defpred S₁[ set ] means ex m being Element of NAT st $1 = 3 * m;
consider E being Subset of NAT such that
A1: for n being Element of NAT holds
( n in E iff S₁[n] ) from SUBSET_1:sch 3();
defpred S₂[ set ] means ex m being Element of NAT st $1 = (3 * m) + 1;
consider G being Subset of NAT such that
A2: for n being Element of NAT holds
( n in G iff S₂[n] ) from SUBSET_1:sch 3();
defpred S₃[ set ] means ex m being Element of NAT st $1 = (3 * m) + 2;
consider K being Subset of NAT such that
A3: for n being Element of NAT holds
( n in K iff S₃[n] ) from SUBSET_1:sch 3();
defpred S₄[ Element of NAT , set ] means ( ( $1 in E implies $2 = F₁(($1 / 3)) ) & ( $1 in G implies $2 = F₂((($1 - 1) / 3)) ) & ( $1 in K implies $2 = F₃((($1 - 2) / 3)) ) );
A4: for n being Element of NAT ex r being Real st S₄[n,r] consider f being Function of NAT,REAL such that
A15: for n being Element of NAT holds S₄[n,f . n] from FUNCT_2:sch 3(A4);
reconsider f = f as Real_Sequence ;
take f ; :: thesis: for n being Element of NAT holds
( f . (3 * n) = F₁(n) & f . ((3 * n) + 1) = F₂(n) & f . ((3 * n) + 2) = F₃(n) )
let n be Element of NAT ; :: thesis: ( f . (3 * n) = F₁(n) & f . ((3 * n) + 1) = F₂(n) & f . ((3 * n) + 2) = F₃(n) )
3 * n in E by A1;
hence f . (3 * n) = F₁(((3 * n) / 3)) by A15
.= F₁(n) ;
:: thesis: ( f . ((3 * n) + 1) = F₂(n) & f . ((3 * n) + 2) = F₃(n) )
(3 * n) + 1 in G by A2;
hence f . ((3 * n) + 1) = F₂(((((3 * n) + 1) - 1) / 3)) by A15
.= F₂(n) ;
:: thesis: f . ((3 * n) + 2) = F₃(n)
(3 * n) + 2 in K by A3;
hence f . ((3 * n) + 2) = F₃(((((3 * n) + 2) - 2) / 3)) by A15
.= F₃(n) ;
:: thesis: verum