let N be non empty with_non-empty_elements set ; :: thesis: for S being non empty stored-program IC-Ins-separated definite steady-programmed AMI-Struct of N
for P being the Instructions of b1 -valued ManySortedSet of NAT
for s being State of S
for n being Element of NAT holds ProgramPart s = ProgramPart (Comput P,s,n)
let S be non empty stored-program IC-Ins-separated definite steady-programmed AMI-Struct of N; :: thesis: for P being the Instructions of S -valued ManySortedSet of NAT
for s being State of S
for n being Element of NAT holds ProgramPart s = ProgramPart (Comput P,s,n)
let P be the Instructions of S -valued ManySortedSet of NAT ; :: thesis: for s being State of S
for n being Element of NAT holds ProgramPart s = ProgramPart (Comput P,s,n)
let s be State of S; :: thesis: for n being Element of NAT holds ProgramPart s = ProgramPart (Comput P,s,n)
defpred S1[ Element of NAT ] means ProgramPart s = ProgramPart (Comput P,s,$1);
A1: now
let n be Element of NAT ; :: thesis: ( S1[n] implies S1[n + 1] )
assume S1[n] ; :: thesis: S1[n + 1]
then ProgramPart s = ProgramPart (Following P,(Comput P,s,n)) by L117
.= ProgramPart (Comput P,s,(n + 1)) by Th14 ;
hence S1[n + 1] ; :: thesis: verum
end;
A2: S1[ 0 ] by Th13;
thus for n being Element of NAT holds S1[n] from NAT_1:sch 1(A2, A1); :: thesis: verum