0.2 Multiresolution analysis and wavelets (Page 2/2)

An introduction to wavelet Page 2 / 2

Theorem ( [link] , Theorem 5.1.1) If a sequence of closed subspaces

{(V_{j})}_{j \in Z}

L_{2} (R)

satisfies [link] , and if, in addition,

{ϕ (x - k), k \in Z}

is an orthogonal basis for

V_{0}

, then there exists one function

ψ (x)

such that

{ψ (x - k); k \in Z}

forms an orthogonal basis for the orthogonal complement

W_{0}

V_{0}

V_{1}

An immediate consequence of [link] is that ${ψ_{j k}, k \in Z}$ constitutes an orthogonal basis for the orthogonal complement $W_{j}$ of $V_{j}$ in $V_{j + 1}$ . In this section, let $P_{j}$ (resp. $Q_{j}$ ) be the orthogonal projection operator onto $V_{j}$ (resp. $W_{j}$ ). The orthogonal expansion

\begin{matrix} f & = & P_{j_{0}} f + \sum_{j = j_{0}}^{\infty} Q_{j} f \\ = & \sum_{k} 〈f, ϕ_{j_{0}, k}〉 ϕ_{j_{0}, k} + \sum_{j = j_{0}}^{\infty} \sum_{k} 〈f, ψ_{j k}〉 ψ_{j k} \end{matrix}

tells us that a first, coarse approximation of $f$ in $V_{j_{0}}$ is further refined with the projection of $f$ onto the detail spaces $W_{j}$ .

[link] shows two examples of orthogonal wavelet functions. The first is the Haar wavelet, associated to the Haar scaling function defined in "Definition of subspaces V j and of scaling functions" .

ψ {(x)}^{Haar} = 2^{- 1 / 2} (ϕ^{Haar} (2 x - 1) - ϕ^{Haar} (2 x)) = 1_{[\frac{1}{2}, 1)} (x) - 1_{[0, \frac{1}{2})} (x) .

The Haar wavelet has only one vanishing moment and consequently is optimal only to represent functions having a low degree of regularity, like, for example, $β -$ Hölder functions with $0 < β < 1$ .

Daubechies constructed in [link] , [link] compactly supported wavelets which have more than one vanishing moment. Compactly supported wavelets are desirable from a numerical point of view, while having more than one vanishing moment allows to reconstruct exactly polynomials of higher order. These wavelets cannot, in general, be written in a closed analytic form. However, their graph can be computed with arbitrarily high precision using a subdivision scheme algorithm. [link] (b) represents the Daubechies Least Asymmetric wavelet with $N = 4$ vanishing moments.

This figure also illustrates the reason behind the name `wavelet': since wavelets are functions with a certain number of vanishing moments, they have the shape of a `little wave' or `wavelet'.

Biorthogonal bases

Having an orthogonal MRA puts strong constraints on the construction of a wavelet basis. For example, the Haar wavelet is the only real-valued function which is compactly supported and symmetric.However, if we relax orthogonality for biorthogonality , then it becomes possible to have real-valued wavelet bases of fixed but arbitrary high order (see Definition 1 from Approximation of Functions ) which are symmetric and compactly supported [link] . In a biorthogonal setting, a dual scaling function $\tilde{ϕ}$ and a dual wavelet function $\tilde{ψ}$ exist. They generate a dual MRA with subspaces ${\tilde{V}}_{j}$ and complement spaces ${\tilde{W}}_{j}$ such that

{\tilde{V}}_{j} ⊥ W_{j} and V_{j} ⊥ {\tilde{W}}_{j} .

In other words,

〈\tilde{ϕ}, ψ (\cdot - k)〉 = 0 and 〈ϕ, \tilde{ψ} (\cdot - k)〉 = 0

Moreover, the dual functions also have to satisfy

〈\tilde{ϕ}, ϕ (\cdot - k)〉 = δ_{k, 0} and 〈\tilde{ψ}, ψ (\cdot - k)〉 = δ_{k, 0},

where $δ_{k, 0}$ is the Kronecker symbol. By construction, the dual scaling and wavelet functions satisfy a refinement equation, similarly to the equations [link] and [link] .

In this work, we use the following convention: the dual MSD will be used to decompose a function (or a signal), while the original, or primal MSD reconstructs the function. This yields the following representation of a function $f \in L_{2} (R)$

f (x) = \sum_{k} 〈f, {\tilde{ϕ}}_{j_{0}, k}〉 ϕ_{j_{0}, k} (x) + \sum_{j = j_{0}}^{\infty} \sum_{k} 〈f, {\tilde{ψ}}_{j k}〉 ψ_{j k} (x) .

[link] shows an example of a biorthogonal wavelet basis built by Cohen, Daubechies and Feauveau in [link] , (called CDF-wavelets hereafter).

Primal and dual scaling and wavelet functions for the (3,1)-Cohen-Daubechies-Feauveau (CDF) biorthogonal basis. The primal wavelet function $ψ$ has one vanishing moment while the dual wavelet $\tilde{ψ}$ has three vanishing moments.

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Source: OpenStax, An introduction to wavelet analysis. OpenStax CNX. Sep 14, 2009 Download for free at http://cnx.org/content/col10566/1.3

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