Let's first ask the question "how many 0-1 sequences of length n are there with no two consecutive 1s?" Let the answer be A(n). We have A(0)=1 (the empty sequence), A(1) = 2 ("0" and "1"), and A(2)=3 ("00", "01" and "10" but not "11").

To make it easier to write a recurrence, we'll compute A(n) as the sum of two numbers:

B(n), the number of such sequences that end with a 0, and

C(n), the number of such sequences that end with a 1.

Then B(n) = A(n-1) (take any such sequence of length n-1, and append a 0)

and C(n) = B(n-1) (because if you have a 1 at position n, you must have a 0 at n-1.)

This gives A(n) = B(n) + C(n) = A(n-1) + B(n-1) = A(n-1) + A(n-2).
By now it should be familiar :-)

A(n) is simply the Fibonacci number F_{n+2} where the Fibonacci sequence is defined by

F_{0}=0, F_{1}=1, and F_{n+2}= F_{n+1}+F_{n} for n ≥ 0.

Now for your question. We'll count the number of arrangements with a_{1}=0 and a_{1}=1 separately. For the former, a_{2} … a_{n} can be any sequence at all (with no consecutive 1s), so the number is A(n-1)=F_{n+1}. For the latter, we must have a_{2}=0, and then a_{3}…a_{n} is any sequence with no consecutive 1s that *ends with a 0*, i.e. B(n-2)=A(n-3)=F_{n-1}.

So **the answer is F**_{n+1} + F_{n-1}.

_{Actually, we can go even further than that answer. Note that if you call the answer as G(n)=Fn+1+Fn-1, then
G(n+1)=Fn+2+Fn, and
G(n+2)=Fn+3+Fn+1, so even G(n) satisfies the same recurrence as the Fibonacci sequence! [Actually, any linear combination of Fibonacci-like sequences will satisfy the same recurrence, so it's not all that surprising.] So another way to compute the answers would be using:
G(2)=3
G(3)=4
G(n)=G(n-1)+G(n-2) for n≥4.}

And now you can also use the closed form F_{n}=(α^{n}-β^{n})/(α-β) (where α and β are (1±√5)/2, the roots of x^{2}-x-1=0), to get

**G(n) = ((1+√5)/2)**^{n} + ((1-√5)/2)^{n}.

[You can ignore the second term because it's very close to 0 for large n, in fact G(n) is the **closest integer to ((1+√5)/2)**^{n} for all n≥2.]