Wavelets are versatile tools of harmonic analysis. Because of their many uses, the word `wavelet' comes with different connotations (and different promises) to users in different fields. Therefore we think it important to set from the beginning the limits of our approach, lest the user be disappointed by unfulfilled expectations.
The wavelet-based tools presented in this brochure are aimed specifically at a more thorough characterization - hopefully leading to better understanding - of experimental time-series. This process comprises three steps:
It is important to formulate these three steps as an unambiguous algorithm, so that the end result can be interpreted accordingly. Indeed, the user has great flexibility at each step. For someone trained in the well-worn grooves of Fourier analysis, so much freedom frequently appears arbitrary; the interplay of the user's options can lead to confusion -- or to creativity. The point is that, with each of many possible algorithms being formulated as a question, the interrogation of the data can be much more thorough. Each quantitative answer can be the basis for comparisons between data sets, or for glimpses of the underlying dynamics.
With this goal in mind, one of wavelets' claims to fame - data compaction - is not a dominant concern. Similarly, the computing time is important (particularly in the context of real-time processing), but not at the expense of physical relevance or richness of interpretation. Thus we find that much of the rapidly growing literature on wavelets has little impact on the present work, as `better wavelets' are either too specialized or have limitations from our viewpoint. We recommend that the non-mathematician reader interested in some rigorous background start with Meyer's little book (Meyer, 1993) or the first three chapters of Daubechies' (Daubechies, 1992).