega) & a in Tarski-Class (a \/ omega) & a in Tarski-Class (e \/ omega) & 1-element_of (Tarski-Class (e \/ omega)) = 1-element_of (Tarski-Class (a \/ omega)) )
by A5, A7, Th57, CLASSES1:def 1;
hence
e = 1 -Veblen a
by A1, A2, A6, Th64; verum