User talk:GFauxPas/Archive1

Induction
I need more time to work on this and it's getting to unwieldy, so I'm taking it off for the time being while I learn more about induction etc. Thanks for your help Lord_Farin. --GFauxPas 16:42, 3 November 2011 (CDT)


 * Please take time, by the way, to study the format in which other pages have been written. It would be instructional for you to note the changes that have been made so far to what you have entered, and to take note for future entries. --prime mover 00:18, 18 October 2011 (CDT)

Okay thank you for the advice, I'm very new at this but I hope I can learn it --GFauxPas 06:04, 18 October 2011 (CDT)
 * So are many others. You'll pick it up. You'll be expected to. You're a mathematician. --prime mover 11:28, 18 October 2011 (CDT)

It seems a bit presumptuous to call myself a mathematician, I'm just a freshman math student D: but thanks for the compliment, I think? Question please: I have my own proof that came about in physics, an object travelling in a parabolic path will have the same magnitude of velocity at any two points with the same elevation, but will differ in sign. Mathematically, given a second order polynomial and a horizontal line intersecting it at two points, the derivatives at the two points of intersection will be equal in magnitude but differ in sign. Is this theorem-worthy? What is the name of this theorem if I want to type up a proof? What do I search for to see if it's already in the wiki? --GFauxPas 11:37, 18 October 2011 (CDT)
 * See those links on the left? See where it says "Proof Index"? I invite you to press it and explore. --prime mover 12:32, 18 October 2011 (CDT)

Convergence and other principles of analysis
Currently I am a teaching assistant for an advanced analysis course, so if you have any questions regarding real (multidimensional or not) analysis, feel free to drop a note on my talk page. When you eventually get there, I might be able to help out on Complex Analysis as well. --Lord_Farin 14:27, 23 October 2011 (CDT)

Awesome, thanks a lot --GFauxPas 14:33, 23 October 2011 (CDT)

Notation
I note from your front page you're setting up some copypasta for yourself. Before you go too far down that route, pls note the following:

1. The raw symbols ≡, · and Δ and so on are never used on ProofWiki. The $\LaTeX$ code is always used: $\equiv, \cdot, \Delta$ (or when appropriate $\triangle$ and its variants).

2. For "defined as" we use $:=$ as this is a specific symbol meaning "is defined as". The $\equiv$ symbol has plenty of other meanings and it is best kept for those.

Hope this is OK. --prime mover 16:29, 24 October 2011 (CDT)

A while back I wrote a proof that all integers are even or odd. The reason I wrote it was just to practice mathematical induction. The theorem itself seems rather unimportant, and so I don't see a reason to make a page for it, but at someone's request I can make it. --GFauxPas 15:56, 4 November 2011 (CDT)
 * I have a feeling that one might already be up, but I don't think it was proved by induction. Can't remember and I don't feel like looking at the moment. --prime mover 17:24, 4 November 2011 (CDT)

Seeing as how we're using an uncommon notation for intervals to avoid ambiguity, what's the defining criterion for whether we use an atypical "better" notation or not? For example, the though the standard notation for function inverse is $f^{-1}$, that notation is the same as that of the multiplicative inverse, very different things. There's $f^\gets$ and $\breve f$ which aren't ambiguous, but they're not common. --GFauxPas 16:41, 8 November 2011 (CST)


 * Good question. There are many notations for intervals, and none of them are very good because it's easy to mistake two numbers separated by a comma for all sorts of other usages. $[a..b]$ is not common but it's completely unambiguous and has a precedent in computer languages, so I'm sort of expecting it to catch on. Getting mathematicians to change their notation, though, is not easy.
 * As for the inverse function notation, "generally speaking" you don't mistake $f^{-1}$ for a multiplicative inverse because the contexts are different. The $f^{\gets}$ notation has been noted on the page for inverse mapping so I suppose we could start using it, if you particularly like it. --prime mover 17:05, 8 November 2011 (CST)


 * I think I oppose to that. The notation for the interval isn't really ambiguous, even if you never saw it before, the meaning is clear. With $f^{\gets}$ I am having the hunch that it will create unnecessary fuss. But that's me, and probably an instantiation of the notation change thing... --Lord_Farin 17:09, 8 November 2011 (CST)

Lord_Farin, just wanted to let you know that I figured out your explanation and PW's approach here Talk:Fundamental_Theorem_of_Calculus/Alternative_Second_Part_Proof, thank you! --GFauxPas 22:19, 5 November 2011 (CDT)


 * Glad I put up sensible stuff. HTH --Lord_Farin 09:01, 6 November 2011 (CST)

Talk page etiquette
I hate having to keep calling you out like this, I sort of hope you will pick up the conventions as you see them being used.

However, it's probably worth mentioning the usual protocol in talk pages, when there's a conversation going on.

You may have noticed that when you start a line with a colon it acts like a tabulator, that is, indents the line by a fixed and noticeable amount. Starting with more colons indents the line further.

Anyway, in a talk page the convention is to start each reply with one colon more at the start of the line. In that way it can be easily worked out who said what, and when they said it, and what they are replying to. Only when the indentation becomes too much (usually about 7 or 8 colons in) is the conversation reverted to the far left hand side of the page again. Usually this does not happen on ProofWiki because issues are usually solved within two or three postings. --prime mover 12:34, 11 November 2011 (CST)
 * Noted. Sorry to disappoint. I'll cop out and play the "not sleeping enough" card. --GFauxPas 12:41, 11 November 2011 (CST)

Book referencing
What I said the other day about learning from examples.

Can you do the same with your book referencing? No doubt you have a copy of Tarski. Rather than just citing it the [terse] way you're doing it, can you stick it inside a BookReference template? Then it will lead you to perhaps put an entry together in the Books namespace. I can't do this myself because I don't have that Tarski book. --prime mover 13:55, 14 November 2011 (CST)
 * I know, I was planning on doing that as soon as I got home, when I put that in I didn't have the book on me. Next time I'll wait until I can do it all at once. Sorry I didn't know doing that "placeholder" method was frowned upon. --GFauxPas 14:02, 14 November 2011 (CST)


 * Nope you're all right. Nice one. What you might want to do, so as to save misunderstanding, is putting a call to the template in place, then we'd all know it's planned. --prime mover 15:41, 14 November 2011 (CST)

Real Number Line
Good job! A couple of things:

a) Tarski may well have been making unwarranted assumptions when he wrote this proof, and/or mathematics has moved on since his day. However, I believe it's not enough to just state that there exist mappings between the two sets for there to be a bijection between them - we need to show they are injective. After all:
 * $A = \{0, 1\}, B = \{2\}, f: A \to B: f(0) = 2, f(1) = 2, g: B \to A: g(2) = 0$

fits the conditions: $f$ and $g$ are both mappings, but $A$ and $B$ are definitely not equinumerous.

b) From the words put forward by Qedetc in the talk page, it appears that Tarski may have defined some axioms in order for assumptions on this page to be valid. Qedetc was insistent that no such mapping could possibly exist without such, but I was not able to pin him down on exactly what needed to be done. Can you read that book carefully (or do further research) to see whether there's something there about that? I don't have the information to hand.

c) When citing an entry in a book, try not to use page numbers, as different printings may cause these to change between editions. Please refer to the section / chapter instead. See the existing examples for a sample of how this works. --prime mover 04:30, 20 November 2011 (CST)


 * Understood, thank you prime.mover. I had a feeling that something like this was the case, but I gave up trying to follow the conversation on the talk page, I felt it was way above my head. I'll see if I can find something, and I'll try the talk page again. --GFauxPas 07:11, 20 November 2011 (CST)


 * I was in over my head too. In fact, I'm fairly sure Qedetc was in over his head as well. Probably so far over his head you couldn't see the bubbles. --prime mover 07:21, 20 November 2011 (CST)


 * I want to add that I refuse to believe all of analytic geometry is based on the axiom of choice. --GFauxPas 08:36, 20 November 2011 (CST)

Sizing of Images
When you are creating images, there is no need to create different versions depending on what size you want it. All you do in the code is add " px" to tell the browser how many pixels (high? wide? Don't know) to render the image.

In order to keep the images folder tidy (it can't be organized easily) I will update the cone page to use File:ConeVolumeProof.png and size it appropriately, then delete File:ConeVolumeProof2.png.

--prime mover 04:45, 20 November 2011 (CST)

Trig integrals
Good work on all these trigonometric integrals. It's something I've been meaning to get round to doing but haven't done yet. We have the opportunity of providing the best repository of integrals on the internet. --prime mover 12:06, 24 November 2011 (CST)
 * My pleasure. I don't like proofs like the secant proof where the steps come out of nowhere, but it is what it is. Thanks for the compliment. --GFauxPas 12:09, 24 November 2011 (CST)
 * Understood, and I'll stick to x if you like x better, I apologize for wasting your time. As I said, I'm a slow learner at some things. I'm still trying to measure what needs to be said and what doesn't. --GFauxPas 14:06, 24 November 2011 (CST)
 * Okay, here's a general rule: if it's in place using notation you're not happy with, but it's sound, then leave well alone unless there's a good reason not to (e.g. it's incorrect). If you prefer using theta in the proofs you work on, fair enough, but if and when we expand the understanding to take on board complex numbers we might take the opportunity of amending the notation again. Of course, if it has a proofread and/or tidy template (or it's otherwise new by a contributor who has not yet assimilated the house style) then the above does not apply. Of course, if you really don't agree with the presentational style, raise the question in the discussion page. That's always an option. --prime mover 14:58, 24 November 2011 (CST)
 * Thank you for your patience with me, Prime.mover. I don't care what symbols I use, and if it makes you happy you can change any notation I use, I don't care. I just have accustomed myself to using theta for trig, I don't mind using x or whatever if you like it better. The main reason I edited the cosine page there was because the proof didn't address the sign of the sine. Also, can I leave it as a given that differentiation and integration are linear operators? I've been putting it in the proofs, but it's left implied in most of the proofs I see outside of PW. --GFauxPas 15:08, 24 November 2011 (CST)
 * I rarely bother to note the derivative of a minus, because it all follows with simple algebra anyway. If there's a specific need to invoke a complicated linear combination, then perhaps note that, but for a simple constant multiple I would not. Note the corollary to the derivative of the exponential which includes the drv. of $e^{cx}$ - you might want to add something similar as a corollary in the trig functions. In fact, drv of $\sin (ax + b) = a \cos (ax + b)$ is a really useful corollary, so when we get onto complicated substitutions in the messy integrations involving quadratics, you just need to invoke that page and it saves a lot of extra work on the substitution. --prime mover 16:26, 24 November 2011 (CST)