96 points
*

x=.9999…

10x=9.9999…

Subtract x from both sides

9x=9

x=1

There it is, folks.

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70 points
*

Somehow I have the feeling that this is not going to convince people who think that 0.9999… /= 1, but only make them madder.

Personally I like to point to the difference, or rather non-difference, between 0.333… and ⅓, then ask them what multiplying each by 3 is.

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1 point

The thing is 0.333… And 1/3 represent the same thing. Base 10 struggles to represent the thirds in decimal form. You get other decimal issues like this in other base formats too

(I think, if I remember correctly. Lol)

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1 point

Oh shit, don’t think I saw that before. That makes it intuitive as hell.

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0 points

Cut a banana into thirds and you lose material from cutting it hence .9999

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3 points

That’s not how fractions and math work though.

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-8 points

I’d just say that not all fractions can be broken down into a proper decimal for a whole number, just like pie never actually ends. We just stop and say it’s close enough to not be important. Need to know about a circle on your whiteboard? 3.14 is accurate enough. Need the entire observable universe measured to within a single atoms worth of accuracy? It only takes 39 digits after the 3.

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10 points

pi isn’t even a fraction. like, it’s actually an important thing that it isn’t

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4 points

The problem is, that’s exactly what the … is for. It is a little weird to our heads, granted, but it does allow the conversion. 0.33 is not the same thing as 0.333… The first is close to one third. The second one is one third. It’s how we express things as a decimal that don’t cleanly map to base ten. It may look funky, but it works.

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3 points
*

Pi isn’t a fraction (in the sense of a rational fraction, an algebraic fraction where the numerator and denominator are both polynomials, like a ratio of 2 integers) – it’s an irrational number, i.e. a number with no fractional form; as opposed to rational numbers, which are defined as being able to be expressed as a fraction. Furthermore, π is a transcendental number, meaning it’s never a solution to f(x) = 0, where f(x) is a non-zero finite-degree polynomial expression with rational coefficients. That’s like, literally part of the definition. They cannot be compared to rational numbers like fractions.

Every rational number (and therefore every fraction) can be expressed using either repeating decimals or terminating decimals. Contrastly, irrational numbers only have decimal expansions which are both non-repeating and non-terminating.

Since |r|<1 → ∑[n=1, ∞] arⁿ = ar/(1-r), and 0.999... is equivalent to that sum with a = 9 and r = 1/10 (visually, 0.999... = 9(0.1) + 9(0.01) + 9(0.001) + ...), it’s easy to see after plugging in, 0.999... = ∑[n=1, ∞] 9(1/10)ⁿ = 9(1/10) / (1 - 1/10) = 0.9/0.9 = 1). This was a proof present in Euler’s Elements of Algebra.

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1 point

There are a lot of concepts in mathematics which do not have good real world analogues.

i, the _imaginary number_for figuring out roots, as one example.

I am fairly certain you cannot actually do the mathematics to predict or approximate the size of an atom or subatomic particle without using complex algebra involving i.

It’s been a while since I watched the entire series Leonard Susskind has up on youtube explaining the basics of the actual math for quantum mechanics, but yeah I am fairly sure it involves complex numbers.

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1 point

pie never actually ends

I want to go to there.

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48 points

I was taught that if 0.9999… didn’t equal 1 there would have to be a number that exists between the two. Since there isn’t, then 0.9999…=1

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3 points

Not even a number between, but there is no distance between the two. There is no value X for 1-x = 0.9~

We can’t notate 0.0~ …01 in any way.

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23 points

Divide 1 by 3: 1÷3=0.3333…

Multiply the result by 3 reverting the operation: 0.3333… x 3 = 0.9999… or just 1

0.9999… = 1

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-9 points

You’re just rounding up an irrational number. You have a non terminating, non repeating number, that will go on forever, because it can never actually get up to its whole value.

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11 points

1/3 is a rational number, because it can be depicted by a ratio of two integers. You clearly don’t know what you’re talking about, you’re getting basic algebra level facts wrong. Maybe take a hint and read some real math instead of relying on your bad intuition.

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5 points

non repeating

it’s literally repeating

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-20 points

In this context, yes, because of the cancellation on the fractions when you recover.

1/3 x 3 = 1

I would say without the context, there is an infinitesimal difference. The approximation solution above essentially ignores the problem which is more of a functional flaw in base 10 than a real number theory issue

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24 points
*

The context doesn’t make a difference

In base 10 --> 1/3 is 0.333…

In base 12 --> 1/3 is 0.4

But they’re both the same number.

Base 10 simply is not capable of displaying it in a concise format. We could say that this is a notation issue. No notation is perfect. Base 10 has some confusing implications

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9 points

This seems to be conflating 0.333...3 with 0.333... One is infinitesimally close to 1/3, the other is a decimal representation of 1/3. Indeed, if 1-0.999... resulted in anything other than 0, that would necessarily be a number with more significant digits than 0.999... which would mean that the ... failed to be an infinite repetition.

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5 points
*

Unfortunately not an ideal proof.

It makes certain assumptions:

  1. That a number 0.999… exists and is well-defined
  2. That multiplication and subtraction for this number work as expected

Similarly, I could prove that the number which consists of infinite 9’s to the left of the decimal separator is equal to -1:

...999.0 = x
...990.0 = 10x

Calculate x - 10x:

x - 10x = ...999.0 - ...990.0
-9x = 9
x = -1

And while this is true for 10-adic numbers, it is certainly not true for the real numbers.

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1 point
*

While I agree that my proof is blunt, yours doesn’t prove that .999… is equal to -1. With your assumption, the infinite 9’s behave like they’re finite, adding the 0 to the end, and you forgot to move the decimal point in the beginning of the number when you multiplied by 10.

x=0.999…999

10x=9.999…990 assuming infinite decimals behave like finite ones.

Now x - 10x = 0.999…999 - 9.999…990

-9x = -9.000…009

x = 1.000…001

Thus, adding or subtracting the infinitesimal makes no difference, meaning it behaves like 0.

Edit: Having written all this I realised that you probably meant the infinitely large number consisting of only 9’s, but with infinity you can’t really prove anything like this. You can’t have one infinite number being 10 times larger than another. It’s like assuming division by 0 is well defined.

0a=0b, thus

a=b, meaning of course your …999 can equal -1.

Edit again: what my proof shows is that even if you assume that .000…001≠0, doing regular algebra makes it behave like 0 anyway. Your proof shows that you can’t to regular maths with infinite numbers, which wasn’t in question. Infinity exists, the infinitesimal does not.

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2 points

Yes, but similar flaws exist for your proof.

The algebraic proof that 0.999… = 1 must first prove why you can assign 0.999… to x.

My “proof” abuses algebraic notation like this - you cannot assign infinity to a variable. After that, regular algebraic rules become meaningless.

The proper proof would use the definition that the value of a limit approaching another value is exactly that value. For any epsilon > 0, 0.999… will be within the epsilon environment of 1 (= the interval 1 ± epsilon), therefore 0.999… is 1.

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2 points

The explanation I’ve seen is that … is notation for something that can be otherwise represented as sums of infinite series.

In the case of 0.999…, it can be shown to converge toward 1 with the convergence rule for geometric series.

If |r| < 1, then:

ar + ar² + ar³ + … = ar / (1 - r)

Thus:

0.999… = 9(1/10) + 9(1/10)² + 9(1/10)³ + …

= 9(1/10) / (1 - 1/10)

= (9/10) / (9/10)

= 1

Just for fun, let’s try 0.424242…

0.424242… = 42(1/100) + 42(1/100)² + 42(1/100)³

= 42(1/100) / (1 - 1/100)

= (42/100) / (99/100)

= 42/99

= 0.424242…

So there you go, nothing gained from that other than seeing that 0.999… is distinct from other known patterns of repeating numbers after the decimal point.

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The explanation I’ve seen is that … is notation for something that can be otherwise represented as sums of infinite series

The ellipsis notation generally refers to repetition of a pattern. Either ad infinitum, or up to some terminus. In this case we have a non-terminating decimal.

In the case of 0.999…, it can be shown to converge toward 1

0.999… is a real number, and not any object that can be said to converge. It is exactly 1.

So there you go, nothing gained from that other than seeing that 0.999… is distinct from other known patterns of repeating numbers after the decimal point

In what way is it distinct?
And what is a ‘repeating number’? Did you mean ‘repeating decimal’?

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1 point
*

The ellipsis notation generally refers to repetition of a pattern.

Ok. In mathematical notation/context, it is more specific, as I outlined.

This technicality is often brushed over or over simplified by math teachers and courses until or unless you take some more advanced courses.

Context matters, here’s an example:

Generally, pdf denotes the file format specific to adobe reader, while in the context of many modern online videos/discussions, it has become a colloquialism to be able to discuss (accused or confirmed) pedophiles and be able to avoid censorship or demonetization.

0.999… is a real number, and not any object that can be said to converge. It is exactly 1.

Ok. Never said 0.999… is not a real number. Yep, it is exactly 1 because solving the equation it truly represents, a geometric series, results in 1. This solution is obtained using what is called the convergence theorem or rule, as I outlined.

In what way is it distinct?

0.424242… solved via the convergence theorem simply results in itself, as represented in mathematical nomenclature.

0.999… does not again result in 0.999…, but results to 1, a notably different representation that causes the entire discussion in this thread.

And what is a ‘repeating number’? Did you mean ‘repeating decimal’?

I meant what I said: “know patterns of repeating numbers after the decimal point.”

Perhaps I should have also clarified known finite patterns to further emphasize the difference between rational and irrational numbers.

EDIT: You used a valid and even more mathematically esoteric method to demonstrate the same thing I demonstrated elsewhere in this thread, I have no idea why you are taking issue with what I’ve said.

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1 point
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-14 points

X=.5555…

10x=5.5555…

Subtract x from both sides.

9x=5

X=1 .5555 must equal 1.

There it isn’t. Because that math is bullshit.

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16 points

x = 5/9 is not 9/9. 5/9 = .55555…

You’re proving that 0.555… equals 5/9 (which it does), not that it equals 1 (which it doesn’t).

It’s absolutely not the same result as x = 0.999… as you claim.

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10 points
*

?
Where did you get 9x=5 -> x=1
and 5/9 is 0.555… so it checks out.

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7 points

Quick maffs

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3 points
*

Lol what? How did you conclude that if 9x = 5 then x = 1? Surely you didn’t pass algebra in high school, otherwise you could see that getting x from 9x = 5 requires dividing both sides by 9, which yields x = 5/9, i.e. 0.555... = 5/9 since x = 0.555....

Also, you shouldn’t just use uppercase X in place of lowercase x or vice versa. Case is usually significant for variable names.

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76 points

Okay, but it equals one.

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-28 points

No, it equals 0.999…

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76 points

2/9 = 0.222… 7/9 = 0.777…

0.222… + 0.777… = 0.999… 2/9 + 7/9 = 1

0.999… = 1

No, it equals 1.

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24 points

Similarly, 1/3 = 0.3333…
So 3 times 1/3 = 0.9999… but also 3/3 = 1

Another nice one:

Let x = 0.9999… (multiply both sides by 10)
10x = 9.99999… (substitute 0.9999… = x)
10x = 9 + x (subtract x from both sides)
9x = 9 (divide both sides by 9)
x = 1

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18 points

That’s the best explanation of this I’ve ever seen, thank you!

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-17 points

If you can’t do it without fractions or a … then it can’t be done.

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-31 points
*

Sure, when you start decoupling the numbers from their actual values. The only thing this proves is that the fraction-to-decimal conversion is inaccurate. Your floating points (and for that matter, our mathematical model) don’t have enough precision to appropriately model what the value of 7/9 actually is. The variation is negligible though, and that’s the core of this, is the variation off what it actually is is so small as to be insignificant and, really undefinable to us - but that doesn’t actually matter in practice, so we just ignore it or convert it. But at the end of the day 0.999… does not equal 1. A number which is not 1 is not equal to 1. That would be absurd. We’re just bad at converting fractions in our current mathematical understanding.

Edit: wow, this has proven HIGHLY unpopular, probably because it’s apparently incorrect. See below for about a dozen people educating me on math I’ve never heard of. The “intuitive” explanation on the Wikipedia page for this makes zero sense to me largely because I don’t understand how and why a repeating decimal can be considered a real number. But I’ll leave that to the math nerds and shut my mouth on the subject.

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10 points

THAT’S EXACTLY WHAT I SAID.

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2 points
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68 points

I thought the muscular guys were supposed to be right in these memes.

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64 points

He is right. 1 approximates 1 to any accuracy you like.

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25 points

Is it true to say that two numbers that are equal are also approximately equal?

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28 points

I recall an anecdote about a mathematician being asked to clarify precisely what he meant by “a close approximation to three”. After thinking for a moment, he replied “any real number other than three”.

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23 points

“Approximately equal” is just a superset of “equal” that also includes values “acceptably close” (using whatever definition you set for acceptable).

Unless you say something like:

a ≈ b ∧ a ≠ b

which implies a is close to b but not exactly equal to b, it’s safe to presume that a ≈ b includes the possibility that a = b.

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6 points
*

Yes, informally in the sense that the error between the two numbers is “arbitrarily small”. Sometimes in introductory real analysis courses you see an exercise like: “prove if x, y are real numbers such that x=y, then for any real epsilon > 0 we have |x - y| < epsilon.” Which is a more rigorous way to say roughly the same thing. Going back to informality, if you give any required degree of accuracy (epsilon), then the error between x and y (which are the same number), is less than your required degree of accuracy

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5 points

It depends on the convention that you use, but in my experience yes; for any equivalence relation, and any metric of “approximate” within the context of that relation, A=B implies A≈B.

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6 points

Nah. They are supposed to not care about stuff and just roll with it without any regrets.

It’s just like the wojak crying with the mask on, but not crying behind it.

There’s plenty of cases of memes where the giga chad is just plainly wrong, but they just don’t care. But it’s not supposed to be in a troll way. The giga chad applies what it believes in. If you want a troll, there’s troll face, who speak with the confidence of a giga chad, but know he is bullshiting

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44 points

0.9<overbar.> is literally equal to 1

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19 points

There’s a Real Analysis proof for it and everything.

Basically boils down to

  • If 0.(9) != 1 then there must be some value between 0.(9) and 1.
  • We know such a number cannot exist, because for any given discrete value (say 0.999…9) there is a number (0.999…99) that is between that discrete value and 0.(9)
  • Therefore, no value exists between 0.(9) and 1.
  • So 0.(9) = 1
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8 points

Even simpler: 1 = 3 * 1/3

1/3 =0.333333…

1/3 + 1/3 + 1/3 = 0.99999999… = 1

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2 points

Even simpler

0.99999999… = 1

But you’re just restating the premise here. You haven’t proven the two are equal.

1/3 =0.333333…

This step

1/3 + 1/3 + 1/3 = 0.99999999…

And this step

Aren’t well-defined. You’re relying on division short-hand rather than a real proof.

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3 points

the explanation (not proof tbf) that actually satisfies my brain is that we’re dealing with infinite repeating digits here, which is what allows something that on the surface doesn’t make sense to actually be true.

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2 points

Infinite repeating digits produce what is understood as a Limit. And Limits are fundamental to proof-based mathematics, when your goal is to demonstrate an infinite sum or series has a finite total.

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2 points

That actually makes sense, thank you.

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-4 points

0.9 is most definitely not equal to 1

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9 points

Hence the overbar. Lemmy should support LaTeX for real though

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7 points

Oh, that’s not even showing as a missing character, to me it just looks like 0.9

At least we agree 0.99… = 1

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34 points

If 0.999… < 1, then that must mean there’s an infinite amount of real numbers between 0.999… and 1. Can you name a single one of these?

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23 points

Sure 0.999…95

Just kidding, the guy on the left is correct.

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7 points

You got me

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6 points

(0.999… + 1) / 2

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4 points

That number happens to be exactly 1

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