Happy number

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A happy number is defined by the following process. Starting with any positive integer, replace the number by the sum of the squares of its digits, and repeat the process until the number equals 1 (where it will stay), or it loops endlessly in a cycle which does not include 1. Those numbers for which this process ends in 1 are happy numbers, while those that do not end in 1 are unhappy numbers. A computer search up to 1020 suggests that about 12% of decimal numbers are happy[1], though no proof is known (Guy 2004:§E34).

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[edit] Overview

More formally, given a number n = n0, define a sequence n1, n2, ... where ni + 1 is the sum of the squares of the digits of ni. Then n is happy if and only if there exists i such that ni = 1.

If a number is happy, then all members of its sequence are happy; if a number is unhappy, all members of its sequence are unhappy.

For example, 7 is happy, as the associated sequence is:

72 = 49
42 + 92 = 97
92 + 72 = 130
12 + 32 + 02 = 10
12 + 02 = 1.

The first few decimal happy numbers are

1, 7, 10, 13, 19, 23, 28, 31, 32, 44, 49, 68, 70, 79, 82, 86, 91, 94, 97, 100, 103, 109, 129, 130, 133, 139, 167, 176, 188, 190, 192, 193, 203, 208, 219, 226, 230, 236, 239, 262, 263, 280, 291, 293, 301, 302, 310, 313, 319, 320, 326, 329, 331, 338, 356, 362, 365, 367, 368, 376, 379, 383, 386, 391, 392, 397, 404, 409, 440, 446, 464, 469, 478, 487, 490, 496. (sequence A007770 in OEIS).

[edit] Sequence behavior

If n is not happy, then its sequence does not go to 1. What happens instead is that it ends up in the cycle

4, 16, 37, 58, 89, 145, 42, 20, 4, ...

To see this fact, first note that if n has m digits, then the sum of the squares of its digits is at most 81m. For m = 4 and above,

n\geq10^{m-1}>81m

so any number over 1000 gets smaller under this process. Once we are under 1000, the number for which the sum of squares of digits is largest is 999, and the result is 3 times 81, that is, 243.

  • In the range 100 to 243, the number 199 produces the largest next value, of 163.
  • In the range 100 to 163, the number 159 produces the largest next value, of 107.
  • In the range 100 to 107, the number 107 produces the largest next value, of 50.

Considering more precisely the intervals [244,999], [164,243], [108,163] and [100,107], we see that every number above 99 gets strictly smaller under this process. Thus, no matter what number we start with, we eventually drop below 100. Exhaustive search then shows that every number in the interval [1,99] is either happy or goes to the above cycle.

[edit] Happy primes

A happy prime is a happy number that is prime. The first few happy primes are

7, 13, 19, 23, 31, 79, 97, 103, 109, 139, 167, 193, 239, 263, 293, 313, 331, 367, 379, 383, 397, 409, 487 (sequence A035497 in OEIS)

Note that all primes of the form Failed to parse (Cannot write to or create math output directory): 10^n + 3

and 10n + 9 are happy.  The palindromic prime 10150006 + 7426247×1075000 + 1 is also a happy prime with 150007 digits because the many 0's do not contribute to the sum of squared digits, and 12 + 72 + 42 + 22 + 62 + 22 + 42 + 72 + 12 = 176, which is a happy number.  Paul Jobling discovered the prime in 2005.[2].

As of June 2007, the largest known happy prime and the twelfth largest known prime is 4847 × 23321063 + 1. The decimal expansion has 999744 digits: 1844857508...(999724 digits omitted)...2886501377. Richard Hassler and Seventeen or Bust discovered the prime in 2005.[3] [4] Jens K. Andersen identified it as the largest known happy prime in June 2007.

In the Doctor Who episode "42", a sequence of happy primes (313, 331, 367, 379) is used as a code for unlocking a sealed door on a spaceship falling into a star.

[edit] Happy numbers in other bases

The definition of happy numbers depends on the decimal (i.e., base 10) representation of the numbers. The definition can be extended to other bases.

To represent numbers in other bases, we may use a subscript to the right to indicate the base. For instance, 1002 represents the number 4, and

123_5 = 1 \cdot 5^2 + 2 \cdot 5 + 3 =38.

Then, it is easy to see that there are happy numbers in every base. For instance, the numbers

1b,10b,100b,1000b,...

are all happy, for any base b.

By a similar argument to the one above for decimal happy numbers, we can see that unhappy numbers in base b lead to cycles of numbers less than 1000b. We can use the fact that if n < 1000b, then the sum of the squares of the base-b digits of n is less than or equal to

3(b − 1)2

which can be shown to be less than b3. This shows that once the sequence reaches a number less than 1000b, it stays below 1000b, and hence must cycle or reach 1.

In base 2, all numbers are happy. All binary numbers larger than 10002 decay into a value equal to or less than 10002, and all such values are happy: The following four sequences contain all numbers less than 10002:

 111_2 \rightarrow 11_2 \rightarrow 10_2 \rightarrow 1
 110_2 \rightarrow 10_2 \rightarrow 1
 101_2 \rightarrow 10_2 \rightarrow 1
 100_2 \rightarrow 1.

Since all sequences end in 1, we conclude that all numbers are happy in base 2. This makes base 2 a happy base.

The only known happy bases are 2 and 4, yet more could exist.

[edit] Origin

Happy numbers were brought to the attention of Reg Allenby[1], a British author and Senior Lecturer in pure mathematics at Leeds University, by his daughter. She had learned of them at school, but they "may have originated in Russia" (Guy 2004:§E34).

[edit] Notes

  1. ^ 12,005,034,444,292,997,294 happy numbers under 1020http://www.research.att.com/~njas/sequences/A068571
  2. ^ http://primes.utm.edu/primes/page.php?id=76550
  3. ^ http://primes.utm.edu/primes/page.php?id=75994
  4. ^ http://www.seventeenorbust.com/documents/prime-101205.txt

[edit] References