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Author: Subject: Calculus! For beginners, with a ‘no theorems’ approach!
blogfast25
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[*] posted on 18-3-2016 at 19:07


Quote: Originally posted by chemrox  
Calculus courses are all about the notation. I never cared for the limit notation or the Δ forms. I like the Liebenetz dy/dx format. Of course you have to explain what they mean..and calculus is the only way to learn trig
dy/dx ≠ Δy/Δx



I have to disagree somewhat here. Notation is mainly conventional. Some prefer Leibniz, others Newton ("dot y"):

$$\dot{y}=\frac{dy}{dx}$$

Using calculus professionally, one has little choice but to familiarise oneself with the various notations and variations. It's a bit like musical notation: it may differ slightly from one composer to another but most will be able to read another's scribblings w/o problems.

As regards limit notation, do you have an alternative?

As regards "dy/dx ≠ Δy/Δx", that case has been firmly made higher up.





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[*] posted on 18-3-2016 at 21:27


There are reasons why both leibniz' dy/dx notation and Newton's f'(x) notation have both survived.

Newton's notation simplifies and manipulates nicely. f'(x) simplifies to f'. f''(x) simplifies to f''. This easily enables f to be manipulated as an algebraic object.
Newton's notation also enables substitution into the function to be shown easily. f(2), f(x), f(t), f(n+3), f(g(x)) and so forth.


Leibniz emphasises the concept of a rate better. It allows for separation of the two differentials which is useful for integration and solving differential equations. (In Leibniz notation, integration is more than just antidifferentiation -- it is a sum to find an area. Conceptually, this is different and it shows in the notation.)
Leibniz is also useful in that it shows the variable that one is differentiating with respect to. dy/dx and dy/dz and so forth. To my knowledge, Newton's applications were differentiating with respect to time only. Leibniz easily allows multi-variable functions and partial differentials. ∂2y/∂x∂z for example.

There are advantages to both notations and a good understanding of calculus is aided by having facility with both.




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[*] posted on 18-3-2016 at 21:44


I'm not seeing a lot of the material you drew. I'm looking at in firefox. Any idea what might be the issue? What format were you putting the math in?



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[*] posted on 18-3-2016 at 21:53


I didn't draw anything. My post is all text.
Bloggers is using latex -- as described here.




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[*] posted on 18-3-2016 at 21:55


Quote: Originally posted by blogfast25  
Quote: Originally posted by chemrox  
Calculus courses are all about the notation. I never cared for the limit notation or the Δ forms. I like the Liebenetz dy/dx format. Of course you have to explain what they mean..and calculus is the only way to learn trig
dy/dx ≠ Δy/Δx



I have to disagree somewhat here. Notation is mainly conventional. Some prefer Leibniz, others Newton ("dot y"):

$$\dot{y}=\frac{dy}{dx}$$



Using calculus professionally, one has little choice but to familiarize oneself with the various notations and variations. It's a bit like musical notation: it may differ slightly from one composer to another but most will be able to read another's scribblings w/o problems.

As regards limit notation, do you have an alternative?

As regards "dy/dx ≠ Δy/Δx", that case has been firmly made higher up.



I see what you mean. The problem I'm having is I'm not seeing it all so please disregard earlier comments. Except for one thing: I would not bother with any theory. You can take analysis if you want to really learn it. If you want to use calculus, professionally or otherwise, jump to the Liebniz (thanks for the spelling) notation. I would however name the rules. For example I think you started out with the product rule. I think naming the rules is a good memory crutch. As far as notations go maybe its a good idea to cover them all right away. I went to a big school where every math prof. liked a different text. It drove me nuts until I found one I liked in the library to carry me through. Linear algebra was the same way. When I took it I found the text was the barrier and I found a 67 page one that covered the course. That course was about making good guesses about series more than anything.




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[*] posted on 18-3-2016 at 22:00


I had to reload my browser. Now about 2/3 of the pages are gone WTF? Did all the latex disappear?



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[*] posted on 19-3-2016 at 06:33


Quote: Originally posted by chemrox  
I had to reload my browser. Now about 2/3 of the pages are gone WTF? Did all the latex disappear?


No, I can see all of it. Looks like a browser problem at your end.

[Edited on 19-3-2016 by blogfast25]




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[*] posted on 19-3-2016 at 09:06
When a derivative becomes zero...


Consider the following smooth and continuous generic function y=f(x):

optima.png - 5kB

I’ve also drawn the tangent lines in various points, in green where the tangent has a positive gradient, in red where the tangent has a negative gradient.

As we move from left to right the positive gradient first becomes smaller and smaller, to reach zero at the top of the ‘hill’ (black tangent is horizontal).

Moving beyond that point the gradient of the tangent line becomes negative, then less and less negative to reach zero at the bottom of the ‘valley’ (black tangent is horizontal). It then becomes positive again.

The points where the tangent line’s gradient becomes zero are called optima (minimum and/or maximum) and are the points are those for which:

$$y’(x_{max})=0\:\text{and}\:y’(x_{min})=0$$

So optima occur where:

$$y’=\frac{dy}{dx}=0$$

Parabola:

An interesting case in point is the quadratic polynomial:

$$y=ax^2+bx+c$$

Graphically it shows as a parabola:

Parabola 2.png - 3kB

Since as:

$$y’=2ax+b$$

There always is an optimum for:

$$2ax+b=0$$

$$x_{opt}=-\frac{b}{2a}$$

The value of y<sub>opt</sub> can be calculated from plugging into y.

Note that here the optimum is a maximum but parabolas that exhibit a minimum also exist of course (just flip the graph over 180 degrees).

This property of derivatives becoming zero where optima of the function f(x) exist is used in optimisation problems (next up).

[Edited on 19-3-2016 by blogfast25]




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[*] posted on 19-3-2016 at 09:28


Yet another notation used for d/dx is simply D. The operator D is a linear functional with the property Df = f'

Powers of D are used to represent repeated differentiation, e.g. D²f = DDf = D(f') = f''.

Integration can be written as 1/D or D-1, e.g. D-1f stands for the integral of f(ξ)dξ from ξ=0 to ξ=x.

Using this notation, one can even use fractional powers, e.g. D½x = 2√x/√π

And of course repeating D½ two times yields D½D½ = D, which simply is taking the first derivative.

The operator D can also be used as argument of (analytic) functions, e.g. eD (here e is the base of the natural logarithm, the number 2.7182818....) and this thing can be applied as operator to functions, e.g.

[eaD]f(x) = f(x+a) for any function f and any constant a.

Here eaD is not a function, but a functional.



[Edited on 19-3-16 by woelen]




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[*] posted on 19-3-2016 at 10:10


And related to the operator Del, is the nabla:

$$\nabla=\Big(\frac{\partial}{\partial x},\frac{\partial}{\partial y},\frac{\partial}{\partial z}\Big)$$

and:

$$\nabla^2$$

But I think we're starting to 'show off', as this thread is mainly intended for the education of the calculus-impaired. :D




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[*] posted on 19-3-2016 at 12:15


Oh dear.

Late for class again. What is going on ?

Latex, derivatives and nablas !

Might have to copy someone's homework. Anybody ? Please ?

Maybe i can get away with trying out some Latex ...

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[*] posted on 19-3-2016 at 15:58


$$=-\infty$$

You tryin' to tell me somethang, mistah? :)

So, what can we do by way of... ermm... remedial classes?





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[*] posted on 20-3-2016 at 10:28


Erm, reading the thread, it all looks a bit over my head.

The Rules thing kinda suggests that despite the 'orrible algebraic complexity, some Genii have worked out some easy-to-apply rules that basically make it a lot simpler if you just follow those rules.

Is that right, or did i just imagine an easy way ?

[Edited on 20-3-2016 by aga]
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[*] posted on 20-3-2016 at 13:21


Quote: Originally posted by aga  

Is that right, or did i just imagine an easy way ?



Yes, that's definitely what they're there for: make derivations easier.

Do you have problems with these:

http://www.sciencemadness.org/talk/viewthread.php?tid=65532#...

Send answers by U2U, if you prefer. :)

[Edited on 20-3-2016 by blogfast25]




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[*] posted on 20-3-2016 at 14:32


Quote: Originally posted by blogfast25  
Do you have problems with these

No, because i'm amazing and am so incredibly awesome that i can eat peanuts ... and my mom has a car ! etc etc.

Honest answer : Yes.

I have not got a Clue how you would even attempt those questions, despite reading, printing, then re-reading your erstwhile explanations.

Add-ups, take-aways, times-bys, share-bys, basic algebra, and possibly some trigOhNometry : they are all OK, as in i understand most of those, i.e. had a basic education.
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[*] posted on 20-3-2016 at 14:54



Keep your socks pulled up there blogfast. There is some serious competition out there!

https://www.coursera.org/learn/calculus1?siteID=.GqSdLGGurk-...

Thanks for the bit about the infitesmals, never knew that or unstood when they were moved about.

[Edited on 20-3-2016 by yobbo I]
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[*] posted on 20-3-2016 at 16:35


Quote: Originally posted by aga  

Add-ups, take-aways, times-bys, share-bys, basic algebra, and possibly some trigOhNometry : they are all OK, as in i understand most of those, i.e. had a basic education.


Ok. If you want to carry on with this 'course', you'll have to 'help me, help you'. I don't understand well enough what causes you to struggle with:

$$y=ax^n$$

Ergo:

$$y'=(ax^n)'=a(x^n)'=a \times nx^{n-1}=anx^{n-1}$$

Maybe try and explain better what you're struggling with? Here or by U2U?


Quote: Originally posted by yobbo I  

Thanks for the bit about the infinitesimals, never knew that or understood when they were moved about.


Thanks.

[Edited on 21-3-2016 by blogfast25]




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[*] posted on 21-3-2016 at 03:49


Quote: Originally posted by blogfast25  
Maybe try and explain better what you're struggling with? Here or by U2U?

I;m still staring at these http://www.sciencemadness.org/talk/viewthread.php?tid=65532#... and wonding what to do.

If you could work through example 1, that would be enormously helpful.
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[*] posted on 21-3-2016 at 04:31


Ok. These are easy. You ca manage them aga.
Drop the power by one.
The new coefficient is the old coefficient multiplied by the old power.
Repeat for each term in the polynomial.


So, if
$$y= 3x^5 + 2x^3 - 9x^2 + 6x +11$$

$$y'=15x^4 + 6x^2 -18x +6$$


The x is infact x^1. It degenerates to x^0 on differentiating. x^0 is of course 1 and so you are left with the coefficient only.

The constant term is a term in x^0. This degenerates to zero on differentiating. There are multiple ways of thinking that through. It is worth pausing to think that one through carefully and convince yourself as to why.
As so often happens, it is the so-called easy ones that are tricky because something simplifies out of sight and the notation starts to alter.




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[*] posted on 21-3-2016 at 05:18


Quote: Originally posted by aga  
Quote: Originally posted by blogfast25  
Maybe try and explain better what you're struggling with? Here or by U2U?

I;m still staring at these http://www.sciencemadness.org/talk/viewthread.php?tid=65532#... and wonding what to do.

If you could work through example 1, that would be enormously helpful.


OK.

Ex. 1:

Derive:

$$(-5x^4)'$$

As -5 is a constant we put it upfront (proof: product rule):

$$(-5x^4)'=-5(x^4)'$$

To derive x4, put the exponent 4 upfront, then reduce the exponent by 1:

$$(x^4)'=4x^3$$

Put it all back together:

$$(-5x^4)'=-5(x^4)'=-5(4x^3)=-20x^3$$

Ex. 3:

$$u=2+5x^{-8}$$

This is a sum, so the derivative is the sum of the derivatives that make up the sum:

$$u'=(2)'+(5x^{-8})'$$

$$(2)'=0$$

$$(5x^{-8})'=5(x^{-8})'=5(-8x^{-9})=-40x^{-9}$$

$$u'=0-40x^{-9}=-40x^{-9}$$

Ex. 5: (the hardest one)

$$z=2-x+ax^{\pi-b}$$

This is a sum (and a difference) of three terms. Derive each term individually, then add them up again:

$$(2)'=0$$

$$(x)'=1$$

$$(ax^{\pi-b})'=a(x^{\pi-b})'=a[(\pi-b)x^{\pi-b-1}]=a(\pi-b)x^{\pi-b-1}$$

Adding up:

$$z'=-1+a(\pi-b)x^{\pi-b-1}$$

<hr>

Recapping:

1. The derivative of a constant (a) equals zero:
$$(a)'=0$$

2. The derivative of x equals 1:
$$(x)'=1$$

3. Constant rule:

$$(af(x))'=af'(x)$$

4. Power rule:

$$(x^n)'=nx^{n-1}$$

5. Sum rule:

$$[f(x)+g(x)]'=f'(x)+g'(x)$$

6. Product rule:

$$[f(x)g(x)]'=f'(x)g(x)+f(x)g'(x)$$

(we'll recap the quotient rule and the chain rule again, later)





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[*] posted on 21-3-2016 at 05:21


Thank you, j_sum1.



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[*] posted on 21-3-2016 at 05:59


Another thing which may help making it more easy to remember is to combine the product rule and chain rule in order to derive the quotient rule. No need to memorize the quotient rule.

[f(x)/g(x)]' can be written as [f(x)u(x)]', where u(x) = 1/g(x).

Now apply the product rule:

[f(x)u(x)]' = f'(x)u(x) + f(x)u'(x)

Next, apply the chain rule for deriving the derivative of u(x) = 1/g(x). Here, 1/g(x) can be written as h(g(x)), with h(x) = 1/x.

[h(g(x))]' = h'(g(x))g'(x).

h'(x) = -1/x2, hence h'(g(x)) = -1/[g(x)]2, hence u'(x) = -g'(x)/[g(x)]2

Now we have all in place to express [f(x)/g(x)]' in terms of f(x), g(x), f'(x) and g'(x):

f'(x)u(x) + f(x)u'(x) = f'(x)/g(x) - f(x)g'(x)/[g(x)]2

Taking everything under the same denominator we get

[f(x)/g(x)]' = [f'(x)g(x) - f(x)g'(x)]/[g(x)]2

-----------------------------------------------------

The only way to make it really is easy is doing/exercising it. Just take derivatives of many different functions and soon you'll see that you naturally apply the product rule and chain rule correctly. I never felt the need to memorize the quotient rule.

Practice, practice and practice!


[Edited on 21-3-16 by woelen]




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[*] posted on 21-3-2016 at 08:33


Many thanks for taking the trouble to show the workings.

i think i got it !

If i did understand it , then Excercise 2 should go like this ...
$$y=2-3x^4+x^6$$
$$y'=0-3(4x^3)+6x^5$$
$$y'=6x^5-12x^3$$

Semantics difficulties : How do you actually say these two, and what is the difference ?
$$f'(x)$$
$$f(x)'$$
First derivative of function f ?

Edit:

Exercise 4 should go like :-
$$v=x-2$$
$$v'=1-0=1$$


[Edited on 21-3-2016 by aga]
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[*] posted on 21-3-2016 at 09:38


Yup, history in the making: first successful derivations (2) by aga on SM! Lift off but we probably need a bit more 'lift' to come.

$$f'(x)=f(x)'=(f(x))'=[f(x)]'$$

... Are all synonymous and can all be used. I prefer f'(x): "the (first) derivative of the function f of x".

Woelen is right on all counts and as with all things, practice makes perfect! So I'll bring on some more specifically chosen examples tonight.

As you've guessed we're now all ganging up on you and further resistance is futile. You're in a corner: either hoist the white flag or fight your way out of it! We WILL teach you some calculus, whether you like it or not, hombre!:cool:




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[*] posted on 21-3-2016 at 11:51


Um, it looked a lot harder : a LOT harder.

Sorry for the prevarication.

Edit:

Is a Green flag OK ?

Just the hanky got used and it's a bit icky now.

[Edited on 21-3-2016 by aga]
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