jrtechs
/
jrtechs-NodeJSBlog
mirror of https://github.com/jrtechs/NodeJSBlog.git

If you have ever taken a computer science class you probably know whatthe fibonacci sequence is and how to calculate it. For those who don'tknow: [Fibonacci](https://en.wikipedia.org/wiki/Fibonacci) is asequence of numbers starting with 0,1 whose next number is the sum ofthe two previous numbers. After having multiple of my CS classes givelectures and homeworks on the Fibonacci sequence; I decided  to writea blog post going over the 4 main ways of calculating the nth term ofthe Fibonacci sequence. In addition to providing the python code forcalculating the nth perm of the sequence, a proof for their validityand an analysis of their time complexities both mathematically andempirically will be examined. 
# Slow Recursive Definition

By the definition of the Fibonacci sequence, it is the most natural towrite it as a recursive definition. 
```Pythondef fib(n):    if n == 0 or n == 1:        return n    return fib(n-1) + fib(n-2)```
##Time Complexity

Observing that each call has two recursive calls we can place an upperbound on this  function as $O(2^n)$. However, if we solve thisrecurrence we can place a tight bound for time complexity. 
We can write a recurrence for the number of times fib is called: 
$$    F(1) = 1\\    F(n) = F(n-1) + F(n-2)\\$$
Next, we replace F(n) with $a^n$ since we want to find rate ofexponential growth. 
$$    a^n = a^{n-1} + a^{n-2}\\    \frac{a^n}{a^{n-2}} = \frac{a^{n-1} + a^{n-2}}{a^{n-2}}\\    a^2 = a + 1\\    a = \frac{1 \pm sqrt(5)}{2}\\$$
From this calculation we can conclude that F(n) $\in \Theta 1.681^n$.We don't have to worry about  the negative root since it would not beasymptotically relevant by the definition of $\Theta$.  


## Measured Performance

Here is a graph of the actual performance that I observed from thisrecursive definition of Fibonacci. 
![Recursive Definition](media/fibonacci/RecursiveDefinition.png)

# Accumulation Solution

The problem with the previous recursive solution is that you had torecalculate certain  terms of fibonacci a ton of times. A summationvariable would help us avoid this problem. You could write thissolution using a simple loop or dynamic programming , however, I choseto use recursion to demonstrate that it's recursion which made thefirst problem slow.  

```Pythondef fibHelper(n, a, b):    if n == 0:        return a    elif n == 1:        return b    return fibHelper(n-1, b, a+b)        ```
```pythondef fibIterative(n):    return fibHelper(n, 0, 1)```
In this code example, fibHelper is a method which accumulates theprevious two terms.  The fibIterative is a wrapper method which setsthe two initial terms equal to 0 and 1  representing the fibonaccisequence. At first it may not be obvious that fibIterative(n) isequivalent to fib(n). To demonstrate that these two are in factequivalent, I broke this  into two inductive proofs.  
## Proof for Fib Helper

**Lemma:** For any n $\epsilon$ N if n $>$ 1 then            $fibHelper(n, a, b) = fibHelper(n - 1, a, b) + fibHelper(n - 2, a, b)$.
**Proof via Induction**
**Base Case**: n = 2:$$    LHS = fibHelper(2, a, b)\\    = fibHelper(1, b, a + b) = a + b\\     RHS =  fibHelper(2 -1, a, b) + fibHelper(2-2, a, b)\\    = a + b\\$$
**Inductive Step:**
Assume proposition is true for all n and show n+1 follows. 
$$    RHS=fibHelper(n+1;a,b)\\    = fibHelper(n;b,a+b)\\    =fibHelper(n-1;b,a+b) + fibHelper(n-2;b,a+b)\\    =fibHelper(n;a,b) + fibHelper(n-1;a,b)\\    =LHS\\$$
$\Box$
## Proof That fibIterative = Fib

**Lemma:** For any n $\in$ N, $fib(n)$ = $fibIterative(n, 0, 1)$
**Proof via Strong Induction**
**Base Case**: n = 0:$$    fibIterative(0, 0, 0) = 0\\    = fib(0)$$
**Base Case**: n = 1:$$    fibIterative(1, 0, 0) = 1\\    = fib(1)$$
**Inductive Step:**
Assume proposition is true for all n and show n+1 follows. 
$$    fib(n+1) = fib(n) + fib(n-1)\\    = fibHelper(n, 0, 1) + fibHelper(n+1, 0 ,1) \quad\text{I.H}\\    = fibHelper(n+1, 0, 1) \quad\text{from result in previous proof}\\$$
$\Box$

## Time Complexity

Suppose that we wish to solve for the time complexity in terms of thenumber of additions needed to be computed. Based on fibHelper we cansee that it performs one addition every recursive call.  We can nowform a recurrence for time complexity.  
$$    T(0) = 0\\    T(1) = 0\\    T(n) = 1 + T(n-1)\\    T(n) = n-1\\$$
From this recurrence we can say that fibHelper $\in \Theta(n)$. 
## Measured Performance

Notice how much faster this solution is compared to the originalrecursive solution for Fibonacci. 
![Iterative Performance](media/fibonacci/Iterative.png)


# Matrix Solution

We can actually get better than linear for performance for Fibonacciwhile still using recursion. However, to do so we need to know thisfact: 
$$  \begin{bmatrix}1 & 1\\1 & 0\end{bmatrix}^n = \begin{bmatrix}F_{n+1} & F_n\\F_n & F{n-1}\end{bmatrix}^n$$
Without any tricks, raising a matrix to a power n times would not getus better than linear performance. However, if we use the[Exponentiation bySquaring](https://en.wikipedia.org/wiki/Exponentiation_by_squaring)method, we can expect to see logarithmic time. Since two spots in thematrix are always equal, I represented the matrix as an array withonly three elements to reduce the space and  computations required.  

```Pythondef multiply(a,b):    product = [0,0,0]    product[0] = a[0]*b[0] + a[1]*b[1]    product[1] = a[0]*b[1] + a[1]*b[2]    product[2] = a[1]*b[1] + a[2]*b[2]    return product```
```pythondef power(l, k):    if k == 1:        return l    temp = power(l, k//2)    if k%2 == 0:        return multiply(temp, temp)    else:        return multiply(l, multiply(temp, temp))```
```python          def fibPower(n):    l = [1,1,0]    return power(l, n)[1]```

## Time Complexity

For this algorithm, lets solve for the time complexity as the numberof additions and multiplications required. 
Since we are always multiplying two 2x2 matrices, that operation isconstant time. 
$$    T_{multiply} = 9$$
Solving for the time complexity of fib power is slightly morecomplicated. 
$$    T_{power}(1) = 0\\    T_{power}(n) = T(\left\lfloor\dfrac{n}{2}\right\rfloor) + T_{multiply}\\      = T(\left\lfloor\dfrac{n}{2}\right\rfloor) + 9\\      = T(\left\lfloor\dfrac{n}{2*2}\right\rfloor) + 9 + 9\\      = T(\left\lfloor\dfrac{n}{2*2*2}\right\rfloor) + 9+ 9 + 9\\    T_{power}(n) =  T(\left\lfloor\dfrac{n}{2^k}\right\rfloor) + 9k\\$$
let $k=k_0$ such that $\left\lfloor\dfrac{n}{2^{k_0}}\right\rfloor =1$ 
$$        \left\lfloor\dfrac{n}{2^{k_0}}\right\rfloor = 1 \rightarrow 1 \leq \frac{n}{2^{k_0}} < 2\\    \rightarrow 2^{k_0} \leq n < 2^{k_0 +1}\\    \rightarrow k_0 \leq lg(n) < k_0+1\\    \rightarrow k_0 = \left\lfloor lg(n)\right\rfloor\\    T_{power}(n) =  T(1) + 9*\left\lfloor lg(n)\right\rfloor\\    T_{power}(n) =  9*\left\lfloor\ lg(n)\right\rfloor\\    T_{fibPower}(n) = T_{power}(n)\\$$
Now we can state that $fibPower(n) \in \Theta(log(n))$. 


## Inductive Proof for Matrix Method

I would like to now prove that this matrix identity is valid since itis not at first obvious. 
**Lemma:** For any n $\epsilon$ N if n $>$ 0 then            $$             \begin{bmatrix}           1 & 1\\           1 & 0           \end{bmatrix}^n =            \begin{bmatrix}           F_{n+1} & F_n\\           F_n & F{n-1}           \end{bmatrix}^n           $$
Let 
$$A=\begin{bmatrix}1 & 1\\1 & 0\end{bmatrix}^n$$
**Base Case:** n = 1$$A^1=\begin{bmatrix}1 & 1\\1 & 0\end{bmatrix}^n = \begin{bmatrix}F_{2} & F_2\\F_2 & F_{0}\end{bmatrix}^n$$
**Inductive Step:** Assume proposition is true for n, show n+1 follows$$A^{n+1}=\begin{bmatrix}1 & 1\\1 & 0\end{bmatrix} \begin{bmatrix}F_{n+1} & F_n\\F_n & F{n-1}\end{bmatrix}^n\\= \begin{bmatrix}F_{n+1} + F_n & F_n + F_{n-1}\\F_{n+1} & F_{n}\end{bmatrix}\\= \begin{bmatrix}F_{n+2} & F_{n+1}\\F_{n+1} & F_{n}\end{bmatrix}\\$$
$\Box$

## Measured Performance

![FibPower Performance](media/fibonacci/FibPower.png)
As expected by our mathematical calculations, the algorithm appears tobe running in logarithmic time.  
## Measured Performance With Large Numbers

![FibPower Performance](media/fibonacci/FibPowerBigPicture.png)
When calculating the fibonacci term for extremely large numbersdespite having a polynomial time complexity, the space required tocompute each Fibonacci term grows exponentially. Since our performanceis only pseudo-polynomial we see a degrade in our performance whencalculating  large terms of the fibonacci sequence. 
The one amazing thing to point out here is that despite calculatingthe 10,000 term of Fibonacci, this algorithm is nearly 400 timesfaster than the recursive algorithm when calculating  the 30th term ofFibonacci. 

# Closed Form Definition

It is actually possible to calculate Fibonacci in constant time usingBinet's Formula. 
$$    F_n = \frac{(\frac{1+\sqrt{5}}{2})^n-(\frac{1-\sqrt{5}}{2})^n}{\sqrt{5}}$$ 
```Pythondef fibClosedFormula(n):    p = ((1+ math.sqrt(5))/2)**n    v = ((1-math.sqrt(5))/2)**n    return (p-v)/math.sqrt(5)```
## Derivation of Binet's Formula

Similar to when we were calculating the time complexity of the basicrecursive definition , we want to start by finding the two roots ofthe equation in terms of exponents. 
$$    a^n = a^{n-1} + a^{n-2}\\    \frac{a^n}{a^{n-2}} = \frac{a^{n-1} + a^{n-2}}{a^{n-2}}\\    a^2 = a + 1\\    0 = a^2 - a - 1\\    a = \frac{1 \pm sqrt(5)}{2}\\$$
Since there are two roots to the equation, the solution of $F_n$ isgoing to be  a linear combination of the two roots. 

$$    F_n = c_1(\frac{1 + \sqrt{5}}{2})^n + c_2(\frac{1 - \sqrt{5}}{2})^n$$
Fact: $F_1$ = 1 
$$    F_1 = 1\\    = c_1(\frac{1 + \sqrt{5}}{2}) + c_2(\frac{1 - \sqrt{5}}{2})\\    = \frac{c_1}{2} + \frac{c_2}{2} + \frac{c_1\sqrt{5}}{2} - \frac{c_2\sqrt{5}}{2}\\$$
Let $c_1 = \frac{1}{\sqrt{5}}$, Let $c_2 = \frac{-1}{\sqrt{5}}$ 
$$    F_n = \frac{1}{\sqrt(5)}((\frac{1+\sqrt{5}}{2})^n-(\frac{1-\sqrt{5}}{2})^n)\\    = \frac{(\frac{1+\sqrt{5}}{2})^n-(\frac{1-\sqrt{5}}{2})^n}{\sqrt{5}}$$
## Time Complexity

Since we managed to find the closed form of the fibonacci sequence wecan expect to see constant performance. 
## Measured Performance

![FibPower Performance](media/fibonacci/ConstantTimeComplexity.png)