Derivative: Difference between revisions

Latest revision as of 02:01, 2 July 2024

The derivative $f'(x)$ , of a differentiable function $f(x)$ , is the slope of the tangent line of $f$ at $x$ . [TODO]

Note that this definition does not talk about taking a limit as epsilon goes to 0.

For some functions (indeed, many functions), there is a way to write $f'(x)$ in terms of other known functions. That is, there is a relationship between the concept $f'(x)$ , and other concepts. This need not be the case in general.

Old stuff [TODO delete]

Let $f:\mathbb {Q} \rightarrow \mathbb {Q}$ be a function, and let $\epsilon :\mathbb {Q} _{>0}$ . I define $\Delta _{\epsilon }f:\mathbb {Q} \rightarrow \mathbb {Q}$ by

(\Delta _{\epsilon }f)(x):={\frac {f(x+\epsilon )-f(x)}{\epsilon }},\quad x:\mathbb {Q} .

I say that

f:\mathbb {Q} \rightarrow \mathbb {Q}

is differentiable at

x:\mathbb {Q}

, if

(\Delta _{\epsilon }f)(x)-(\Delta _{\epsilon '}f)(x)

is nill whenever

\epsilon ,\epsilon ':\mathbb {Q} _{>0}

are both nill.

If $f:\mathbb {Q} \rightarrow \mathbb {Q}$ is differentiable at $x:\mathbb {Q}$ , then I define the derivative of $f$ at $x$ as $f'(x):=(\Delta _{\epsilon }f)(x)$ , for some nill $\epsilon :\mathbb {Q} _{>0}$ .

Criticism

This definition makes things way more complicated. I will demonstrate this with the following example.

Let's suppose that $f(x)=x^{3}$ so $(\Delta _{\epsilon }f)(x)=3x^{2}+3\epsilon x+\epsilon ^{2}$ and $(\Delta _{\epsilon }f-\Delta _{\epsilon '}f)(x)=3(\epsilon -\epsilon ')x+(\epsilon ^{2}-\epsilon '^{2})$ . And let's say that we are in a context where anything with absolute value below 0.1 is nill. Let $\epsilon =0.091$ and $\epsilon '=0.001$ . Then $(\Delta _{\epsilon }f-\Delta _{\epsilon '}f)(x)=0.27x+0.00828$ . This quantity is greater than 0.1, and thus non-nill, when $x>0.339{\overline {703}}$ , so we reach the seemingly absurd conclusion that $f(x)=x^{3}$ is not differentiable where $x>0.339{\overline {703}}$ .

More generally, if $\nu :\mathbb {Q} _{>0}$ is the nill cutoff (where we also assume $\nu \leq 1$ ), then $f(x)=x^{3}$ is only "differentiable" in the region

-{\frac {1}{3}}(1+\nu )<x<{\frac {1}{3}}(1-\nu )

This seems like an absurd conclusion.

Polynomial derivatives

Somewhat interesting, but also somewhat obvious vid https://www.youtube.com/watch?v=oW4jM0smS_E

You can get the tangent line to a polynomial without actually invoking limits. My guess is that you can also get the tangent line to a rational function somehow.

@@ Line 1: / Line 1: @@
-Let <math>f : \mathbb{Q} \rightarrow \mathbb{Q}</math>, and let <math>\epsilon : \mathbb{Q}</math> be positive. We define <math>\Delta_\epsilon f : \mathbb{Q} \rightarrow \mathbb{Q}</math> by<math display="block">(\Delta_\epsilon f) (x) := \frac{f(x + \epsilon) - f(x)}{\epsilon}. </math>We say that <math>f</math> is '''differentiable''' if is .... [[nill]] whenever
+The '''derivative''' <math>f'(x)</math>, of a differentiable function <math>f(x)</math>, is the slope of the tangent line of <math>f</math> at <math>x</math>. [TODO]
+Note that this definition does not talk about taking a limit as epsilon goes to 0.
+For some functions (indeed, many functions), there is a way to write <math>f'(x)</math> in terms of other known functions. That is, there is a relationship between the concept <math>f'(x)</math>, and other concepts. This need not be the case in general.
+== Old stuff [TODO delete] ==
+Let <math>f : \mathbb{Q} \rightarrow \mathbb{Q}</math> be a [[function]], and let <math>\epsilon : \mathbb{Q}_{>0}</math>. I define <math>\Delta_\epsilon f : \mathbb{Q} \rightarrow \mathbb{Q}</math> by<math display="block">(\Delta_\epsilon f) (x) := \frac{f(x + \epsilon) - f(x)}{\epsilon}, \quad x : \mathbb{Q}. </math>I say that <math>f : \mathbb{Q} \rightarrow \mathbb{Q}</math> is '''differentiable''' at <math>x:\mathbb{Q}</math>, if <math>(\Delta_\epsilon f)(x) - (\Delta_{\epsilon'} f)(x) </math> is [[nill]] whenever <math>\epsilon, \epsilon' : \mathbb{Q}_{>0} </math> are both nill.
+If <math>f : \mathbb{Q} \rightarrow \mathbb{Q}</math> is differentiable at <math>x:\mathbb{Q}</math>, then I define the '''derivative''' of <math>f</math> at <math>x</math> as <math>f'(x) := (\Delta_\epsilon f)(x) </math>, for some nill <math>\epsilon : \mathbb{Q}_{>0}</math>.
+=== Criticism ===
+This definition makes things way more complicated. I will demonstrate this with the following example.
+Let's suppose that <math>f(x) = x^3</math> so <math>(\Delta_\epsilon f)(x) = 3x^2 + 3\epsilon x + \epsilon^2 </math> and <math>(\Delta_\epsilon f - \Delta_{\epsilon'} f)(x) = 3 (\epsilon - \epsilon' )x + ( \epsilon^2 - \epsilon'^2)</math>. And let's say that we are in a context where anything with absolute value below 0.1 is nill. Let <math>\epsilon  = 0.091 </math> and <math>\epsilon' = 0.001</math>. Then <math>(\Delta_\epsilon f - \Delta_{\epsilon'} f)(x) = 0.27 x + 0.00828 </math>. This quantity is greater than 0.1, and thus non-nill, when <math>x > 0.339\overline{703}</math>, so we reach the seemingly absurd conclusion that <math>f(x) = x^3</math> is not differentiable where <math>x > 0.339\overline{703}</math>.
+More generally, if <math>\nu : \mathbb{Q}_{>0}</math> is the nill cutoff (where we also assume <math>\nu \leq 1</math>), then <math>f(x) = x^3</math> is only "differentiable" in the region <math display="block">-\frac{1}{3}(1 + \nu) < x < \frac{1}{3}(1 - \nu)</math>This seems like an absurd conclusion.
+=== Polynomial derivatives ===
+Somewhat interesting, but also somewhat obvious vid https://www.youtube.com/watch?v=oW4jM0smS_E
+You can get the tangent line to a polynomial without actually invoking limits. My guess is that you can also get the tangent line to a rational function somehow.

Derivative: Difference between revisions

Latest revision as of 02:01, 2 July 2024

Old stuff [TODO delete]

Criticism

Polynomial derivatives

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