I'll present a method to solve this problem without even understanding the solution.

Assuming that you are familiar with the fibonacci numbers:

```
ghci> let fib = 0 : 1 : zipWith (+) fib (tail fib)
ghci> take 16 fib
[0,1,1,2,3,5,8,13,21,34,55,89,144,233,377,610]
```

And are also familiar with its closed form expression:

```
ghci> let calcFib i = round (((1 + sqrt 5) / 2) ^ i / sqrt 5)
ghci> map calcFib [0..15]
[0,1,1,2,3,5,8,13,21,34,55,89,144,233,377,610]
```

And you notice the similarity of ((1 + sqrt 5) / 2)^{n} and (3 + sqrt 5)^{n}.

From here one can guess that there is probably a series similar to fibonacci to calculate this.

But what series? So you calculate the first few items:

```
ghci> let calcThing i = floor ((3 + sqrt 5) ^ i)
ghci> map calcThing [0..5]
[1,5,27,143,751,3935]
```

Guessing that the formula is of the form:

thing_{n} = a*thing_{n-1} + b*thing_{n-2}

We have:

27 = a*5 + b*1

143 = a*27 + b*5

We solve the linear equations set and get:

thing_{n} = 4*thing_{n-1} + 7*thing_{n-2} (a = 4, b = 7)

We check:

```
ghci> let thing = 1 : 5 : zipWith (+) (map (* 4) (tail thing)) (map (* 7) thing)
ghci> take 10 thing
[1,5,27,143,761,4045,21507,114343,607921,3232085]
ghci> map calcThing [0..9]
[1,5,27,143,751,3935,20607,107903,564991,2958335]
```

Then we find out that sadly this does not compute our function. But then we get cheered by the fact that it gets the right-most digit right. Not understanding why, but encouraged by this fact, we try to something similar. To find the parameters for a modified formula:

thing_{n} = a*thing_{n-1} + b*thing_{n-2} + c

We then arrive at:

thing_{n} = 6*thing_{n-1} - 4*thing_{n-2} + 1

We check it:

```
ghci> let thing =
1 : 5 : map (+1) (zipWith (+)
(map (*6) (tail thing))
(map (* negate 4) thing))
ghci> take 16 thing == map calcThing [0..15]
True
```