On spaces of periodic functions with wavelet transforms

Some boundedness results for the wavelet transform on $F_p([0,1]^n)$ and $F_p^*([0,1]^n)$, the spaces of periodic test functions, are obtained. The wavelet transform is also studied on generalized Sobolev space $B^\kappa_p([0,1]^n)$.

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Medical Image Feature Matching Based on Wavelet Transform and SIFT Algorithm

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.65.497 ◽

2011 ◽

Vol 65 ◽

pp. 497-502

Author(s):

Yan Wei Wang ◽

Hui Li Yu

Keyword(s):

Wavelet Transform ◽

Wavelet Transforms ◽

Medical Image ◽

Feature Matching ◽

Image Feature ◽

Scale Invariant ◽

Sift Algorithm ◽

Matching Algorithm ◽

Invariant Feature ◽

Scale Invariant Feature

A feature matching algorithm based on wavelet transform and SIFT is proposed in this paper, Firstly, Biorthogonal wavelet transforms algorithm is used for medical image to delaminating, and restoration the processed image. Then the SIFT (Scale Invariant Feature Transform) applied in this paper to abstracting key point. Experimental results show that our algorithm compares favorably in high-compressive ratio, the rapid matching speed and low storage of the image, especially for the tilt and rotation conditions.

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Wavelet transform to quantify heart rate variability and to assess its instantaneous changes

Journal of Applied Physiology ◽

10.1152/jappl.1999.86.3.1081 ◽

1999 ◽

Vol 86 (3) ◽

pp. 1081-1091 ◽

Cited By ~ 145

Author(s):

Vincent Pichot ◽

Jean-Michel Gaspoz ◽

Serge Molliex ◽

Anestis Antoniadis ◽

Thierry Busso ◽

...

Keyword(s):

Heart Rate ◽

Heart Rate Variability ◽

Nervous System ◽

Fourier Transform ◽

Wavelet Transform ◽

Wavelet Transforms ◽

Autonomous Nervous System ◽

Dynamic Changes ◽

Nonstationary Signals ◽

Higher Doses

Heart rate variability is a recognized parameter for assessing autonomous nervous system activity. Fourier transform, the most commonly used method to analyze variability, does not offer an easy assessment of its dynamics because of limitations inherent in its stationary hypothesis. Conversely, wavelet transform allows analysis of nonstationary signals. We compared the respective yields of Fourier and wavelet transforms in analyzing heart rate variability during dynamic changes in autonomous nervous system balance induced by atropine and propranolol. Fourier and wavelet transforms were applied to sequences of heart rate intervals in six subjects receiving increasing doses of atropine and propranolol. At the lowest doses of atropine administered, heart rate variability increased, followed by a progressive decrease with higher doses. With the first dose of propranolol, there was a significant increase in heart rate variability, which progressively disappeared after the last dose. Wavelet transform gave significantly better quantitative analysis of heart rate variability than did Fourier transform during autonomous nervous system adaptations induced by both agents and provided novel temporally localized information.

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Discrete and Dual Tree Wavelet Features for Real-Time Speech/Music Discrimination

ISRN Signal Processing ◽

10.5402/2011/269361 ◽

2011 ◽

Vol 2011 ◽

pp. 1-10 ◽

Cited By ~ 3

Author(s):

Timur Düzenli ◽

Nalan Özkurt

Keyword(s):

Wavelet Transform ◽

Real Time ◽

Wavelet Transforms ◽

Principal Component ◽

Discrete Wavelet ◽

Vanishing Moments ◽

Zero Crossings ◽

Time Frequency ◽

Common Time ◽

Classification Tool

The performance of wavelet transform-based features for the speech/music discrimination task has been investigated. In order to extract wavelet domain features, discrete and complex orthogonal wavelet transforms have been used. The performance of the proposed feature set has been compared with a feature set constructed from the most common time, frequency and cepstral domain features such as number of zero crossings, spectral centroid, spectral flux, and Mel cepstral coefficients. The artificial neural networks have been used as classification tool. The principal component analysis has been applied to eliminate the correlated features before the classification stage. For discrete wavelet transform, considering the number of vanishing moments and orthogonality, the best performance is obtained with Daubechies8 wavelet among the other members of the Daubechies family. The dual tree wavelet transform has also demonstrated a successful performance both in terms of accuracy and time consumption. Finally, a real-time discrimination system has been implemented using the Daubhecies8 wavelet which has the best accuracy.

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Pattern Changes of Time-Shifted Vibration Signals on Wavelet Time-Scale Maps

Volume 3A: 15th Biennial Conference on Mechanical Vibration and Noise — Vibration of Nonlinear, Random, and Time-Varying Systems ◽

10.1115/detc1995-0381 ◽

1995 ◽

Author(s):

Da Jun Chen ◽

Wei Ji Wang

Keyword(s):

Wavelet Transform ◽

Time Scale ◽

Wavelet Transforms ◽

Vibration Signal ◽

Continuous Wavelet ◽

Time Axis ◽

Orthogonal Wavelet ◽

Signal Component ◽

Analysis Technique ◽

Map Analysis

Abstract As a multi-resolution signal decomposition and analysis technique, the wavelet transforms have been already introduced to vibration signal processing. In this paper, a comparison on the time-scale map analysis is made between the discrete and the continuous wavelet transform. The orthogonal wavelet transform decomposes the vibration signal onto a series of orthogonal wavelet functions and the number of wavelets on one wavelet level is different from those on the other levels. Since the grids are unevenly distributed on the time-scale map, it is shown that a representation pattern of a vibration component on the map may be significantly altered or even be broken down into pieces when the signal has a shift along the time axis. On contrary, there is no such uneven distribution of grids on the continuous wavelet time-scale map, so that the representation pattern of a vibration signal component will not change its shape when the signal component shifts along the time axis. Therefore, the patterns in the continuous wavelet time-scale map are more easily recognised by human visual inspection or computerised automatic diagnosis systems. Using a Gaussian enveloped oscillation wavelet, the wavelet transform is capable of retaining the frequency meaning used in the spectral analysis, while making the interpretation of patterns on the time-scale maps easier.

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Quantum Wavelet Transforms

Examining Quantum Algorithms for Quantum Image Processing - Advances in Computer and Electrical Engineering ◽

10.4018/978-1-7998-3799-2.ch005 ◽

2021 ◽

pp. 193-220

Keyword(s):

Information Processing ◽

Quantum Information ◽

Wavelet Transform ◽

Tensor Product ◽

Wavelet Transforms ◽

Quantum Information Processing ◽

Complexity Analysis ◽

Simulation Experiments ◽

Multi Level

The classical wavelet transform has been widely applied in the information processing field. It implies that quantum wavelet transform (QWT) may play an important role in quantum information processing. This chapter firstly describes the iteration equations of the general QWT using generalized tensor product. Then, Haar QWT (HQWT), Daubechies D4 QWT (DQWT), and their inverse transforms are proposed respectively. Meanwhile, the circuits of the two kinds of multi-level HQWT are designed. What's more, the multi-level DQWT based on the periodization extension is implemented. The complexity analysis shows that the proposed multi-level QWTs on 2n elements can be implemented by O(n3) basic operations. Simulation experiments demonstrate that the proposed QWTs are correct and effective.

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Region-Based Fractional Wavelet Transform Using Post Processing Artifact Reduction

Iraqi Journal for Electrical And Electronic Engineering ◽

10.37917/ijeee.8.1.5 ◽

2012 ◽

Vol 8 (8) ◽

pp. 45-53

Author(s):

Jassim Abdul-Jabbar ◽

Alyaa Taqi

Keyword(s):

Wavelet Transform ◽

Wavelet Transforms ◽

Low Cost ◽

Image Features ◽

Artifact Reduction ◽

Digital Cameras ◽

Wireless Multimedia ◽

Wavelet Filters ◽

Fractional Wavelet Transform ◽

Memory Resources

Wavelet-based algorithms are increasingly used in the source coding of remote sensing, satellite and other geospatial imagery. At the same time, wavelet-based coding applications are also increased in robust communication and network transmission of images. Although wireless multimedia sensors are widely used to deliver multimedia content due to the availability of inexpensive CMOS cameras, their computational and memory resources are still typically very limited. It is known that allowing a low-cost camera sensor node with limited RAM size to perform a multi-level wavelet transform, will in return limit the size of the acquired image. Recently, fractional wavelet filter technique became an interesting solution to reduce communication energy and wireless bandwidth, for resource-constrained devices (e.g. digital cameras). The reduction in the required memory in these fractional wavelet transforms is achieved at the expense of the image quality. In this paper, an adaptive fractional artifacts reduction approach is proposed for efficient filtering operations according to the desired compromise between the effectiveness of artifact reduction and algorithm simplicity using some local image features to reduce boundaries artifacts caused by fractional wavelet. Applying such technique on different types of images with different sizes using CDF 9/7 wavelet filters results in a good performance.

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Medical Image Compression Using Integer Wavelet Transformations

Handbook of Research on Informatics in Healthcare and Biomedicine ◽

10.4018/978-1-59140-982-3.ch036 ◽

2011 ◽

pp. 277-286

Author(s):

B. Ramakrishnan ◽

N. Sriraam

Keyword(s):

Wavelet Transform ◽

Wavelet Transforms ◽

Medical Images ◽

Lossy Compression ◽

Data Sets ◽

Optimal Method ◽

Medical Image Compression ◽

Integer Wavelet ◽

Wavelet Transformations ◽

Lossless And Lossy Compression

In this chapter, we have focused on compression of medical images using integer wavelet transforms. Lifting transforms such as S, TS, S+P(B), S+P(C), 5/3, 2+@, 2, 9/7-M and 9/7-F transforms are used to evaluate the performances of lossless and lossy compression. Four medical images, namely, MRI, CT, ultrasound, and angiograms are used as test data sets. It is found from the experiments that, among the different transforms, the 9/7-M wavelet transform is identified as the optimal method for lossless and lossy compression of medical images.

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Applicataion of ormsby wavelet for generation of synthetic seismic signals

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i2.7.10980 ◽

2018 ◽

Vol 7 (2.7) ◽

pp. 794

Author(s):

E Sai Sumanth ◽

V Joseph ◽

Dr K S Ramesh ◽

Dr S Koteswara Rao

Keyword(s):

Wavelet Transform ◽

Seismic Data ◽

Wavelet Transforms ◽

Seismic Signal ◽

Core Structure ◽

Seismic Signals ◽

Seismic Reflections ◽

Input Wave

Investigation of signals reflected from earth’s surface and its crust helps in understanding its core structure. Wavelet transforms is one of the sophisticated tools for analyzing the seismic reflections. In the present work a synthetic seismic signal contaminated with noise is synthesized and analyzed using Ormsby wavelet[1]. The wavelet transform has efficiently extracted the spectra of the synthetic seismic signal as it smoothens the noise present in the data and upgrades the flag quality of the seismic data due to termers. Ormsby wavelet gives the most redefined spectrum of the input wave so it could be used for the analysis of the seismic reflections.

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Progressive Gelfand-Shilov Spaces and Wavelet Transforms

Journal of Function Spaces and Applications ◽

10.1155/2012/951819 ◽

2012 ◽

Vol 2012 ◽

pp. 1-19 ◽

Cited By ~ 1

Author(s):

Dušan Rakić ◽

Nenad Teofanov

Keyword(s):

Wavelet Transform ◽

Exponential Decay ◽

Wavelet Transforms ◽

Localization Property ◽

Continuity Properties ◽

Analytic Signals

We discuss progressive Gelfand-Shilov spaces consisting of analytic signals with almost exponential decay in time and frequency variables. It is shown that such signals enjoy an additional localization property. We define wavelet transform and inverse wavelet transform in (progressive) Gelfand-Shilov spaces and study their continuity properties. It is shown that with a slightly faster decay in domain we may control the decay of the wavelet transform independently in each variable.

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Treatment of Noise in Experimental Transport Measurements Plots With Discrete Wavelet Transforms

Volume 5: Fuel Cycle and High and Low Level Waste Management and Decommissioning; Computational Fluid Dynamics (CFD), Neutronics Methods and Coupled Codes; Instrumentation and Control ◽

10.1115/icone17-75731 ◽

2009 ◽

Author(s):

Rube´n Panta Pazos

Keyword(s):

Wavelet Transform ◽

Wavelet Transforms ◽

Transport Theory ◽

Discrete Wavelet ◽

Transform Method ◽

Pass Filter ◽

Low Pass Filter ◽

Low Pass ◽

Thresholding Algorithm ◽

High Pass

In this work it is applied the wavelet transform method [2] in order to reduce diverse type of noises of experimental measurement plots in transport theory. First, suppose that a problem is governed by the transport equation for neutral particles, and an unknown perturbation occurs. In this case, the perturbation can be associated to the source, or even to the flux inside the domain X. How is the behavior of the perturbed flux in relation to the flux without the perturbation? For that, we employ the wavelet transform method in order to compress the angular flux considered as a 1D, or n-th dimensional signal ψ. The compression of this signal can be performed up to some a convenient order (that depends of the length of the signal). Now, the transport signal is decomposed as [9, 11]: ψ=〈am|dm|dm−1|dm−2|⋯|d2|d1〉 where ak represents the sub signal of k-th level generated by the low-pass filter associated to the discrete wavelet transform (DWT) chosen, and dk the sub signal of k-th level generated by the high-pass filter associated to the same DWT. It is applied basically the Haar, Daub4 and Coiflet wavelets transforms. Indeed, the sub signal am cumulates the energy, for this work of order 96% of the original signal ψ. A thresholding algorithm provides treatment for the noise, with significant reduction in the compressed signal. Then, it is established a comparison with a base of data in order to identify the perturbed signal. After the identification, it is recomposed the signal applying the inverse DWT. Many assumptions can be established: the rate signal-to-noise is properly high, the base of data must contain so many perturbed signals all with the same level of compression. The problem considered is for perturbations in the signal. For measurements the problem is similar, but in this case the unknown perturbations are generated by the apparatus of measurements, problems in experimental techniques, or simply by random noises. With the same above assumptions, the DWT is applied. For the identification, it is used a method evolving statistical and metric techniques. It is given some results obtained with an algebraic computer system.

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