Complex analysis

Ramanujan’s master theorem

Posted on by John

Ramanujan's passport photo from 1913

A few weeks ago I wrote about the Mellin transform. Mitchell Wheat left comment saying the transform seems reminiscent of Ramanujan’s master theorem, which motivated this post.

Suppose you have a function f that is nice enough to have a power series.

f(z) = \sum_{k=0}^\infty a_k z^k

Now focus on the coefficients ak as a function of k. We’ll introduce a function φ that yields the coefficients, with a twist.

f(z) = \sum_{k=0}^\infty \frac{\varphi(k)}{k!} (-z)^k

and so φ(k) = (−1)k k! ak. Another way to look at it is that f is the exponential generating function of (−1)k φ(k).

Then Ramanujan’s master theorem gives a formula for the Mellin transform of f:

\int_0^\infty z^{s-1} f(z) \, dz = \Gamma(s) \varphi(-s)

This equation was the basis of many of Ramanujan’s theorems.

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Laplace transform inversion theorems

Posted on by John

The way Laplace transforms, as presented in a typical differential equation course, are not very useful. Laplace transforms are useful, but not as presented.

The use of Laplace transforms is presented is as follows:

  1. Transform your differential equation into an algebraic equation.
  2. Solve the algebraic equation.
  3. Invert the transform to obtain your solution.

This is correct, but step 3 is typically presented in a misleading way. For pedagogical reasons, students are only given problems for which the last step is easy. They’re given a table with functions on the left and transforms on the right, and you compute an inverse transform by recognizing the result of step 2 in the right column.

Because of the limitations listed above, Laplace transforms, as presented in an introductory course, can only solve problems that could just as easily be solved by other methods presented in the same course.

What good is it, in an undergraduate classroom setting, if you reduce a problem to inverting a Laplace transform but the inverse problem doesn’t have a simple solution?

Of course in practice, rather than in a classroom, it might be very useful to reduce a complicated problem to the problem of inverting a Laplace transform. The latter problem may not be trivial, but it’s a standard problem. You could ask someone to solve the inversion problem who does not understand where the transform of the solution came from.

Laplace inversion theorem

The most well-known Laplace inversion theorem states that if f is a function and F is the Laplace transform of f, then you can recover f from F via the following integral.

f(x) = \frac{1}{2\pi i} \int_{c -\infty i}^{c + \infty i} \exp(sx) \, F(s)\, ds

It’s understandable that you wouldn’t want to present this to most differential equation students. It’s not even clear what the right hand side means, much less how you would calculate it. As for what it means, it says you can calculate the integral along any line parallel to the imaginary axis. In practice, the integral may be evaluated using contour integration, in particular using the so-called Bromwich contour.

It might be difficult to invert the Laplace transform, either numerically or analytically, but at least this is a separate problem from whatever led to this. Maybe the original problem was more difficult, such as a complicated delay differential equation.

Post-Widder theorem

There is a lesser-known theorem for inverting a Laplace transform, the Post-Widder theorem. It says

f(x) = \lim_{n\to\infty} \frac{(-1)^n}{n!} \left( \frac{n}{x} \right)^{n+1} F^{(n)}\left( \frac{n}{x} \right)

where F(n) is the nth derivative of F. This may not be an improvement—it might be much worse than evaluating the integral above—but it’s an option. It doesn’t involve functions of a complex variable, so in that sense it is more elementary [1].

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[1] The use of the word elementary in mathematics can be puzzling. Particularly in the context of number theory, elementary essentially means “without using complex variables.” An elementary proof may be far more difficult to follow than a proof using complex variables.

Shifted reciprocal

Posted on by John

It’s interesting to visualize functions of a complex variable, even very simple functions like f(z) = 1/z. The previous post looked at what happens to triangles under the reciprocal map w = 1/z. This post will look at the same map applied to a polar grid, then look at the effect a shift has, replacing 1/z with 1/(zc).

The function 1/z is a Möbius transformation, and so it maps lines and circles to lines and circles. And in the case of a polar grid, lines go to lines and circles go to circles. The overall grid is unchanged, even though circles swap places with other circles, and lines swap places with other lines. To see this, note that

1/reiθ = (1/r)eiθ

This means that the function 1/z maps a circle of radius r to a circle of radius 1/r, and it maps a line of slope m to a line of slope −1/m.

Things get more interesting when we shift the reciprocal function to w = 1/(zc). Now lines will map to circles, unless the line passes through c. Circles will still map to circles, unless the circle passes through c, but we won’t have circles swapping places because the function 1/(zc) is not its own inverse, unlike 1/z. Here’s a plot with c = 0.1.

Note that circles map to circles, but the center of a circle does not necessarily map to the center of the image circle. So the green circles in the z-plane map to green circles in the w-plane, but the circles in the z-plane are concentric while their images in the w-plane are not.

The blue lines in the z-plane become blue circles in the w-plane, though some of the circles are too large to fit in the frame of the plot.

As we discussed in the previous post, Möbius transformations are easier to discuss if you adjoint a point at infinity to the complex plane. The radial lines in the z-plane all meet at ∞, and so their images in the w-plane all meet at 1/(∞ – c) = 0.

One final thing to note is that however small ε > 0 is, the images of the grid lines are very different under 1/(z − ε) compared to 1/z. Individual z‘s that start out close together are mapped to w‘s that are close together, but the images of the system of lines and circles is qualitatively different for ε > 0 versus ε = 0.

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Triangles to Triangles

Posted on by John

The set of functions of the form

f(z) = (az + b)/(cz + d)

with adbc are called bilinear transformations or Möbius transformations. These functions have three degrees of freedom—there are four parameters, but multiplying all parameters by a constant defines the same function—and so you can uniquely determine such a function by picking three points and specifying where they go.

Here’s an explicit formula for the Möbius transformation that takes z1, z2, and z3 to w1, w2, and w3.

\begin{vmatrix} 1 & z & w & zw \\ 1 & z_1 & w_1 & z_1w_1 \\ 1 & z_2 & w_2 & z_2w_2 \\ 1 & z_3 & w_3 & z_3w_3 \\ \end{vmatrix} = 0

To see that this is correct, or at least possible, note that if you set z = zi and w = wi for some i then two rows of the matrix are equal and so the determinant is zero.

Triangles, lines, and circles

You can pick three points in one complex plane, the z-plane, and three points in another complex plane, the w-plane, and find a Möbius transformation w = f(z) taking the z-plane to the w-plane sending the specified z‘s to the specified w‘s.

If you view the three points as vertices of a triangle, you’re specifying that one triangle gets mapped to another triangle. However, the sides of your triangle may or may not be straight lines.

Möbius transformations map circles and lines to circles and lines, but a circle might become a line or vice versa. So the straight lines of our original triangle may map to straight lines or they may become circular arcs. How can you tell whether the image of a side of a triangle will be straight or curved?

When does a line map to a line?

It’ll be easier if we add a point ∞ to the complex plane and think of lines as infinitely big circles, circles that pass through ∞.

The Möbius transformation (az + b)/(cz + d) takes ∞ to a/c and it takes −d/c to ∞.

The sides of a triangle are line segments. If we look at the entire line, not just the segment, then this line is mapped to a circle. If this line contains the point that gets mapped to ∞ then the image of the line is an infinite circle (i.e. a line). Otherwise the image of the line is a finite circle.

The line between z1 and  z2 can be parameterized by

z1 + t(z2z1)

where t is real. So the image of this line will be a line if and only if

z1 + t(z2z1) = −d/c

for some real t. So solve for t and see whether you get a real number.

Note that if the point that is mapped to ∞ lies inside the line segment, not just on the line, then the image of that side of the triangle is infinitely long.

Examples

To keep things as simple as possible without being trivial, we’ll use the Möbius transformation f(z) = 1/z. Clearly the origin is the point that is mapped to ∞. The side of a triangle is mapped to a straight line if and only if the side is part of a line through the origin.

First let’s look at the triangle with vertices at (1, 1), (1, 4), and (5, 1). None of the sides is on a line that extends to the origin, so all sides map to circular arcs.

Next let’s move the second point from (1, 4) to (4, 4). The line running between (1, 1) and (4, 4) goes through the origin, and so the segment along that line maps to a straight line.

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Computing logarithms of complex numbers

Posted on by John

The previous post showed how to compute logarithms using tables. It gives an example of calculating a logarithm to 15 figures precision using tables that only allow 4 figures of precision for inputs.

Not only can you bootstrap tables to calculate logarithms of real numbers not given in the tables, you can also bootstrap a table of logarithms and a table of arctangents to calculate logarithms of complex numbers.

One of the examples in Abramowitz and Stegun (Example 7, page 90) is to compute log(2 + 3i). How could you do that with tables? Or with a programming language that doesn’t support complex numbers?

What does this even mean?

Now we have to be a little careful about what we mean by the logarithm of a complex number.

In the context of real numbers, the logarithm of a real number x is the real number y such that ey = x. This equation has a unique solution if x is positive and no solution otherwise.

In the context of complex numbers, a logarithm of the complex number z is any complex number w such that ew = z. This equation has no solution if z = 0, and it has infinitely many solutions otherwise: for any solution w, w + 2nπi is also a solution for all integers n.

Solution

If you write the complex number z in polar form

z = r eiθ

then

log(z) = log(r) + iθ.

The proof is immediate:

elog(r) + iθ = elog(r) eiθ = r eiθ.

So computing the logarithm of a complex number boils down to computing its magnitude r and its argument θ.

The equation defining a logarithm has a unique solution if we make a branch cut along the negative real axis and restrict θ to be in the range −π < θ ≤ π. This is called the principal branch of log, sometimes written Log. As far as I know, every programming language that supports complex logarithms uses the principal branch implicitly. For example, in Python (NumPy), log(x) computes the principal branch of the log function.

Example

Going back to the example mentioned above,

log(2 + 3i) = log( √(2² + 3²) ) + arctan(3/2) = ½ log(13) + arctan(3/2) i.

This could easily be computed by looking up the logarithm of 13 and the arc tangent of 3/2.

The exercise in A&S actually asks the reader to calculate log(±2 ± 3i). The reason for the variety of signs is to require the reader to pick the value of θ that lies in the range −π < θ ≤ π. For example,

log(−2 + 3i) =  = ½ log(13) + (π − arctan(3/2)) i.

Numerical application of mean value theorem

Posted on by John

Suppose you’d like to evaluate the function

u(z) = \frac{e^z - 1 - z}{z^2}

for small values of z, say z = 10−8. This example comes from [1].

The Python code

    from numpy import exp
    def f(z): return (exp(z) - 1 - z)/z**2
    print(f(1e-8))

prints -0.607747099184471.

Now suppose you suspect numerical difficulties and compute your result to 50 decimal places using bc -l.

    scale = 50
    z = 10^-8
    (e(z) - 1 - z)/z^2

Now you get u(z) = .50000000166666667….

This suggests original calculation was completely wrong. What’s going on?

For small z,

ez ≈ 1 + z

and so we lose precision when directly evaluating the numerator in the definition of u. In our example, we lost all precision.

The mean value theorem from complex analysis says that the value of an analytic function at a point equals the continuous average of the values over a circle centered at that point. If we approximate this average by taking the average of 16 values in a circle of radius 1 around our point, we get full accuracy. The Python code

    def g(z):
        N = 16
        ws = z + exp(2j*pi*arange(N)/N)
        return sum(f(ws))/N

returns

    0.5000000016666668 + 8.673617379884035e-19j

which departs from the result calculated with bc in the 16th decimal place.

At a high level, we’re avoiding numerical difficulties by averaging over points far from the difficult region.

 

[1] Lloyd N. Trefethen and J. A. C. Weideman. The Exponentially Convergent Trapezoid Rule. SIAM Review. Vol. 56, No. 3. pp. 385–458.

Numerical differentiation with a complex step

Posted on by John

The most obvious way to approximate the derivative of a function numerically is to use the definition of derivative and stick in a small value of the step size h.

f′ (x) ≈ ( f(x + h) − f(x) ) / h.

How small should h be? Since the exact value of the derivative is the limit as h goes to zero, the smaller h is the better. Except that’s not true in computer arithmetic. When h is too small, f(x + h) is so close to f(x) that the subtraction loses precision.

One way to see this is to think of the extreme case of h so small that f(x + h) equals f(x) to machine precision. Then the derivative is approximated by 0, regardless of what the actual derivative is.

As h gets smaller, the approximation error decreases, but the numerical error increases, and so there is some optimal value of h.

You can do significantly better by using a symmetric approximation for the derivative:

f′ (x) ≈ ( f(x + h) − f(xh) ) / 2h.

For a given value of h, this formula has about the same numerical error but less approximation error. You still have a trade-off between approximation error and numerical error, but it’s a better trade-off.

If the function f that you want to differentiate is analytic, i.e. differentiable as a function of a complex variable, you can take the step h to be a complex number. When you do, the numerical difficulty completely goes away, and you can take h much smaller.

Suppose h is a small real number and you take

f′ (x) ≈ ( f(x + ih) − f(xih) ) / 2ih.

Now f(x + ih) and −f(xih) are approximately equal by the Schwarz reflection principle. And so rather than canceling out, the terms in the numerator add. We have

f(x + ih) − f(xih) ≈ 2 f(x + ih)

and so

f′ (x) ≈ f(x + ih) / ih.

Example

Let’s take the derivative of the gamma function Γ(x) at 1 using each of the three methods above. The exact value is −γ where γ is the Euler-Mascheroni constant. The following Python code shows the accuracy of each approach.

    from scipy.special import gamma

    def diff1(f, x, h):
        return (f(x + h) - f(x))/h

    def diff2(f, x, h):
        return (f(x + h) - f(x - h))/(2*h)

    γ = 0.5772156649015328606065

    x     = 1
    h     = 1e-7
    exact = -γ

    approx1 = diff1(gamma, x, h)
    approx2 = diff2(gamma, x, h)
    approx3 = diff2(gamma, x, h*1j)

    print(approx1 - exact)
    print(approx2 - exact)
    print(approx3 - exact)

This prints

    9.95565755390615e-08
    1.9161483510998778e-10
    (9.103828801926284e-15-0j)

In this example the symmetric finite difference approximation is about 5 times more accurate than the asymmetric approximation, but the complex step approximation is 10,000,000 times more accurate.

It’s a little awkward that the complex step approximation returns a complex number, albeit one with zero complex part. We can eliminate this problem by using the approximation

f′ (x) ≈ Im f(x + ih) / h

which will return a real number. When we implement this in Python as

    def diff3(f, x, h):
        return (f(x + h*1j) / h).imag

we see that it produces the same result as diff2 but without the zero imaginary part.

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Hypergeometric function of a large negative argument

Posted on by John

It’s occasionally necessary to evaluate a hypergeometric function at a large negative argument. I was working on a project today that involved evaluating F(a, b; c; z) where z is a large negative number.

The hypergeometric function F(a, b; c; z) is defined by a power series in z whose coefficients are functions of a, b, and c. However, this power series has radius of convergence 1. This means you can’t use the series to evaluate F(a, b; c; z) for z < −1.

It’s important to keep in mind the difference between a function and its power series representation. The former may exist where the latter does not. A simple example is the function f(z) = 1/(1 − z). The power series for this function has radius 1, but the function is defined everywhere except at z = 1.

Although the series defining F(a, b; c; z) is confined to the unit disk, the function itself is not. It can be extended analytically beyond the unit disk, usually with a branch cut along the real axis for z ≥ 1.

It’s good to know that our function can be evaluated for large negative x, but how do we evaluate it?

Linear transformation formulas

Hypergeometric functions satisfy a huge number of identities, the simplest of which are known as the linear transformation formulas even though they are not linear transformations of z. They involve bilinear transformations z, a.k.a. fractional linear transformations, a.k.a. Möbius transformations. [1]

One such transformation is the following, found in A&S 15.3.4 [2].

F(a, b; c; z) = (1-z)^{-a} F\left(a, c-b; c; \frac{z}{z-1} \right)

If z < 1, then 0 < z/(z − 1) < 1, which is inside the radius of convergence. However, as z goes off to −∞, z/(z − 1) approaches 1, and the convergence of the power series will be slow.

A more complicated, but more efficient, formula is A&S 15.3.7, a linear transformation formula relates F at z to two other hypergeometric functions evaluated at 1/z. Now when z is large, 1/z is small, and these series will converge quickly.

\begin{align*} F(a, b; c; z) &= \frac{\Gamma(c) \Gamma(b-a)}{\Gamma(b) \Gamma(c-a)} \,(-z)^{-a\phantom{b}} F\left(a, 1-c+a; 1-b+a; \frac{1}{z}\right) \\ &+ \frac{\Gamma(c) \Gamma(a-b)}{\Gamma(a) \Gamma(c-b)} \,(-z)^{-b\phantom{a}} F\left(\,b, 1-c+b; 1-a+b; \,\frac{1}{z}\right) \\ \end{align*}

Related posts

[1] It turns out these transformations are linear, but not as functions of a complex argument. They’re linear as transformations on a projective space. More on that here.

[2] A&S refers to the venerable Handbook of Mathematical Functions by Abramowitz and Stegun.

When zeros at natural numbers implies zero everywhere

Posted on by John

Suppose a function f(z) equals 0 at z = 0, 1, 2, 3, …. Under what circumstances might you be able to conclude that f is zero everywhere?

Clearly you need some hypothesis on f. For example, the function sin(πz) is zero at every integer but certainly not constantly zero.

Carlson’s theorem says that if f is analytic and bounded for z with non-negative real part, and equals zero at non-negative integers, then f is constantly zero.

Carlson’s theorem doesn’t apply to sin(πz) because this function is not bounded in the complex plane. It is bounded on the real axis, but that’s not enough. The identity

sin(z) = ( exp(iz) – exp(-iz) ) / 2i

shows that the sine function grows exponentially in the vertical direction.

Liouville’s theorem says that if a function is analytic and bounded everywhere then it must be constant. Carleson’s theorem does not require that the function f be bounded everywhere but in the right half-plane.

In fact, the boundedness requirement can be weakened to requiring f(z) be O( exp(k|z|) ) for some k < π. This, in combination with having zeros at 0, 1, 2, 3, …. is enough to conclude that f is zero.

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Conformal map between disk and equilateral triangle

Posted on by John

The Dixon elliptic functions sm and cm are in some ways analogous to sine and cosine. However, whereas sine and cosine satisfy

\sin^2(z) + \cos^2(z) = 1

the Dixon functions satisfy

\text{sm}^3(z) + \text{cm}^3(z) = 1

The exponent 3 foreshadows the fact that these functions have a sort of three-fold symmetry. In particular, the function sm maps an equilateral triangle in the complex plane to the unit circle. The function sm gives a conformal map from the interior of this circle to the interior of the unit disk.

In this post we will work with sm−1 rather than sm, mapping the unit circle to an equilateral triangle. An advantage of working with the inverse function is that we can start with the unit circle and see what triangle it maps to; if we started with the triangle it might seem arbitrary. Also, the function sm is not commonly part of mathematical software libraries—it’s not in Mathematica or SciPy—but you can compute its inverse via

\text{sm}^{-1}(z) = {}_2F_1(\tfrac{1}{3}, \tfrac{2}{3}; \tfrac{4}{3}; z^3) \, z

using the hypergeometric function 2F1, which is a common part of mathematical libraries.

The following image shows concentric circles in the z plane and their image under sm−1 in the w plane, w = sm−1(z).

Conformal map of unit disk to equilateral triangle using the inverse of the Dixon elliptic function sm

If we were to use this in applications, we’d need to know the vertices of the image triangle so we could do a change of variables to transform this triangle into a particular triangle we’re interested in.

The centroid of the image is at the origin, and the right-most vertex is at approximately 1.7666. To be exact, the vertex is at

v = ⅓ B(⅓, ⅓)

where B is the beta function. (Notice all the 3’s in the formula for v.) The other two vertices are at exp(2π/3)v and exp(4πi/3) v.

One way this conformal map could arise in practice is solving Laplace’s equation on a triangle. You can solve Laplace’s equation on a disk in closed form, and transform that solution into a solution on the triangle.

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