SIO239: Math Methods for Geophysics, 2008

Instructors: Glenn Ierley and Bob Parker

Fourier Series

The first topic is Fourier series. The material is also covered in Chapters 12 and 13 of Mathematical Methods for Physics and Engineering by Riley, Hobson and Bence, the main text for the course. However, I will take a different approach, and so I will provide detailed notes that you will be able to download from this site. The class will be given as a series of lectures, at a time to be determined. I treat Fourier series as a particular example of expansion in an orthogonal basis on a Hilbert space. Without getting too abstract, we can get a lot of insight by treating the general situtation, mostly on a finite real interval. So we will see inner products, and norms, Schwarz's inequality, Parseval's theorem, self adjoint operators and their eigenfunctions. We can illustrate the general concepts with expansions in sines and cosines (Fourier series), orthogonal polynomials, spherical harmonics and orthogonal taper functions used in the estimation of power spectra. But Fourier series are still the simplest kind and so we give some explicit series and study different modes of convergence, including a discussion of Gibbs' phenomenon.

Fourier Transforms

Here I follow the traditional motivation that the Fourier transform decomposes a function into components with different frequencies. I derive or state a number elementary properties, such as 2-norm invariance, transformation under scaling and a shift of origin. We calculate a number of explicit transforms, for functions such as the box car and the Gaussian. Then we discuss convolution and the Convolution theorem and its implications for the impulse and frequency responses of a simple seismometer. The numerical approximation of the transform with the FFT and the trapezoidal rule is developed, which brings in the amazing Poisson Sum Rule. The Fourier transform in two or more dimensions is explained, with an introduction to the special properties connected with circular symmetry about the origin, and the Hankel transform. Finally, if time permits, we take a peek at distribution theory and the mathematics connected with generalized functions, such as the infamous delta function.