@BenjaminGruenbaum are you from germany?

tbh I don't really understand much about this stuff formally

You need a very fundamental axiom of supremums to get from the rational numbers to the real numbers but the complex numbers are just a definition. You can also derive them as an algebraically complete field.

@KTWorks No, my grandparents were though, why?

@BenjaminGruenbaum I like math. Lately I've been looking more into non-Euclidian geometry.

The geometric proofs are pretty interesting for stuff.

because of the name :) Do you have been in germany?

@KendallFrey I don't mind and if I sound like a dick or am using terms that are unclear feel free to stop me and I'll try to explain. I didn't know any of this shit before I got my BSc in it.

IIRC, you lose the axiom of ordering by going from reals to complex, so it's not just a straight extension, right?

@KTWorks last week in a Node.js thing.

@KendallFrey well, the complex numbers aren't even ordered, you can even prove you can't find an ordering on them.

oh cool :D in which city?

right

But I recall there being some axiom which defines ordering of the reals

You can look at ordering stuff (not a complete ordering) like a topological sorting (which creates a DAG which is a bunch of trees).

@KendallFrey I think numberphile had a video about going beyond i, and how you lose more stuff the more dimensions you get into

@KendallFrey Are you asking how > is defined?

basically that, yeah

@towc ah yeah, that's quite cool as well

You need the axiom of supremum to define ordering on non-rational numbers.

> In order theory, this property can be generalized to a notion of completeness for any partially ordered set. A linearly ordered set that is dense and has the least upper bound property is called a linear continuum.

@BenjaminGruenbaum I was thinking of part of this: math.stackexchange.com/a/257208/26832

@KendallFrey Okay. I did some Googling. I guess there can be a non-local hidden variable.

< is defined as a relation @KendallFrey , it is a very specific kind that has to hold properties: !(a < a), a < b && b < c => a < c

I forgot it actually mentions 3 axioms that the complex numbers lose

Oh and a < b => !(b < a)

@Allenph I basically invented that idea myself before slowly realizing it was already well-developed :P

@BenjaminGruenbaum Lemme guess, there's gotta be some base case like 0 < 1, right?

I think his point is that this ordering doesn't need to apply to numbers

Oh sure

That's basically ordering, the real numbers are ordered based on an ordering of the rational numbers. We derive the natural numbers from the paeno axioms (or the ZF construction) for example. Then we derive the integers by closing the set of natural numbers to subtraction (and define the relation on those numbers explicitly). Then we derive the rational numbers by closing it to division.

you can have ordering rules for sets, or any other entity, as long as the rule you chose satisfies these things

Then we use the supremum axiom from above to show that inequality in real numbers is the same thing as the limit of inequality on rational numbers approximating those numbers.

But it applies to reals, but reals are a subset of complex numbers

@KendallFrey We start with 0 is a number, each number has a successor. Then we just say a < succ(a) to define the original relation.

so it seems you can't just add axioms to get complexes from reals, you need to peel some away

@KendallFrey that doesn't mean automatically that the relation carries on. When you add elements to the set it loses properties.

@BenjaminGruenbaum well, that makes perfect sense

@BenjaminGruenbaum Yeah that's the whole confusing thing

math.stackexchange.com/questions/487997/… .

@KendallFrey Yeah. I hate when that happens.

I did that with a bins sorting algorithm when I was like 14. I was so excited to show my dad just to get crushed.

Basically, complex numbers are "isomorphic" to 2d polar points (scaling for the real number, rotation for the imaginary part). You can't really order points in a 2d space because everything on the same "circle" would have the same "value".

yup

You take two different numbers who are on the same circle, the first is bigger than the second but the second is also bigger than the first (just from the other direction of the rotation). I think that came out as confusing but if you know the representation then maybe.

That's why e^Pi*i = -1 makes sense, that's how the Pi got there, because it's rotation.

Yeah I get the whole no-order thing

it's the fact that the reals have it and the apparent extension of the reals doesn't

So either complex is an extension of some sub-real numbers, or extending a system can lose properties of that system

It's an extension that can lose properties. The reason it is confusing is that you assumed that the square root of -1 isn't defined when you ordered your numbers.

I did?

@BenjaminGruenbaum can't you say something like: "the ordering score of an imaginary number is <radius> + epsilon * <radiant>"? Or if infinitesimals are a problem, you just split it into conditions: "order by radius. If same radius, order by radiant"?

I can't see any problems that come from that

Yeah, let's look at just rational numbers, at some point you said that if a > b then n*a > n*b for every integer n and proved it (say first for natural numbers, then for division of 1/n and then show it holds for every property). You don't get that for free you have to prove it.

Then, you showed it for real numbers with limit arithmetic, I can find a proof if you'd like. These are all things we had to do ourselves in our calculus course.

You need to prove it for complex numbers and you can't, it's impossible to prove it.

@towc read the proof I posted above chat.stackoverflow.com/transcript/message/42887996#42887996

@towc math.stackexchange.com/a/488015/33091

@towc That means that i > 0 but i * -1 > i which leads to a contradiction

@BenjaminGruenbaum yeah, but that's a different set of rules from the ones you first mentioned

I thought you also said that ordering can't be defined with that either, for complex numbers

@towc oh, the proof just shows you can't define < as anything that is an ordering - namely the way you suggested. In order to show that it is an ordering you would have to show that the three rules hold.

That is, you will be unable to prove that "number + radius * someValue" holds the three laws an ordering requires.

oh wait

yours, for sure

ok, that's interesting

Same ones, ` !(a < a), a < b && b < c => a < c` and a < b => !(b < a)

are you guys still talking about multiverses?

@BenjaminGruenbaum I'm not writing a formal proof, but I don't see where you'd get stuck

if you use the 2-condition ordering rule, you just run all the conditions combinations with the three laws, and they should turn up fine

I'm obviously wrong somewhere, just can't think of where

@towc then try to prove it - that's the best way to understand really. It's also a good reminder that you can't rely on things you think work without actually proving them in Math.

I mean, I'm assuming I'm wrong. I'm asking because I don't really want to spend time doing it. Not today anyway

@FahadUddin Sure

what is a complete JS developer?

like full stack, or well rounded in the docs?

I mean of those we only use Node

Sure

Be great at all of them and a master of none, I'm not a master in any programming language and I'm doing fine.

(Am also not great in many)

with the ordering rule for less than: "compare (a.radius, b.radius) { less: true, more: false, same: compare (a.radiant, b.radiant) { less: true, more: false, same: false } }", first one seems trivial: !(a < a). a has same radius as a, but also has same radiant as a, so not less than

@towc with that ordering i > 0 but -1 > i (by multiplying both sides with i) so -1 > 0 which is false.

@FahadUddin usually if you go over the language before the interview and have used it "for real" before you'll do fine.

@BenjaminGruenbaum but this doesn't go against your laws

it goes agains the laws in that SE q

It goes against the law that a < b => !(b < a) since -1 < 0

@BenjaminGruenbaum your rules never mentioned that multiplying both sides keep the ordering

@towc that's derived from how real numbers are compared which you used in your compare.

(was in the middle of writing this, I'll just finish it) last one has slightly more steps, but is about as trivial: a < b => !(b < a): if a < b, it means that either a.radius < b.radius, or a.radius = b.radius && a.radiant < b.radiant. In the first case, !(b < a) because a.radius < b.radius, in the second case, a.radius = b.radius && a.radiant < b.radiant, so it's false either way

oh wait, I had a problem with you multiplying. But either way, the multiplication seems irrelevant

@BenjaminGruenbaum actually, that's fine. With this ordering, -1 > 0 is true, which doesn't break any laws of the ordering itself

the < for complex doesn't have to extend the < for reals

@towc Then that implies 1 < 0 which is false, that's by definition from how we ordered the natural numbers.

does my last message make you change that statement?

@towc it doesn't have to - but the way you defined it it does.

Look at your compare thing - the first thing you're doing is comparing the "real" part of the number.

sure, but it's using another operation, not itself

maybe I should have been more verbose

but making it use itself just seems pointless

either way, you can make it an extension, by saying that at the same radius, the value at radiant = pi, is less than any other value in that circle

It's not that it's using another operation - it's the fact that passing any two real numbers through it it returns the same thing as the regular ordering on real numbers. You constructed it that way, if a < b for two real numbers then a < b for two complex numbers with your scheme.

it will extend for truthiness. Still won't work for multiplying both sides etc

@BenjaminGruenbaum I'm confused

The proof from Math.se shows that no matter what scheme you try to come up with then a contradiction will be reached. That's the beauty of it - it shows something to be impossible.

with the rules the q provides, not yours

I'm still trying to understand "You constructed it that way, if a < b for two real numbers then a < b for two complex numbers with your scheme."

clearly not. 0 < -1 is completely valid here

I don't know where you're getting that -1 < 0 in my scheme

-1 has bigger radius, end of the check

compare (a.radius, b.radius) { less: true, more: false , ... }

// check for a < b
compare (a.radius, b.radius) {
  less: true,
  more: false,
  same: compare (a.radiant, b.radiant) {
    less: true,
    more: false,
    same: false
  }
}

Oh, you mean you're comparing them by absolute value? So -3 > 1 in your scheme?

oh, no

actually, yeah

So -3 + 3 > 1 + 3 since you can add a number to an inequality?

taking the radius is like taking the absolute value, so I guess so

@BenjaminGruenbaum again, I'm not extending the rules of applying operation on both sides

that's not in the rules you gave

But then neither -3 > 3 nor -3 < 3

-3 > 3

same radius, but pi > 0

Why?

What Pi?

the radient

What radiant?

if you use [0, tau)

Then it's 0, there is no imaginary part to -3, it's just a real number

@BenjaminGruenbaum well, -3 is 3*e^(i*pi)

lol, still on this

@towc so?

so it doesn't matter if it also happens to be a real number

it's very definitely part of complex numbers too

I don't think you've thought this through... that's not how the e ^ (pi * i) = -1 thing works. How would this work for actual imaginary numbers?

That is, -3 + 2i > 3 - 1000i ?

LHS.radius < RHS.radius => LHS < RHS; end of check

what's the issue?

You said -3 > 3

@BenjaminGruenbaum sure

Then LHS has bigger radius

-3 and -3 + 2i are different numbers

by radius I don't mean the real part

Then what do you mean by the radius?

<radius>e^(i*<radiant>)

You mean in r cis(theta) notation?

What are we doing here, trying to find a counterexample to towc's ordering?

Oh, then you should have said so :P That still breaks for the same reason though, just walk through the example proof from Math.se, it works here.

he said he did, but I don't understand it, so I'm asking for clarification

@BenjaminGruenbaum I mean, when I hear radius and radiant, polar coordinates seem like the obvious context

In your notation, does 1 cis (Pi / 2) < 0 cis(0) or no?

@BenjaminGruenbaum only if you want to keep ii and iii

@BenjaminGruenbaum no

Without them it's simply not an ordering

0 < 1

@BenjaminGruenbaum well, it wasn't part of your rules

I was solving for your rules

You mean 0 < i in this case?

@BenjaminGruenbaum yes

but point is that the check stops at 0 < 1

you don't even care about the radiant at that point

If you don't define addition or multiplication for complex numbers then they aren't complex numbers and you can do your relation - but it's no longer an algebraically closed field at that point.

oh wait, I might have to read on relations then

that might define the operation thing

and if so, you were right

No the operation thing is specifically for a specific kind of a relation and how we define ordering on the real numbers.

I assume you meant to link to this, actually? en.wikipedia.org/wiki/Binary_relation

@BenjaminGruenbaum well, you never mentioned that

Well, pretty sure we did bring it up several times.

you insisted my scheme didn't support those operations, and I agreed

??

it's late for you benji, go to sleep :P

Damn, it's late .. <input type="number"> How can I select that in plain js?

something like

document.querySelectorAll('input[type="number"]')

or just add an id to the input and then

document.getElementById("number")

hey guys, wanna influence my work's internal survey on what they should name the new conference room?

pollmaker.vote/p/T0GHZJ5H

lolol

yeeahh they changed the link

new one: strawpoll.com/7b9sf7yr

they changed it like 20 minutes ago, I just pasted the wrong one

Those are terrible conference room names

I vote for the purple rocket personally.

Mix the two names and it's perfect.

they seem too terrible to be true, I think they must be categories or something

I don't understand what "ambtion" would mean as a category anyway

One of our conference rooms is called the fishbowl because it's glass. Another is "Innovation Central" because it's for developers to go hash out shit on the walls, and I don't think we have a name for the board room

they can't even spell ambition

isn't it great

so it seems I can cast votes on your companies poll too? lol

just voted for rockets

that's why the link is here

don't vote for rockets, you've tied it now

ambtion is much more entertaining

sorry

but theyre both terrible

true

ok deleted the cookies then it let me vote again :D

hahahaha no don't worry about it

it checks by IP