Hilbert transform as an infinite matrix

Posted on by John

The previous post linked to a post I wrote a few years ago about the Hilbert transform and Fourier series. That post says that if the Fourier series of a function is

f(t) = \sum_{n=1}^\infty \left\{ a_n \sin(nt) + b_n\cos(nt) \right\}

then the Fourier series of its Hilbert transform is

f_H(x) = \sum_{n=1}^\infty \left\{ -b_n \sin(nx) + a_n\cos(nx) \right\}

When I looked back at that post I thought about how if you thought of the Fourier coefficients as elements of an infinite vector then the Hilbert transform can be represented as multiplying by an infinite block matrix.

\left[ \begin{array}{cc|cc|cc|c} 0 & -1 & 0 & 0 & 0 & 0 & \cdots \\ 1 & 0 & 0 & 0 & 0 & 0 & \cdots \\ \hline 0 & 0 & 0 & -1 & 0 & 0 & \cdots \\ 0 & 0 & 1 & 0 & 0 & 0 & \cdots \\ \hline 0 & 0 & 0 & 0 & 0 & -1 & \cdots \\ 0 & 0 & 0 & 0 & 1 & 0 & \cdots \\ \hline \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \ddots \end{array} \right] \left[ \begin{array}{c} a_1 \\ b_1 \\ \hline a_2 \\ b_2 \\ \hline a_3 \\ b_3 \\ \hline \vdots \end{array} \right]

I rarely see infinite matrices except in older math books. Apparently they were more fashionable a few decades ago than they are now. I suppose the notation falls between two stools, too concrete for some tastes and not concrete enough for others. The former folks would prefer something like H and the latter would prefer the sum above.

Real and imaginary parts

Posted on by John

The previous post announced some notes I wrote up based on an article by Henry Baker implementing functions of a complex variable in terms of functions of a real variable. That is, it finds functions u(x, y) and v(x, y) such that

f(x + iy) = u(x, y) + i v(x, y)

where xyu, and v are all real-valued. Not only that, but if f is an elementary function, so are u and v. Here “elementary” has a technical meaning, but essentially it means functions that you could evaluate on a scientific calculator. A couple of the functions might be unfamiliar, such as sgn and atan2, but there are no functions like the gamma function that are defined in terms of integrals.

One application of Baker’s equations would be to bootstrap a math library that doesn’t support complex numbers into one that does. But the equations could be useful in pure math when you’d like to have a convenient expression for the real or imaginary part of a function.

The real and imaginary parts of a complex analytic function are harmonic functions. So the functions on the right hand side of Baker’s equations satisfy Laplace’s equation:

uxx + uyy = 0

and

vxx + vyy = 0.

Furthermore, the functions u and v form harmonic conjugate pairs, meaning each is the Hilbert transform of the other.

Building complex functions out of real parts

Posted on by John

A couple months ago I wrote about how to compute the sine and cosine of a complex number using only real functions of real variables using the equations

\begin{align*} \sin(x + iy) &= \sin x \cosh y + i \cos x \sinh y \\ \cos(x + iy) &= \cos x \cosh y - i \sin x \sinh y \\ \end{align*}

You can do something analogous for all the elementary functions, though some of the equations are quite a bit more complicated than the ones above. See the equations here.

The equations come from a paper by Henry G. Baker, cited in the linked page. I wrote up Baker’s equations in LaTeX, then used ChatGPT to generate Python code from the LaTeX to numerically verify the equations and my typesetting of them. This caught a few typos on my part.

The test code evaluated the equations at points from each quadrant. All matched NumPy, implying that Baker and NumPy use the same branch cuts on inverse functions.

***

This post is part of a thread that has gone on for a few days. Maybe it’s the last post in the thread; we’ll see.

It all started with a post on Markov’s equation

x² + y² + z² = 3 xyz

and an approximation to the equation that has a closed-form solution. That led to the identity

cosh( arccosh(a) + arccosh(b) ) = ab + √(a² − 1) √(b² − 1).

The approximation to Markov’s equation only needed the identity to be valid for real a and b greater than 1. But when I looked closer at the identity I found several complications with branch cuts. The identity doesn’t hold everywhere using the principle branch of the square root function. But if you define √(z² − 1) to have a branch cut along [−1, 1] then the equation holds everywhere in the complex plane. And that led to my writing up some notes on how to define all the elementary inverse functions in terms of log.

Someone reading these posts suggested I look at a paper that mentioned “couth” and “uncouth” function pairs, which led to this post and its warm up.

I find all this interesting because it’s an advanced perspective on a questions that are latent in an intro calculus class. What exactly do functions like arccos mean and why where they defined as they were? These are fairly deep and interesting questions that are swept under the rug, and swept there for good reason. A calculus class has to cover an enormous amount of material and there’s no time to dwell on fine points. Some of my favorite posts look back leisurely on things that go by in a blur when you’re a student.

Couth and uncouth function pairs

Posted on by John

“You can’t always get what you want. But sometimes you get what you need.” — The Rolling Stones

Circular functions and hyperbolic functions aren’t invertible, but we invert them anyway. These functions map many points in the domain to each point in the range, and we invert them by mapping a point in the range back to some point in the domain. Often this works as expected, but sometimes it doesn’t.

In the previous post I said

You can relate each trig function “foo” with its hyperbolic counterpart “fooh” by applying one of the functions to iz then multiplying by a constant c that depends on foo: ci for sin and tan, c = 1 for cos and sec, and c = −i for csc and cot.

In symbols,

c foo(z) = fooh(iz).

Let’s suppose foo and fooh are invertible, ignoring any complications, and solve foo(z) = w for z. We get

i foo−1(w) = fooh−1(cw)

or using “arc” nomenclature for inverse functions

i arcfoo(w) = arcfooh(cw).

When the naive calculation above holds, except possibly at a finite number of points, we say the pair (foo, fooh) is couth. Otherwise we say the pair is uncouth. These term were coined by Robert Corless and his coauthors in their paper [1].

Whether the pair (foo, fooh) is couth depends not only on foo and fooh, but also on the details of how arcfoo and arcfooh are defined.

In Python’s NumPy library, the pairs (sin, sinh) and (tan, tanh) are couth, but the pair (cos, cosh) is uncouth.

Numpy doesn’t define the reciprocal functions sec, sech, csc, csch, cot, and coth. I used to find that annoying, but I’m beginning to think that was wise. These functions cause problems. For example, there may be two reasonable ways to define these functions, one of which forms a couth pair and one of which forms an uncouth pair.

For example, how should you define cot and coth? There would be no disagreement over the definition

cot = lambda x: 1/tan(x)

but there are at least two definitions of inverse coth that you’ll find in practice:

arccot = lambda z: 0.5*pi - arctan(z)
arccot = lambda z: arctan(1/z).

Both definitions have their advantages, but the former is uncouth while the latter is couth. You can verify that both definitions are the same at z = 1 but not at z = −1.

With the following definitions, the pairs (cos, cosh) and (sec, sech) are uncouth and the rest are couth.

from numpy import *

csc     = lambda x: 1/sin(x)
sec     = lambda x: 1/cos(x)
cot     = lambda x: 1/tan(x)
csch    = lambda x: 1/sinh(x)
sech    = lambda x: 1/cosh(x)
coth    = lambda x: 1/tanh(x)

arccot  = lambda z: arctan(1/z)
arcsec  = lambda z: arccos(1/z)
arccsc  = lambda z: arcsin(1/z)
arccoth = lambda z: arctanh(1/z)
arcsech = lambda z: arccosh(1/z)
arccsch = lambda z: arcsinh(1/z)

[1] “According to Abramowitz and Stegun” or arccoth needn’t be uncouth. Robert M. Corless et al. ACM SIGSAM Bulletin, Volume 34, Issue 2, pp 58 – 65 https://doi.org/10.1145/362001.362023

Circular and hyperbolic functions differ by rotations

Posted on by John

The difference between a circular function and a hyperbolic function is a rotation or two.

For example, cosh(z) = cos(iz). You can read that as saying that to find the hyperbolic cosine of z, first you rotate z a quarter turn to the left (i.e. multiply by i) and then take the cosine.

For another example, sinh(z) = −i sin(iz). This says that you can calculate the hyperbolic sine of z by rotating z to the left, taking the sine, and then rotating to the right.

You can relate each trig function “foo” with its hyperbolic counterpart “fooh” by applying one of the functions to iz then multiplying by a constant c that depends on foo: ci for sin and tan, c = 1 for cos and sec, and c = −i for csc and cot.

Note that if the constant for foo is c, the constant for 1/foo is 1/c. So, for example, the constant for tan is i and the constant for cot is 1/i = −i.

We have four groups of equations, depending on whether the left side of the equation is foo(iz), fooh(iz), foo(z), or fooh(z).

This post was written as a warm-up for the next post on couth and uncouth function pairs.

foo(iz)

\begin{align*} \sin(iz) & = \phantom{-}i\sinh(z) \\ \cos(iz) & = \phantom{-i}\cosh(z) \\ \tan(iz) & = \phantom{-}i\tanh(z) \\ \csc(iz) & = -i\text{csch}(z) \\ \sec(iz) & = \phantom{-i}\text{sech}(z) \\ \cot(iz) & = -i\coth(z) \\ \end{align*}

fooh(iz)


\begin{align*} \sinh(iz) & = \phantom{-}i\sin(z) \\ \cosh(iz) & = \phantom{-i}\cos(z) \\ \tanh(iz) & = \phantom{-}i\tan(z) \\ \text{csch}(iz) & = -i\csc(z) \\ \text{sech}(iz) & = \phantom{-i}\sec(z) \\ \coth(iz) & = -i\cot(z) \\ \end{align*}

foo(z)

\begin{align*} \sin(z) & = -i\sinh(iz) \\ \cos(z) & = \phantom{-i}\cosh(iz) \\ \tan(z) & = -i\tanh(iz) \\ \csc(z) & = \phantom{-}i\text{csch}(iz) \\ \sec(z) & = \phantom{-i}\text{sech}(iz) \\ \cot(z) & = \phantom{-}i\coth(iz) \\ \end{align*}

fooh(z)

\begin{align*} \sinh(z) & = -i\sin(iz) \\ \cosh(z) & = \phantom{-i}\cos(iz) \\ \tanh(z) & = -i\tan(iz) \\ \text{csch}(z) & = \phantom{-}i\csc(iz) \\ \text{sech}(z) & = \phantom{-i}\sec(iz) \\ \coth(z) & = \phantom{-}i\cot(iz) \\ \end{align*}

Square root of x² − 1

Posted on by John

How should we define √(z² − 1)? Well, you could square z, subtract 1, and take the square root. What else would you do?!

The question turns out to be more subtle than it looks.

When x is a non-negative real number, √x is defined to be the non-negative real number whose square is x. When x is a complex number √x is defined to be a function that extends √x from the real line to the complex plane by analytic continuation. But we can’t extend √x as an analytic function to the entire complex plane ℂ. We have to choose to make a “cut” somewhere, and the conventional choice is to make a cut along the negative real axis.

Using the principal branch

The “principal branch” of the square root function is defined to be the unique function that analytically extends √x from the positive reals to ℂ \ (−∞, 0].

Assume for now that by √x we mean the principal branch of the square root function. Now what does √(z² − 1) mean? It could mean just what we said at the top of the post: we square z, subtract 1, and apply the (principal branch of the) square root function. If we do that, we must exclude those values of z such that (z² − 1) is negative. This means we have to cut out the imaginary axis and the interval [−1, 1].

This is what Mathematica will do when asked to evaluate Sqrt[z^2 - 1]. The command

ComplexPlot[Sqrt[z^2 - 1], {z, -2 - 2 I, 2 + 2 I}]

makes the branch cuts clear by abrupt changes in color.

A different approach

Now let’s take a different approach. Consider the function √(z² − 1) as a whole. Do not think of it procedurally as above, first squaring z etc. Instead, think of a it as a black box that takes in z and returns a complex number whose square is z² − 1.

This function has an obvious definition for z > 1. And we can extend this function, via analytic continuation, to more of the complex plane. We can do this directly, not by extending the square root function. But as before, we cannot extend the function analytically to all of ℂ. We have to cut something out. A common choice is to cut out [−1, 1]. This eliminates the need for a branch cut along the imaginary axis.

The function

f(z) = \exp\left( \tfrac{1}{2}\left( \log(z - 1) + \log(z + 1) \right) \right)

extends √(z² − 1) the way we want [1].

The Mathematica code

ComplexPlot[Exp[(1/2) (Log[z - 1 ] + Log[z + 1])], {z, -2 - 2 I, 2 + 2 I}]

shows that our function is now continuous across the imaginary axis, though there’s still a discontinuity as you cross [−1, 1].

We used this analytic extension of √(z² − 1) in the previous post to eliminate branch cuts in an identity.

Related posts

[1] The principal branch of the logarithm has a cut along the negative real axis. Why does our square root function, defined using log, not have a branch cut along the negative axis?

First of all, the log function, and Mathematica’s implementation of it Log[], isn’t undefined on (−∞, 1), it just isn’t continuous there. The function still has a value. By convention, the value is taken to be the limit of log(z) approaching z from above, i.e. from the 2nd quadrant.

Second, the value of (log(z – 1) + log(z + 1))/2 differs by a factor of 2πi when approaching a value z < −1 from above versus from below. This factor goes away when taking the exponential. So our function f(z) is analytic across (−∞, 1) even though the log functions in its definition are not.

Closer look at an identity

Posted on by John

The previous post derived the identity

\cosh\Big( \operatorname{arccosh}(x) + \operatorname{arccosh}(y)\Big) = xy + \sqrt{x^2 -1} \sqrt{y^2 -1}

and said in a footnote that the identity holds at least for x > 1 and y > 1. That’s true, but let’s see why the footnote is necessary.

Let’s have Mathematica plot

\left| \cosh\Big( \operatorname{arccosh}(x) + \operatorname{arccosh}(y)\Big) - xy - \sqrt{x^2 -1} \sqrt{y^2 -1} \right|

The plot will be 0 where the identity above holds.

The plot is indeed flat for x > 1 and y > 1, and more, but not everywhere.

If we combine the two square roots

\left| \cosh\Big( \operatorname{arccosh}(x) + \operatorname{arccosh}(y)\Big) - xy - \sqrt{(x^2 -1) (y^2 -1)} \right|

and plot again we still get a valid identity for x > 1 and y > 1, but the plot changes.

This is because √ab does not necessarily equal √(ab) when the arguments may be negative.

The square root function and the arccosh function are not naturally single-valued functions. They require branch cuts to force them to be single-valued, and the two functions require different branch cuts. I go into this in some detail here.

There is a way to reformulate our identity so that it holds everywhere. If we replace

\sqrt{z^2 - 1}

with

f(z) = \exp\left( \tfrac{1}{2}\left( \log(z - 1) + \log(z + 1) \right) \right)

which is equivalent for z > 1, the corresponding identity holds everywhere.

We can verify this with the following Mathematica code.

f[z_] := Exp[(1/2) (Log[z - 1 ] + Log[z + 1])]
FullSimplify[Cosh[ArcCosh[x] + ArcCosh[y]] - x y - f[x] f[y]]

This returns 0.

By contrast, the code

FullSimplify[
 Cosh[ArcCosh[x] + ArcCosh[y]] - x y - Sqrt[x^2 - 1] Sqrt[y^2 - 1]]

simply returns its input with no simplification, unless we add restrictions on x and y. The code

FullSimplify[
 Cosh[ArcCosh[x] + ArcCosh[y]] - x y - Sqrt[x^2 - 1] Sqrt[y^2 - 1], 
 Assumptions -> {x > -1 && y > -1}]

does return 0.

Related posts

Approximating Markov’s equation

Posted on by John

Markov numbers are integer solutions to

x² + y² + z² = 3xyz.

The Wikipedia article on Markov numbers mentions that Don Zagier studied Markov numbers by looking the approximating equation

x² + y² + z² = 3xyz + 4/9

which is equivalent to

f(x) + f(y) = f(z)

where f(t) is defined as arccosh(3t/2). It wasn’t clear to me why the two previous equations are equivalent, so I’m writing this post to show that they are equivalent.

Examples

Before showing the equivalence of Zagier’s two equations, let’s look at an example that shows solutions to his second equation approximate solutions to Markov’s equation.

The following code verifies that (5, 13, 194) is a solution to Markov’s equation.

x, y, z = 5, 13, 194
assert(x**2 + y**2 + z**2 == 3*x*y*z)

With the same x and y above, let’s show that the z in Zagier’s second equation is close to the z above.

from math import cosh, acosh

f = lambda t: acosh(3*t/2)
g = lambda t: cosh(t)*2/3
z = g(f(x) + f(y))
print(z)

This gives z = 194.0023, which is close to the value of z in the Markov triple above.

Applying Osborn’s rule

Now suppose

f(x) + f(y) = f(z)

which expands to

arccosh(3x/2) + arccosh(3y/2)  = arccosh(3z/2).

It seems sensible to apply cosh to both sides. Is there some identity for cosh of a sum? Maybe you recall the equation for cosine of a sum:

cos(ab) = cos(a) cos(b) − sin(a) sin(b).

Then Osborn’s rule says the corresponding hyperbolic identity is

cosh(ab) = cosh(a) cosh(b) − sinh(a) sinh(b).

Osborn’s rule also says that the analog of the familiar identity

sin²(a) + cos²(b) = 1

is

sinh²(a) = cosh²(b) − 1.

From these two hyperbolic identities we can show that [1]

cosh( arccosh(a) + arccosh(b) ) = ab + √(a² − 1) √(b² − 1).

Slug it out

The identity derived above is the tool we need to reduce our task to routine algebra.

If

arccosh(3x/2) + arccosh(3y/2)  = arccosh(3z/2)

then

(3x/2)  (3y/2)  + √((3x/2)² − 1) √((3y/2)² − 1) = 3z / 2

which simplifies to Zagier’s equation

x² + y² + z² = 3xyz + 4/9.

Related posts

[1] The equation holds at least for x > 1 and y > 1, which is enough for this post. More general arguments run into complications due to branch cuts.

Recovering the state of xorshift128

Posted on by John

I’ve written a couple posts lately about reverse engineering the internal state of a random number generator, first Mersenne Twister then lehmer64. This post will look at xorshift128, implemented below.

import random

# Seed the generator state
a: int = random.getrandbits(32)
b: int = random.getrandbits(32)
c: int = random.getrandbits(32)
d: int = random.getrandbits(32)

MASK = 0xFFFFFFFF

def xorshift128() -> int:
    global a, b, c, d

    t = d
    s = a

    t ^= (t << 11) & MASK t ^= (t >>  8) & MASK
    s ^= (s >> 19) & MASK

    a, b, c, d = (t ^ s) & MASK, a, b, c

    return a

Recovering state

Recovering the internal state of the generator is simple: it’s the four latest outputs in reverse order. This is illustrated by the following chart.

a b c d output 5081e5ca 79259a41 63e12955 651e537d c793d11c c793d11c 5081e5ca 79259a41 63e12955 ad52e33a ad52e33a c793d11c 5081e5ca 79259a41 f8f09343 f8f09343 ad52e33a c793d11c 5081e5ca a7009622 a7009622 f8f09343 ad52e33a c793d11c fe42a8ef

This means that once we’ve seen four outputs, we can predict the rest of the outputs. The following code demonstrates this.

Let’s generate five random values.

out = [xorshift128() for _ in range(5)]

Running

print(hex(out[4]))

shows the output 0xc3f4795d.

If we reset the state of the generator using the first four outputs

d, c, b, a, _ = out
print(hex(xorshift128()))

we get the same result.

Good stats, bad security

Mersenne Twister and lehmer64 have good statistical properties, despite being predictable. The xorshift128 generator is even easier to predict, but it also has good statistical properties. These generators would be fine for many applications, such as Monte Carlo simulation, but disastrous for use in cryptography.

The post on lehmer64 mentioned at the end that the internal state of PCG64 can also be recovered from its output. However, doing so requires far more sophisticated math and thousands of hours of compute time. Still, it’s not adequate for cryptography. For that you’d need a random number generator designed to be secure, such as ChaCha.

So why not just use a cryptographically secure random number generator (CSPRNG) for everything? You could, but the other generators mentioned in this post use less memory and are much faster. PCG64 occupies an interesting middle ground: simple and fast, but not easily reversible.

Initialize and print 128-bit integers in C

Posted on by John

If you look very closely at my previous post, you’ll notice that I initialize a 128-bit integer with a 64-bit value. The 128-bit unsigned integer represents the internal state of a random number generator. Why not initialize it to a 128-bit value? I was trying to keep the code simple.

A surprising feature of C compilers, at least of GCC and Clang, is that you cannot initialize a 128-bit integer to a 128-bit integer literal. You can’t directly print a 128-bit integer either, which is why the previous post introduces a function print_u128.

The code

__uint128_t x = 0x00112233445566778899aabbccddeeff;

Produces the following error message.

error: integer literal is too large to be represented in any integer type

The problem isn’t initializing a 128-bit number to a 128-bit value; the problem is that the compiler cannot parse the literal expression

0x00112233445566778899aabbccddeeff

One solution to the problem is to introduce the macro

#define U128(hi, lo) (((__uint128_t)(hi) << 64) | (lo))

and use it to initialize the variable.

__uint128_t x = U128(0x0011223344556677, 0x8899aabbccddeeff);

You can verify that x has the intended state by calling print_u128 from the previous post.

void print_u128(__uint128_t n)
{
    printf("0x%016lx%016lx\n",
           (uint64_t)(n >> 64),      // upper 64 bits
           (uint64_t)n);             // lower 64 bits
}

Then

print_u128(x);

prints

0x00112233445566778899aabbccddeeff

Update. The code for print_u128 above compiles cleanly with gcc but clang gives the following warning.

warning: format specifies type 'unsigned long' but the argument has type 'uint64_t' (aka 'unsigned long long') [-Wformat]

You can suppress the warning by including the inttypes header and modifying the print_u128 function.

Here’s the final code. It compiles cleanly under gcc and clang.

#include <stdio.h>
#include <stdint.h>
#include <inttypes.h>
#define U128(hi, lo) (((__uint128_t)(hi) << 64) | (lo))

void print_u128(__uint128_t n)
{
    printf("0x%016" PRIx64 "%016" PRIx64 "\n",
           (uint64_t)(n >> 64),
           (uint64_t)n);
}

int main(void)
{
    __uint128_t x = U128(0x0011223344556677, 0x8899aabbccddeeff);
    print_u128(x);
    return 0;
}