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Second Update: I see that some answers that reference my image are more closely answering my question. Here is a second image to clarify my point.

Take this image representing a checkerboard like configuration. If I asked you to move the X negative 1 space it would be impossible. You would have to make a guess as to which direction is negative. However, I can ask you to move the X 1 space/unit, since moving to any square from the center would satisfy moving 1 space/unit.

But wait! Once you complete moving the X 1 space/unit; I could now follow up and request you move negative 1 space, since you have now already travelled in one direction. Now you are able to negate the original request by 1 space/unit

Therefore negative doesn't exists until you have already begun moving in some direction/unit/space/time/apples.

enter image description here


update enter image description here

Maybe this helps illustrate my point.

In this image there is a line, going either direction will take you to infinity (A or B), the number of spaces you move is always a positive number. If I moved 20 widgets closer to infinity A. or I moved 20 widgets closer to infinity B. So, negative numbers don't exist and are only positive numbers that are increasing in the opposite direction

Negative indicates the direction of travel on a line. the measure of movements will always be positive.

Does a negative number really exist? I can't have -1 apples. I can only imagine I had an apple when I really did not. Thus, in reality I would have -1 apple as compared to my imagination.

didn't know how to tag this

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    I can't wait to the number 1337 walking down the street2015-06-18

9 Answers 9

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Doug, one cannot move in the opposite direction ($-1$) with relation to anything until one has chosen a direction, i.e. a basis.

No numbers exist other than in theory -- negative, positive, imaginary, or otherwise. Can you point to $3$ in the real world? Not to an example of $3$ (like 3 rocks) but $3$ itself?

Willard van Orman Quine had an interesting way of defining what $3$ itself is: $3 \equiv \text{ the equivalence class of all sets with cardinality } 3$. Can you use that kind of reasoning to come up with a definition of $-3$ ?

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    Lao: That definition of 3 (or any cardinal number) goes back to Bertrand Russell.2011-07-01
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Asking whether a negative number "really exists" is not really a meaningful question, to my mind. A number (of any kind) is an abstract mathematical idea, and it's not really clear how to talk about whether ideas "exist". Does justice really exist?

However, what we can say is that there are situations in the real world for which the idea of a negative number gives a useful description or model: any situation where something is removed or decreased.

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    Quantum mechanics. That's real world, but definitely not intuitively easy.2014-05-14
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Where the philosophy of negative numbers "existing" is concerned, I think Nate Eldredge answered the question very nicely. However, let me post a separate answer (really an extended comment) to address the diagram.

I think there's some confusion regarding the distinction between position and distance.

If we want to talk about position on the diagram that you've drawn, then one natural way of doing so is introducing some sort of coordinate system. Let's start by labelling "You are here" as 0. Going to the right, we can introduce 1, 2, 3,... (in whatever your favorite unit is). Going to the left, we have a couple of options:

  • We could perhaps label going to the left as 1, 2, 3,... -- but then we have to specify what side of "here" we're on: left or right. In other words, one's position on the line would have to be specified as "x units left" or "x units right."

  • An easier approach, then, might be to label the left side as -1, -2, -3....

The point is, though, that these two approaches are equivalent: Here $-x$ means "x units left."

But if we want to talk about distance -- that is, how far we are from "here," independent of our direction -- then, yes, our distance will always be positive.

Mathematically, this can be represented by taking the absolute value of the position. This makes sense since the absolute value of a number is often defined as "distance from zero," thereby forgetting about the distinction between left and right.

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    @MVCylon: If you don't know which direction is negative, how can you know which direction is positive?2013-02-08
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I think this is rather a philosophical than a mathematical question. The question whether numbers exist is almost as old as mathematics itself.

When I think about this I always have to smile and think about something like the image from René Magritte: enter image description here

It says in french "this is not a pipe". The question you ask is very simillar. Of course we encounter numbers in the nature, but are they already there or did we invent them?

Maybe this link could also be interesting:

http://queuea9.wordpress.com/category/philosophy/

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    Was a typo :-] ${}$2011-07-01
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The term 'imaginary' in mathematics is usually reserved for a technical concept involving $\sqrt{-1}$. Because it is easy to confuse with the normal everday English usage of 'existing only in the imagination', mathematician's prefer to use 'complex number' instead.

If you are wondering whether a negative number 'exists only in the imagination', then I agree it is hard to be very literal and count a negative number of apples.

But numbers have many uses (and so follow many different rules). Think of money: suppose you have 5 dollars in your hand but you owe someone 7 dollars. Then in on sense/use of numbers you really have a usable amount of -2 dollars.

The difficulty with negative numbers is that, well, the positive numbers are just so obviously represented by objects, but negative numbers are not. But really, both kinds, positive and negative, are in your imagination. You don't have 5 in your hands, you have 5 dollars in your hand and the 5 is really how your imagination will deal with the situation.

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    You said "mathematician's prefer to use 'complex number' instead". That's not right. Properly, for a mathematician, an imaginary number is a real multiple of $i$, and a complex number is a sum of a real and an imaginary one. Both terms (with their different meanings) are regularly used in the mathematical literature. In particular, it is standard to talk about the *imaginary part of a complex number*.2012-03-31
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$-1$ is an integer. It is not imaginary. It is a complex number with zero imaginary part (i.e. $-1 = -1 + 0i$).

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    maybe imagi$n$ary was the wrong term. "conceptual". I forgot Imaginary is a special math word.2011-02-01
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In your image

number line

you have a line. Suppose we want to label the point on this line for the purpose of describing things that we can measure (i.e. number of apples, temperature of sun or moon, charge on a particle, weight of a car, etc). The line is not very useful in and of itself for this purpose because it has no point of reference. The ends will not do for such a purpose as they are at infinity. We therefore define a reference point, a datum, or a landmark on the line (you call it "you are here") called zero. We then adopt conventions stating that a certain distance from that datum is one 'unit' which we call 1. We use this point as a abstract way to refer to the number of a given set of objects. It could be one apple, one car, one planet, one atom; we use the same label to refer to one unit of anything. We then define other labels (i.e. 2,3,4,...) as multiples of this unit to count. Some things that we want to label are not discrete objects, but can be divided continuously such as distance (i.e. distance from home to work is 13.77 miles). Here we are assuming that we are always on the same side of our datum '0'. There are other quantities that we measure and wish to label that can be increased arbitrarily but also decreased arbitrarily such as electric charge, a force, a moment, a voltage, a DC current, etc. In these cases, we not only want to signify how far we are from our datum, but we also want to know which side of the datum we are on. We use negative numbers to signify that our quantity is the same in magnitude but opposite in direction of what we decide to call positive (an arbitrary choice by the way).

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Think about it. Does a positive number really exist?

Just like negative numbers, complex numbers, positive numbers have a status that is no different. And you can ask the same question for other mathematical objects, sets, groups, etc. (And depending on what you mean by "exist").

Think about complex numbers. At first glance, they look like non-sense. I mean how can $\sqrt{-1}$ exist? But when I read complex analysis, I realized what a beauty I was missing. My heart was more than ever, ready to accept the existence of complex numbers. "It gave us a new way to model this world", and "new way to derive meaning from complexity and confusion", and thats what most mathematical objects do in the end, even though they may take abstraction to the highest level.

If you look at it more closely, the problem is not with "numbers", the problem is with the word "exist". My answer to your doubt will be "Cogito ergo sum" (I think therefore I am).

Peace :)

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I don't pretend to know the answer, but a lot of smart people (e.g. Gödel) think the question is meaningful and even have positions on the matter. See

http://en.wikipedia.org/wiki/Philosophy_of_mathematics#Contemporary_schools_of_thought

Incidentally, I think most philosophers (and mathematicians for that matter) would distinguish numbers from their application to physical concepts of magnitude, direction, distance, quantity, etc. So just because you find the application of a particular number system (like integers) to a particular physical concept (like directed distance) unnatural, that doesn't directly bear on the existence question. It could be that your mathematical model is a poor fit for the physical phenomenon. In the particular example you give, however, the integers are a proven good fit, as they wrap magnitude and direction into a single number. The magnitude is always positive, yes, but the number is the combination of the magnitude and the sign.