Haar wavelet

The Haar wavelet

Two iterations of the 2D Haar wavelet decomposition on the Lenna image. The original image is high-pass filtered, yielding the three detail coefficients subimages (top right: horizontal, bottom left: vertical, and bottom right: diagonal). It is then low-pass filtered and downscaled, yielding an approximation coefficients subimage (top left); the filtering process is repeated once again on this approximation image.

In mathematics, the Haar wavelet is a sequence of rescaled "square-shaped" functions which together form a wavelet family or basis. Wavelet analysis is similar to Fourier analysis in that it allows a target function over an interval to be represented in terms of an orthonormal basis. The Haar sequence is now recognised as the first known wavelet basis and extensively used as a teaching example.

The Haar sequence was proposed in 1909 by Alfréd Haar.^[1] Haar used these functions to give an example of an orthonormal system for the space of square-integrable functions on the unit interval [0, 1]. The study of wavelets, and even the term "wavelet", did not come until much later. As a special case of the Daubechies wavelet, the Haar wavelet is also known as Db1.

The Haar wavelet is also the simplest possible wavelet. The technical disadvantage of the Haar wavelet is that it is not continuous, and therefore not differentiable. This property can, however, be an advantage for the analysis of signals with sudden transitions, such as monitoring of tool failure in machines.^[2]

The Haar wavelet's mother wavelet function $\psi(t)$ can be described as

\psi (t)={\begin{cases}1\quad &0\leq t<{\frac {1}{2}},\\-1&{\frac {1}{2}}\leq t<1,\\0&{\mbox{otherwise.}}\end{cases}}

Its scaling function $\phi (t)$ can be described as

\phi (t)={\begin{cases}1\quad &0\leq t<1,\\0&{\mbox{otherwise.}}\end{cases}}

Haar functions and Haar system

For every pair n, k of integers in Z, the Haar function ψ_n, k is defined on the real line R by the formula

\psi _{{n,k}}(t)=2^{{n/2}}\psi (2^{n}t-k),\quad t\in {\mathbf {R}}.

This function is supported on the right-open interval I_{n, k} = [ k 2⁻ⁿ, (k+1) 2⁻ⁿ), i.e., it vanishes outside that interval. It has integral 0 and norm 1 in the Hilbert space L²(R),

\int _{{{\mathbf {R}}}}\psi _{{n,k}}(t)\,dt=0,\quad \|\psi _{{n,k}}\|_{{L^{2}({\mathbf {R}})}}^{2}=\int _{{{\mathbf {R}}}}\psi _{{n,k}}(t)^{2}\,dt=1.

The Haar functions are pairwise orthogonal,

\int _{{{\mathbf {R}}}}\psi _{{n_{1},k_{1}}}(t)\psi _{{n_{2},k_{2}}}(t)\,dt=\delta _{{n_{1},n_{2}}}\delta _{{k_{1},k_{2}}},

where δ_i,j represents the Kronecker delta. Here is the reason for orthogonality: when the two supporting intervals $I_{{n_{1},k_{1}}}$ and $I_{{n_{2},k_{2}}}$ are not equal, then they are either disjoint, or else, the smaller of the two supports, say $I_{{n_{1},k_{1}}}$ , is contained in the lower or in the upper half of the other interval, on which the function $\psi _{{n_{2},k_{2}}}$ remains constant. It follows in this case that the product of these two Haar functions is a multiple of the first Haar function, hence the product has integral 0.

The Haar system on the real line is the set of functions

\{\psi _{{n,k}}(t)\;;\;n\in {\mathbf {Z}},\;k\in {\mathbf {Z}}\}.

It is complete in L²(R): The Haar system on the line is an orthonormal basis in L²(R).

Haar wavelet properties

The Haar wavelet has several notable properties:

Any continuous real function with compact support can be approximated uniformly by linear combinations of $\phi (t),\phi (2t),\phi (4t),\dots ,\phi (2^{n}t),\dots$ and their shifted functions. This extends to those function spaces where any function therein can be approximated by continuous functions.
Any continuous real function on [0, 1] can be approximated uniformly on [0, 1] by linear combinations of the constant function 1, $\psi (t),\psi (2t),\psi (4t),\dots ,\psi (2^{n}t),\dots$ and their shifted functions.^[3]
Orthogonality in the form

$\int _{{-\infty }}^{{\infty }}2^{{(n+n_{1})/2}}\psi (2^{n}t-k)\psi (2^{{n_{1}}}t-k_{1})\,dt=\delta _{{n,n_{1}}}\delta _{{k,k_{1}}}.$

Here δ_i,j represents the Kronecker delta. The dual function of ψ(t) is ψ(t) itself.

Wavelet/scaling functions with different scale n have a functional relationship:^[4] since

{\begin{aligned}\phi (t)&=\phi (2t)+\phi (2t-1)\\[.2em]\psi (t)&=\phi (2t)-\phi (2t-1),\end{aligned}}

it follows that coefficients of scale n can be calculated by coefficients of scale n+1:

\chi _{w}(k,n)=2^{{n/2}}\int _{{-\infty }}^{{\infty }}x(t)\phi (2^{n}t-k)\,dt

and

\mathrm{X} _{w}(k,n)=2^{{n/2}}\int _{{-\infty }}^{{\infty }}x(t)\psi (2^{n}t-k)\,dt

then

\chi _{w}(k,n)=2^{{-1/2}}{\bigl (}\chi _{w}(2k,n+1)+\chi _{w}(2k+1,n+1){\bigr )}

\mathrm{X} _{w}(k,n)=2^{{-1/2}}{\bigl (}\chi _{w}(2k,n+1)-\chi _{w}(2k+1,n+1){\bigr )}.

Haar system on the unit interval and related systems

In this section, the discussion is restricted to the unit interval [0, 1] and to the Haar functions that are supported on [0, 1]. The system of functions considered by Haar in 1910,^[5] called the Haar system on [0, 1] in this article, consists of the subset of Haar wavelets defined as

\{t\in [0,1]\mapsto \psi _{{n,k}}(t)\;;\;n\in \mathbb{N} \cup \{0\},\;0\leq k<2^{n}\},

with the addition of the constant function 1 on [0, 1].

In Hilbert space terms, this Haar system on [0, 1] is a complete orthonormal system, i.e., an orthonormal basis, for the space L²([0, 1]) of square integrable functions on the unit interval.

The Haar system on [0, 1] —with the constant function 1 as first element, followed with the Haar functions ordered according to the lexicographic ordering of couples (n, k)— is further a monotone Schauder basis for the space L^p([0, 1]) when 1 ≤ p < ∞.^[6] This basis is unconditional when 1 < p < ∞.^[7]

There is a related Rademacher system consisting of sums of Haar functions,

r_{n}(t)=2^{{-n/2}}\sum _{{k=0}}^{{2^{n}-1}}\psi _{{n,k}}(t),\quad t\in [0,1],\ n\geq 0.

Notice that |r_n(t)| = 1 on [0, 1). This is an orthonormal system but it is not complete.^[8]^[9] In the language of probability theory, the Rademacher sequence is an instance of a sequence of independent Bernoulli random variables with mean 0. The Khintchine inequality expresses the fact that in all the spaces L^p([0, 1]), 1 ≤ p < ∞, the Rademacher sequence is equivalent to the unit vector basis in ℓ².^[10] In particular, the closed linear span of the Rademacher sequence in L^p([0, 1]), 1 ≤ p < ∞, is isomorphic to ℓ².

The Faber–Schauder system

The Faber–Schauder system^[11]^[12]^[13] is the family of continuous functions on [0, 1] consisting of the constant function 1, and of multiples of indefinite integrals of the functions in the Haar system on [0, 1], chosen to have norm 1 in the maximum norm. This system begins with s₀ = 1, then s₁(t) = t is the indefinite integral vanishing at 0 of the function 1, first element of the Haar system on [0, 1]. Next, for every integer n ≥ 0, functions s_n, k are defined by the formula

s_{{n,k}}(t)=2^{{1+n/2}}\int _{0}^{t}\psi _{{n,k}}(u)\,du,\quad t\in [0,1],\ 0\leq k<2^{n}.

These functions s_n, k are continuous, piecewise linear, supported by the interval I_n, k that also supports ψ_n, k. The function s_n, k is equal to 1 at the midpoint x_n, k of the interval I_n, k, linear on both halves of that interval. It takes values between 0 and 1 everywhere.

The Faber–Schauder system is a Schauder basis for the space C([0, 1]) of continuous functions on [0, 1].^[6] For every f in C([0, 1]), the partial sum

f_{{n+1}}=a_{0}s_{0}+a_{1}s_{1}+\sum _{{m=0}}^{{n-1}}{\Bigl (}\sum _{{k=0}}^{{2^{m}-1}}a_{{m,k}}s_{{m,k}}{\Bigr )}\in C([0,1])

of the series expansion of f in the Faber–Schauder system is the continuous piecewise linear function that agrees with f at the 2ⁿ + 1 points k 2⁻ⁿ, where 0 ≤ k ≤ 2ⁿ. Next, the formula

f_{{n+2}}-f_{{n+1}}=\sum _{{k=0}}^{{2^{n}-1}}{\bigl (}f(x_{{n,k}})-f_{{n+1}}(x_{{n,k}}){\bigr )}s_{{n,k}}=\sum _{{k=0}}^{{2^{n}-1}}a_{{n,k}}s_{{n,k}}

gives a way to compute the expansion of f step by step. Since f is uniformly continuous, the sequence {f_n} converges uniformly to f. It follows that the Faber–Schauder series expansion of f converges in C([0, 1]), and the sum of this series is equal to f.

The Franklin system

The Franklin system is obtained from the Faber–Schauder system by the Gram–Schmidt orthonormalization procedure.^[14]^[15] Since the Franklin system has the same linear span as that of the Faber–Schauder system, this span is dense in C([0, 1]), hence in L²([0, 1]). The Franklin system is therefore an orthonormal basis for L²([0, 1]), consisting of continuous piecewise linear functions. P. Franklin proved in 1928 that this system is a Schauder basis for C([0, 1]).^[16] The Franklin system is also an unconditional basis for the space L^p([0, 1]) when 1 < p < ∞.^[17] The Franklin system provides a Schauder basis in the disk algebra A(D).^[17] This was proved in 1974 by Bočkarev, after the existence of a basis for the disk algebra had remained open for more than forty years.^[18]

Bočkarev's construction of a Schauder basis in A(D) goes as follows: let f be a complex valued Lipschitz function on [0, π]; then f is the sum of a cosine series with absolutely summable coefficients. Let T(f) be the element of A(D) defined by the complex power series with the same coefficients,

\left\{f:x\in [0,\pi ]\rightarrow \sum _{{n=0}}^{\infty }a_{n}\cos(nx)\right\}\longrightarrow \left\{T(f):z\rightarrow \sum _{{n=0}}^{\infty }a_{n}z^{n},\quad |z|\leq 1\right\}.

Bočkarev's basis for A(D) is formed by the images under T of the functions in the Franklin system on [0, π]. Bočkarev's equivalent description for the mapping T starts by extending f to an even Lipschitz function g₁ on [−π, π], identified with a Lipschitz function on the unit circle T. Next, let g₂ be the conjugate function of g₁, and define T(f) to be the function in A(D) whose value on the boundary T of D is equal to g₁ + i g₂.

When dealing with 1-periodic continuous functions, or rather with continuous functions f on [0, 1] such that f(0) = f(1), one removes the function s₁(t) = t from the Faber–Schauder system, in order to obtain the periodic Faber–Schauder system. The periodic Franklin system is obtained by orthonormalization from the periodic Faber–-Schauder system.^[19] One can prove Bočkarev's result on A(D) by proving that the periodic Franklin system on [0, 2π] is a basis for a Banach space A_r isomorphic to A(D).^[19] The space A_r consists of complex continuous functions on the unit circle T whose conjugate function is also continuous.

Haar matrix

The 2×2 Haar matrix that is associated with the Haar wavelet is

H_{2}={\begin{bmatrix}1&1\\1&-1\end{bmatrix}}.

Using the discrete wavelet transform, one can transform any sequence $(a_{0},a_{1},\dots ,a_{{2n}},a_{{2n+1}})$ of even length into a sequence of two-component-vectors $\left(\left(a_{0},a_{1}\right),\dots ,\left(a_{{2n}},a_{{2n+1}}\right)\right)$ . If one right-multiplies each vector with the matrix $H_{2}$ , one gets the result $\left(\left(s_{0},d_{0}\right),\dots ,\left(s_{n},d_{n}\right)\right)$ of one stage of the fast Haar-wavelet transform. Usually one separates the sequences s and d and continues with transforming the sequence s. Sequence s is often referred to as the averages part, whereas d is known as the details part.^[20]

If one has a sequence of length a multiple of four, one can build blocks of 4 elements and transform them in a similar manner with the 4×4 Haar matrix

H_{4}={\begin{bmatrix}1&1&1&1\\1&1&-1&-1\\1&-1&0&0\\0&0&1&-1\end{bmatrix}},

which combines two stages of the fast Haar-wavelet transform.

Compare with a Walsh matrix, which is a non-localized 1/–1 matrix.

Generally, the 2N×2N Haar matrix can be derived by the following equation.

H_{{2N}}={\begin{bmatrix}H_{{N}}\otimes [1,1]\\I_{{N}}\otimes [1,-1]\end{bmatrix}}

where

I_{{N}}={\begin{bmatrix}1&0&\dots &0\\0&1&\dots &0\\\vdots &\vdots &\ddots &\vdots \\0&0&\dots &1\end{bmatrix}}

and

\otimes

is the Kronecker product.

The Kronecker product of $A\otimes B$ , where $A$ is an m×n matrix and $B$ is a p×q matrix, is expressed as

A\otimes B={\begin{bmatrix}a_{{11}}B&\dots &a_{{1n}}B\\\vdots &\ddots &\vdots \\a_{{m1}}B&\dots &a_{{mn}}B\end{bmatrix}}.

An un-normalized 8-point Haar matrix $H_{8}$ is shown below

H_{{8}}={\begin{bmatrix}1&1&1&1&1&1&1&1\\1&1&1&1&-1&-1&-1&-1\\1&1&-1&-1&0&0&0&0&\\0&0&0&0&1&1&-1&-1\\1&-1&0&0&0&0&0&0&\\0&0&1&-1&0&0&0&0\\0&0&0&0&1&-1&0&0&\\0&0&0&0&0&0&1&-1\end{bmatrix}}.

Note that, the above matrix is an un-normalized Haar matrix. The Haar matrix required by the Haar transform should be normalized.

From the definition of the Haar matrix $H$ , one can observe that, unlike the Fourier transform, $H$ has only real elements (i.e., 1, -1 or 0) and is non-symmetric.

Take the 8-point Haar matrix $H_{8}$ as an example. The first row of $H_{8}$ measures the average value, and the second row of $H_{8}$ measures a low frequency component of the input vector. The next two rows are sensitive to the first and second half of the input vector respectively, which corresponds to moderate frequency components. The remaining four rows are sensitive to the four section of the input vector, which corresponds to high frequency components.^[21]

Haar transform

The Haar transform is the simplest of the wavelet transforms. This transform cross-multiplies a function against the Haar wavelet with various shifts and stretches, like the Fourier transform cross-multiplies a function against a sine wave with two phases and many stretches.^[22]

Introduction

The Haar transform is one of the oldest transform functions, proposed in 1910 by the Hungarian mathematician Alfréd Haar. It is found effective in applications such as signal and image compression in electrical and computer engineering as it provides a simple and computationally efficient approach for analysing the local aspects of a signal.

The Haar transform is derived from the Haar matrix. An example of a 4x4 Haar transformation matrix is shown below.

H_{4}={\frac {1}{2}}{\begin{bmatrix}1&1&1&1\\1&1&-1&-1\\{\sqrt {2}}&-{\sqrt {2}}&0&0\\0&0&{\sqrt {2}}&-{\sqrt {2}}\end{bmatrix}}

The Haar transform can be thought of as a sampling process in which rows of the transformation matrix act as samples of finer and finer resolution.

Compare with the Walsh transform, which is also 1/–1, but is non-localized.

Property

The Haar transform has the following properties

1. No need for multiplications. It requires only additions and there are many elements with zero value in the Haar matrix, so the computation time is short. It is faster than Walsh transform, whose matrix is composed of +1 and −1.

2. Input and output length are the same. However, the length should be a power of 2, i.e.

N=2^{k},k\in {\mathbb {N}}

3. It can be used to analyse the localized feature of signals. Due to the orthogonal property of the Haar function, the frequency components of input signal can be analyzed.

Haar transform and Inverse Haar transform

The Haar transform y_n of an n-input function x_n is

y_{n}=H_{n}x_{n}

The Haar transform matrix is real and orthogonal. Thus, the inverse Haar transform can be derived by the following equations.

H=H^{*},H^{{-1}}=H^{T},{\text{i.e. }}HH^{T}=I

where

I

is the identity matrix. For example, when n = 4

H_{4}^{{T}}H_{4}={\frac {1}{2}}{\begin{bmatrix}1&1&{\sqrt {2}}&0\\1&1&-{\sqrt {2}}&0\\1&-1&0&{\sqrt {2}}\\1&-1&0&-{\sqrt {2}}\end{bmatrix}}\cdot \;{\frac {1}{2}}{\begin{bmatrix}1&1&1&1\\1&1&-1&-1\\{\sqrt {2}}&-{\sqrt {2}}&0&0\\0&0&{\sqrt {2}}&-{\sqrt {2}}\end{bmatrix}}={\begin{bmatrix}1&0&0&0\\0&1&0&0\\0&0&1&0\\0&0&0&1\end{bmatrix}}

Thus, the inverse Haar transform is

x_{{n}}=H^{{T}}y_{{n}}

Example

The Haar transform coefficients of a n=4-point signal $x_{{4}}=[1,2,3,4]^{{T}}$ can be found as

y_{{4}}=H_{4}x_{4}={\frac {1}{2}}{\begin{bmatrix}1&1&1&1\\1&1&-1&-1\\{\sqrt {2}}&-{\sqrt {2}}&0&0\\0&0&{\sqrt {2}}&-{\sqrt {2}}\end{bmatrix}}{\begin{bmatrix}1\\2\\3\\4\end{bmatrix}}={\begin{bmatrix}5\\-2\\-1/{\sqrt {2}}\\-1/{\sqrt {2}}\end{bmatrix}}

The input signal can then be perfectly reconstructed by the inverse Haar transform

{\hat {x_{{4}}}}=H_{{4}}^{{T}}y_{{4}}={\frac {1}{2}}{\begin{bmatrix}1&1&{\sqrt {2}}&0\\1&1&-{\sqrt {2}}&0\\1&-1&0&{\sqrt {2}}\\1&-1&0&-{\sqrt {2}}\end{bmatrix}}{\begin{bmatrix}5\\-2\\-1/{\sqrt {2}}\\-1/{\sqrt {2}}\end{bmatrix}}={\begin{bmatrix}1\\2\\3\\4\end{bmatrix}}

Application

Modern cameras are capable of producing images with resolutions in the range of tens of megapixels. These images need to be compressed before storage and transfer. The Haar transform can be used for image compression. The basic idea is to transfer the image into a matrix in which each element of the matrix represents a pixel in the image. For example, a 256×256 matrix is saved for a 256×256 image. JPEG image compression involves cutting the original image into 8×8 sub-images. Each sub-image is an 8×8 matrix.

The 2-D Haar transform is required. The equation of the Haar transform is $B_{{n}}=H_{{n}}A_{{n}}H_{{n}}^{{T}}$ , where $A_{n}$ is a n×n matrix and $H_{{n}}$ is n-point Haar transform. The inverse Haar transform is $A_{{n}}=H_{{n}}^{{T}}B_{{n}}H_{{n}}$

Notes

↑ see p. 361 in Haar (1910).
↑ Lee, B.; Tarng, Y. S. (1999). "Application of the discrete wavelet transform to the monitoring of tool failure in end milling using the spindle motor current". International Journal of Advanced Manufacturing Technology. 15 (4): 238–243. doi:10.1007/s001700050062.
↑ As opposed to the preceding statement, this fact is not obvious: see p. 363 in Haar (1910).
↑ Vidakovic, Brani (2010). Statistical Modeling by Wavelets (2 ed.). pp. 60, 63. doi:10.1002/9780470317020.
↑ p. 361 in Haar (1910)
1 2 see p. 3 in J. Lindenstrauss, L. Tzafriri, (1977), "Classical Banach Spaces I, Sequence Spaces", Ergebnisse der Mathematik und ihrer Grenzgebiete 92, Berlin: Springer-Verlag, ISBN 3-540-08072-4.
↑ The result is due to R. E. Paley, A remarkable series of orthogonal functions (I), Proc. London Math. Soc. 34 (1931) pp. 241-264. See also p. 155 in J. Lindenstrauss, L. Tzafriri, (1979), "Classical Banach spaces II, Function spaces". Ergebnisse der Mathematik und ihrer Grenzgebiete 97, Berlin: Springer-Verlag, ISBN 3-540-08888-1.
↑ "Orthogonal system". Encyclopaedia of Mathematics.
↑ Walter, Gilbert G.; Shen, Xiaoping (2001). Wavelets and Other Orthogonal Systems. Boca Raton: Chapman. ISBN 1-58488-227-1.
↑ see for example p. 66 in J. Lindenstrauss, L. Tzafriri, (1977), "Classical Banach Spaces I, Sequence Spaces", Ergebnisse der Mathematik und ihrer Grenzgebiete 92, Berlin: Springer-Verlag, ISBN 3-540-08072-4.
↑ Faber, Georg (1910), "Über die Orthogonalfunktionen des Herrn Haar", Deutsche Math.-Ver (in German) 19: 104–112. ISSN 0012-0456; http://www-gdz.sub.uni-goettingen.de/cgi-bin/digbib.cgi?PPN37721857X ; http://resolver.sub.uni-goettingen.de/purl?GDZPPN002122553
↑ Schauder, Juliusz (1928), "Eine Eigenschaft des Haarschen Orthogonalsystems", Mathematische Zeitschrift 28: 317–320.
↑ Golubov, B.I. (2001), "Faber–Schauder system", in Hazewinkel, Michiel, Encyclopedia of Mathematics, Springer, ISBN 978-1-55608-010-4
↑ see Z. Ciesielski, Properties of the orthonormal Franklin system. Studia Math. 23 1963 141–157.
↑ Franklin system. B.I. Golubov (originator), Encyclopedia of Mathematics. URL: http://www.encyclopediaofmath.org/index.php?title=Franklin_system&oldid=16655
↑ Philip Franklin, A set of continuous orthogonal functions, Math. Ann. 100 (1928), 522-529.
1 2 S. V. Bočkarev, Existence of a basis in the space of functions analytic in the disc, and some properties of Franklin's system. Mat. Sb. 95 (1974), 3–18 (Russian). Translated in Math. USSR-Sb. 24 (1974), 1–16.
↑ The question appears p. 238, §3 in Banach's book, Banach, Stefan (1932), Théorie des opérations linéaires, Monografie Matematyczne, 1, Warszawa: Subwencji Funduszu Kultury Narodowej, Zbl 0005.20901 . The disk algebra A(D) appears as Example 10, p. 12 in Banach's book.
1 2 See p. 161, III.D.20 and p. 192, III.E.17 in Wojtaszczyk, Przemysław (1991), Banach spaces for analysts, Cambridge Studies in Advanced Mathematics, 25, Cambridge: Cambridge University Press, pp. xiv+382, ISBN 0-521-35618-0
↑ Ruch, David K.; Van Fleet, Patrick J. (2009). Wavelet Theory: An Elementary Approach with Applications. John Wiley & Sons. ISBN 978-0-470-38840-2.
↑ "haar". Fourier.eng.hmc.edu. 2013-10-30. Retrieved 2013-11-23.
↑ The Haar Transform

References

Haar, Alfréd (1910), "Zur Theorie der orthogonalen Funktionensysteme", Mathematische Annalen, 69 (3): 331–371, doi:10.1007/BF01456326
Charles K. Chui, An Introduction to Wavelets, (1992), Academic Press, San Diego, ISBN 0-585-47090-1
English Translation of Haar's seminal article: https://www.uni-hohenheim.de/~gzim/Publications/haar.pdf

External links

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Hazewinkel, Michiel, ed. (2001), "Haar system", Encyclopedia of Mathematics, Springer, ISBN 978-1-55608-010-4
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Free Haar wavelet denoising and lossy signal compression

Haar transform

This article is issued from Wikipedia - version of the 6/3/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.

Haar wavelet

Haar functions and Haar system

Haar wavelet properties

Haar system on the unit interval and related systems

The Faber–Schauder system

The Franklin system

Haar matrix

Haar transform

Introduction

Property

Haar transform and Inverse Haar transform

Example

Application

See also

Notes

References

External links

Haar transform