• Semi-Hemi-Lemmygod
    link
    fedilink
    English
    725 months ago

    If pi is truly infinite, then it contains all the works of Shakespeare, every version of Windows, and this comment I’m typing right now.

    • @driving_crooner@lemmy.eco.br
      link
      fedilink
      865 months ago

      That’s not how it’s works. Being “infinite” is not enough, the number 1.110100100010000… is “infinite”, without repeating patterns and dosen’t have other digits that 1 or 0.

      • HatchetHaro
        link
        fedilink
        37
        edit-2
        5 months ago

        to be fair, though, 1 and 0 are just binary representations of values, same as decimal and hexadecimal. within your example, we’d absolutely find the entire works of shakespeare encoded in ascii, unicode, and lcd pixel format with each letter arranged in 3x5 grids.

          • @leverage@lemdro.id
            link
            fedilink
            English
            75 months ago

            You can encode base 2 as base 10, I don’t think anyone is saying it exists in binary form.

            • Turun
              link
              fedilink
              155 months ago

              No, because you can’t mathematically guarantee that pi contains long strings of predetermined patterns.

              The 1.101001000100001… example by the other user was just that - an example. Their number is infinite, but never contains a 2. Pi is also infinite, but does it contain the number e to 100 digits of precision? Maybe. Maybe not. The point is, we don’t know and we can’t prove it either way (except finding it by accident).

        • @CanadaPlus
          link
          7
          edit-2
          5 months ago

          Actually, there’d only be single pixels past digit 225 in the last example, if I understand you correctly.

          If we can choose encoding, we can “cheat” by effectively embedding whatever we want to find in the encoding. The existence of every substring in a one of a set of ordinary encodings might not even be a weaker property than a fixed encoding, though, because infinities can be like that.

      • Fubber Nuckin'
        link
        fedilink
        95 months ago

        If it’s infinite without repeating patterns then it just contain all patterns, no? Eh i guess that’s not how that works, is it? Half of all patterns is still infinity.

          • @Ultraviolet@lemmy.world
            link
            fedilink
            English
            95 months ago

            However, as the name implies, this is nothing special about pi. Almost all numbers have this property. If anything, it’s the integers that we should be finding weird, like you mean to tell me that every single digit after the decimal point is a zero? No matter how far you go, just zeroes forever?

          • kn0wmad1c
            link
            fedilink
            English
            25 months ago

            Yeah, but your number doesn’t fit pi. It may not have a pattern, but it’s predictable and deterministic.

            • @OhNoMoreLemmy@lemmy.ml
              link
              fedilink
              95 months ago

              Pi is predictable and deterministic.

              Computer programs exist that can tell you what the next digit is. That means it’s deterministic, and running the program will give you a prediction for each digit (within the memory constraints of your computer).

              The fact that it’s deterministic is exactly why pi is interesting. If it was random it would typically be much easier to prove properties about it’s digits.

              • kn0wmad1c
                link
                fedilink
                English
                -2
                edit-2
                5 months ago

                There’s no way to predict what the next unsolved pi digit will be just by looking at what came before it. It’s neither predictable nor deterministic. The very existence of calculations to get the next digit supports that.

                Note: I’m not saying Pi is random. Again, the calculations support the general non-randomness of it. It is possible to be unpredictable, undeterministic, and completely logical.

                Note Note: I don’t know everything. For all I know, we’re in a simulation and we’ll eventually hit the floating point limit of pi and underflow the universe. I just wanted to point out that your example doesn’t quite fit with pi.

                • Tlaloc_Temporal
                  link
                  fedilink
                  65 months ago

                  π isn’t deterministic? How do you figure that? If two people calculate π they get different answers?

                  What π is, is fully determined by it’s definition and the geometry of a circle.

                  Also, unpredictable? Difficult to predict, sure. Unpredictable by simple methods, sure. But fully impossible to predict at all?

                  • kn0wmad1c
                    link
                    fedilink
                    English
                    -15 months ago

                    As I said, you can’t predict the next number simply based upon the set of numbers that came before. You have to calculate it, and that calculation can be so complex that it takes insane amounts of energy to do it.

                    Also, I think I was thinking of the philisophical definition of “deterministic” when I was using it earlier. That doesn’t really apply to pi… unless we really do live in a simulation.

        • @driving_crooner@lemmy.eco.br
          link
          fedilink
          85 months ago

          Not, the example I gave have infinite decimals who doesn’t repeat and don’t contain any patterns.

          What people think about when said that pi contain all patters, is in normal numbers. Pi is believed to be normal, but haven’t been proven yet.

          An easy example of a number who contains “all patterns” is 0.12345678910111213…

        • Kogasa
          link
          fedilink
          215 months ago

          Still not enough, or at least pi is not known to have this property. You need the number to be “normal” (or a slightly weaker property) which turns out to be hard to prove about most numbers.

            • Ephera
              link
              fedilink
              125 months ago

              > natural numbers
              > rational numbers
              > real numbers
              > regular numbers
              > normal numbers
              > simply normal numbers
              > absolutely normal numbers

              Have mathematicians considered talking about what numbers they find okay, rather than everyone just picking their favorite and saying that one’s the ordinary one?

              • @CanadaPlus
                link
                3
                edit-2
                5 months ago

                I mean, unironically yes. It seems the most popular stance is that all math regardless of how weird is Platonically real, although that causes some real bad problems when put down rigorously. Personally I’m more of an Aristotelian.

                In the case of things like rational or real numbers, they have a counterpart that’s weirder (irrational and imaginary numbers). For the rest I’m not sure, but it’s pretty common to just pick an adjective for a new concept. There’s even situations where the same term gets used more than once in different subfields, and then they collide so you have to add another one to clarify.

                For example, one open interval in the context of a small set of open intervals isn’t closed analytically under limits, or algebraically closed, but is topologically closed (and also topologically open, as the name suggests).

            • @barsquid@lemmy.world
              link
              fedilink
              35 months ago

              “Nearly all real numbers are normal (basically no real numbers are not normal), but we’re only aware of a few. This one literally non-computable one for sure. Maybe sqrt(2).”

              Gotta love it.

              • @CanadaPlus
                link
                5
                edit-2
                5 months ago

                We’re so used to dealing with real numbers it’s easy to forget they’re terrible. These puppies are a particularly egregious example I like to point to - functions that preserve addition but literally black out the entire x-y plane when plotted. On rational numbers all additive functions are automatically linear, of the form mx+n. There’s no nice in-between on the reals, either; it’s the “curve” from hell or a line.

                Hot take, but I really hope physics will turn out to work without them.

          • @Archpawn@lemmy.world
            link
            fedilink
            15 months ago

            Simply containing each number sequence is a significantly weaker property than having them all occur at the right frequency. Still, while nobody has proven it, it’s generally expected to be true.

      • @pivot_root@lemmy.world
        link
        fedilink
        55 months ago

        In some encoding scheme, those digits can represent something other than binary digits. If we consider your string of digits to truly be infinite, some substring somewhere will be meaningful.

        • Semi-Hemi-Lemmygod
          link
          fedilink
          English
          15 months ago

          One of the many things I loved about Sagan’s Contact is that, at the end, they found a pattern in pi when put into base 13. He didn’t really go into it as it was the end of the book, but I really wish he’d survived to write a sequel.

    • @Naz@sh.itjust.works
      link
      fedilink
      75 months ago

      shaves the sphere down with a sculptor’s knife

      There. 3.1416. Not perfectly round but it’ll bake in the oven just fine.