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.

However, `Fib(n)`

has `Θ(n)`

bits, so the number of bit-operations is not logarithmic. There is a multiplication of a number the size of `Fib(n)`

with `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 `O(n*log n)`

.

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)
```

where

```
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 ...
```

The relation `Luc(n) = Fib(n+1) + Fib(n-1)`

allows an easy conversion between Fibonacci and Lucas numbers, and computation of `Luc(n)`

in `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`

.

Now, since `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

```
n-1
∑ 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
k=1
```

`n`

is so small that`Fib(n)`

fits in a standard 64-bit integer, that doesn't matter, of course. – Daniel Fischer Sep 3 '12 at 13:22