let k be Element of NAT ; :: thesis: ex rseq being Real_Sequence st
for n being Element of NAT holds
( ( n <= k implies rseq . n = F₁(k,n) ) & ( n > k implies rseq . n = 0 ) )
defpred S₁[ set , set ] means ex n being Element of NAT st
( n = $1 & ( n <= k implies $2 = F₁(k,n) ) & ( n > k implies $2 = 0 ) );
consider f being Function such that
A8: dom f = NAT and
A9: for x being set st x in NAT holds
S₁[x,f . x] from CLASSES1:sch 1(A1);
reconsider f = f as Real_Sequence by A8, A10, SEQ_1:3;
take rseq = f; :: thesis: for n being Element of NAT holds
( ( n <= k implies rseq . n = F₁(k,n) ) & ( n > k implies rseq . n = 0 ) )
let n be Element of NAT ; :: thesis: ( ( n <= k implies rseq . n = F₁(k,n) ) & ( n > k implies rseq . n = 0 ) )
A13: ex l being Element of NAT st
( l = n & ( l <= k implies rseq . n = F₁(k,l) ) & ( l > k implies rseq . n = 0 ) ) by A9;
thus ( ( n <= k implies rseq . n = F₁(k,n) ) & ( n > k implies rseq . n = 0 ) ) by A13; :: thesis: verum