reserve n for Nat,
  a,b for Real,
  s for Real_Sequence;

theorem
  (for n holds s.n = n*(n+1)*(n+2)*(n+3)) implies for n holds
  Partial_Sums(s).n = n*(n+1)*(n+2)*(n+3)*(n+4)/5
proof
  defpred X[Nat] means Partial_Sums(s).$1 = $1*($1+1)*($1+2)*($1+3)
  *($1+4)/5;
  assume
A1: for n holds s.n = n*(n+1)*(n+2)*(n+3);
A2: for n st X[n] holds X[n+1]
  proof
    let n;
    assume Partial_Sums(s).n =n*(n+1)*(n+2)*(n+3)*(n+4)/5;
    then Partial_Sums(s).(n+1) = n*(n+1)*(n+2)*(n+3)*(n+4)/5 + s.(n+1) by
SERIES_1:def 1
      .=n*(n+1)*(n+2)*(n+3)*(n+4)/5+ (n+1)*(n+1+1)*(n+1+2)*(n+1+3) by A1
      .=(n+1)*(n+2)*(n+3)*(n+4)*(n+5)/5;
    hence thesis;
  end;
  Partial_Sums(s).0 = s.0 by SERIES_1:def 1
    .=0*(0+1)*(0+2)*(0+3)*(0+4)/4 by A1;
  then
A3: X[0];
  for n holds X[n] from NAT_1:sch 2(A3,A2);
  hence thesis;
end;
