Advanced Concepts (Wavelet Toolbox)

Wavelet Toolbox

Wavelets and Associated Families

In the one-dimensional context, we distinguish the wavelet from the associated function , called the scaling function. Some properties of and are

The integral of is zero,

, and is used to define the details.
The integral of is 1,

, and is used to define the approximations.

The usual two-dimensional wavelets are defined as tensor products of one-dimensional wavelets: is the scaling function and

are the three wavelets.

The following figure shows the four functions associated with the two-dimensional coif2 wavelet.

Figure 6-2: Two-Dimensional coif2 Wavelet

To each of these functions, we associate its doubly indexed family, which is used to

Move the basic shape from one side to the other, translating it to position b (see the following figure).
Keep the shape while changing the one-dimensional time scale a () (see Figure 6-4,).

So a wavelet family member has to be thought as a function located at a position b, and having a scale a.

In one-dimensional situations, the family of translated and scaled wavelets associated with is expressed as follows.

Translation
Change of Scale
Translation and Change of Scale

(x-b)

Translation	Change of Scale	Translation and Change of Scale
(x-b)

Figure 6-3: Translated Wavelets

Figure 6-4: Time Scaled One-Dimensional Wavelet

In a two-dimensional context, we have the translation by vector and a change of scale of parameter .

Translation and change of scale become

In most cases, we will limit our choice of a and b values by using only the following discrete set (coming back to the one-dimensional context):

Let us define

We now have a hierarchical organization similar to the organization of a decomposition; this is represented in the example of Figure 6-5, Wavelets Organization. Let k = 0 and leave the translations aside for the moment. The functions associated with j = 0, 1, 2, 3 for (expressed as _j_,0) and with j = 1, 2, 3 for (expressed as _j_,0) are displayed in the following figure for the db3 wavelet.

Figure 6-5: Wavelets Organization

In Figure 6-5, Wavelets Organization, the four-level decomposition is shown, progressing from the top to the bottom. We find _0,0; then 2^1/2_1,0, 2^1/2_1,0; then 2_2,0, 2_2,0; then 2^3/2_3,0, 2^3/2_3,0. The wavelet is db3.

Wavelet Shapes Wavelet Transforms: Continuous and Discrete