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I created this page in response to I saw and the confusion that arose. Figured it was something worth noting. --] 18:58, 6 May 2005 (UTC)
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== Yet another anon ==
: I think you are right. I submitted it first for deletion because the title looked a bit misleading. This is not a series of nines, the series is if you wish of
''Moved to ] subpage''
:<math>\frac{9}{10^n}</math>
Cheers, ] 19:01, 6 May 2005 (UTC)


== Intuitive explanation ==
True, the title was a little slap-dash. Thanks for the improvement. --] 19:03, 6 May 2005 (UTC)


There seems to be an error in the intuitive explanation:
==Abra-cadabra==
For any number x that is less than 1, the sequence 0.9, 0.99, 0.999, and so on will eventually reach a number larger than x⁠⁠.
If we set x = 0.̅9 then the sequence will never reach a number ''larger'' than x. ] (]) 12:16, 4 October 2024 (UTC)
:If x = 0.̅9 then x is not less than 1, so the conditional statement is true. What is the error? ] (]) 12:50, 4 October 2024 (UTC)
::If you presuppose that 0.̅9 is less than one, the argument that should prove you wrong may apprear to be sort of circular. Would it be better to say "to the left of 1 on the number line" instead of "less than 1"? I know it's the same, but then the person believing 0.̅9 to be less than one would have to place it on the number line! ] (]) 14:47, 4 October 2024 (UTC)
:What does the notation 0.̅9 mean? ] (]) 15:43, 4 October 2024 (UTC)


::It means zero followed by the decimal point, followed by an infinite sequence of 9s. ] (]) 00:24, 5 October 2024 (UTC)
"In mathematics, one could easily fall in the trap of thinking that while 0.999... is certainly close to 1, nevertheless the two are not equal. Here's a proof that they actually are."
:::Thanks! Seems a bit odd that this is curious combination of characters (which I don't know how to type) is not listed in the article on 0.999... ] (]) 01:47, 5 October 2024 (UTC)


== B and C ==
0,999... is ''irrational'' and so is the article. Basis on "the proof" that 0.9999...=1 one could argue that ''irrational'' is '''rational''' which is simply jargon.


@]. There are other unsourced facts in the given sections. For example:
* There is no source mentions about "Every element of 0.999... is less than 1, so it is an element of the real number 1. Conversely, all elements of 1 are rational numbers that can be written as..." in Dedekind cuts.
* There is no source mentions about "Continuing this process yields an infinite sequence of ], labeled by an infinite sequence of digits ⁠{{math|1=''b''<sub>1</sub>, ''b''<sub>2</sub>⁠⁠, ''b''<sub>3</sub>, ...}}, and one writes..." in Nested intervals and least upper bounds. This is just one of them.
] (]) 11:00, 30 October 2024 (UTC)


: The section on Dedekind cuts is sourced to Richman throughout. The paragraph on nested intervals has three different sources attached to it. ] (]) 11:35, 30 October 2024 (UTC)
: How about <math>\frac{999\ldots}{1000\ldots}</math>? Might want to take a look at ]. --] 20:16, 6 May 2005 (UTC)
::Are you saying that citations in the latter paragraph supports the previous paragraphs? If that's the case, I prefer to attach the same citations into those previous ones. ] (]) 12:52, 30 October 2024 (UTC)
:::Not sure what you mean. Both paragraphs have citations. ] (]) 13:09, 30 October 2024 (UTC)


== Intuitive counterproof ==
If 0.999... is 1 then the whole basis of mathematics should be re-written. Mathematics is considered to be exact science. If 0.999... was EXACT 1 then it would not make ''any difference'' to say exempli gratia (for example) that domain is same than [0,1[ or 0.000...0001 is 0 which is the basis of differential calculus. One should not confuse the concept of irrationality with the concept rationality, or infinity with finity, or inexact with exact.


The logic in the so-called intuitive proofs (rather: naïve arguments) relies on extending known properties and algorithms for finite decimals to infinite decimals, without formal definitions or formal proof. Along the same lines:
: Could you please prove your statement? This page has a proof as to why 0.999~ = 1. Please provide your counter-proof. --] 20:38, 6 May 2005 (UTC)
* 0.9 < 1
* 0.99 < 1
* 0.999 < 1
* ...
* hence 0.999... < 1.
I think this fallacious intuitive argument is at the core of students' misgivings about 0.999... = 1, and I think this should be in the article - but that's just me ... I know I'd need a source. I have not perused the literature, but isn't there a good source saying something like this anywhere? ] (]) 08:50, 29 November 2024 (UTC)


== Greater than or equal to ==
1/3 is often writen as 0.333... If you multiply 1/3 (or in your case referred as 0.333...) by 3 you get exact 1. It's not proofing. Is's abracadabra id est (that is) mumbo jumbo in ''magic'' industry. If you
geometrically plot function Y=1/X where X= (instead of domain ]0,1]) what value do you get for Y when X=0 or how do you present it?


I inserted "or equal to" in the lead, thus:
"~=" is different than "=" (equality)
:In ], '''0.999...''' (also written as '''0.{{overline|9}}''', '''0.{{overset|.|9}}''', or '''0.(9)''') denotes the smallest number greater than '''''or equal to''''' every ] in the sequence {{nowrap|(0.9, 0.99, 0.999, ...)}}. It can be proved that this number is{{spaces}}]; that is,

:: <math>0.999... = 1.</math>
:: What's your point? The number 0.9999... is not in ] 21:05, 6 May 2005 (UTC)
(I did ''not'' emphasize the words as shown here.)

But it was reverted by ]. Let me argue why I think it was an improvement, while both versions are correct.
"What's your point? The number 0.9999... is not in [0, 1[. Oleg Alexandrov 21:05, 6 May 2005 (UTC)"
First, "my" version it s correct because it is true: 1 is greater than or equal to every number in the sequence, and any number less than 1 is not. Secondly, if a reader has the misconception that 0.999... is slightly less than 1, they may oppose the idea that the value must be strictly greater than alle numbers in the sequence - and they would be right in opposing that, if not in ''this'' case, then in other cases. E.g., 0.9000... is ''not'' greater than every number in the corresponding sequence, 0.9, 0.90, 0.900, ...; it is in fact equal to all of them. ] (]) 12:07, 29 November 2024 (UTC)

:I think it's confusing because 1 doesn't belong to the sequence, so "or equal" are unnecessary extra words. A reader might wonder why those extra words are there at all, and the lead doesnt seem like the place to flesh this out. ] (]) 13:40, 29 November 2024 (UTC)
:Well, 0.999... is not the zero, it's the other bound i.e. number of the domain/range [0,1[. It think you can guess which one of the bounds it is.
::Certainly, both fomulations are correct. This sentence is here for recalling the definition of the notation in this specific case, and must be kept as simple as possible. Therefore, I agree with Tito. The only case for which this definition of ellipsis notation is incorrect is when the ellipsis replaces an infinite sequence of zeros, that is when the notation is useful only for emphasizing that finite decimals are a special case of infinite decimals. Otherwise, notation 0.100... is very rarely used. For people for which this notation of finite decimals has been taught, one could add a footnote such as 'For taking into account the case of an infinity of trailing zeros, one replaces often "greater" with "greater or equal"; the two definitions of the notation are equivalent in all other cases'. I am not sure that this is really needed. ] (]) 14:46, 29 November 2024 (UTC)

:::Could you point to where the values of decimals are defined in this way - in wikipedia, or a good source? I can eassily find definitions in terms of limits, but not so easily with inequality signs (strict or not).
: 0,999... approaches its limit 1 BUT not equals 1. (anon forgot to sign)
:::I think the version with strict inequality signs is weaker in terms of stating the case clearly for a skeptic. ] (]) 17:45, 30 November 2024 (UTC)

:::Agree that both versions are correct. My inclination from years of mathematical training is to use the simplest, most succinct statement rather than a more complicated one that adds nothing. So, I'm with Tito and D. here. ] (]) 18:24, 30 November 2024 (UTC)
:: Well, that's the very purpose of this article, to convince you that 0.999.. equals 1. You either show that this theorem is wrong, or believe it. :) ] 21:39, 6 May 2005 (UTC)
::::I think many mathematicians feel that "greater than or equal to" is the primitive notion and "strictly greater than" is the derived notion, notwithstanding that the former has more words. Therefore it's not at all clear that the "greater than" version is "simpler". --] (]) 03:13, 1 December 2024 (UTC)

:::The general case is "greater than or equal to", and I would support phrasing it that way. I think we don't need to explain why we say "or equal to"; just put it there without belaboring it. --] (]) 03:06, 1 December 2024 (UTC)
::: To be convinced that 0.999~ doesn't equal 1, you'd have to give me a proof. Any of the following methods are not acceptable:

Latest revision as of 03:13, 1 December 2024

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Q: Are you positive that 0.999... equals 1 exactly, not approximately?
A: In the set of real numbers, yes. This is covered in the article. If you still have doubts, you can discuss it at Talk:0.999.../Arguments. However, please note that original research should never be added to a Misplaced Pages article, and original arguments and research in the talk pages will not change the content of the article—only reputable secondary and tertiary sources can do so.


Q: Can't "1 - 0.999..." be expressed as "0.000...1"?
A: No. The string "0.000...1" is not a meaningful real decimal because, although a decimal representation of a real number has a potentially infinite number of decimal places, each of the decimal places is a finite distance from the decimal point; the meaning of digit d being k places past the decimal point is that the digit contributes d · 10 toward the value of the number represented. It may help to ask yourself how many places past the decimal point the "1" is. It cannot be an infinite number of real decimal places, because all real places must be finite. Also ask yourself what the value of 0.000 1 10 {\displaystyle {\frac {0.000\dots 1}{10}}} would be. Those proposing this argument generally believe the answer to be 0.000...1, but, basic algebra shows that, if a real number divided by 10 is itself, then that number must be 0.


Q: The highest number in 0.999... is 0.999...9, with a last '9' after an infinite number of 9s, so isn't it smaller than 1?
A: If you have a number like 0.999...9, it is not the last number in the sequence (0.9, 0.99, ...); you can always create 0.999...99, which is a higher number. The limit 0.999 = lim n 0. 99 9 n {\displaystyle 0.999\ldots =\lim _{n\to \infty }0.\underbrace {99\ldots 9} _{n}} is not defined as the highest number in the sequence, but as the smallest number that is higher than any number in the sequence. In the reals, that smallest number is the number 1.


Q: 0.9 < 1, 0.99 < 1, and so forth. Therefore it's obvious that 0.999... < 1.
A: No. By this logic, 0.9 < 0.999...; 0.99 < 0.999... and so forth. Therefore 0.999... < 0.999..., which is absurd.
Something that holds for various values need not hold for the limit of those values. For example, f (x)=x/x is positive (>0) for all values in its implied domain (x ≠ 0). However, the limit as x goes to 0 is 0, which is not positive. This is an important consideration in proving inequalities based on limits. Moreover, although you may have been taught that 0. x 1 x 2 x 3 . . . {\displaystyle 0.x_{1}x_{2}x_{3}...} must be less than 1. y 1 y 2 y 3 . . . {\displaystyle 1.y_{1}y_{2}y_{3}...} for any values, this is not an axiom of decimal representation, but rather a property for terminating decimals that can be derived from the definition of decimals and the axioms of the real numbers. Systems of numbers have axioms; representations of numbers do not. To emphasize: Decimal representation, being only a representation, has no associated axioms or other special significance over any other numerical representation.


Q: 0.999... is written differently from 1, so it can't be equal.
A: 1 can be written many ways: 1/1, 2/2, cos 0, ln e, i, 2 - 1, 1e0, 12, and so forth. Another way of writing it is 0.999...; contrary to the intuition of many people, decimal notation is not a bijection from decimal representations to real numbers.


Q: Is it possible to create a new number system other than the reals in which 0.999... < 1, the difference being an infinitesimal amount?
A: Yes, although such systems are neither as used nor as useful as the real numbers, lacking properties such as the ability to take limits (which defines the real numbers), to divide (which defines the rational numbers, and thus applies to real numbers), or to add and subtract (which defines the integers, and thus applies to real numbers). Furthermore, we must define what we mean by "an infinitesimal amount." There is no nonzero constant infinitesimal in the real numbers; quantities generally thought of informally as "infinitesimal" include ε, which is not a fixed constant; differentials, which are not numbers at all; differential forms, which are not real numbers and have anticommutativity; 0, which is not a number, but rather part of the expression lim x 0 + f ( x ) {\displaystyle \lim _{x\rightarrow 0^{+}}f(x)} , the right limit of x (which can also be expressed without the "+" as lim x 0 f ( x ) {\displaystyle \lim _{x\downarrow 0}f(x)} ); and values in number systems such as dual numbers and hyperreals. In these systems, 0.999... = 1 still holds due to real numbers being a subfield. As detailed in the main article, there are systems for which 0.999... and 1 are distinct, systems that have both alternative means of notation and alternative properties, and systems for which subtraction no longer holds. These, however, are rarely used and possess little to no practical application.


Q: Are you sure 0.999... equals 1 in hyperreals?
A: If notation '0.999...' means anything useful in hyperreals, it still means number 1. There are several ways to define hyperreal numbers, but if we use the construction given here, the problem is that almost same sequences give different hyperreal numbers, 0. ( 9 ) < 0.9 ( 9 ) < 0.99 ( 9 ) < 0. ( 99 ) < 0.9 ( 99 ) < 0. ( 999 ) < 1 {\displaystyle 0.(9)<0.9(9)<0.99(9)<0.(99)<0.9(99)<0.(999)<1\;} , and even the '()' notation doesn't represent all hyperreals. The correct notation is (0.9; 0.99; 0,999; ...).


Q: If it is possible to construct number systems in which 0.999... is less than 1, shouldn't we be talking about those instead of focusing so much on the real numbers? Aren't people justified in believing that 0.999... is less than one when other number systems can show this explicitly?
A: At the expense of abandoning many familiar features of mathematics, it is possible to construct a system of notation in which the string of symbols "0.999..." is different than the number 1. This object would represent a different number than the topic of this article, and this notation has no use in applied mathematics. Moreover, it does not change the fact that 0.999... = 1 in the real number system. The fact that 0.999... = 1 is not a "problem" with the real number system and is not something that other number systems "fix". Absent a WP:POV desire to cling to intuitive misconceptions about real numbers, there is little incentive to use a different system.


Q: The initial proofs don't seem formal and the later proofs don't seem understandable. Are you sure you proved this? I'm an intelligent person, but this doesn't seem right.
A: Yes. The initial proofs are necessarily somewhat informal so as to be understandable by novices. The later proofs are formal, but more difficult to understand. If you haven't completed a course on real analysis, it shouldn't be surprising that you find difficulty understanding some of the proofs, and, indeed, might have some skepticism that 0.999... = 1; this isn't a sign of inferior intelligence. Hopefully the informal arguments can give you a flavor of why 0.999... = 1. If you want to formally understand 0.999..., however, you'd be best to study real analysis. If you're getting a college degree in engineering, mathematics, statistics, computer science, or a natural science, it would probably help you in the future anyway.


Q: But I still think I'm right! Shouldn't both sides of the debate be discussed in the article?
A: The criteria for inclusion in Misplaced Pages is for information to be attributable to a reliable published source, not an editor's opinion. Regardless of how confident you may be, at least one published, reliable source is needed to warrant space in the article. Until such a document is provided, including such material would violate Misplaced Pages policy. Arguments posted on the Talk:0.999.../Arguments page are disqualified, as their inclusion would violate Misplaced Pages policy on original research.
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Arguments Archives: Index, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12

Yet another anon

Moved to Arguments subpage

Intuitive explanation

There seems to be an error in the intuitive explanation:

For any number x that is less than 1, the sequence 0.9, 0.99, 0.999, and so on will eventually reach a number larger than x⁠⁠.

If we set x = 0.̅9 then the sequence will never reach a number larger than x. 2A01:799:39E:1300:F896:4392:8DAA:D475 (talk) 12:16, 4 October 2024 (UTC)

If x = 0.̅9 then x is not less than 1, so the conditional statement is true. What is the error? MartinPoulter (talk) 12:50, 4 October 2024 (UTC)
If you presuppose that 0.̅9 is less than one, the argument that should prove you wrong may apprear to be sort of circular. Would it be better to say "to the left of 1 on the number line" instead of "less than 1"? I know it's the same, but then the person believing 0.̅9 to be less than one would have to place it on the number line! (talk) 14:47, 4 October 2024 (UTC)
What does the notation 0.̅9 mean? Johnjbarton (talk) 15:43, 4 October 2024 (UTC)
It means zero followed by the decimal point, followed by an infinite sequence of 9s. Mr. Swordfish (talk) 00:24, 5 October 2024 (UTC)
Thanks! Seems a bit odd that this is curious combination of characters (which I don't know how to type) is not listed in the article on 0.999... Johnjbarton (talk) 01:47, 5 October 2024 (UTC)

B and C

@Tito Omburo. There are other unsourced facts in the given sections. For example:

  • There is no source mentions about "Every element of 0.999... is less than 1, so it is an element of the real number 1. Conversely, all elements of 1 are rational numbers that can be written as..." in Dedekind cuts.
  • There is no source mentions about "Continuing this process yields an infinite sequence of nested intervals, labeled by an infinite sequence of digits ⁠b1, b2⁠⁠, b3, ..., and one writes..." in Nested intervals and least upper bounds. This is just one of them.

Dedhert.Jr (talk) 11:00, 30 October 2024 (UTC)

The section on Dedekind cuts is sourced to Richman throughout. The paragraph on nested intervals has three different sources attached to it. Tito Omburo (talk) 11:35, 30 October 2024 (UTC)
Are you saying that citations in the latter paragraph supports the previous paragraphs? If that's the case, I prefer to attach the same citations into those previous ones. Dedhert.Jr (talk) 12:52, 30 October 2024 (UTC)
Not sure what you mean. Both paragraphs have citations. Tito Omburo (talk) 13:09, 30 October 2024 (UTC)

Intuitive counterproof

The logic in the so-called intuitive proofs (rather: naïve arguments) relies on extending known properties and algorithms for finite decimals to infinite decimals, without formal definitions or formal proof. Along the same lines:

  • 0.9 < 1
  • 0.99 < 1
  • 0.999 < 1
  • ...
  • hence 0.999... < 1.

I think this fallacious intuitive argument is at the core of students' misgivings about 0.999... = 1, and I think this should be in the article - but that's just me ... I know I'd need a source. I have not perused the literature, but isn't there a good source saying something like this anywhere? (talk) 08:50, 29 November 2024 (UTC)

Greater than or equal to

I inserted "or equal to" in the lead, thus:

In mathematics, 0.999... (also written as 0.9, 0..9, or 0.(9)) denotes the smallest number greater than or equal to every number in the sequence (0.9, 0.99, 0.999, ...). It can be proved that this number is 1; that is,
0.999... = 1. {\displaystyle 0.999...=1.}

(I did not emphasize the words as shown here.) But it was reverted by user:Tito Omburo. Let me argue why I think it was an improvement, while both versions are correct. First, "my" version it s correct because it is true: 1 is greater than or equal to every number in the sequence, and any number less than 1 is not. Secondly, if a reader has the misconception that 0.999... is slightly less than 1, they may oppose the idea that the value must be strictly greater than alle numbers in the sequence - and they would be right in opposing that, if not in this case, then in other cases. E.g., 0.9000... is not greater than every number in the corresponding sequence, 0.9, 0.90, 0.900, ...; it is in fact equal to all of them. (talk) 12:07, 29 November 2024 (UTC)

I think it's confusing because 1 doesn't belong to the sequence, so "or equal" are unnecessary extra words. A reader might wonder why those extra words are there at all, and the lead doesnt seem like the place to flesh this out. Tito Omburo (talk) 13:40, 29 November 2024 (UTC)
Certainly, both fomulations are correct. This sentence is here for recalling the definition of the notation in this specific case, and must be kept as simple as possible. Therefore, I agree with Tito. The only case for which this definition of ellipsis notation is incorrect is when the ellipsis replaces an infinite sequence of zeros, that is when the notation is useful only for emphasizing that finite decimals are a special case of infinite decimals. Otherwise, notation 0.100... is very rarely used. For people for which this notation of finite decimals has been taught, one could add a footnote such as 'For taking into account the case of an infinity of trailing zeros, one replaces often "greater" with "greater or equal"; the two definitions of the notation are equivalent in all other cases'. I am not sure that this is really needed. D.Lazard (talk) 14:46, 29 November 2024 (UTC)
Could you point to where the values of decimals are defined in this way - in wikipedia, or a good source? I can eassily find definitions in terms of limits, but not so easily with inequality signs (strict or not).
I think the version with strict inequality signs is weaker in terms of stating the case clearly for a skeptic. (talk) 17:45, 30 November 2024 (UTC)
Agree that both versions are correct. My inclination from years of mathematical training is to use the simplest, most succinct statement rather than a more complicated one that adds nothing. So, I'm with Tito and D. here. Mr. Swordfish (talk) 18:24, 30 November 2024 (UTC)
I think many mathematicians feel that "greater than or equal to" is the primitive notion and "strictly greater than" is the derived notion, notwithstanding that the former has more words. Therefore it's not at all clear that the "greater than" version is "simpler". --Trovatore (talk) 03:13, 1 December 2024 (UTC)
The general case is "greater than or equal to", and I would support phrasing it that way. I think we don't need to explain why we say "or equal to"; just put it there without belaboring it. --Trovatore (talk) 03:06, 1 December 2024 (UTC)
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