"The book is a much-welcomed addition to the literature on stable laws and should signifcantly contribute to the further popularization of these laws among practitioners. It is rigorously written without much loss of accessibility to a less technically oriented reader. ... The text should be on the bookshelf of any researcher-practitioner or probabilist who is interested in the phenomena characterized by heavy tails." (Krzysztof Podgorski, Mathematical Reviews, April, 2022)

"This book is an excellent reference for researchers and practitioners looking to make use of both the rich theory and applicability offered by stable distributions. The text is clear and accessible throughout, including all the necessary mathematical and statistical details to make it both a thorough and practical work on univariate modelling using stable distributions." (Fraser Daly, zbMATH 1455.62003, 2021)

Basic Properties of Univariate Stable Distributions.- Modeling with Stable Distributions.- Technical Results for Univariate Stable Distributions.- Univariate Estimation.- Stable Regression.- Signal Processing with Stable Distributions.- Related Distributions.- Appendix A: Mathematical Facts.- Appendix B: Stable Quantiles.- Appendix C: Stable Modes.- Appendix D: Asymptotic Standard Deviations of ML Estimators.

​John Nolan received his PhD from the University of Virginia, and has taught at the University of Zambia, Kenyon College, and American University. He also worked in a software firm, developing systems for intensive care units. His main research interests are in models for heavy tailed data and extremes.

This textbook highlights the many practical uses of stable distributions, exploring the theory, numerical algorithms, and statistical methods used to work with stable laws. Because of the author’s accessible and comprehensive approach, readers will be able to understand and use these methods. Both mathematicians and non-mathematicians will find this a valuable resource for more accurately modelling and predicting large values in a number of real-world scenarios.