References

Steven B. Damelin; Willard Miller, Jr

doi:10.1017/CBO9781139003896.015

References

Published online by Cambridge University Press: 05 June 2012

Steven B. Damelin and

Willard Miller, Jr

Show author details

Steven B. Damelin: Affiliation:
Unit for Advances in Mathematics and its Applications, USA
Willard Miller, Jr: Affiliation:
University of Minnesota

Book contents

Get access

Summary

A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'

Type: Chapter
Information: The Mathematics of Signal Processing , pp. 437 - 442

DOI: https://doi.org/10.1017/CBO9781139003896.015 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1] D., Achlioptas, Database-friendly random projections: Johnson-Lindenstrauss with binary coins, J. Comp. Sys. Sci., 66 (4), (2003), 671–687.Google Scholar

[2] A., Akansu and R., Haddad, Multiresolution Signal Decomposition, Academic Press, 1993.Google Scholar

[3] G. E., Andrews, R., Askey and R., Roy, Special Functions, Encyclopedia of Mathematics and its Applications, Cambridge University Press, 1999.Google Scholar

[4] T. M., Apostol, Calculus, Blaisdell Publishing Co., 1967–1969.

[5] L. J., Bain and M., Engelhardt, Introduction to Probability and Mathe-matical Statistics, 2nd edn., PWS-Kent, 1992.Google Scholar

[6] R., Baraniuk, M., Davenport, R., DeVore and M., Wakin, A simple proof of the restricted isometry property for random matrices, Const. Approx., 28, (2008), 253–263.Google Scholar

[7] R., Baraniuk and M. B., Wakin, Random projections on smooth manifolds, Found. Comput. Math., 9, (2009), 51–77.Google Scholar

[8] M., Belkin and P., Niyogi, Laplacian eigenmaps for dimensionality reduction and data representation, Neural Comput., 15 (6), (2003), 1373–1396.Google Scholar

[9] A., Berlinet and C. T., Agnan, Reproducing Kernel Hilbert Spaces in Probability and Statistics, Kluwer, 2004.Google Scholar

[10] J. J, Benedetto and M. W., Frazier, Wavelets: Mathematics and Applications, CRC Press, 1994.Google Scholar

[11] J. J., Benedetto and A. I., Zayed, Sampling, Wavelets and Tomography, Birkhauser, 2004.Google Scholar

[12] P., Binev, A., Cohen, W., Dahmen and V., Temlyakov, Universal algorithms for learning theory part I: piecewise constant functions, J. Mach. Learn. Res., 6, (2005), 1297–1321.Google Scholar

[13] M. M., Bronstein and I., Kokkinos, Scale Invariance in Local Heat Kernel Descriptors without Scale Selection and Normalization, INRIA Research Report 7161, 2009.Google Scholar

[14] A. M., Bruckstein, D. L., Donoho and M., Elad, From sparse solutions of systems of equations to sparse modeling of signals and images, SIAM Review, 51, February 2009, 34–81.Google Scholar

[15] A., Boggess and F. J., Narcowich, A First Course in Wavelets with Fourier Analysis, Prentice-Hall, 2001.Google Scholar

[16] S., Boyd and L., Vandenberghe, Convex Optimization, Cambridge University Press, 2004.Google Scholar

[17] C. S., Burrus, R. A., Gopinath and H., Guo, Introduction to Wavelets and Wavelet Transforms. A Primer, Prentice-Hall, 1998.Google Scholar

[18] A., Bultheel, Learning to swim in the sea of wavelets, Bull. Belg. Math. Soc., 2, (1995), 1–44.Google Scholar

[19] E. J., Candes, Compressive sampling, Proceedings of the International Congress of Mathematicians, Madrid, Spain, (2006).Google Scholar

[20] E. J., Candes, Ridgelets and their derivatives: Representation of images with edges, in Curves and Surfaces, ed. L. L., Schumaker et al., Vanderbilt University Press, 2000, pp. 1–10.Google Scholar

[21] E. J., Candes, The restricted isometry property and its implications for compressed sensing, C. R. Acad, Sci. Paris Ser. I Math., 346, (2008), 589–592.Google Scholar

[22] E. J., Candes and D. L., Donoho, Continuous curvelet transform: I. Resolution of the wavefront set, Appl. Comput. Harmon. Anal., 19, (2005), 162–197.Google Scholar

[23] E. J., Candes and E. L., Donoho, Continuous curvelet transform: II. Discretization and frames, Appl. Comput. Harmon. Anal., 19, (2005), 198–222.Google Scholar

[24] E. J., Candes and E. L., Donoho, New tight frames of curvelets and optimal representations of objects with piecewise-C2 singularities, Comm. Pure Appl. Math, 57, (2006), 219–266.Google Scholar

[25] E. J., Candes, X., Li, Y., Ma and J., Wright, Robust principal component analysis?, J. ACM, 58 (1), 1–37.

[26] E. J., Candes, J., Romberg and T., Tao, Robust uncertainty principles: exact signal reconstruction from highly incomplete frequency information, IEEE Trans. Inform. Theory, 52, (2006), 489–509.Google Scholar

[27] E. J., Candes, J., Romberg and T., Tao, Stable signal recovery from incomplete and inaccurate measurements, Comm. Pure and Appl. Math., 59, (2006), 1207–1223.Google Scholar

[28] E. J., Candes and T., Tao, Decoding by linear programing, IEEE Trans. Inform. Theory, 51, (2005), 4203–4215.Google Scholar

[29] E. J., Candes and T., Tao, Near optimal signal recovery from random projections: universal encoding strategies, IEEE Trans. Inform. Theory, 52, 5406–5425.

[30] E. J., Candes and T., Tao, The Dantzig selector: Statistical estimation when p is much larger than n, Ann. Stat., 35, (2007), 2313–2351.Google Scholar

[31] K., Carter, R., Raich and A., Hero, On local dimension estimation and its applications, IEEE Trans. Signal Process., 58 (2), (2010), 762–780.Google Scholar

[32] K., Carter, R., Raich, W.G.|Finn and A. O., Hero, FINE: Fisher information non-parametric embedding, IEEE Trans. Pattern Analysis and Machine Intelligence (PAMI), 31 (3), (2009), 2093–2098.Google Scholar

[33] K., Causwe, M, Sears, A., Robin, Using random matrix theory to determine the number of endmembers in a hyperspectral image, Whispers Proceedings, 3, (2010), 32–40.Google Scholar

[34] T. F., Chan and J., Shen, Image Processing and Analysis, SIAM, 2005.Google Scholar

[35] C., Chui, An Introduction to Wavelets, Academic Press, 1992.Google Scholar

[36] C., Chui and H. N., Mhaskar, MRA contextual-recovery extension of smooth functions on manifolds, App. Comput. Harmon. Anal., 28, (2010), 104–113.Google Scholar

[37] A., Cohen, W., Dahmen, I., Daubechies and R., DeVore, Tree approximation and encoding, Appl. Comput. Harmon. Anal., 11, (2001), 192–226.Google Scholar

[38] A., Cohen, W., Dahmen and R., DeVore, Compressed sensing and k-term approximation, Journal of the AMS, 22, (2009), 211–231.Google Scholar

[39] A., Cohen, I., Daubechies and J. C., Feauveau, Biorthogonal bases of compactly supported wavelets, Comm. Pure Appl. Math., 45, (1992), 485–560.Google Scholar

[40] A., Cohen and R. D, Ryan, Wavelets and Multiscale Signal Processing, Chapman and Hall, 1995.Google Scholar

[41] A., Cohen, Wavelets and digital signal processing, in Wavelets and their Applications, ed. M. B., Ruskai et al., Jones and Bartlett, 1992.Google Scholar

[42] A., Cohen and J., Froment, Image compression and multiscale approximation, in Wavelets and Applications (Marseille, Juin 89), ed. Y., Meyer, Masson, 1992.Google Scholar

[43] A., Cohen, Wavelets, approximation theory and subdivision schemes, in Approximation Theory VII (Austin, 1992), ed. E. W., Cheney et al., Academic Press, 1993.Google Scholar

[44] R. R., Coifman and S., Lafon, Diffusion maps, Appl. Comp. Harmon. Anal., 21, (2006), 5–30.Google Scholar

[45] R. R., Coifman and M., Maggioni, Diffusion wavelets, Appl. Comput. Harmon. Anal., 21 (1), (2006), 53–94.Google Scholar

[46] J. A., Costa and A. O., Hero, Geodesic entropic graphs for dimension and entropy estimation in manifold learning, IEEE Trans. Signal Process., 52 (8), (2004), 2210–2221.Google Scholar

[47] F., Cucker and S., Smale, On the mathematical foundations of learning theory, Bull. Amer. Math. Soc., 39, (2002), 1–49.Google Scholar

[48] S. B., Damelin, A walk through energy, discrepancy, numerical integration and group invariant measures on measurable subsets of euclidean space, Numer. Algorithms, 48 (1), (2008), 213–235.Google Scholar

[49] S. B., Damelin, On bounds for diffusion, discrepancy and fill distance metrics, in Principal Manfolds, Springer Lecture Notes in Computational Science and Engineering, vol. 58, 2008, pp. 32–42.Google Scholar

[50] S. B., Damelin and A. J., Devaney, Local Paley Wiener theorems for analytic functions on the unit sphere, Inverse Probl., 23, (2007), 1–12.Google Scholar

[51] S. B., Damelin, F., Hickernell, D., Ragozin and X., Zeng, On energy, discrepancy and G invariant measures on measurable subsets of Euclidean space, J. Fourier Anal. Appl., 16, (2010), 813–839.Google Scholar

[52] I., Daubechies, Orthonormal bases of compactly supported wavelets, Comm. Pure Appl. Math., 41, (1988), 909–996.Google Scholar

[53] I., Daubechies, Ten Lectures on Wavelets, CBMS-NSF Regional Conf. Ser. Appl. Math, 61, SIAM, 1992.Google Scholar

[54] I., Daubechies, R., Devore, D., Donoho and M., Vetterli, Data compression and harmonic analysis, IEEE Trans. Inform. Theory Numerica, 44, (1998), 2435–2467.Google Scholar

[55] K. R., Davidson and A. P., Donsig, Real Analysis with Real Applications, Prentice Hall, 2002.Google Scholar

[56] L., Demaret, N., Dyn and A., Iske, Compression by linear splines over adaptive triangulations, Signal Process. J., 86 (7), July 2006, 1604–1616.Google Scholar

[57] L., Demaret, A., Iske and W., Khachabi, A contextual image compression from adaptive sparse data representations, Proceedings of SPARS09, April 2009, Saint-Malo.

[58] R., DeVore, Nonlinear approximation, Acta Numer., 7, (1998), 51–150.Google Scholar

[59] R., Devore, Optimal computation, Proceedings of the International Congress of Mathematicians, Madrid, Spain, 2006.Google Scholar

[60] R., Devore, Deterministic constructions of compressed sensing matrices, J. Complexity, 23, (2007), 918–925.Google Scholar

[61] R., Devore and G., Lorentz, Constructive Approximation, Comprehensive Studies in Mathematics 303, Springer-Verlag, 1993.Google Scholar

[62] D., Donoho, Compressed sensing, IEEE Trans. Inform. Theory, 52 (4), (2006), 23–45.Google Scholar

[63] D., Donoho, M., Elad and V., Temlyakov, Stable recovery of sparse overcomplete representations in the presence of noise, IEEE Trans. Inf. Theory, 52 (1), (2006), 6–18.Google Scholar

[64] L., du Plessis, R., Xu, S. B., Damelin, M., Sears and D., Wunsch, Reducing dimensionality of hyperspectral data with diffusion maps and clustering with K means and fuzzy art, Int. J. Sys. Control Comm., 3 (2011), 3–10.Google Scholar

[65] L., du Plessis, R., Xu, S., Damelin, M., Sears and D., Wunsch, Reducing dimensionality of hyperspectral data with diffusion maps and clustering with K-means and fuzzy art, Proceedings of International Conference of Neural Networks, Atlanta, 2009, pp. 32–36.Google Scholar

[66] D.T., Finkbeiner, Introduction to Matrices and Linear Transformations, 3rd edn., Freeman, 1978.Google Scholar

[67] M., Herman and T., Strohmer, Compressed sensing radar, ICASSP 2008, pp. 1509–1512.

[68] M., Herman and T., Strohmer, High resolution radar via compressed sensing, IEEE Trans. Signal Process., November 2008, 1–10.Google Scholar

[69] E., Hernandez and G., Weiss, A First Course on Wavelets, CRC Press, 1996.Google Scholar

[70] W., Hoeffding, Probability inequalities for sums of bounded random variables, J. Amer. Statist. Assoc., 58, (1963), 13–30.Google Scholar

[71] B. B., Hubbard, The World According to Wavelets, A. K Peters, 1996.Google Scholar

[72] P. E. T., Jorgensen, Analysis and Probability: Wavelets, Signals, Fractals, Graduate Texts in Mathematics, 234 Springer, 2006.Google Scholar

[73] D. W., Kammler, A First Course in Fourier Analysis, Prentice-Hall, 2000.Google Scholar

[74] F., Keinert, Wavelets and Multiwavelets, Chapman and Hall/CRC, 2004.Google Scholar

[75] J., Korevaar, Mathematical Methods (Linear algebra, Normed spaces, Distributions, Integration), Academic Press, 1968.Google Scholar

[76] A. M., Krall, Applied Analysis, D. Reidel Publishing Co., 1986.Google Scholar

[77] S., Kritchman and B., Nadler, Non-parametric detection of the number of signals, hypothesis testing and random matrix theory, IEEE Trans. Signal Process., 57 (10), (2009), 3930–3941.Google Scholar

[78] H. J., Larson, Introduction to Probability Theory and Statistical Inference, Wiley, 1969.Google Scholar

[79] G. G., Lorentz, M., von Golitschek and M., Makovoz, Constructive Approximation: Advanced Problems, Grundlehren Math. Wiss, 304, Springer-Verlag, 1996.Google Scholar

[80] D. S., Lubinsky, A survey of mean convergence of orthogonal polynomial expansions, in Proceedings of the Second Conference on Functions Spaces (Illinois), ed. K., Jarosz, CRC press, 1995, pp. 281–310.Google Scholar

[81] B., Lucier and R., Devore, Wavelets, Acta Numer., 1, (1992), 1–56.Google Scholar

[82] S., Mallat, A Wavelet Tour of Signal Processing, 2nd edn., Academic Press, 2001.Google Scholar

[83] S., Mallat, A wavelet tour of signal processing - the Sparse way, Science-Direct (Online service), Elsevier/Academic Press, 2009.Google Scholar

[84] Y., Meyer, Wavelets: Algorithms and Applications, translated by R. D., Ryan, SIAM, 1993.Google Scholar

[85] W., Miller, Topics in harmonic analysis with applications to radar and sonar, in Radar and Sonar, Part 1, R., Blahut, W., Miller and C., Wilcox, IMA Volumes in Mathematics and its Applications, Springer-Verlag, 1991.Google Scholar

[86] M., Mitchley, M., Sears and S. B., Damelin, Target detection in hyperspectral mineral data using wavelet analysis, Proceedings of the 2009 IEEE Geosciences and Remote Sensing Symposium, Cape Town, pp. 23–45.

[87] B., Nadler, Finite sample approximation results for principal component analysis: A matrix perturbation approach, Ann. Stat., 36 (6), (2008), 2791–2817.Google Scholar

[88] H. J., Nussbaumer, Fast Fourier Transform and Convolution Algorithms, Springer-Verlag, 1982.Google Scholar

[89] P., Olver and C., Shakiban, Applied Linear Algebra, Pearson, Prentice-Hall, 2006.Google Scholar

[90] J., Ramanathan, Methods of Applied Fourier Analysis, Birkhauser, 1998.Google Scholar

[91] H. L., Royden, Real Analysis, Macmillan Co., 1988.Google Scholar

[92] W., Rudin, Real and Complex Analysis, McGraw-Hill, 1987.Google Scholar

[93] W., Rudin, Functional Analysis, McGraw-Hill, 1973.Google Scholar

[94] G., Strang, Linear Algebra and its Applications, 3rd edn., Harcourt Brace Jovanovich, 1988.Google Scholar

[95] G., Strang and T., Nguyen, Wavelets and Filter Banks, Wellesley-Cambridge Press, 1996.Google Scholar

[96] R., Strichartz, A Guide to Distribution Theory and Fourier Transforms, CRC Press, 1994.Google Scholar

[97] J., Tropp, Just relax: convex programming methods for identifying sparse signals in noise, IEEE Trans. Inf. Theory, 52 (3), (2006), 1030–1051.Google Scholar

[98] B. L., Van Der Waerden, Modern Algebra, Volume 1 (English translation), Ungar, 1953.Google Scholar

[99] G. G., Walter and X., Shen, Wavelets and other Orthogonal Systems, 2nd ed., Chapman and Hall, 2001.Google Scholar

[100] E. T., Whittaker and G. M., Watson, A Course in Modern Analysis, Cambridge University Press, 1958.Google Scholar

[101] P., Wojtaszczyk, A Mathematical Introduction to Wavelets, London Mathematical Society Student Texts, 37, Cambridge University Press, 1997.Google Scholar

[102] R. J., Zimmer, Essential Results of Functional Analysis, University of Chicago Press, 1990.Google Scholar

[103] A., Zygmund, Trignometrical Series, Dover reprint, 1955.Google Scholar

Book contents

References

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive