The Ulam spiral is named after Stanislaw Ulam, who discovered it by chance in 1963 while doodling on scratch paper at a scientific meeting. Integers are placed on a square spiral. By marking the prime numbers, you can see that they tend to form patterns lining up in diagonal, horizontal, and vertical lines. This phenomenon can be best observed by drawing a large number of primes. When starting the spiral with 41, a long diagonal line is clearly visible. Triangular numbers (of the form ... ) as well as pentagonal numbers (of the form ... ) give rise to pinwheel patterns on the spiral. The divisor function ... is the sum of the ... powers of the divisors of ... . By marking out the numbers ... for which ... is odd, you can also see a pinwheel pattern for ... . Some things to try • Play "number of integers" and/or "start from" to see how spiral patterns evolve. • Set "number of integers" to its maximum and observe the pattern, a very regular, pleasant, spiral shape. • Slide "start from" to its maximum. Notice the pattern disappears. It looks just like random noise. • Play "number of integers" and/or "start from" to watch spiral patterns evolve.


    Education Levels:


      EUN,LOM,LRE4,work-cmr-id:397441,http://demonstrations.wolfram.com:http://demonstrations.wolfram.com/ExperimentingWithTheUlamSpiral/,ilox,learning resource exchange,LRE metadata application profile,LRE


      Access Privileges:

      Public - Available to anyone

      License Deed:

      Creative Commons Attribution 3.0


      This resource has not yet been aligned.
      Curriki Rating
      'NR' - This resource has not been rated
      'NR' - This resource has not been rated

      This resource has not yet been reviewed.

      Not Rated Yet.

      Non-profit Tax ID # 203478467