Compression and interpolation

Posted on by John

Data compression is everywhere. We’re unaware of it when it is done well. We only become aware of it when it is pushed too far, such as when a photo looks grainy or fuzzy because it was compressed too much.

The basic idea of data compression is to not transmit the raw data but to transmit some of the data along with instructions for how to approximately reconstruct the rest [1].

Fifty years ago scientists were concerned with a different application of compression: reducing the size of mathematical tables. Books of tabulated functions are obsolete now, but the principles used in producing these tables are still very much relevant. We use compression and interpolation far more often now, though it’s almost always invisibly executed by software.

Compressing tables

In this post I want to expand on comments by Forman Acton from his book Numerical Methods That Work on compression.

Many persons are unaware of the considerable compression in a table that even the use of quadratic interpolation permits. A table of sin x covering the first quadrant, for example, requires 541 pages if it is to be linearly interpolable to eight decimal places. If quadratic interpolation is used, the same table takes only one page having entries at one-degree intervals with functions of the first and second differences being recorded together with the sine itself.

Acton goes on to mention the advantage of condensing shelf space by a factor of 500. We no longer care about saving shelf space, but we may care very much about saving memory in an embedded device.

Quadratic interpolation does allow more compression than linear interpolation, but not by a factor of 500. I admire Acton’s numerical methods book, but I’m afraid he got this one wrong.

Interpolation error bound

In order to test Acton’s claim we will need the following theorem on interpolation error [2].

Let f be a function so that f(n+1) is continuous on [a, b] and satisfies |f(n+1) (x)| ≤ M. Let p be the polynomial of degree ≤ n that interpolates f at n + 1 equally spaced nodes in [a, b], including the end points. Then on [a, b],

|f(x) - p(x)| \leq \frac{1}{4(n+1)} M \left(\frac{b-a}{n}\right)^{n+1}

Quadratic interpolation error

Acton claims that quadratic interpolation at intervals of one degree is adequate to produce eight decimal places of accuracy. Quadratic interpolation means n = 2.

We have our function tabulated at evenly spaced points a distance h = π/180 radians apart. Quadratic interpolation requires function values at three points, so ba = 2h = π/90. The third derivative of sine is negative cosine, so M = 1.

This gives an error bound of 4.43 × 10−7, so this would give slightly better than six decimal place accuracy, not eight.

Linear interpolation error

Suppose we wanted to create a table of sine values so that linear interpolation would give results accurate to eight decimal places.
In the interpolation error formula we have M = 1 as before, and now n = 1. We would need to tabulate sine at enough points that h = b − a is small enough that the error is less than 5 × 10−9. It follows that h = 0.0002 radians. Covering a range of π/2 radians in increments of 0.0002 radians would require 7854 function values. Acton implicitly assumes 90 values to a page, so this would take about 87 pages.

Abramowitz and Stegun devotes 32 pages to tabulating sine and cosine at increments of 0.001 radian. This does not always guarantee eight decimal place accuracy using linear interpolation, but it does guarantee at least seven places (more on that here), which is better than a table at one degree increments would deliver using quadratic interpolation. So it would have been more accurate for Acton to say quadratic interpolation reduces the number of pages by a factor of 30 rather than 500.

Cubic interpolation error

If we have a table of sine values at one degree increments, how much accuracy could we get using cubic interpolation? In that case we’d apply the interpolation error theorem with n = 3 and ba = 3(π/180) = π/60. Then the error bound is 5.8 × 10−9. This would usually give you eight decimal place accuracy, so perhaps Acton carried out the calculation for cubic interpolation rather than quadratic interpolation.

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[1] This is what’s known as lossy compression; some information is lost in the compression process. Lossless compression also replaces the original data with a description that can be used to reproduce the data, but in this case the reconstruction process is perfect.

[2] Ward Cheney and David Kincaid. Numerical Methods and Computation. Third edition.

 

Chebyshev polynomials as distorted cosines

Posted on by John

Forman Acton’s book Numerical Methods that Work describes Chebyschev polynomials as

cosine curves with a somewhat disturbed horizontal scale, but the vertical scale has not been touched.

The relation between Chebyshev polynomials and cosines is

Tn(cos θ) = cos(nθ).

Some sources take this as the definition of Chebyshev polynomials. Other sources define the polynomials differently and prove this equation as a theorem.

It follows that if we let x = cos θ then

Tn(x) = cos(n arccos x).

Now sin x = cos(π/2 − x) and for small x, sin x ≈ x. This means

arccos(x) ≈ π/2 − x

for x near 0, and so we should expect the approximation

Tn(x) ≈ cos(n(π/2 − x)).

to be accurate near the middle of the interval [−1, 1] though not at the ends. A couple plots show that this is the case.

Mote Chebyshev posts

Math’s base 32 versus Linux’s base 32

Posted on by John

The convention in math for writing numbers in bases larger than 10 is to insert capital letters after 9, starting with A. So, for example, the digits in base 12 are 0, 1, 2, …, 9, A, and B.

So if you’re familiar with math but not Linux, and you run across the base32 utility, you might naturally assume that the command converts numbers to base 32 using the symbols 0, 1, 2, &hellip, 9, A, B, C, …, V. That’s a reasonable guess, but it actually uses the symbols A, B, C, …, Z, 2, 3, 4, 5, 6, and 7. It’s all described in RFC 3548.

What’s going on? The purpose of base 32 encoding is to render binary data in a way that is human readable and capable of being processed by software that was originally written with human readable input in mind. The purpose is not to carry out mathematical operations.

Note that the digit 0 is not used, because it’s visually similar to the letter O. The digit 1 is also not used, perhaps because it looks like a lowercase l in some fonts.

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Editing a file without an editor

Posted on by John

I don’t use sed very often, but it’s very handy when I do use it, particularly when needing to make a small change to a large file.

Fixing a JSON file

Lately I’ve been trying to fix a 30 MB JSON file that has been corrupted somehow. The file is one very long line.

Emacs was unable to open the file. (It might have eventually opened the file, but I killed the process when it took longer than I was willing to wait.)

Emacs can open large files, but it has trouble with long lines. Somewhere its data structures assume lines are not typically millions of characters long.

I used sed to add line breaks after closing brackets

    sed -i 's/]/]\n/g' myfile.json

and then I was able to open the file in Emacs.

If the problem with my JSON file were simply a missing closing brace—it’s not—then I could add a closing brace with

    sed -i 's/$/}/' myfile.json

Using sed to find a job

I had a friend in college who got a job because of a sed script he wrote as an intern.

A finite element program would crash when it attempted to take too large a time step, but the program would not finish by the time the results were needed if it always took tiny time steps. So they’d let the program crash occasionally, then edit the configuration file with a smaller time step and restart the program.

They were asking engineers to work around the clock so someone could edit the configuration file and restart the finite element program if it crashed in the middle of the night. My friend wrote a shell script to automate this process, using sed to do the file editing. He eliminated the need for a night shift and got a job offer.

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Interpolating the gamma function

Posted on by John

Suppose you wanted to approximate Γ(10.3). You know it’s somewhere between Γ(10) = 9! and Γ(11) = 10!, and linear interpolation would give you

Γ(10.3) ≈ 0.7 × 9! + 0.3 × 10! = 1342656.

But the exact value is closer to 716430.69, and so our estimate is 53% too high. Not a very good approximation.

Now let’s try again, applying linear interpolation to the log of the gamma function. Our approximation is

log Γ(10.3) ≈ 0.7 × log 9! + 0.3 × log 10! = 13.4926

while the actual value is 13.4820, an error of about 0.08%. If we take exponentials to get an approximation of Γ(10.3), not log Γ(10.3), the error is larger, about 1%, but still much better than 53% error.

The gamma function grows very quickly, and so the log gamma function is usually easier to work with.

As a bonus, the Bohr–Mollerup theorem says that log gamma is a convex function. This tells us that not only does linear interpolation give an approximation, it gives us an upper bound.

The Bohr–Mollerup theorem essentially says that the gamma function is the only function that extends factorial from a function on the integers to a log-convex function on the real numbers. This isn’t quite true since it’s actually &Gamma(x + 1) that extends factorial. Showing the gamma function is unique is the hard part. In the preceding paragraph we used the easy direction of the theorem, saying that gamma is log-convex.

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Too clever Monte Carlo

Posted on by John

One way to find the volume of a sphere would be to imagine the sphere in a box, randomly select points in the box, and count how many of these points fall inside the sphere. In principle this would work in any dimension.

The problem with naive Monte Carlo

We could write a program to estimate the volume of a high-dimensional sphere this way. But there’s a problem: very few random samples will fall in the sphere. The ratio of the volume of a sphere to the volume of a box it fits in goes to zero as the dimension increases. We might take a large number of samples and none of them fall inside the sphere. In this case we’d estimate the volume as zero. This estimate would have small absolute error, but 100% relative error.

A more clever approach

So instead of actually writing a program to randomly sample a high dimensional cube, let’s imagine that we did. Instead of doing a big Monte Carlo study, we could be clever and use theory.

Let n be our dimension. We want to draw uniform random samples from [−1, 1]n and see whether they land inside the unit sphere. So we’d draw n random samples from [−1, 1] and see whether the sum of their squares is less than or equal to 1.

Let Xi be a uniform random variable on [−1, 1]. We want to know the probability that

X1² + X2² + X3² + … + Xn² ≤ 1.

This would be an ugly calculation, but since we’re primarily interested in the case of large n, we can approximate the sum using the central limit theorem (CLT). We can show, using the transformation theorem, that each Xi² has mean 1/3 and variance 4/45. The CLT says that the sum has approximately the distribution of a normal random variable with mean n/3 and variance 4n/45.

Too clever by half

The approach above turns out to be a bad idea, though it’s not obvious why.

The CLT does provide a good approximation of the sum above, near the mean. But we have a sum with mean n/3, with n large, and we’re asking for the probability that the sum is less than 1. In other words, we’re asking for the probability in the tail where the CLT approximation error is a bad (relative) fit. More on this here.

This post turned out to not be about what I thought it would be about. I thought this post would lead to a asymptotic approximation for the volume of an n-dimensional sphere. I would compare the approximation to the exact value and see how well it did. Except it did terribly. So instead, this post a cautionary tale about remembering how convergence works in the CLT.

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Evaluating a class of infinite sums in closed form

Posted on by John

The other day I ran across the surprising identity

\sum_{n=1}^\infty \frac{n^3}{2^n} = 26

and wondered how many sums of this form can be evaluated in closed form like this. Quite a few it turns out.

Sums of the form

\sum_{n=1}^\infty \frac{n^k}{c^n}

evaluate to a rational number when k is a non-negative integer and c is a rational number with |c| > 1. Furthermore, there is an algorithm for finding the value of the sum.

The sums can be evaluated using the polylogarithm function Lis(z) defined as

\text{Li}_s(z) = \sum_{n=1}^\infty \frac{z^n}{n^s}

using the identity

\sum_{n=1}^\infty \frac{n^k}{c^n} = \text{Li}{-k}\left(\frac{1}{c}\right)

We then need to have a way to evaluate Lis(z). This cannot be done in closed form in general, but it can be done when s is a negative integer as above. To evaluate Lik(z) we need to know two things. First,

Li_1(z) = -\log(1-z)

and second,

\text{Li}_{s-1}(z) = z \frac{d}{dz} \text{Li}_s(z)

Now Li0(z) is a rational function of z, namely z/(1 − z). The derivative of a rational function is a rational function, and multiplying a rational function of z by z produces another rational function, so Lis(z) is a rational function of z whenever s is a non-positive integer.

Assuming the results cited above, we can prove the identity

\sum_{n=1}^\infty \frac{n^3}{2^n} = 26

stated at the top of the post.The sum equals Li−3(1/2), and

\text{Li}_{-3}(z) = \left(z \frac{d}{dz}\right)^3 \frac{z}{1-z} = \frac{z(1 + 4z + z^2)}{(1-z)^4}

The result comes from plugging in z= 1/2 and getting out 26.

When k and c are positive integers, the sum

\sum_{n=1}^\infty \frac{n^k}{c^n}

is not necessarily an integer, as it is when k = 3 and c = 2, but it is always rational. It looks like the sum is an integer if c= 2; I verified that the sum is an integer for c = 2 and k = 1 through 10 using the PolyLog function in Mathematica.

Update: Here is a proof that the sum is an integer when n = 2. From a comment by Theophylline on Substack.

The sum is occasionally an integer for larger values of c. For example,

\sum_{n=1}^\infty \frac{n^4}{3^n} = 15

and

\sum_{n=1}^\infty \frac{n^8}{3^n} = 17295

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Sphere spilling out

Posted on by John

Center a small blue sphere on every corner of an n-dimensional unit hypercube. These are the points in ℝn for which every coordinate is either a 0 or a 1. Now inflate each of these small spheres at the same time until they touch. Each sphere will have radius 1/2. For example, the spheres centered at

(0, 0, 0, …, 0)

and

(0, 0, 0, …, 1)

can’t have a radius larger than 1/2 because they’ll intersect at (0, 0, 0, …, 1/2).

Now center a little red sphere at center, the point where every coordinate equals 1/2, and blow it up until it touches the blue spheres. Which is larger, the blue spheres or the red one?

The answer depends on n. In low dimensions, the blue spheres are larger. But in higher dimensions, the red sphere is larger.

The distance of from the center of the hypercube to any of the vertices is √n / 2 and so the radius of the red sphere is (√n − 1) / 2. When n = 4, the radius of the red sphere equals the radius of the blue spheres.

The hypercube and blue spheres will fit inside a hypercube whose side is length 2. But if n > 9 the red sphere will spill out of this larger hypercube.

This post was motivate by this post by Aryeh Kontorovich on Twitter.

More on high-dimensional spheres

A variation on Rock, Paper, Scissors

Posted on by John

Imagine in a game of Rock, Paper, Scissors one player is free to play as usual but the other is required to choose each option the same number of times. That is, in 3n rounds of the game, the disadvantaged player much choose Rock n times, Paper n times, and Scissors n times.

Obviously the unrestricted player would be expected to win more games, but how many more? At least one, because the unrestricted player knows what the restricted player will do on the last round.

If n is large, then in the early rounds of the game it makes little difference that one of the players is restricted. The restriction doesn’t give the unrestricted player much exploitable information. But in the later rounds of the game, the limitations on the restricted player’s moves increase the other players chances of winning more.

It turns out that the if the unrestricted player uses an optimal strategy, he can expect to win O(√n) more rounds than he loses. More precisely, the expected advantage approaches 1.4658√n as n grows. You can find a thorough analysis of the problem in this paper.

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q-analog of rising powers

Posted on by John

The previous post looked at the probability that a random n by n matrix over a finite field of order q is invertible. This works out to be

\prod_{i=1}^n \left(1 - \frac{1}{q^i}\right)

This function of q and n comes up in other contexts as well and has a name that we will get to shortly.

Pochhammer symbols

Leo August Pochhammer (1841–1920) defined the kth rising power of x by

(x)_k = x(x + 1)(x + 2)\cdots(x + k - 1)

Rising and falling powers come up naturally in combinatorics, finite difference analogs of calculus, and in the definition of hypergeometric functions.

q-Pochhammer symbols

The q-analog of the Pochhammer symbol is defined as

(a;q)_n = \prod_{k=0}^{n-1} (1-aq^k)=(1-a)(1-aq)(1-aq^2)\cdots(1-aq^{n-1})

Like the Pochhammer symbol, the q-Pochhammer symbol also comes up in combinatorics.

In general, q-analogs of various concepts are generalizations that reduce to the original concept in some sort of limit as q goes to 1. The relationship between the q-Pochhammer symbol and the Pochhammer symbol is

\lim_{q\to 1} \frac{(q^x;q)_n}{(1-q)^n} = (x)_n
For a simpler introduction to q-analogs, see this post on q-factorial and q-binomial coefficients.

Back to our probability problem

The motivation for this post was to give a name to the function that gives probability a random n by n matrix over a finite field of order q is invertible. In the notation above, this function is (1/q; 1/q)n.

There’s a confusing notational coincidence here. The number of elements in a finite field is usually denoted by q. The q in q-analogs such as the q-Pochhammer symbol has absolute value less than 1. It’s a coincidence that they both use the letter q, and the q in our application of q-Pochhammer symbols is the reciprocal of the q representing the order of a finite field.

I mentioned in the previous post that the probability of the matrix being invertible is a decreasing function of n. This probability decreases to a positive limit, varying with the value of q. This limit is (1/q; 1/q). Here the subscript ∞ denotes that we take the limit in (1/q; 1/q)n as n goes to infinity. There’s no problem here because the infinite product converges.

Mathematica and plotting

The q-Pochhammer symbol (a; q)n is implemented in Mathematica as QPochhammer[a, q, n] and the special case (q; q) is implemented as QPochhammer[q]. We can use the latter to make the following plot.

Plot[QPochhammer[q], {q, -1, 1}]

Recall that the q in our motivating application is the reciprocal of the q in the q-Pochhhammer symbol. This says for large fields, the limiting probability that an n by n matrix is invertible as n increases is near 1, but that for smaller fields the limiting probability is also smaller. For q = 2, the probability is 0.288788.

Plot[QPochhammer[1/q], {q, 2, 100}, PlotRange -> All]

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