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Some Theory and an Experiment on the Fundamentals of Hirschman Uncertainty

The Heisenberg Uncertainty principle is a fundamental concept from Quantum Mechanics that also describes the Fourier Transform. Unfortunately, it does not directly apply to the
digital signals. However, it can be generalized if we use entropy rather than energy to form an uncertainty relation. This form of uncertainty, called the Hirschman Uncertainty, uses the
Shannon Entropy. The Hirschman Uncertainty is defined as the average of the Shannon entropies of the discrete-time signal and its Fourier Transform. The functions that minimize this
uncertainty are not the wellknown Gaussians from the Heisenberg theory, but are the picket fence functions first noticed in wavelet denoising. This connection suggests that the Hirschman
Uncertainty is fundamental, but not conclusively. Here in this research, we develop two new uncertainty measures that are derived from the Hirschman Uncertainty. We want to use these
measures to explore the fundamental nature of the Hirschman Uncertainty. In the first case, we replace the Shannon entropy with the Rényi entropy and study the impact of varying the
Rényi order on the uncertainty of various digital signals. We call this new uncertainty measure, the Hirschman-Rényi uncertainty denoted by U[alpha over ½](x). We find that the derived
uncertainty measure is invariant to the Rényi order in case of the picket fence signals and varies in case of other the digital signals like rectagular, cosine, square wave signals to
name a few. This new uncertainty measure that utilizes the Rényi entropy decays with the increase in Rényi order value. Considering the invariance in uncertainty in case of picket fence
signal, we can use either Shannon or Rényi entropy with any value of Rényi order to calculate Hirschman Uncertainty. In the second case, we derive an uncertainty measure that replaces
the Fourier Transform with the Fractional Fourier Transform. The Hirschman Uncertainty using dFRT denoted by U[alpha over ½](x) is explored with the help of the minimizers of the Hirschman
Uncertainty (the picket fence signals) along with the other digital signals. In this case, we find that the degree of rotation in the Fractional Fourier Transform does impact the
uncertainty at the integer values of the transfer order. But for the non-interger values of the transfer order, the uncertainty variations are greatly reduced or are minimal. Finally to
help verify our theory, we perform a classical texture recognition experiment. We find that the recognition performance follows directly as our developed Hirschman Rényi Uncertainty and
the Hirschman Uncertainty using dFRT theory suggests. Additionally, it appears that a predictive solution for the proper selection of the Rényi order and the rotation angle can be
developed that could significantly aid in image analysis. Our recognition results are consistent with entropic invariance theory in case of the two uncertainty measures. These results
suggests that the Hirschman Uncertainty may be a fundamental characteristic of the digital signals. / A Dissertation submitted to the Department of Electrical and Computer Engineering in partial fulfillment of the requirements for the degree of Doctor of
Philosophy. / Fall Semester 2015. / November 3, 2015. / Discrete fractional fourier transform, entropy, Hirschman Uncertainty, Texture classification, Uncertainty / Includes bibliographical references. / Victor DeBrunner, Professor Directing Dissertation; Anuj Srivastava, University Representative; Linda DeBrunner, Committee Member; Bruce Harvey,
Committee Member; Rodney Roberts, Committee Member.

Identiferoai:union.ndltd.org:fsu.edu/oai:fsu.digital.flvc.org:fsu_291290
ContributorsGhuman, Kirandeep (authoraut), DeBrunner, Victor E. (professor directing dissertation), Srivastava, Anuj, 1068- (university representative), DeBrunner, Linda S. (Linda Sumners) (committee member), Harvey, Bruce A., 1961- (committee member), Roberts, Rodney G. (committee member), Florida State University (degree granting institution), FAMU-FSU College of Engineering (degree granting college), Department of Electrical and Computer Engineering (degree granting department)
PublisherFlorida State University
Source SetsFlorida State University
LanguageEnglish, English
Detected LanguageEnglish
TypeText, text
Format1 online resource (87 pages), computer, application/pdf

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