For a positive real number x, the expression x mod 1 means the fractional part of x:

x mod 1 = x − ⌊ x ⌋.

This post will look at the distributions of nx mod 1 and xⁿ mod 1 for n = 1, 2, 3, ….

The distribution of nx mod 1 is easy to classify. If x is rational then nx will cycle through a finite number of values in the interval [0, 1]. If x is irrational then nx will be uniformly distributed in the interval.

The distribution of xⁿ mod 1 is more subtle. We have three basic facts.

1. If 0 ≤ x < 1, then xⁿ → 0 as n → ∞.
2. If x = 1 then xⁿ = 1 for all n.
3. For almost all x > 1 the sequence xⁿ mod 1 is uniformly distributed. But for some values of x it is not, and there’s no known classification for these exceptional values of x.

The rest of the post will focus on the third fact.

Suppose x = √2. Then for all even n, xⁿ mod 1 = 0. The sequence isn’t uniformly distributed in [0, 1] because half the sequence is piled up at 0.

For another example, let’s look at powers of the golden ratio φ = (1 + √5)/2. For even values of n the sequence φⁿ converges to 1, and for odd values of n it converges to 0. You can find a proof here.

At one time it was not known whether xⁿ mod 1 is uniformly distributed for x = 3 + √2.  (See HAKMEM, item 32.) I don’t know whether this is still unknown. Let’s see what we can tell from a plot.

Apparently sometime around n = 25 the sequence suddenly converges to 0. That looks awfully suspicious. Let’s calculate x²⁵ using bc.

    $ echo '(3 + sqrt(2))^25' | bc -l
    13223107213151867.43024035874391918714

This says x²⁵ mod 1 should be around 0.43, not near 0. The reason we’re seeing all zeros is that all the bits in the significand are being used to store the integer part and none are left over for the fractional part. A standard floating point number has 53 bits of significand and

(3 + √2)²⁵ > 2⁵³.

For more details, see Anatomy of a floating point number.

Now let’s see what happens when we calculate xⁿ mod 1 correctly using bc. Here’s the revised plot.

Is this uniformly distributed? Well, it’s not obviously not uniformly distributed. But we can’t tell by looking at a plot because uniform distribution is an asymptotic property.

We didn’t give the definition of a uniformly distributed sequence until now because an intuitive understanding of the term was sufficient. Now we should be more precise.

Given a set E, a sequence ω, and an integer N, define A(E, ω, N) to be the number of elements in the first N elements of the sequence ω that fall inside E. We say ω is uniformly distributed mod 1 if for every 0 ≤ a ≤ b ≤ 1,

lim_{N → ∞} A([a, b), ω, N) / N = b − a.

That is, the relative port of points that fall in an interval is equal to the length of the interval.

Now let’s go back to the example x = √2. We know that the powers of this value of x are not uniformly distributed mod 1. But we also said that for almost all x > 1 the powers of x are uniformly distributed. That means every tiny little interval around √2 contains a number y such that the powers of y are uniformly distributed mod 1. Now if y is very close to √2 and we plot the first few values of yⁿ mod 1 then half of the values will be near 0. The sequence will not look uniformly distributed, though it is uniformly distributed in the limit.

Years ago I wrote a post Golden powers are nearly integers. The post was picked up by Hacker News and got a lot of traffic. The post was commenting on a line from Terry Tao:

The powers φ, φ², φ³, … of the golden ratio lie unexpectedly close to integers: for instance, φ¹¹ = 199.005… is unusually close to 199.

In the process of writing my recent post on base-φ numbers I came across some equations that explain exactly why golden powers are nearly integers.

Let φ be the golden ratio and ψ = −1/φ. That is, φ and ψ are the larger and smaller roots of

x² − x − 1 = 0.

Then powers of φ reduce to an integer and an integer multiple of φ. This is true for negative powers of φ as well, and so powers of ψ also reduce to an integer and an integer multiple of ψ. And in fact, the integers alluded to are Fibonacci numbers.

φⁿ = F_n φ + F_{n − 1}
ψⁿ = F_n ψ + F_{n − 1}

These equations can be found in TAOCP 1.2.8 exercise 11.

Adding the two equations leads to [1]

φⁿ = F_{n + 1} + F_{n − 1} − ψⁿ

So yes, φⁿ is nearly an integer. In fact, it’s nearly the sum of the (n + 1)st and (n − 1)st Fibonacci numbers. The error in this approximation is −ψⁿ, and so the error decreases exponentially with alternating signs.

Related posts

• Plastic powers
• Golden ratio primes
• Golden integration

[1] φⁿ + ψⁿ = F_n (φ + ψ) + 2 F_{n − 1} = F_n + 2 F_{n − 1} = F_n + F_{n − 1} + F_{n − 1} = F_{n + 1} + F_{n − 1}

Casting out nines is a well-known way of finding the remainder when a number is divided by 9. You add all the digits of a number n. And if that number is bigger than 9, add all the digits of that number. You keep this up until you get a number less than 9.

This is an example of persistence. The persistence of a number, relative to some operation, is the number of times you have to apply that operation before you reach a fixed point, a point where applying the operation further makes no change.

The additive persistence of a number is the number of times you have to take the digit sum before getting a fixed point (i.e. a number less than 9). For example, the additive persistence of 8675309 is 3 because the digits in 8675309 sum to 38, the digits in 38 sum to 11, and the digits in 11 sum to 2.

The additive persistence of a number in base b is bounded above by its iterated logarithm in base b.

The smallest number with additive persistence n is sequence A006050 in OEIS.

Multiplicative persistence is analogous, except you multiply digits together. Curiously, it seems that multiplicative persistence is bounded. This is true for numbers with less than 30,000 digits, and it is conjectured to be true for all integers.

The smallest number with multiplicative persistence n is sequence A003001 in OEIS.

Here’s Python code to compute multiplicative persistence.

def digit_prod(n):
    s = str(n)
    prod = 1
    for d in s:
        prod *= int(d)
    return prod

def persistence(n):
    c = 0
    while n > 9:
        n = digit_prod(n)
        print(n)
        c += 1
    return c   

You could use this to verify that 277777788888899 has persistence 11. It is conjectured that no number has larger persistence larger than 11.

The persistence of a large number is very likely 1. If you pick a number with 1000 digits at random, for example, it’s very likely that at least of these digits will be 0. So it would seem that the probability of a large number having persistence larger than 11 would be incredibly small, but I would not have expected it to be zero.

Here are plots to visualize the fixed points of the numbers less than N for increasing values of N.

It’s not surprising that zeros become more common as N increases. And a moments thought will explain why even numbers are more common than odd numbers. But it’s a little surprising that 4 is much less common than 2, 6, or 8.

Incidentally, we have worked in base 10 so far. In base 2, the maximum persistence is 1: when you multiply a bunch of 0s and 1s together, you either get 0 or 1. It is conjectured that the maximum persistence in base 3 is 3.

Fermat’s primality test

Fermat’s little theorem says that if p is a prime and a is not a multiple of p, then

a^p−1 = 1 (mod p).

The contrapositive of Fermat’s little theorem says if

a^p−1 ≠ 1 (mod p)

then either p is not prime or a is a multiple of p. The contrapositive is used to test whether a number is prime. Pick a number a less than p (and so a is clearly not a multiple of p) and compute a^p−1 mod p.  If the result is not congruent to 1 mod p, then p is not a prime.

So Fermat’s little theorem gives us a way to prove that a number is composite: if a^p−1 mod p equals anything other than 1, p is definitely composite. But if a^p−1 mod p does equal 1, the test is inconclusive. Such a result suggests that p is prime, but it might not be.

Examples

For example, suppose we want to test whether 57 is prime. If we apply Fermat’s primality test with a = 2 we find that 57 is not prime, as the following bit of Python shows.

    >>> pow(2, 56, 57)
    4

Now let’s test whether 91 is prime using a = 64. Then Fermat’s test is inconclusive.

    >>> pow(64, 90, 91)
    1

In fact 91 is not prime because it factors into 7 × 13.

If we had used a = 2 as our base we would have had proof that 91 is composite. In practice, Fermat’s test is applied with multiple values of a (if necessary).

Witnesses

If a^p−1 = 1 (mod p), then a is a witness to the primality of p. It’s not proof, but it’s evidence. It’s still possible p is not prime, in which case a is a false witness to the primality of p, or p is a pseudoprime to the base a. In the examples above, 64 is a false witness to the primality of 91.

Until I stumbled on a paper [1] recently, I didn’t realize that on average composite numbers have a lot of false witnesses. For large N, the average number of false witnesses for composite numbers less than N is greater than N^15/23. Although N^15/23 is big, it’s small relative to N when N is huge. And in applications, N is huge, e.g. N = 2²⁰⁴⁸ for RSA encryption.

However, your chances of picking one of these false witnesses, if you were to choose a base a at random, is small, and so probabilistic primality testing based on Fermat’s little theorem is practical, and in fact common.

Note that the result quoted above is a lower bound on the average number of false witnesses. You really want an upper bound if you want to say that you’re unlikely to run into a false witness by accident. The authors in [1] do give upper bounds, but they’re much more complicated expressions than the lower bound.

Related posts

• Fast exponentiation
• Testing for primes less than a quintillion
• What does it mean to say a number is probably prime?

[1] Paul Erdős and Carl Pomerance. On the Number of False Witnesses for a Composite Number. Mathematics of Computation. Volume 46, Number 173 (January 1986), pp. 259–279.