let n be Nat; :: thesis: for e being epsilon Ordinal st 0 in n holds
e |^|^ (n + 2) = exp (omega,(e |^|^ (n + 1)))
let e be epsilon Ordinal; :: thesis: ( 0 in n implies e |^|^ (n + 2) = exp (omega,(e |^|^ (n + 1))) )
assume A1: 0 in n ; :: thesis: e |^|^ (n + 2) = exp (omega,(e |^|^ (n + 1)))
0 in e by ORDINAL3:8;
then ( omega in e & e c= e |^|^ n ) by A1, Th23, Th37;
then A2: omega c= e |^|^ n by ORDINAL1:def 2;
thus e |^|^ (n + 2) = e |^|^ (Segm ((n + 1) + 1))
.= e |^|^ (succ (Segm (n + 1))) by NAT_1:38
.= exp (e,(e |^|^ (n + 1))) by Th14
.= exp ((exp (omega,e)),(e |^|^ (n + 1))) by Def5
.= exp (omega,((e |^|^ (Segm (n + 1))) *^ e)) by ORDINAL4:31
.= exp (omega,((e |^|^ (succ (Segm n))) *^ e)) by NAT_1:38
.= exp (omega,((exp (e,(e |^|^ n))) *^ e)) by Th14
.= exp (omega,((exp (e,(e |^|^ n))) *^ (exp (e,1)))) by ORDINAL2:46
.= exp (omega,(exp (e,(1 +^ (e |^|^ n))))) by ORDINAL4:30
.= exp (omega,(exp (e,(e |^|^ n)))) by A2, CARD_2:74
.= exp (omega,(e |^|^ (succ (Segm n)))) by Th14
.= exp (omega,(e |^|^ (Segm (n + 1)))) by NAT_1:38
.= exp (omega,(e |^|^ (n + 1))) ; :: thesis: verum