I can't reduce the sum to a single term, but it can be reduced to a sum of five terms, which reduces the complexity to
O(log n) arithmetic operations.
Θ(n) bits, so the number of bit-operations is not logarithmic. There is a multiplication of a number the size of
n-1, so the number of bit-operations is
M(n,log n), where
M(a,b) is the bit-operation complexity of a multiplication of an
a-bit number with a
b-bit number. For the naive algorithm,
M(a,b) = a*b, so the number of bit-operations in the below algorithm is
The fact that allows this reduction is that Fibonacci numbers (like all numbers in a sequence defined by a linear recurrence) can be written as the sum of pure exponential terms, in particular
Fib(n) = (α^n - β^n) / (α - β)
α = (1 + √5)/2; β = (1 - √5)/2.
In addition to the Fibonacci numbers, I also use the Lucas numbers, which follow the same recurrence as the Fibonacci numbers,
Luc(n) = α^n + β^n
so the sequence of Lucas numbers (starting from index 0) begins with
2 1 3 4 7 11 18 29 47 ...
Luc(n) = Fib(n+1) + Fib(n-1) allows an easy conversion between Fibonacci and Lucas numbers, and computation of
O(log n) steps can reuse the Fibonacci code.
So with the representation of Fibonacci numbers given above, we find
(α - β)^2 * Fib(k) * Fib(n+3-k) = (α^k - β^k) * (α^(n+3-k) - β^(n+3-k))
= α^(n+3) + β^(n+3) - (α^k * β^(n+3-k)) - (α^(n+3-k) * β^k)
= Luc(n+3) - ((-1)^k * α^(2k) * β^(n+3)) - ((-1)^k * α^(n+3) * β^(2k))
using the relation
α * β = -1.
α - β = √5 the summation
k = 1, ..., n-1 yields
n-1 n-1 n-1
5 * ∑ Fib(k)*Fib(n+3-k) = (n-1)*Luc(n+3) - β^(n+3) * ∑ (-α²)^k - α^(n+3) * ∑ (-β²)^k
k=1 k=1 k=1
The geometric sums can be written in closed form, and a bit of juggling yields the formula
∑ Fib(k)*Fib(n+3-k) = [5*(n-1)*Luc(n+3) + Luc(n+2) + 2*Luc(n+1) - 2*Luc(n-3) + Luc(n-4)]/25