The Surprises Never Eend: The Ulam Spiral of Primes

Jun 22 2010 Published by under goodmath, Numbers

One of the things that's endlessly fascinating to me about math and
science is the way that, no matter how much we know, we're constantly
discovering more things that we don't know. Even in simple, fundamental
areas, there's always a surprise waiting just around the corner.

A great example of this is something called the Ulam spiral,
named after Stanislaw Ulam, who first noticed it. Take a sheet of graph paper.
Put "1" in some square. Then, spiral out from there, putting one number in
each square. Then circle each of the prime numbers. Like the following:


If you do that for a while - and zoom out, so that you can't see the numbers,
but just dots for each circled number, what you'll get will look something like


That's the Ulam spiral filling a 200x200 grid. Look at how many diagonal
line segments you get! And look how many diagonal line segments occur along
the same lines! Why do the prime numbers tend to occur in clusters
along the diagonals of this spiral? I don't have a clue. Nor, to my knowledge,
does anyone else!

And it gets even a bit more surprising: you don't need to start
the spiral with one. You can start it with one hundred, or seventeen thousand. If
you draw the spiral, you'll find primes along diagonals.

Intuitions about it are almost certainly wrong. For example, when I first
thought about it, I tried to find a numerical pattern around the diagonals.
There are lots of patterns. For example, one of the simplest ones is
that an awful lot of primes occur along the set of lines
f(n) = 4n2+n+c, for a variety of values of b and c. But what does
that tell you? Alas, not much. Why do so many primes occur along
those families of lines?

You can make the effect even more prominent by making the spiral
a bit more regular. Instead of graph paper, draw an archimedean spiral - that
is, the classic circular spiral path. Each revolution around the circle, evenly
distribute the numbers up to the next perfect square. So the first spiral will have 2, 3, 4;
the next will have 5, 6, 7, 8, 9. And so on. What you'll wind up with is
called the Sack's spiral, which looks like this:

Sacks spiral.png

This has been cited by some religious folks as being a proof of the
existence of God. Personally, I think that that's silly; my personal
belief is that even a deity can't change the way the numbers work: the
nature of the numbers and how they behave in inescapable. Even a deity who
could create the universe couldn't make 4 a prime number.

Even just working with simple integers, and as simple a concept of
the prime numbers, there are still surprises waiting for us.

67 responses so far

  • BenE says:

    It'd be interesting to see these graphs with a color gradient varying with number of divisors instead of just black for two divisors (prime) and white for more than two. I wonder what kind of patterns would emerge.

  • Anonymous says:

    We did some Ulam spiral visualizations recently. Check them out at:

  • Rob T. says:

    I assume the fact that the squares all extend on two diagonals coming out from center is completely unsurprising given that squares are represented by x[n] = x[n-1] + 2n - 1 -- or also x[n] = x[n-2] + 4(n-1)
    I also did a quick check to see if it was simple pareidolia by generating a 200x200 grid with 4203 random dots in it (or rather, each of the 40000 pixels having a 4203/40000 chance of having a dot) - because according to Wolfram Alpha there are 4203 primes less than 40000 (
    But several runs provided nothing like those hard diagonal lines. It all just looked (unsurprisingly) like noise.
    At least you got me thinking...

  • Jeff Alexander says:

    Is the clustering all that surprising? The primes will need to be on diagonals because that is where you find the odd numbers. What happens when you randomly distribute a similar number of points on the odd numbers using a distribution that mimics the density of the primes (approximate π(x))?

  • Eduardo Diaz says:

    Well, the Sack's spiral looks like the Death Star, perhaps this is a proof of the existence of the Dark Side of the Force??

  • Nick Johnson says:

    The intuition that occurred to Jeff @4 also occurred to me. Do interesting patterns show up if you plot only odd numbers?

  • I've seen the Ulam spiral before and the first time I saw it the first thing I asked was whether the diagonal lines were the level you'd expect from a reasonably random model. I've never got an answer, at some point when I have free time I intend to do the obvious thing and make some spirals which have points colored in with probability 1/ log n and see how visually similar they look. If there's a real phenomenon going on here they should look different in a very obvious way.

  • Thasc says:

    I wrote a program a few days ago that made Ulam spirals, they make pretty desktop backgrounds. :3
    This is my current:

  • You could possibly also try plotting on a fibbonacci type of spiral

  • Maht Gut says:

    @nick and @jeff coloring in all odd numbers would only give you a uniform grey shading. Not a spiral.
    Don't believe me? Try it.

  • Mark C. Chu-Carroll says:

    This is a surprisingly robust process. You can try a lot of naive approaches - like shading in random numbers with the same probability distribution as the primes; or shading various odds - you'll either get an extremely strong pattern (like a uniform grey for all odd numbers, or a cross-hatch far various determinstic subsets of the odds), but this scattershot process with a high-level uniformity? It's really hard to design some kind of set that produces a pattern like this. That's part of what makes it so damned fascinating. You can create things with much more structure, and you can create things with much less structure - but finding something that's got this kind of structure to it is really surprisingly difficult.

  • Stefan Keller says:

    if you draw primes in circles an the distribution of primes is somehow related with pi, some kinds of patterns should occur, right? But you're: It's fascinating. Again and again and again. If you love mathematics, you'll never be bored;-)
    Thanx for this nice post.

  • Nick Johnson says:

    @Maht #10: I wasn't suggesting coloring all the odd numbers - I was suggesting plotting a Ulam spiral that only includes odd numbers, then coloring the primes.

  • Thasc says:

    @Nick #13 Just coded that, exhibits similar diagonal patterns to the normal Ulam spiral.

  • Rob T. says: I want to plot it on a hex grid...

  • Mark C. Chu-Carroll says:

    #14, and others:
    If you produce any interesting variants, I'd love to link to them. If you don't have a place to host the image, just email it to me, and I'll host it at SB.

  • Nick Johnson says:

    @Thasc #14 Nice! Thanks for trying it out.

  • Anonymous says:

    This has been cited by some religious folks as being a proof of the existence of God. Personally, I think that that's silly; my personal belief is that even a deity can't change the way the numbers work: the nature of the numbers and how they behave in inescapable. Even a deity who could create the universe couldn't make 4 a prime number.

    Additionally, it's not actually an argument for God's existence so much as somebody going "Oooh, something neat was discovered! Quick, attribute it to God!"

  • Peter Boothe says:

    A month back I made a big PDF of the Ulam spiral that one can download at
    It prints out quite nicely on a 24" roll-fed printer.

  • Shanquanzekye says:

    Did you try only having random odd numbers generated (dots in a checkerboard pattern)?
    Also, there's a typo in the title.

  • SoloGen says:

    I am wondering how it would be extended to higher dimensions. Instead of following a curves, we may define a way to fill a surface.

  • Cairnarvon says:

    It's actually the Sacks spiral, not Sack's. It was discovered by Robert Sacks.
    I came across Ulam's spiral when I was looking up some things about Ulam's cellular automata, but I hadn't seen Sacks' variant. Pretty neat.

  • a soulless automaton says:

    Something similar that I find even more intriguing is the following construction: For some natural numbers D and N, take all polynomials of degree less than or equal to D, with nonzero integer coefficients from the range -N to N, inclusive. Find all complex roots for the set of polynomials, then plot the density of roots on the complex plane. The resulting plot will look roughly similar for most choices of D and N, with increasing detail for larger values of D. Any guess what it ends up looking like?
    Well, here's what you get for D = 24, N = 1. Anyone got an explanation for that?
    For further details (and proper credit for the previous image), see this page about plots of polynomial roots.

  • Rob T. says:

    Plotted on a triangle:
    2 3
    4 5 6
    7 8 9 10 ...

  • Anonymous says:

    How about this:
    1) Consider a series of squares formed by a series of uniform steps that doesn't cross a diagonal. The nth square will have a value determined by a quadratic polynomial in n.
    2) IIRC, for an odd prime p, a quadratic polynomial with integer coefficents whose n^2 coefficient does not vanish mod p will have (p+1)/2 residues mod p and (p-1)/2 nonresidues mod p.
    3) Diagonal sequences will be all even or all odd.
    In short, polynomial sequences will tend to be streakier with respect to primes.
    For example, Euler's prime-generating polynomial n^2+n+41 is never divisible by any prime less than 41, and probably has average luck with respect to the higher primes.
    By contrast, n^2+n+43 is average wrt. 3, and is worse than average wrt. 5, 7, and 11 (2 out of 5 are divisible by 5, 2 out of 7 are divisible by 7, and 2 out of 11 are divisible by 11).

  • woupiestek says:

    This may not show that God exists, but I'm starting to wonder about the devil 😉

  • ralphmerridew says:

    Elaboration on #26:
    Define the luck of a sequence (mod p), where p is prime, as:
    - "perfect luck" if no member is divisible by p
    - "average luck" if 1/p members are divisible by p
    - "poor luck" if 2/p members are divisible by p
    - "no luck" if every member is divisible by p
    (Ignoring the edge case of when p itself appears in the sequence (which will happen at most finitely many times for polynomial sequences), unlucky sequences have fewer primes than usual, and lucky sequences have more primes than usual.)
    The luck of a quadratic sequence a_n := Ann + Bn + C mod p will be:
    : For p = 2
    :: A != B (mod 2) -> average luck
    :: A == B (mod 2), C == 0 (mod 2) -> no luck
    :: A == B (mod 2), C == 1 (mod 2) -> perfect luck
    : For p = 2k+1
    :: A != 0 (mod p)
    ::: Set d := C % p.
    ::: For 1 value of d, the series has average luck; for k values of d, the series has poor luck; for k values of d, the series has perfect luck.
    :: A == 0 (mod p), B != 0 (mod p) -> average luck
    :: A == 0 (mod p), B == 0 (mod p), C == 0 (mod p) -> perfect luck
    (Well established results in number theory; search for quadratic residues if you want proofs.)
    Fix A and B with A+B even.
    There will be 1 way to choose C (mod 2) so that the sequence has perfect luck mod 2, 1 way to choose C (mod 3) so it has perfect luck mod 3, 2 ways to choose C (mod 5) so it has perfect luck mod 5, and so on. (Exceptions when p is an odd prime dividing A.)
    By the Chinese remainder theorem, it is possible to choose C so that the sequence has perfect luck for an arbitrary number of primes.
    If a sequence has perfect luck for a number of small primes, members are significantly more likely to be prime, even if the sequence has poor luck with later primes. A random integer will 12% chance of having no prime factor

  • KeithB says:

    I think you found your book jacket illustration, Mark.

  • Paul Murray says:

    I'd like to see an animation of the sieve of erasothenes running against the numbers plotted out like this.
    Also - as I understand it, the density of the primes is approximately n/ln(n), right? So to plot out a spiral that has an even density of primes across its area, the radius at n should be not sqrt(n) - which gives you an even density for all nunmbers - but ... ?
    Actually, all things considered, sqrt(n) will be pretty good, because the rate at which the rate changes is much less than sqrt(n).
    Hmm. I feel an applet coming on ...

  • Mystyk says:

    I totally was not expecting that PDF to dynamically generate the spiral. As the PDF loaded in the browser, I saw it growing from the center of the spiral out...

  • Marion D. Cohen says:

    Here's an idea, just an idea... In the diagram, lines of slope 2, 3 (or 1/2, 1/3) and higher (or lower) don't have as many points on them, period (much less primes). So any cluster of primes on those lines wouldn't be as dense as on the slope-1 and slope-minus 1 lines, so they wouldn't be as noticeable. -- I'm not sure that's the reason, but it did occur to me.

  • Peter Gerdes says:

    Well of course there are still surprises waiting for us. I mean you can interpret pretty much all mathematics as statements about the primes.
    Hell, we know that even the question of which Diophantine equations are solvable is non-computable and hence can't ever be fully characterized in a predicatively useful way.

  • Paul Murray says:

    Working with the first 100K primes.
    To plot prime number n, theta = sqrt(n)*2pi, and r = sqrt(n) to give an even distribution of numbers across the disc, or r = sqrt(n / log(n)) to give an even distribution of primes across the disc.

  • Thorny says:

    @32: Skewing the picture by a linear transformation would expose those lines, and it doesn't: if you use the transformation matrix ((1 1) (0 1)), you see dotted vertical lines and even hints of lines of slope 1/2, but no diagonals.

  • Thorny says:

    Dang, spoke too soon. Lines with slope 3 do actually show quite a bit, and even slopes can be seen if one wants to see them. I would guess that this just corresponds to forms 4n^2+2bn+c differing only by a constant from 2n(2n+b), which is likely to be divisible by all kinds of primes, so they "have a smaller chance" to be composite themselves. The same pattern is probably true for numbers of form 2n(n+1)(n+2)+c as well, it is just that they do not form an easily recognizable pattern on the spiral.

  • novin says:

    hi . your math blog is very good . thanks .
    luck .
    my math blog is persian , whoes I link its translate .

  • I wonder what happens when you do a Sacks spiral with one revolution every odd perfect square? ie, 2 3 4 5 6 7 8 9 in the first circuit, 10-25 in the next circuit, etc. That would more closely match the Ulam spiral.

  • John says:

    Multiples of many (all?) numbers form diagonal patterns. The spaces left will surely also form occasional diagonals, am i missing something or can it be that simple?
    Move a bishop around a chessboard a few times and record squares that haven't been crossed and you should see something similar.
    As Paul Murray said (30) I think an animation of the sieve would make this a little more clearer to see.

  • After seeing the Ulam and the Sacks spirals I had been playing with spirals and primes myself a while ago and came up with this:
    I fear it's probably just a pretty picture that I got after exploring various spiral factors; still I was quite surprised when I hit on it.

  • Feynmaniac says:

    Interesting post.

    For example, one of the simplest ones is that an awful lot of primes occur along the set of lines f(n) = 4n2+n+c, for a variety of values of b and c.

    Should that be f(n) = 4n2+bn+c?

  • ohwilleke says:

    Reminds me of the plots of the large scale structure of the universe with boxes along lines and holes.
    I wonder how you could generalize the concept to 3D to get that kind of plot.

  • andrew says:

    this is fascinating stuff. those patterns--so close, so tantalizingly close to looking like something predictable. amazing, thanks for sharing.

  • Keshav Srinivasan says:

    I don't know whether you read your comment threads in their entirety, but I'd be very interested to hear your thoughts about the following. You said: "Personally, I think that that's silly; my personal belief is that even a deity can't change the way the numbers work: the nature of the numbers and how they behave is inescapable. Even a deity who could create the universe couldn't make 4 a prime number." I agree that simply creating the physical universe doesn't mean you can change the behavior of numbers, which are "inescapable" in the sense that the laws of logic would not allow them to behave in any other way. In other words, the behavior of numbers are fixed as soon as the laws of logic are.
    But what if God created logic itself? It seems counterintuitive, but what if even the most basic axioms of logic, like "P implies P", were actually contingent upon God's will? In essence, what I'm claiming is that God "wrote" truth, in the sense that he chose which propositions are true and which aren't. And he wrote logic, in the sense that he chose how propositions logically followed from each other. So yes, I think God designed Sack's spiral.
    Remember, if your only response is that my world view, in which logic and mathematics could have been different from what they are, is logically impossible, then you've missed the point!

  • Mark C. Chu-Carroll says:

    Logic isn't a single thing. It's a formal system, defined from abstract rules. First order predicate logic, which is the main logic we use in math, isn't part of the universe. It's an abstraction, defined by a system of rules.
    There are some things which are inevitably true. And no one and nothing can possibly get around that.
    God *can't* create a universe where "A ∧ ¬ A" is true in FOPL. Not because of any limit on the power of god, but because it's meaningless. FOPL is something specific, which has a set of rules that define it. You *can't* create a universe where those rules don't work - because they don't depend on the universe; they're pure abstraction. Within their system, the results that you can get from them are absolutely inevitable.
    Creating a "universe" where A ∧ ¬ A is true in FOPL is like creating a Universe
    where the universe doesn't exist. What does it mean to create a universe where the universe doesn't exist? It doesn't mean anything. It's a non-sensical phrase.

  • red pepper says:

    I agree that simply creating the physical universe doesn't mean you can change the behavior of numbers, which are "inescapable" in the sense that the laws of logic would not allow them to behave in any other way. In other words, the behavior of numbers are fixed as soon as the laws of logic are.

  • Mark C. Chu-Carroll says:

    Close, but you're still missing one absolutely crucial bit: the laws of logic are arbitrary. Logic isn't something that's defined by the physical properties of the universe. Logic is just a system for describing statements and inference rules.
    FOPL seems very natural to us - but that's mainly just because we've grown up using it. Even before we knew what formal logic was, we were learning things in terms of FOPL. But there's no reason that anyone has to use FOPL.
    To give an example of a different approach, many people argue that intuitionistic logic is preferable. But in first order intuitionist predicate logic, A&lor;¬A is not necessarily true!
    Even a world creating deity couldn't make numbers work differently in FOPL.

  • animateholic says:

    a math animation blog

  • Keshav Srinivasan says:

    @45 I'm sorry, but I don't think I was sufficiently clear. When I said that God created logic, I didn't just mean that God created formal logical systems, like First Order Logic or the Propositional Calculus. I meant that he created logical consequence itself. A formal system is just a set of axioms, which give you some theorems to start off with, and a set of inference rules, which tell you how to produce new theorems from old ones. But given the specification of a particular formal system, how do you actually conclude that something is a theorem?
    An axiom may be of the form A, and a rule of inference may be of the form "If A is a theorem, then B is a theorem." But then how do you actually conclude that B is a theorem? You need the logical principle that if P is true and P implies Q, then Q is true. Where does this logic come from? Of course, you can use an axiomatization of logic like the Propositional Calculus, but that too is a formal system, so you're just kicking the problem somewhere else. (If you want to read more about this, check out this dialog by Lewis Carrol.)
    My point is that there is something pre-formal called Logic. You can formalize things like logical consequence, but ultimately to even use formal systems you need the original pre-formal God-given notion. To respond to your example, it is indeed possible that God could have made "A & not A" a theorem of first order logic, since he has full control over that pre-formal Logic we rely upon.
    Also, I don't understand why you think that "pure abstractions" are out of reach of God. I guess the issue boils down to what your philosophical views are. If you believe that truth, in particular mathematical truth, is just a subjective thing produced by the human brain, then all of this would be irrelevant, because the primeness of 4 would just be a matter of opinion. If, on the other hand, you believe as I do that mathematical truth is independent of human beliefs, then the question arises: where does mathematical truth come from? I think the only truly satisfactory answer is that something as absolute as Truth can only come from something as absolute as God.

  • ralphmerridew says:

    Did anybody notice my posts 26 & 28? I gave an explanation why some diagonals are prime-rich. (Short version: Given a set S of primes and fixed A, B, with A+B even, it is possible to choose C so that An^2 + Bn + C is never divisible by any prime in S.)

  • Will Orrick says:

    I think your explanation gets to the heart of the matter. There is actually a long-standing conjecture about the density of primes in sequences generated by quadratic polynomials going back to Hardy and Littlewood from which one would be led to expect that some diagonals should have higher density than others. This is a generalization of their conjecture about the number of primes of the form n^2+1, and was in turn generalized to polynomials of arbitrary degree and to collections of polynomials by Bateman and Horn. I think the heuristic argument given by Bateman and Horn for their conjecture is quite similar to yours.
    It seems to be "common knowledge" that the the sharp diagonal lines in the Ulam spiral are an unexpected phenomenon. Where this "common knowledge" came from, I'm not sure, but I suspect that professional analytic number theorists do not share the surprise. I would be interested to hear opinions about this, one way or the other.

  • Bill Snedden says:

    @49 "To respond to your example, it is indeed possible that God could have made "A & not A" a theorem of first order logic, since he has full control over that pre-formal Logic we rely upon."
    It's simply not possible for God or any being to have "control" over basic "laws" of logic (or rather, the referents thereof as the formalization is a human construction as Mark notes). Consider: it would have been impossible for God to instantiate the referent of the law of non-contradiction for that would necessitate that before He did so, He both existed and didn't exist. It would also necessitate that He could at any point revert reality to it's "pre" LoNC state. Which would of its own necessitate that He would both be able to do so and NOT be able to do so.
    TL;DR - grounding logic in God's will yields incoherency and chaos and is thus impossible.

  • Keshav Srinivasan says:

    @52 I'll refer you to the last sentence of my first comment: "Remember, if your only response is that my world view, in which logic and mathematics could have been different from what they are, is logically impossible, then you've missed the point!" Of course it is logically absurd for logic to be different than what it is, just as it is logically absurd for "A & not A" to be a theorem of first order logic. But the key word is "logically". It is useless to reason logically about a situation in which logic itself is different.

  • Bill Snedden says:

    @53: "It is useless to reason logically about a situation in which logic itself is different.", then you might as well shorten that sentence to read, "It is useless to reason." I hope you at least realize that your own argument is self-contradictory: if you're right, you're also wrong. A bit like arguing for solipsism; sure you might be right, but if you are you're talking to yourself...why argue the point?

  • Bill Snedden says:

    Damn this lack of an edit feature!
    @53: Besides which, it's not in any way a case of "mathematics and logic being different. It's a case of them not existing at all. If the state of affairs of existence were to be such that the law of non-contradiction were not to be a veridical representation of it, there could be no logic or mathematics at all; there would be only eternal, immutable chaos. Without a means of determining the state of reality, there would be no way to formalize (or even conceptualize) logic, not to mention the total inability to form any abstractions or concepts whatsoever. Without distinction of differences, there could be no numbers and no way to conceive or formalize mathematics.

  • Mark C. Chu-Carroll says:

    You're basically falling back to an un-falsifiable position, while challenging us to falsify it:
    You're asserting that there is some sort of pre-logic, without which logic as we understand it couldn't exist. But, you cannot describe or define that pre-logic in any meaningful way.
    Naturally, any attempt to argue against that position is doomed to fail, for the same reasons as any non-falsifiable argument: since your argument is fundamentally based on something undefined, no matter what someone puts forward as a counter-argument, you can always say "No, that's not what I'm talking about".
    Logic is a complete, self-contained formal system of abstract rules. Those rules have inevitable consequences. Those consequences aren't dependent on any "pre-formal" system. In fact, they aren't dependent on any notion of semantics or meaning. Logic is purely mechanical, syntactic inference.
    You don't need any agent to tell you that if "A" is true, and "A ⇒ B" is true, then "B" is true. That's not dependent on meaning. It's not dependent on a pre-formal logic.
    You're also pulling out one of the standard, rubbish traps of theistic arguments: that if there's no god, then there's no truth. Again, that's crap. The universe exists. We can see that. That's true. Whether or not God exists, I can observe that I exist. That is true, regardless of whether or not there is a God.
    If you define numbers axiomatically (i.e., using logic), then the prime numbers exist. They're just a simple consequence of definition. God can't make 4 prime, because 4 is 2*2.
    God can't create a universe where first order predicate logic doesn't work - first order predicate logic doesn't even require a universe to exist at all: it's a pure abstraction. An all-powerful deity could create a universe where FOPL doesn't accurately describe anything about the behavior of the universe. For example, blow away cause and effect, and FOPL ceases to be a particularly useful tool. But that doesn't change the fundamental validity of
    FOPL as a self-contained formal system.
    I can define a logical system which is valid, but which doesn't do anything particularly useful. I can use FOPL to define a number system which works in bizarre ways. (In fact, John Conway did exactly that with the Nimbers, which are incredibly strange.) But the existence of an alternate number system doesn't change the fact that if you take FOPL and the Peano axioms, you'll get the natural numbers. And no matter what anyone does, no matter what form the universe takes, no matter what the deity wills, if you use FOPL and Peano to define the natural numbers, 4 will not be a prime.
    As I've said plenty of times around here: I'm not an atheist; I'm a religious Jew. But I find this kind of argument for theism to be pathetically shallow and foolish. I don't understand the need to create these ridiculous assertions like "If there's no god, then you could just say 4 is prime". That's doesn't support your argument: it just shows that you don't understand what you're talking about.

  • Steven Twentyman says:

    These spiral of primes are your 2D thought pattern produced onto a 2d sheet. You have to make quantum leaps from point to point based on an ever expanding and then contracting personal math pi. It is your personal thought being projected onto one inner side of perfect cube box that you alone inhabit. Inside, at each moment your wave function completely collapses and then returns depending on your WILL).
    You can see the fully completed equations between our Matrix/Avatar/Inception "real life" that leads in thought and logic to classical theory which finally leads to quantum theory here:
    All of existence is built on these 3 principles constantly extrapolating from the original zero => [The Big Bang(i.e. The centre super-massive black hole at the centre of our galaxy) that is attempting to pull us(STARS back in)].
    There will be a total collapse of our sector of the universe. It is a gravity wave; the same kind that wiped out Atlantis; the dinosaurs and other major civilizations.
    Unless we apply the simple visual principle to keep re-building the "big box" the outcome is an escalating probability towards TRUE. We will either make it or we won't.
    If not, our "powerful" civilization will be wiped out in a day leaving nothing but small radiations from the edge of the black hole as hawking described.
    We are nothing but imagination and memories and WILL anyhow. I wonder if we'll make it this time??? I guess it's a better shot as we have better communications this time.
    The universe is digital. It always has been. It's nothing more than mathematical logic that sprang from the fear of NOT existing.
    A B C easy as 1 2 3 easy as DO RAY ME ABC 1 2 3 BABY YOU AND ME GIRL.
    I hope you do TOO. I guess you will seeing as you're fractal just like me.
    It just that I found the bottom, made sure everything was al-right and then start to look around and find you people.
    You are a singular STAR with a perfectly cubed black hole at the centre of you. How do you think we're communicating?
    The internet???
    Do you think that's air you're breathing???
    That's just alternating fission and fusion.
    Pick a random length of pie(your stars diameter) and STOP and look around(360 degrees in all directions).
    Start making connections in a non linear way. You simply are a box and are in a box.
    Time does not exist now. We don't need it.
    It is just a construct that either points you in a direction(old school watch) or gives you a position in a perfectly cubed grid that tells you x,y,z where you are.(digital). You are who, what and where you are.
    Start making connections with your "family".
    Superposition holds true. You are everywhere and no-where. That's why no-one in the world knows what we need to do.
    You're in a box that surrounds the milky way. It's the first quantum computer and each of you are a bit in that system. I couldn't show the ALPHA release until now for reasons I'll keep to myself.
    Just know that it is a self organising system that will work with you; not against. Karma rings TRUE fully in this system. I just thought I'd let you know that.
    Finally; the math PROVES that re-incarnation is TRUE.
    It doesn't say what you will become; but your memory and WILL lives forever. Once you have been "born" you CANNOT die. You might as well face whatever you have done and start your LIFE again. What's the point in waiting for what comes after???

  • rpsms says:

    @#57: Let me be first to say: LOLWUT?!

  • Punarva says:

    Hello people,
    I just went through the document. I also tried similar spirals with numbers divisible by other numbers. I am sharing the images in Have a look at them.

  • Punarva says:

    The spiral for Fibonacci numbers have very scarce details. Because occurance of fibonacci numbers is only scarce.
    Check the image in my blog

  • I have a number of short publications and presentations, and hundreds of pages of notes, on the Semiprime Spiral.
    A semiprime, also called a 2-almost prime, biprime (Conway et al. 2008), or pq-number, is a composite number that is the product of two (possibly equal) primes. The first few are 4, 6, 9, 10, 14, 15, 21, 22, ...
    For an example, see:
    A113688 Isolated semiprimes in the semiprime spiral.
    65, 74, 249, 295, 309, 355, 422, 511, 545, 667, 669, 721, 723, 749, 758 (list; graph; listen)
    Write the integers 1, 2, 3, 4, ... in a counterclockwise square spiral. Analogous to Ulam coloring in the primes in the spiral and discovering unexpectedly many connected diagonals, we construct a semiprime spiral by coloring in all semiprimes (A001358). Each integer has 8 adjacent integers in the spiral, horizontally, vertically and diagonally. Curious extended clumps coagulate, slightly denser towards the origin, of semiprimes connected by adjacency. This sequence gives isolated semiprimes in the semiprime spiral, namely those semiprimes none of whose adjacent integers in the spiral are semiprimes. A113688 gives an enumeration of the number of semiprimes in clumps of size >1 through n^2.
    Stein, M. and Ulam, S. M. "An Observation on the Distribution of Primes." Amer. Math. Monthly 74, 43-44, 1967.
    Stein, M. L.; Ulam, S. M.; and Wells, M. B. "A Visual Display of Some Properties of the Distribution of Primes." Amer. Math. Monthly 71, 516-520, 1964.
    S. M. Ellerstein, The square spiral, J. Recreational Mathematics 29 (#3, 1998) 188; 30 (#4, 1999-2000), 246-250.
    Eric Weisstein's World of Mathematics, "Prime Spiral".
    Eric Weisstein's World of Mathematics, "Semiprime.".
    ... 17 16 15 14 13 ...
    ... 18 5 4 3 12 ...
    ... 19 6 1 2 11 ...
    ... 20 7 8 9 10 ...
    ... 21 22 23 24 25 ...
    Cf. A001107, A001358, A002939, A002943, A004526, A005620, A007742, A033951-A033954, A033988, A033989-A033991, A033996, A063826.
    Jonathan Vos Post (jvospost3(AT), Nov 05 2005

  • Mads Anker says:

    Take a sheet of graph paper. Put "1" in some square. Then put "2" in the square to the right and continue on from there, putting one number in each square. Then circle each of the prime numbers.
    If you do that for a while - and zoom out, so that you can't see the numbers, but just dots for each circled number, what you'll get will look something like this:
    . . . ...... .. . . . . .. . .
    Oh my gawd - notice how the prime numbers form a completely straight line!!!
    I call that Ankers line. It's amazing how were still discovering underlying principles of math and the universe.

  • @50 and @51 seem to explain why there are diagonals. But why does the Ulam figure as a whole seem to have a half-rotation symmetry? Notice that the NE-SW prime-rich lines in the NW quadrant seem to match up with those in the SE. But while NW-SE prime-rich diagonals do exist, they don't have the half-rotation symmetry.
    Or has someone already answered that?

  • ralphmerridew says:

    My method really divides things into N, S, E, W quadrants.
    Produce the polynomials for some of the NE-SW lines in ? quadrant and the corresponding ? quadrant and we'll see if there's a relationship.

  • Will Orrick says:

    This is a real effect. The line joining the NW to the SE corner of the figure divides the square into two triangles. The lines lying above the division and heading in the NE direction have equations of the form 4x^2-2x+c; the lines lying below the division and heading in the SW direction have equations of the form 4x^2+2x+c. For a given c value, these two lines are expected to contain the same density of primes as x=0,1,2,... In fact, if x is allowed to take negative values, these two lines are seen to be the same. That is, they connect to each other, after spiraling around a bit in the center. To be more precise, the density of primes lying on a quadratic is conjectured to be sensitive to the discriminant, which equals 4-16c^2 for both types of line. This is the reason for the symmetry you observed.
    Why isn't there a similar symmetry between the NW and SE lines? In this case we divide the square into two triangles by drawing the line joining the NE and SW corners. The lines lying above the division and heading in the NW direction have the form 4x^2+c, while the lines lying below the division and heading in the SE direction have the form 4x^2+4x+c = (2x+1)^2 + (c-1). Notice that these two types of lines are not related to each other by negating x as was the case before. (For both types, the "negative" half of a line coincides with its positive half.) The discriminant of the NW lines is -16c, while the discriminant of the SE lines is 16-16c. It might appear that for a given NW line 4x^2+c, the SE line 4x^2+4x+(c+1) would have the same discriminant, and therefore the same density of primes. The reason this doesn't happen is that if c is odd then c+1 is even, and 4x^2+4x+(c+1) contains no primes at all! Likewise if c is even, 4x^2+c contains no primes, while 4x^2+4x+(c+1) is expected to contain infinitely many of them.
    It is important to note that nobody has any idea how to prove that even a single quadratic ax^2+bx+c contains infinitely many primes, although this is widely believed to be the case as long as the quadratic doesn't fail for one of the obvious reasons, the "obvious" reasons being that
    1) a, b, c have a common factor;
    2) (a+b) and c are both even;
    3) the polynomial is reducible.
    The conjecture for the density of primes on a quadratic obviously depends on there being infinitely many of them, and is therefore even farther from rigorous proof.

  • Doc says:


    Thank you! This whole thread is a hoot. Who cares? and why?

  • giovannaroda says:

    Some more visualizations at "Experimenting with the Ulam spiral"

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