lizfcm/homeworks/hw-3.org

#+TITLE: HW 03
#+AUTHOR: Elizabeth Hunt
#+STARTUP: entitiespretty fold inlineimages
#+LATEX_HEADER: \notindent \notag  \usepackage{amsmath} \usepackage[a4paper,margin=1in,portrait]{geometry}
#+LATEX: \setlength\parindent{0pt}
#+OPTIONS: toc:nil

* Question One
** Three Terms
\begin{align*}
Si_3(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!}}{s} dx \\
&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)}
\end{align*}
** Five Terms
\begin{align*}
Si_3(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!} - \frac{s^7}{7!} + \frac{s^9}{9!}}{s} dx \\
&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)} - \frac{x^7}{(7!)(7)} + \frac{s^9}{(9!)(9)}
\end{align*}
** Ten Terms
\begin{align*}
Si_{10}(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!} - \frac{s^7}{7!} + \frac{s^9}{9!} - \frac{s^{11}}{11!} + \frac{s^{13}}{13!} - \frac{s^{15}}{15!} + \frac{s^{17}}{17!} - \frac{s^{19}}{19!}}{s} ds \\
&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)} - \frac{x^7}{(7!)(7)} + \frac{s^9}{(9!)(9)} - \frac{s^{11}}{(11!)(11)} + \frac{s^{13}}{(13!)(13)} - \frac{s^{15}}{(15!)(15)} \\
&+ \frac{s^{17}}{(17!)(17)} - \frac{s^{19}}{(19!)(19)}
\end{align*}
* Question Three
For the second term in the difference quotient, we can expand the taylor series centered at x=a:

\begin{equation*}
f(x) = f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots \\
\end{equation*}

Which we substitute into the difference quotient:

\begin{equation*}
\frac{f(a) - f(a - h)}{h} = \frac{f(a) - (f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots)}{h}
\end{equation*}

And subs. $x=a-h$:

\begin{align*}
\frac{f(a) - (f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots)}{h} &= -f'(a)(-1) + -\frac{1}{2}f''(a)h \\
&= f'(a) - \frac{1}{2}f''(a)h + \cdots \\
\end{align*}

Which we now plug into the initial $e_{\text{abs}}$:

\begin{align*}
e_{\text{abs}} &= |f'(a) - \frac{f(a) - f(a - h)}{h}| \\
&= |f'(a) - (f'(a) +  -\frac{f''(a)}{2}h + \cdots)| \\
&= |- \frac{1}{2}f''(a)h + \cdots | \\
\end{align*}

With the Taylor Remainder theorem we can absorb the series following the second term:

\begin{equation*}
e_{\text{abs}} = |- \frac{1}{2}f''(a)h + \cdots | = |\frac{1}{2}f''(\xi)h| \leq Ch
\end{equation*}

Thus our error is bounded linearly with $h$.

* Question Four
For the first term in the difference quotient we know, from the given notes,

\begin{equation*}
f(a+h) = f(a) + f'(a)h + \frac{1}{2}f''(a)h^2 + \frac{1}{6}f'''(a)(h^3)
\end{equation*}

And from some of the work in Question Three,

\begin{equation*}
f(a - h) = f(a) + f'(a)(-h) + \frac{1}{2}f''(a)(-h)^2 + \frac{1}{6}f'''(a)(-h^3)
\end{equation*}

We can substitute immediately into $e_{\text{abs}} = |f'(a) - (\frac{f(a+h) - f(a-h)}{2h})|$:

\begin{align*}
e_{\text{abs}} &= |f'(a) - \frac{1}{2h}((f(a) + f'(a)h + \frac{1}{2}f''(a)h^2 + \cdots) - (f(a) - f'(a)h + \frac{1}{2}f''(a)h^2 + \cdots))| \\
&= |f'(a) - \frac{1}{2h}(2f'(a)h + \frac{1}{6}f'''(a)h^3 + \cdots)| \\
&= |f'(a) - f'(a) - \frac{1}{12}f'''(a)h^2 + \cdots| \\
&= |-\frac{1}{12}f'''(a)h^2 + \cdots|
\end{align*}

Finally, with the Taylor Remainder theorem we can absorb the series following the third term:

\begin{equation*}
e_{\text{abs}} = |-\frac{1}{12}f'''(\xi)h^2| = |\frac{1}{12}f'''(\xi)h^2| \leq Ch^2
\end{equation*}

Meaning that as $h$ scales linearly, our error is bounded by $h^2$ as opposed to linearly as in Question Three.

* Question Six
** A
#+BEGIN_SRC lisp
  (load "../lizfcm.asd")
  (ql:quickload :lizfcm)

  (defun f (x)
    (/ (- x 1) (+ x 1)))

  (defun fprime (x)
    (/ 2 (expt (+ x 1) 2)))

  (let ((domain-values (loop for a from 0 to 2
                             append 
                             (loop for i from 0 to 9
                                   for h = (/ 1.0 (expt 2 i))
                                   collect (list a h)))))
    (lizfcm.utils:table (:headers '("a" "h" "f'" "\\approx f'" "e_{\\text{abs}}")
                         :domain-order (a h)
                         :domain-values domain-values)
      (fprime a)
      (lizfcm.approx:fwd-derivative-at 'f a h)
      (abs (- (fprime a)
              (lizfcm.approx:fwd-derivative-at 'f a h)))))
#+END_SRC

#+RESULTS:
| a |           h | f'  |       \approx f' |   e_{\text{abs}} |
| 0 |         1.0 | 2   |        1.0 |           1.0 |
| 0 |         0.5 | 2   |  1.3333333 |    0.66666675 |
| 0 |        0.25 | 2   |  1.5999999 |     0.4000001 |
| 0 |       0.125 | 2   |  1.7777777 |    0.22222233 |
| 0 |      0.0625 | 2   |  1.8823528 |    0.11764717 |
| 0 |     0.03125 | 2   |   1.939394 |   0.060606003 |
| 0 |    0.015625 | 2   |  1.9692307 |   0.030769348 |
| 0 |   0.0078125 | 2   |  1.9844971 |    0.01550293 |
| 0 |  0.00390625 | 2   |   1.992218 |  0.0077819824 |
| 0 | 0.001953125 | 2   |  1.9960938 |    0.00390625 |
| 1 |         1.0 | 1/2 | 0.33333334 |    0.16666666 |
| 1 |         0.5 | 1/2 |        0.4 |   0.099999994 |
| 1 |        0.25 | 1/2 | 0.44444445 |   0.055555552 |
| 1 |       0.125 | 1/2 | 0.47058824 |   0.029411763 |
| 1 |      0.0625 | 1/2 |  0.4848485 |   0.015151501 |
| 1 |     0.03125 | 1/2 |  0.4923077 |  0.0076923072 |
| 1 |    0.015625 | 1/2 | 0.49612403 |  0.0038759708 |
| 1 |   0.0078125 | 1/2 | 0.49805447 |  0.0019455254 |
| 1 |  0.00390625 | 1/2 | 0.49902534 | 0.00097465515 |
| 1 | 0.001953125 | 1/2 |  0.4995122 |  0.0004878044 |
| 2 |         1.0 | 2/9 | 0.16666666 |   0.055555567 |
| 2 |         0.5 | 2/9 | 0.19047618 |   0.031746045 |
| 2 |        0.25 | 2/9 |  0.2051282 |   0.017094031 |
| 2 |       0.125 | 2/9 | 0.21333337 |   0.008888856 |
| 2 |      0.0625 | 2/9 | 0.21768713 |   0.004535094 |
| 2 |     0.03125 | 2/9 | 0.21993065 |   0.002291575 |
| 2 |    0.015625 | 2/9 | 0.22106934 |  0.0011528879 |
| 2 |   0.0078125 | 2/9 | 0.22164536 | 0.00057686865 |
| 2 |  0.00390625 | 2/9 | 0.22193146 | 0.00029076636 |
| 2 | 0.001953125 | 2/9 | 0.22207642 | 0.00014580786 |

* Question Nine
** C

#+BEGIN_SRC lisp
  (load "../lizfcm.asd")
  (ql:quickload :lizfcm)

  (defun factorial (n)
    (if (= n 0)
        1
        (* n (factorial (- n 1)))))

  (defun taylor-term (n x)
    (/ (* (expt (- 1) n)
          (expt x (+ (* 2 n) 1)))
       (* (factorial n)
          (+ (* 2 n) 1))))

  (defun f (x &optional (max-iterations 30))
    (let ((sum 0.0))
      (dotimes (n max-iterations)
        (setq sum (+ sum (taylor-term n x))))
      (* sum (/ 2 (sqrt pi)))))

  (defun fprime (x)
    (* (/ 2 (sqrt pi)) (exp (- 0 (* x x)))))

  (let ((domain-values (loop for a from 0 to 1
                             append 
                             (loop for i from 0 to 9
                                   for h = (/ 1.0 (expt 2 i))
                                   collect (list a h)))))
    (lizfcm.utils:table (:headers '("a" "h" "f'" "\\approx f'" "e_{\\text{abs}}")
                         :domain-order (a h)
                         :domain-values domain-values)
      (fprime a)
      (lizfcm.approx:central-derivative-at 'f a h)
      (abs (- (fprime a)
              (lizfcm.approx:central-derivative-at 'f a h)))))
#+END_SRC


| a |           h |                    f' |                  \approx f' |             e_{\text{abs}} |
| 0 |         1.0 |  1.1283791670955126d0 |  0.8427006725464232d0 |   0.28567849454908933d0 |
| 0 |         0.5 |  1.1283791670955126d0 |  1.0409997446922075d0 |    0.0873794224033051d0 |
| 0 |        0.25 |  1.1283791670955126d0 |  1.1053055663206806d0 |  0.023073600774832004d0 |
| 0 |       0.125 |  1.1283791670955126d0 |   1.122529655394656d0 |  0.005849511700856569d0 |
| 0 |      0.0625 |  1.1283791670955126d0 |  1.1269116944798618d0 | 0.0014674726156507223d0 |
| 0 |     0.03125 |  1.1283791670955126d0 |  1.1280120131008824d0 |   3.6715399463016496d-4 |
| 0 |    0.015625 |  1.1283791670955126d0 |  1.1282873617826952d0 |    9.180531281738347d-5 |
| 0 |   0.0078125 |  1.1283791670955126d0 |   1.128356232581468d0 |    2.293451404455915d-5 |
| 0 |  0.00390625 |  1.1283791670955126d0 |  1.1283734502811613d0 |     5.71681435124205d-6 |
| 0 | 0.001953125 |  1.1283791670955126d0 |  1.1283777547060847d0 |   1.4123894278572635d-6 |
| 1 |         1.0 | 0.41510750774498784d0 |  0.4976611317561498d0 |   0.08255362401116195d0 |
| 1 |         0.5 | 0.41510750774498784d0 | 0.44560523266293384d0 |     0.030497724917946d0 |
| 1 |        0.25 | 0.41510750774498784d0 |  0.4234889628937013d0 |  0.008381455148713468d0 |
| 1 |       0.125 | 0.41510750774498784d0 | 0.41725265825950153d0 |  0.002145150514513694d0 |
| 1 |      0.0625 | 0.41510750774498784d0 | 0.41564710776310854d0 |    5.396000181207006d-4 |
| 1 |     0.03125 | 0.41510750774498784d0 |  0.4152414157140871d0 |   1.3390796909928948d-4 |
| 1 |    0.015625 | 0.41510750774498784d0 | 0.41514241394084905d0 |    3.490619586121735d-5 |
| 1 |   0.0078125 | 0.41510750774498784d0 | 0.41510582632900395d0 |   1.6814159838896003d-6 |
| 1 |  0.00390625 | 0.41510750774498784d0 |   0.415092913054238d0 |   1.4594690749825112d-5 |
| 1 | 0.001953125 | 0.41510750774498784d0 |  0.4150670865046777d0 |   4.0421240310117845d-5 |

* Question Twelve

First we'll place a bound on $h$; looking at a graph of $f$ it's pretty obvious from the asymptotes that we don't want to go much further than $|h| = 2 - \frac{pi}{2}$.

Following similar reasoning as Question Four, we can determine an optimal $h$ by computing $e_{\text{abs}}$ for the central difference, but now including a roundoff error for each time we run $f$
such that $|f_{\text{machine}}(x) - f(x)| \le \epsilon_{\text{dblprec}}$ (we'll use double precision numbers, from HW 2 we know $\epsilon_{\text{dblprec}} \approx 2.22045 (10^{-16})$).

We'll just assume $|f_{\text{machine}}(x) - f(x)| = \epsilon_{\text{dblprec}}$ so our new difference quotient becomes:

\begin{align*}
e_{\text{abs}} &= |f'(a) - (\frac{f(a+h) - f(a-h) + 2\epsilon_{\text{dblprec}}}{2h})| \\
&= |\frac{1}{12}f'''(\xi)h^2 + \frac{\epsilon_{\text{dblprec}}}{h}|
\end{align*}

Because we bounded our $|h| = 2 - \frac{pi}{2}$ we'll find the maximum value of $f'''$ between $a - (2 - \frac{\pi}{2})$ and $a - (2 - \frac{\pi}{3})$. Using [[https://www.desmos.com/calculator/gen1zpohh2][desmos]] I found this to be -2.

Thus, $e_{\text{abs}} \leq \frac{1}{6}h^2 + \frac{\epsilon_{\text{dblprec}}}{h}$. Finding the derivative:

\begin{equation*}
e' = \frac{1}{3}h - \frac{\epsilon_{\text{dblprec}}}{h^2}
\end{equation*}

And solving at $e' = 0$:

\begin{equation*}
\frac{1}{3}h = \frac{\epsilon_{\text{dblprec}}}{h^2} \Rightarrow h^3 = 3\epsilon_{\text{dblprec}} \Rightarrow h = (3\epsilon_{\text{dblprec}})^{1/3}
\end{equation*}

Which is $\approx (3(2.22045 (10^{-16}))^{\frac{1}{3}} \approx 8.7335 10^{-6}$.
updates 10/9 2023-10-09 23:08:25 -04:00			`#+TITLE: HW 03`
			`#+AUTHOR: Elizabeth Hunt`
			`#+STARTUP: entitiespretty fold inlineimages`
			`#+LATEX_HEADER: \notindent \notag \usepackage{amsmath} \usepackage[a4paper,margin=1in,portrait]{geometry}`
			`#+LATEX: \setlength\parindent{0pt}`
			`#+OPTIONS: toc:nil`

			`* Question One`
			`** Three Terms`
			`\begin{align*}`
			`Si_3(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!}}{s} dx \\`
			`&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)}`
			`\end{align*}`
			`** Five Terms`
			`\begin{align*}`
			`Si_3(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!} - \frac{s^7}{7!} + \frac{s^9}{9!}}{s} dx \\`
			`&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)} - \frac{x^7}{(7!)(7)} + \frac{s^9}{(9!)(9)}`
			`\end{align*}`
			`** Ten Terms`
			`\begin{align*}`
			`Si_{10}(x) &= \int_0^x \frac{s - \frac{s^3}{3!} + \frac{s^5}{5!} - \frac{s^7}{7!} + \frac{s^9}{9!} - \frac{s^{11}}{11!} + \frac{s^{13}}{13!} - \frac{s^{15}}{15!} + \frac{s^{17}}{17!} - \frac{s^{19}}{19!}}{s} ds \\`
			`&= x - \frac{x^3}{(3!)(3)} + \frac{x^5}{(5!)(5)} - \frac{x^7}{(7!)(7)} + \frac{s^9}{(9!)(9)} - \frac{s^{11}}{(11!)(11)} + \frac{s^{13}}{(13!)(13)} - \frac{s^{15}}{(15!)(15)} \\`
			`&+ \frac{s^{17}}{(17!)(17)} - \frac{s^{19}}{(19!)(19)}`
			`\end{align*}`
			`* Question Three`
			`For the second term in the difference quotient, we can expand the taylor series centered at x=a:`

			`\begin{equation*}`
			`f(x) = f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots \\`
			`\end{equation*}`

			`Which we substitute into the difference quotient:`

			`\begin{equation*}`
			`\frac{f(a) - f(a - h)}{h} = \frac{f(a) - (f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots)}{h}`
			`\end{equation*}`

			`And subs. $x=a-h$:`

			`\begin{align*}`
			`\frac{f(a) - (f(a) + f'(a)(x-a) + \frac{f''(a)}{2}(x-a)^2 + \cdots)}{h} &= -f'(a)(-1) + -\frac{1}{2}f''(a)h \\`
			`&= f'(a) - \frac{1}{2}f''(a)h + \cdots \\`
			`\end{align*}`

			`Which we now plug into the initial $e_{\text{abs}}$:`

			`\begin{align*}`
			`e_{\text{abs}} &= \|f'(a) - \frac{f(a) - f(a - h)}{h}\| \\`
			`&= \|f'(a) - (f'(a) + -\frac{f''(a)}{2}h + \cdots)\| \\`
			`&= \|- \frac{1}{2}f''(a)h + \cdots \| \\`
			`\end{align*}`

			`With the Taylor Remainder theorem we can absorb the series following the second term:`

			`\begin{equation*}`
			`e_{\text{abs}} = \|- \frac{1}{2}f''(a)h + \cdots \| = \|\frac{1}{2}f''(\xi)h\| \leq Ch`
			`\end{equation*}`

			`Thus our error is bounded linearly with $h$.`

			`* Question Four`
			`For the first term in the difference quotient we know, from the given notes,`

			`\begin{equation*}`
			`f(a+h) = f(a) + f'(a)h + \frac{1}{2}f''(a)h^2 + \frac{1}{6}f'''(a)(h^3)`
			`\end{equation*}`

			`And from some of the work in Question Three,`

			`\begin{equation*}`
			`f(a - h) = f(a) + f'(a)(-h) + \frac{1}{2}f''(a)(-h)^2 + \frac{1}{6}f'''(a)(-h^3)`
			`\end{equation*}`

			`We can substitute immediately into $e_{\text{abs}} = \|f'(a) - (\frac{f(a+h) - f(a-h)}{2h})\|$:`

			`\begin{align*}`
			`e_{\text{abs}} &= \|f'(a) - \frac{1}{2h}((f(a) + f'(a)h + \frac{1}{2}f''(a)h^2 + \cdots) - (f(a) - f'(a)h + \frac{1}{2}f''(a)h^2 + \cdots))\| \\`
			`&= \|f'(a) - \frac{1}{2h}(2f'(a)h + \frac{1}{6}f'''(a)h^3 + \cdots)\| \\`
			`&= \|f'(a) - f'(a) - \frac{1}{12}f'''(a)h^2 + \cdots\| \\`
			`&= \|-\frac{1}{12}f'''(a)h^2 + \cdots\|`
			`\end{align*}`

			`Finally, with the Taylor Remainder theorem we can absorb the series following the third term:`

			`\begin{equation*}`
			`e_{\text{abs}} = \|-\frac{1}{12}f'''(\xi)h^2\| = \|\frac{1}{12}f'''(\xi)h^2\| \leq Ch^2`
			`\end{equation*}`

			`Meaning that as $h$ scales linearly, our error is bounded by $h^2$ as opposed to linearly as in Question Three.`

			`* Question Six`
			`** A`
			`#+BEGIN_SRC lisp`
			`(load "../lizfcm.asd")`
			`(ql:quickload :lizfcm)`

			`(defun f (x)`
			`(/ (- x 1) (+ x 1)))`

			`(defun fprime (x)`
			`(/ 2 (expt (+ x 1) 2)))`

			`(let ((domain-values (loop for a from 0 to 2`
			`append`
			`(loop for i from 0 to 9`
			`for h = (/ 1.0 (expt 2 i))`
			`collect (list a h)))))`
			`(lizfcm.utils:table (:headers '("a" "h" "f'" "\\approx f'" "e_{\\text{abs}}")`
			`:domain-order (a h)`
			`:domain-values domain-values)`
			`(fprime a)`
			`(lizfcm.approx:fwd-derivative-at 'f a h)`
			`(abs (- (fprime a)`
			`(lizfcm.approx:fwd-derivative-at 'f a h)))))`
			`#+END_SRC`

			`#+RESULTS:`
			`\| a \| h \| f' \| \approx f' \| e_{\text{abs}} \|`
			`\| 0 \| 1.0 \| 2 \| 1.0 \| 1.0 \|`
			`\| 0 \| 0.5 \| 2 \| 1.3333333 \| 0.66666675 \|`
			`\| 0 \| 0.25 \| 2 \| 1.5999999 \| 0.4000001 \|`
			`\| 0 \| 0.125 \| 2 \| 1.7777777 \| 0.22222233 \|`
			`\| 0 \| 0.0625 \| 2 \| 1.8823528 \| 0.11764717 \|`
			`\| 0 \| 0.03125 \| 2 \| 1.939394 \| 0.060606003 \|`
			`\| 0 \| 0.015625 \| 2 \| 1.9692307 \| 0.030769348 \|`
			`\| 0 \| 0.0078125 \| 2 \| 1.9844971 \| 0.01550293 \|`
			`\| 0 \| 0.00390625 \| 2 \| 1.992218 \| 0.0077819824 \|`
			`\| 0 \| 0.001953125 \| 2 \| 1.9960938 \| 0.00390625 \|`
			`\| 1 \| 1.0 \| 1/2 \| 0.33333334 \| 0.16666666 \|`
			`\| 1 \| 0.5 \| 1/2 \| 0.4 \| 0.099999994 \|`
			`\| 1 \| 0.25 \| 1/2 \| 0.44444445 \| 0.055555552 \|`
			`\| 1 \| 0.125 \| 1/2 \| 0.47058824 \| 0.029411763 \|`
			`\| 1 \| 0.0625 \| 1/2 \| 0.4848485 \| 0.015151501 \|`
			`\| 1 \| 0.03125 \| 1/2 \| 0.4923077 \| 0.0076923072 \|`
			`\| 1 \| 0.015625 \| 1/2 \| 0.49612403 \| 0.0038759708 \|`
			`\| 1 \| 0.0078125 \| 1/2 \| 0.49805447 \| 0.0019455254 \|`
			`\| 1 \| 0.00390625 \| 1/2 \| 0.49902534 \| 0.00097465515 \|`
			`\| 1 \| 0.001953125 \| 1/2 \| 0.4995122 \| 0.0004878044 \|`
			`\| 2 \| 1.0 \| 2/9 \| 0.16666666 \| 0.055555567 \|`
			`\| 2 \| 0.5 \| 2/9 \| 0.19047618 \| 0.031746045 \|`
			`\| 2 \| 0.25 \| 2/9 \| 0.2051282 \| 0.017094031 \|`
			`\| 2 \| 0.125 \| 2/9 \| 0.21333337 \| 0.008888856 \|`
			`\| 2 \| 0.0625 \| 2/9 \| 0.21768713 \| 0.004535094 \|`
			`\| 2 \| 0.03125 \| 2/9 \| 0.21993065 \| 0.002291575 \|`
			`\| 2 \| 0.015625 \| 2/9 \| 0.22106934 \| 0.0011528879 \|`
			`\| 2 \| 0.0078125 \| 2/9 \| 0.22164536 \| 0.00057686865 \|`
			`\| 2 \| 0.00390625 \| 2/9 \| 0.22193146 \| 0.00029076636 \|`
			`\| 2 \| 0.001953125 \| 2/9 \| 0.22207642 \| 0.00014580786 \|`

			`* Question Nine`
			`** C`

			`#+BEGIN_SRC lisp`
			`(load "../lizfcm.asd")`
			`(ql:quickload :lizfcm)`

			`(defun factorial (n)`
			`(if (= n 0)`
			`1`
			`(* n (factorial (- n 1)))))`

			`(defun taylor-term (n x)`
			`(/ (* (expt (- 1) n)`
			`(expt x (+ (* 2 n) 1)))`
			`(* (factorial n)`
			`(+ (* 2 n) 1))))`

			`(defun f (x &optional (max-iterations 30))`
			`(let ((sum 0.0))`
			`(dotimes (n max-iterations)`
			`(setq sum (+ sum (taylor-term n x))))`
			`(* sum (/ 2 (sqrt pi)))))`

			`(defun fprime (x)`
			`(* (/ 2 (sqrt pi)) (exp (- 0 (* x x)))))`

			`(let ((domain-values (loop for a from 0 to 1`
			`append`
			`(loop for i from 0 to 9`
			`for h = (/ 1.0 (expt 2 i))`
			`collect (list a h)))))`
			`(lizfcm.utils:table (:headers '("a" "h" "f'" "\\approx f'" "e_{\\text{abs}}")`
			`:domain-order (a h)`
			`:domain-values domain-values)`
			`(fprime a)`
			`(lizfcm.approx:central-derivative-at 'f a h)`
			`(abs (- (fprime a)`
			`(lizfcm.approx:central-derivative-at 'f a h)))))`
			`#+END_SRC`


			`\| a \| h \| f' \| \approx f' \| e_{\text{abs}} \|`
			`\| 0 \| 1.0 \| 1.1283791670955126d0 \| 0.8427006725464232d0 \| 0.28567849454908933d0 \|`
			`\| 0 \| 0.5 \| 1.1283791670955126d0 \| 1.0409997446922075d0 \| 0.0873794224033051d0 \|`
			`\| 0 \| 0.25 \| 1.1283791670955126d0 \| 1.1053055663206806d0 \| 0.023073600774832004d0 \|`
			`\| 0 \| 0.125 \| 1.1283791670955126d0 \| 1.122529655394656d0 \| 0.005849511700856569d0 \|`
			`\| 0 \| 0.0625 \| 1.1283791670955126d0 \| 1.1269116944798618d0 \| 0.0014674726156507223d0 \|`
			`\| 0 \| 0.03125 \| 1.1283791670955126d0 \| 1.1280120131008824d0 \| 3.6715399463016496d-4 \|`
			`\| 0 \| 0.015625 \| 1.1283791670955126d0 \| 1.1282873617826952d0 \| 9.180531281738347d-5 \|`
			`\| 0 \| 0.0078125 \| 1.1283791670955126d0 \| 1.128356232581468d0 \| 2.293451404455915d-5 \|`
			`\| 0 \| 0.00390625 \| 1.1283791670955126d0 \| 1.1283734502811613d0 \| 5.71681435124205d-6 \|`
			`\| 0 \| 0.001953125 \| 1.1283791670955126d0 \| 1.1283777547060847d0 \| 1.4123894278572635d-6 \|`
			`\| 1 \| 1.0 \| 0.41510750774498784d0 \| 0.4976611317561498d0 \| 0.08255362401116195d0 \|`
			`\| 1 \| 0.5 \| 0.41510750774498784d0 \| 0.44560523266293384d0 \| 0.030497724917946d0 \|`
			`\| 1 \| 0.25 \| 0.41510750774498784d0 \| 0.4234889628937013d0 \| 0.008381455148713468d0 \|`
			`\| 1 \| 0.125 \| 0.41510750774498784d0 \| 0.41725265825950153d0 \| 0.002145150514513694d0 \|`
			`\| 1 \| 0.0625 \| 0.41510750774498784d0 \| 0.41564710776310854d0 \| 5.396000181207006d-4 \|`
			`\| 1 \| 0.03125 \| 0.41510750774498784d0 \| 0.4152414157140871d0 \| 1.3390796909928948d-4 \|`
			`\| 1 \| 0.015625 \| 0.41510750774498784d0 \| 0.41514241394084905d0 \| 3.490619586121735d-5 \|`
			`\| 1 \| 0.0078125 \| 0.41510750774498784d0 \| 0.41510582632900395d0 \| 1.6814159838896003d-6 \|`
			`\| 1 \| 0.00390625 \| 0.41510750774498784d0 \| 0.415092913054238d0 \| 1.4594690749825112d-5 \|`
			`\| 1 \| 0.001953125 \| 0.41510750774498784d0 \| 0.4150670865046777d0 \| 4.0421240310117845d-5 \|`

			`* Question Twelve`

			`First we'll place a bound on $h$; looking at a graph of $f$ it's pretty obvious from the asymptotes that we don't want to go much further than $\|h\| = 2 - \frac{pi}{2}$.`

			`Following similar reasoning as Question Four, we can determine an optimal $h$ by computing $e_{\text{abs}}$ for the central difference, but now including a roundoff error for each time we run $f$`
			`such that $\|f_{\text{machine}}(x) - f(x)\| \le \epsilon_{\text{dblprec}}$ (we'll use double precision numbers, from HW 2 we know $\epsilon_{\text{dblprec}} \approx 2.22045 (10^{-16})$).`

			`We'll just assume $\|f_{\text{machine}}(x) - f(x)\| = \epsilon_{\text{dblprec}}$ so our new difference quotient becomes:`

			`\begin{align*}`
			`e_{\text{abs}} &= \|f'(a) - (\frac{f(a+h) - f(a-h) + 2\epsilon_{\text{dblprec}}}{2h})\| \\`
			`&= \|\frac{1}{12}f'''(\xi)h^2 + \frac{\epsilon_{\text{dblprec}}}{h}\|`
			`\end{align*}`

			`Because we bounded our $\|h\| = 2 - \frac{pi}{2}$ we'll find the maximum value of $f'''$ between $a - (2 - \frac{\pi}{2})$ and $a - (2 - \frac{\pi}{3})$. Using [[https://www.desmos.com/calculator/gen1zpohh2][desmos]] I found this to be -2.`

			`Thus, $e_{\text{abs}} \leq \frac{1}{6}h^2 + \frac{\epsilon_{\text{dblprec}}}{h}$. Finding the derivative:`

			`\begin{equation*}`
			`e' = \frac{1}{3}h - \frac{\epsilon_{\text{dblprec}}}{h^2}`
			`\end{equation*}`

			`And solving at $e' = 0$:`

			`\begin{equation*}`
			`\frac{1}{3}h = \frac{\epsilon_{\text{dblprec}}}{h^2} \Rightarrow h^3 = 3\epsilon_{\text{dblprec}} \Rightarrow h = (3\epsilon_{\text{dblprec}})^{1/3}`
			`\end{equation*}`

			`Which is $\approx (3(2.22045 (10^{-16}))^{\frac{1}{3}} \approx 8.7335 10^{-6}$.`