Is 1 = 0.999... ? Really?

That is all I meant. So if 0.333… represents the 3s being at infinity then you agree that 0.333… = 1/3.

Semantic = meaning
Infinite = that which has no beginning and no end
Infinity = that which no greater quantity can be conceived of

If I ask the question what is the answer to a third of 21 exactly, the answer I would get is 7. Not 21/3. Perhaps someone might say you will find the answer when you divide 70 by 10, but they are still saying you will find the answer after you do this division.

To convey what I’m trying to convey more clearly, if I ask the question what is a third of a 1 meter ruler, I would not get the answer, well that’s just a third of a one meter ruler. I would either get the answer you cannot have a third of a meter, or it’s .333…m or 33.333…cm

Are you asking the same question that I just answered?

I’ve already stated multiple times that 1/3=0.333… exactly.

But that doesn’t mean that you can’t divide the meter. It only means that you cannot say it using decimal digits.

Bend that meter into a circle an cut it at exactly 120 degrees and you have your 1/3 meter. Ask someone how long those portions are in centimeters and they cannot give you an exact number.

I think I already did. (10^{\infty}) stands for “10 multiplied by itself infinitely”. Every term in that sentence (such as 10, multiplication and infinity) has an established definition. My claim is that all you have to do is use the established rules and deduce the meaning of the expression (in the same way one can deduce the meaning of “2 + 2” without having to look for an answer from mathematicians, books and online encyclopedias.) If you want a longer description, here is one: the statement tells you to calculate the result of (10 \times 10) and then take that result and multiply it by (10) to get a new result and then take that result and multiply it by (10) to get a new result and so on for an infinite number of times. What you get after you’re done multiplying all the (10)s is what the expression stands for. What exactly is unclear and/or unconventional about that? How can I help you if you are not willing to explain what’s unclear and/or unconventional? Merely repeating yourself by saying “It’s undefined”, “You haven’t defined it!” and “Define it!” will get you nowhere. A better approach would be to explain what it means for something to be undefined, and if it proves to be necessary, to present an argument that my expression is undefined.

  • That is ambiguous - not “well-defined”. There might be many values that fit into those categories.

Perhaps you should start by defining what the word “ambiguous” means.

When we say that what someone is saying is ambiguous, we are merely saying that we cannot determine exactly what that person is talking about (“He might be talking about X, but also, he might be talking about Y”.)

Wikipedia seems to be unambiguous about the meaning of the word “infinity”. It tells us right at the start that the word means “something that is larger than any real or natural number”. What exactly is ambiguous about that?

The fact that the word “infinity” can be used to represent more than one number does not mean that it is ambiguous. It merely means that it is not a specific number but a category of numbers (similar to the word “integer”.)

And even if “infinity” is an ambiguous term, what makes you think that logic can’t handle ambiguity? Of course, ambiguous terms have limited use but that’s a different subject.

In maths that is exactly what ambiguous means - not specific enough to use.

2 * integer = ?
integer / 8 = ?
(10^{integer} = ?)

The word “integer” cannot be used - as an integer - because it is mathematically ambiguous - it is a category of values, not a specific value. And “infinity” is equally a category of values - not a specific value.

(10^{\infty} = ?)

If you want to use maths and be specific just use (infA) instead -
(10^{infA} = 10^{Natural Number Count} = 10^1x10^2x10^3x…)

  • which is not a natural number itself.

What makes you think that I cannot use categories of numbers?

What makes you think that (b) in (a^b) cannot be a category of numbers?

You think that exponentiation is limited to specific numbers? (Sort of like how wtf thinks it is limited to real numbers?)

The only definition I could find for the ellipsis “…” is in Wikipedia -

I have never seen “…” being used to mean anything other than “continue indexed throughout the natural numbers”. So without a formal definition in our debate I would have stated -
Ellipsis - “…” = “repeated throughout the natural numbers with index starting at either the first digit to the right of the decimal (when a decimal is to its left) or repeated throughout the natural numbers with index starting at the first left hand digit indicated at the left of the symbol.”

From there, most of our argumentation would never have occurred - although perhaps you want to debate a “better” definition - but that is a different debate.

Where .333… is meaningful, it is hypothetically possible to divide the meter into 3 equal parts. But the equality of those parts must be expressed by saying that each part is .333…m long. .333…m long is either meaningful (therefore it has an exact meaning, which means it can serve as an exact answer), or it is not meaningful (which means we cannot divide the meter into three meaningfully equal parts). It would be like saying:

A: I’ve just divided x into 3 equal parts.
B: How big is each part
A: Unknown in terms of exact size
B: How do you meaningfully know they are exactly equal?

or

A: I’ve just divided x into 3 equal parts.
B: How big is each part
A: It is exactly 1/3 of the whole of x
B: How big is 1/3 of the whole of x
A: I can’t give an exact answer to this
B: Does an exact answer actually exist but you just don’t know it, or is it the case that no exact answer exists?
A: No exact answer exists
B: You are saying 1/3 of x is meaningful, yet you are also saying that there is no objective truth regarding what 1/3 of x actually amounts to in terms of size/measure. How can one of those three pieces of x not have a measurable value? If it has a size, it has a measurable value.

I don’t think that is true.

It is meaningful to say that 1/3=0.333…

But that does not mean that 0.333… is truly an exact match to 1/3.

What 0.333… represents exactly is a number that is within an infinitesimal of being 1/3 - and that is a useful meaning.

But you have not mathematically demonstrated the existence of this infinitesimal, while others have mathematically demonstrated the lack of an infinitesimal.

That is not true.

No matter how many 3s are implied by the ellipsis, the expression is never equal to (\frac{1}{3}). In other words, even with a (3) located at the position with an index of (-infA) (or any other negative infinity), the number would still be less than (\frac{1}{3}).

The larger the number of (3)s, the closer the number is to (\frac{1}{3}). But it can never be exactly (\frac{1}{3}).

That is basically contradicted by all the mathematical results shown in this thread.

Sure, you can say that but at the same time you are saying that the sum of a converging geometric series is wrong. (For example)

Which result do you prefer to retain?

I prefer not to throw away the work on geometric series.

Do you think that you can Resolution Debate that proposal?

No problem. But let’s not start a new debate until we review and summarize our first debate. Also, I’d want to make certain things clear in advance. (And I won’t be available until the weekend or so.)

But I’m surprised you disagree. What’s your position on the issue?

I think you’re presenting a false dichotomy. You either accept that (0.33\dot3 < \frac{1}{3}) and throw away the work on geometric series or you reject that (0.33\dot3 < \frac{1}{3}) and keep the work on geometric series. In reality, you can accept that the two numbers aren’t equal AND keep the existing work by making an adjustment to it.

What they have shown is that the limit of (0.3 + 0.03 + 0.003 + \cdots) is (\frac{1}{3}). I don’t dispute that. But then they erroneously conclude that (0.33\dot3 = \frac{1}{3}). It’s like someone correctly showing that the ceiling of (1 + 5 \div 10) is (2) but then erroneously concluding that (1 + 5 \div 10 = 1).

But that is the DEFINITION of the sum of the infinite series.

It’s not an erroneous equating. It’s a definition.