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My physics teacher told me recently that -10 is less than -100.

The way I look at it is in 2 ways:

  1. Having minus £100 would mean you have less money that if you had -£10.
  2. If you are presented with a number spectrum ranging from -100 to 100, it is clear that -100 is lowest down the spectrum and therefore lower/less that -10.

So is there any valid explanation as to why is -10 less than -100?

  • 7
    Both your examples (and some of the answers below) show that -100 is *less than* -10. This is true, as you can easily check using the definition of *less than*. The terms *less than* and *greater than* are very standard; everyone should use them in the same way. I consider a statement like "-10 is smaller than -100" to be more ambiguous and informal. For example, if we set up a coordinate system and use it to describe forces of -10 and -100, then the force of -10 *is* the smaller force. You should use the context to determine if "smaller than" means "less than" or "smaller in magnitude."2012-10-09
  • 0
    Yes, I should really have mentioned that in this case it is smaller in magnitude, as he was talking about the current through the circuit.2012-10-09
  • 1
    My friend just said, "I think -10 is less that -100 because it's closer to 0 and 0 is as low as possible" - any counter arguments? can't think of one.2012-10-09
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    "Zero is not as low as possible"2012-10-09
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    @OllyPrice Doesn't current involve inverses in some equations? So, `1/-10` would indeed be less than `1/-100`, and he could have been talking about the terms rather than the numbers?2012-10-09
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    I'm not entirely sure, I'm not doing high level physics, only AS at the moment.2012-10-09
  • 0
    "-10" has one less character than "-100". In this respect, -10 is the smaller of the two.2012-10-09
  • 3
    Send your physics teacher here.2012-10-10

6 Answers 6

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Your teacher is wrong or you misheard him/her. $x < y$ means $x$ is to the left of $y$ on the number line, when $x$ and $y$ are real numbers. Since $-100$ is to the left of $-10$, $-100 < -10$.

If you want to talk about magnitude, then you're comparing absolute values, i.e., the distance from $0$. In that case, we're comparing $|-100| = 100$ and $|-10| = 10$. And, $10 < 100$ so $|-10| < |-100|$. But, if that is what you are talking about, you would need to mention something about magnitude or distance from $0$.

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    He was talking about magnitude as it was when doing an experiment involving the current of an electrical circuit - therefore he is correct2012-10-09
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    @OllyPrice Yes, so he was correct and you heard him correctly but there was a slight misunderstanding as to what exactly he was referring to?2012-10-09
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    @Graphth I could of course be wrong, but I believe the OP is just nitpicking. He/she clearly understands magnitude and is in a class where they are taught about currents. They knew what the teacher was saying. I think.2012-10-09
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    ah sorry, wasn't clear2012-10-09
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    @AK4749 No problem!2012-10-09
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    Actually, I wouldn't have thought about magnitude before today, I've only just started AS Level.2012-10-09
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    It's correct to say -10 is *smaller* or *of lesser magnitude* than -100, but "less" by itself doesn't mean smaller in magnitude. What words exactly did your teacher use?2012-10-10
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I think your physics teacher is mistaken. -100 is unquestionably less than -10, because $-100 < -10$. If you owe \$100 you have less money than someone who owes only \$10.

However, -100 is bigger than -10, because if you owe \$100 you owe a bigger amount than someone who owes only \$10.

Addendum: Some commenters have claimed that "-100 is unquestionably less than -10, because $-100 < -10$" is tautological. It is not. The first clause concerns the meaning of the English-language phrase "less than", which is what the original question was asking about. The second clause concerns the formal mathematical statement that $-100 < -10$. I am asserting that the phrase "less than" is normally understood to mean the mathematical relation denoted by "$<$". The conventional reading of "$<$" as "less than" or "is less than" supports this claim. In contrast, in the following paragraph I am claiming that the meaning of the English-language phrase "is bigger than" (and implicitly, "is smaller than") is not modeled by the mathematical $<$ relation. (More precisely, it is modeled by $<$ only for non-negative quantities.)

These claims might be false, or poorly supported by evidence, but they are not tautological. I hope this clears things up.

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    Huh? I've never in my life seen this usage of *bigger* before. Does *bigger* mean "larger as an absolute value" for you? Where is that definition taught?2012-10-09
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    "-100 is unquestionably less than -10, because $-100 < -10$" This is a tautology..2012-10-09
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    Similarly: "one plus one is two, because $1 + 1 = 2$"2012-10-09
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    “-100 is … less than -10, because $-100 < -10$” – what is this sentence supposed to mean? This is just “x because x”.2012-10-09
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    I owe my Dad \$100 but I still have more money than my son who owes me \$10.2012-10-09
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    *Bigger* is a vague term to which you can give a local definition in your discussion, lecture, paper or book. -100 is certainly more "magnitudinous" than -10, and so if you define "bigger" as "more magnitudinous" then it is bigger.2012-10-10
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It isn't, plain and simple. -100 is less than -10, i.e. -10 is larger than -100. Generally, $x$ is less than $y$ ($x < y$) if $x-y$ is negative.

Since $(-100) - (-10) = -100 + 10 = -90$ is negative, $-100$ is less than $-10$.

Your physics teacher was wrong, or he defined a non-standard less-than operation on the integers first. If you define your own meaning of less-than, you can obviously make it behave arbitrarily. Whether or not such a definition has any value is a different question, though.

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    And if you apply $x$ to -10 and $y$ to -100?2012-10-09
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    Then you're asking if $-10$ is less than $-100$. Since $(-10) - (-100) = -10 + 100 = 90$, the answer is *no*. Note that if you swap the values of $x$ and $y$ in $x-y$, the sign of the result changes. Thus you always have exactly *one* of $x < y$ or $y < x$, never neither and never both, since exactly *one* of the differences will have a negative sign.2012-10-09
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By definition we say that a number $x$ is less than a number $y$ if the number $y - x$ is positive. So with $x = -100$ and $y= -10$ we have that $y - x = 90 > 0$, so by definition $-100$ is less than $-10$.

I am guessing that your teacher had different definition. You might want to ask a physics.stackexchange.com about whether such a definition would exist for some physics problem.

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    It would seem that Graphth's answer is somewhat related to what my teacher was thinking about when he said it (absolute values).2012-10-09
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    @OllyPrice: That might be what your teacher was talking about. So, yes I guess that you could define $x < y$ if and only if $\lvert x\lvert < \lvert y \lvert$. But then again, on the real line you would have $-10 = 10$.... which would be (IMO) a bit of a mathematical headache.2012-10-09
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There is an easier way to see this (not using inequality). We say that $x$ is less than $y$ if there is a positive number $z$ such that $y=x+z$ (in fact this is the definition of $x < y$ for real numbers).

In this case you can say $-100$ is less than $-10$ because there is a positive number $z$ such that $-10=-100+z$, of course $z = 90$.

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As far as physics is concerned, it is a matter of context. Sometimes, negative numbers are just part of a scale, as I am sure that your teacher would agree that -100°C is less than -10°C and sometimes, negative numbers are a way of indicating directions, a negative current is actually just a positive current in another direction. The problem disappears if you leave the 1-dimensional world and note that the first kind of quantities are scalar and the second kind of quantities are vectors. One can employ a more precise language than your teacher, but there is no ambiguity in context. It is not useful to insist on unnecessarily formal terminology.