Numberphile has a nice video on the fifth root trick: someone raises a two-digit number to the 5th power, reads the number aloud, and you tell them immediately what the number was.

Here’s the trick in a nutshell. For any number n, n⁵ ends in the same last digit as n. You could prove that by brute force or by Euler’s theorem. So when someone tells you n⁵, you immediately know the last digit. Now you need to find the first digit, and you can do that by learning, approximately, the powers (10k)⁵ for i = 1, 2, 3, …, 9. Then you can determine the first digit by the range.

Here’s where the video is a little vague. It says that you don’t need to know the powers of 10k very accurately. This is true, but just how accurately do you need to know the ranges?

If the two-digit number is a multiple of 10, you’ll recognize the zeros at the end, and the last non-zero digit is the first digit of n. For example, if n⁵ = 777,600,000 then you know n is a multiple of 10, and since the last non-zero digit is 6, n = 60.

So you need to know the fifth powers of multiples of 10 well enough to distinguish (10k – 1)⁵ from (10k + 1)⁵. The following table shows what these numbers are.

|---+---------------+---------------|
| k | (10k - 1)^5   | (10k + 1)^5   |
|---+---------------+---------------|
| 1 |        59,049 |       161,051 |
| 2 |     2,476,099 |     4,084,101 |
| 3 |    20,511,149 |    28,629,151 |
| 4 |    90,224,199 |   115,856,201 |
| 5 |   282,475,249 |   345,025,251 |
| 6 |   714,924,299 |   844,596,301 |
| 7 | 1,564,031,349 | 1,804,229,351 |
| 8 | 3,077,056,399 | 3,486,784,401 |
| 9 | 5,584,059,449 | 6,240,321,451 |
|---+---------------+---------------|

So any number less than a million has first digit 1. Any number between 1 million and 3 million has first digit 2. Etc.

You could choose the following boundaries, if you like.

|---+----------------|
| k | upper boundary |
|---+----------------|
| 1 |      1,000,000 |
| 2 |      3,000,000 |
| 3 |     25,000,000 |
| 4 |    100,000,000 |
| 5 |    300,000,000 |
| 6 |    800,000,000 |
| 7 |  1,700,000,000 |
| 8 |  3,200,000,000 |
| 9 |  6,000,000,000 |
|---+----------------|

The Numberphile video says you should have someone say the number aloud, in words. So as soon as you hear “six billion …”, you know the first digit of n is 9. If you hear “five billion” or “four billion” you know the first digit is 8. If you hear “three billion” then you know to pay attention to the next number, to decide whether the first digit is 7 or 8. Once you hear the first few syllables of the number, you can stop pay attention until you hear the last syllable or two.

Let u be a real-valued function of n variables, and let v be a vector-valued function of n variables, a function from n variables to a vector of size n. Then we have the following product rule:

D(uv) = v Du + u Dv.

It looks strange that the first term on the right isn’t Du v.

The function uv is a function from n dimensions to n dimensions, so it’s derivative must be an n by n matrix. So the two terms on the right must be n by n matrices, and they are. But Du v is a 1 by 1 matrix, so it would not make sense on the right side.

Here’s why the product rule above looks strange: the multiplication by u is a scalar product, not a matrix product. Sometimes you can think of real numbers as 1 by 1 matrices and everything works out just fine, but not here. The product uv doesn’t make sense if you think of the output of u as a 1 by 1 matrix. Neither does the product u Dv.

If you think of v as an n by 1 matrix and Du as a 1 by n matrix, everything works. If you think of v and Du as vectors, then v Du is the outer product of the two vectors. You could think of Du as the gradient of u, but be sure you think of it horizontally, i.e. as a 1 by n matrix. And finally, D(uv) and Dv are Jacobian matrices.

Update: As Harald points out in the comments, the usual product rule applies if you write the scalar-vector product uv as the matrix product vu where now are are thinking of u as a 1 by 1 matrix! Now the product rule looks right

D(vu) = Dv u + v Du

but the product vu looks wrong because you always write scalars on the left. But here u isn’t a scalar!

A few days ago I wrote about finite simple groups and said that I might write more about them. This post is a follow-on to that one.

In my earlier post I said that finite simple groups fell into five broad categories, and that three of these were easy to describe. This post will chip away at one of the categories I said was hard to describe briefly, namely groups of Lie type or classical groups. These are finite groups that are analogous to (continuous) Lie groups. Continue reading →

Today‘s exponential sum curve is simply a triangle.

But yesterday‘s curve was more complex

and tomorrow‘s curve will be more complex as well.

Why is today’s curve so simple? The vertices of the curves are the partial sums of the series

where m is the month, d is the day, and y is the last two digits of the year. Typically the sums are too complicated to work out explicitly by hand, but today’s sum is fairly simple. We have m = 9, d = 6, and y = 18. The three fractions add to (2n + 3n² + n³)/18. Reduced mod 18, the numerators are

0, 6, 6, 6, 12, 12, 12, 0, 0, 0, 6, 6, 6, 12, 12, 12, 0, 0

The repetition in the terms of the sum leads to the straight lines in the plot. The terms in the exponential sum only take on three values, the three cube roots of 1. These three roots are 1, a, and b where

a = exp(2πi/3) = -1/2 + i√3/2

and

b = exp(-2πi/3) = -1/2 – i√3/2

is the complex conjugate of a.

Using Mathematica we have

    Table[ Exp[2 Pi I (2 n + 3 n^2 + n^3)/18], {n, 0, 17}] 
        /. {Exp[2 Pi I/3] -> a, Exp[-2 Pi I/3] -> b}

which produces

1, a, a, a, b, b, b, 1, 1, 1, a, a, a, b, b, b, 1, 1

When we take the partial sums, we get four points in a straight line because they differ by a:

1, 1 + a, 1 + 2a, 1 + 3a

 then three points in a straight line because they differ by b:

(1 + 3a), (1 + 3a) + b, (1 + 3a) + 2b, (1 + 3a) + 3b

and so forth.

There’s no direct way to define the sum of an infinite number of terms. Addition takes two arguments, and you can apply the definition repeatedly to define the sum of any finite number of terms. But an infinite sum depends on a theory of convergence. Without a definition of convergence, you have no way to define the value of an infinite sum. And with different definitions of convergence, you can get different values.

In this post I’ll review two ways of assigning a meaning to divergent series that I’ve written about before, then mention a third way.

Asymptotic series

A few months ago I wrote about an asymptotic series solution to the differential equation

You end up with the solution

which diverges for all x. That is, for each x, the partial sums of the series do not get closer to any number that you could call the sum. In fact, the individual terms of the series eventually get bigger and bigger. Surely this is a useless solution, right?

Actually, it is useful if you change your perspective. Instead of holding x fixed and letting n go to infinity, fix a value of n and let x go to infinity. In that sense, the series converges. For fixed n and large x, this gives accurate approximations to the solution of the differential equation.

Analytic continuation

At the end of a post on Bernoulli numbers I briefly explain the interpretation of the apparently nonsensical equation

1 + 2 + 3 + … = -1/12.

In a nutshell, the Riemann zeta function is defined by a two-step process. First define

for s with real part strictly bigger than 1. Then define the zeta function for the rest of the complex plane (except the point s = 1) by analytic continuation. If the infinite sum for zeta were valid for s = -1, which is it not, then it would equal 1 + 2 + 3 + …

The analytic continuation of the zeta function is defined at -1, and there the function equals -1/12. So to make sense of the sum of the positive integers, interpret the sum as a sort of pun, a funny way to write ζ(-1).

p-adic numbers

This is the most radical way to make sense of divergent series: change your number system so that they aren’t divergent!

The sum

1 + 2 + 4 + 8 + …

diverges because the partial sums (1, 3, 7, 15, …) are not getting closer to anything. But you can make the series converge by changing the way you measure distance between numbers. That’s what p-adic numbers do. For any fixed prime number p, define the distance between two numbers as the reciprocal of the largest power of p that divides their difference. That is, numbers are close together if they differ by a large power of p. We can make sense of the sum above in the 2-adic numbers, i.e. the p-adic numbers with p = 2.

The nth partial sum of the series above is 2ⁿ – 1. The 2-adic distance between 2ⁿ – 1 and -1 is 2^–n, which goes to zero, so the series converges to -1.

1 + 2 + 4 + 8 + … = -1.

Note that all the partial sums are the same, whether in the real numbers or the 2-adics, but the two number systems disagree on whether the partial sums converge.

If that explanation went by too quickly, here’s a 15-minute video expands on the same derivation.

Names for extremely large numbers are kinda pointless. The purpose of a name is to communicate something, and if the meaning of the name is not widely known, the name doesn’t serve that purpose. It’s even counterproductive if two people have incompatible ideas what the word means. It’s much safer to simply use scientific notation for extremely large numbers.

Obscure or confusing

Everyone knows what a million is. Any larger than that and you may run into trouble. The next large number name, billion, means 10⁹ to some people and 10¹² to others.

When writing for those who take one billion to mean 10⁹, your audience may or may not know that one trillion is 10¹² according to that convention. You cannot count on people knowing the names of larger numbers: quadrillion, quintillion, sextillion, etc.

To support this last claim, let’s look at the frequency of large number names according to Google’s Ngram viewer. Presumably the less often a word is used, the less likely people are to recognize it.

Here’s a bar chart for the data from 2005, plotting on a logarithmic scale. The chart has a roughly linear slope, which means the frequency of the words drops exponentially. Million is used more than 24,000 times as often as septillion.

Here’s the raw data.

    |-------------+--------------|
    | Name        |    Frequency |
    |-------------+--------------| 
    | Million     | 0.0096086564 |
    | Billion     | 0.0030243298 |
    | Trillion    | 0.0002595139 |
    | Quadrillion | 0.0000074383 |
    | Quintillion | 0.0000016745 |
    | Sextillion  | 0.0000006676 |
    | Septillion  | 0.0000003970 |
    |-------------+--------------|

Latin prefixes for large numbers

There is a consistency to these names, though they are not well known. Using the convention that these names refer to powers of 1000, the pattern is

[Latin prefix for n] + llion = 1000ⁿ⁺¹

So for example, billion is 1000²⁺¹ because bi- is the Latin prefix for 2. A trillion is 1000³⁺¹ because tri- corresponds to 3, and so forth. A duodecillion is 1000¹³ because the Latin prefix duodec- corresponds to 12.

    |-------------------+---------|
    | Name              | Meaning |
    |-------------------+---------|
    | Billion           |   10^09 |
    | Trillion          |   10^12 |
    | Quadrillion       |   10^15 |
    | Quintillion       |   10^18 |
    | Sextillion        |   10^21 |
    | Septillion        |   10^24 |
    | Octillion         |   10^27 |
    | Nonillion         |   10^30 |
    | Decillion         |   10^33 |
    | Undecillion       |   10^36 |
    | Duodecillion      |   10^39 |
    | Tredecillion      |   10^42 |
    | Quattuordecillion |   10^45 |
    | Quindecillion     |   10^48 |
    | Sexdecillion      |   10^51 |
    | Septendecillion   |   10^54 |
    | Octodecillion     |   10^57 |
    | Novemdecillion    |   10^60 |
    | Vigintillion      |   10^63 |
    |-------------------+---------|

Code

Here’s the Mathematica code that was used to create the plot above.

    BarChart[ 
        {0.0096086564, 0.0030243298, 0.0002595139, 0.0000074383, 
         0.0000016745, 0.0000006676, 0.0000003970}, 
         ChartLabels -> {"million", "billion", "trillion", "quadrillion", 
                         "quintillion", "sextillion", "septillion"}, 
         ScalingFunctions -> "Log", 
         ChartStyle -> "DarkRainbow"
    ]

Which has more mobility on an empty chessboard: a rook, a king or a knight?

On an ordinary 8 by 8 chessboard, a rook can move to any one of 14 squares, no matter where it starts. A knight and a king both have 8 possible moves from the middle of the board, fewer moves from an edge.

If we make the board bigger or higher dimensional, what happens to the relative mobility of each piece? Assume we’re playing chess on a hypercube lattice, n points along each edge, in d dimensions. So standard chess corresponds to n = 8 and d = 2.

A rook can move to any square in a coordinate direction, so it can choose one of n-1 squares in each of d dimensions, for a total of (n-1)d possibilities.

A king can move a distance of 0, 1, or -1 in each coordinate. In d dimensions, this gives him 3^d – 1 options. (Minus one for the position he’s initially on: moving 0 in every coordinate isn’t a move!)

What about a knight? There are C(d, 2) ways to choose two coordinate directions. For each pair of directions, there are 8 possibilities: two ways to choose which direction to move two steps in, and then whether to move + or – in each direction. So there are 4d(d – 1) possibilities.

In short:

• A king’s mobility increases exponentially with dimension and is independent of the size of the board.
• A rook’s mobility increases linearly with dimension and linearly with the size of the board.
• A knight’s mobility increases quadratically with dimension and independent of the size of the board.

The rules above are not the only way to generalize chess rules to higher dimensions. Here’s an interesting alternative way to define a knight’s moves: a knight can move to any lattice point a distance √5 away. In dimensions up to 4, this corresponds to the definition above. But in dimension 5 and higher, there’s a new possibility: moving one step in each of five dimensions. In that case, the number of possible knight moves increases with dimension like d⁵.

Related post: A knight’s random walk in 3 or 4 dimensions

The sum of the squares of consecutive Fibonacci numbers is another Fibonacci number. Specifically we have

and so we have the following right triangle.

The hypotenuse will always be irrational because the only Fibonacci numbers that are squares are 1 and 144, and 144 is the 12th Fibonacci number.

It’s hard to find bounds on binomial coefficients that are both simple and accurate, but in 1990, E. T. H. Wang upper and lower bounds on the central coefficient that are both, valid for n at least 4.

Here are a few numerical results to give an idea of the accuracy of the bounds on a log scale. The first column is the argument n, The second is the log of the CBC (central binomial coefficient) minus the log of the lower bound. The third column is the log of the upper bound minus the log of the CBC.

    |---+--------+--------|
    | n |  lower |  upper |
    |---+--------+--------|
    | 1 | 0.0000 | 0.3465 |
    | 2 | 0.0588 | 0.2876 |
    | 3 | 0.0793 | 0.2672 |
    | 4 | 0.0896 | 0.2569 |
    | 5 | 0.0958 | 0.2507 |
    | 6 | 0.0999 | 0.2466 |
    | 7 | 0.1029 | 0.2436 |
    | 8 | 0.1051 | 0.2414 |
    | 9 | 0.1069 | 0.2396 |
    |---+--------+--------|

And here’s a plot of the same data taking n out further.

So the ratio of the upper bound to the CBC and the ratio of the CBC to the lower bound both quickly approach an asymptote, and the lower bound is better.

Quaternion multiplication is associative but not commutative. An earlier post looked at the average size of the commutator xy – yx as a measure of how far quaternion multiplication is from being commutative.

This post looks at an analogous question for octonions. Octonion mulitplication is neither commutative nor associative. So in this post we look at the associator of three octonions (xy)z – x(yz) as a measure of how far octonion multiplication is from being associative.

(A post from yesterday looked at how close octonion multiplication comes to being associative in an algebraic sense, looking at weak forms of associativity. This post looks at how close multiplication comes to being associative in an analytical sense, looking at norm distances rather than algebraic identities.)

We will use a simulation to look at the average norm of the octonion associator over the octionions of unit length, analogous to the earlier post that looked at the commutator of the quaternions. We developed code for octonion multiplication in the previous post and will reuse that code here. We also developed code for generating random unit-length octonions in the same post.

Here’s code to find the average norm of the associator and plot a histogram of its values.

    
    import matplotlib.pyplot as plt

    # omult is octonion multiplication. 
    # See previous post.
    def associator(x, y, z):
        return omult(omult(x, y), z) - 
               omult(x, omult(y, z))

    N = 100000
    s = 0
    h = np.zeros(N)
    for n in range(N):
        x = random_unit_octonion()
        y = random_unit_octonion()
        z = random_unit_octonion()    
        t = norm(associator(x, y, z))
        s += t
        h[n] = t

    print(s/N)
    plt.hist(h, bins=50)
    plt.show()

This gives an average of 1.095 and the histogram below.

Update: Greg Egan calculated the exact mean value for the norm of the associator to be 147456/(42875 π) ≈ 1.0947336. Here are the details.