Since this is a 2nd Edition, we are giving below the topics we wish to add/update/revise in roughly the same chapter sequence as we had in the existing 1st Edition of the book. In addition to a general revision of the text, we propose the following major modifications (the asterisks denote the amount of text added/modified and/or or the difficulty level of the topics being discussed):
Chapter 2
- Subsection 2.1.2: add discussion on how to find all zeros by means
of the Newton method (*)
Chapter 3
- Expand Subsection 3.2.7 on solving the A*x = b equations with sparse
matrices to a full Section (**)
- Expand Subsection 3.4.5 on solving the eigenvalue problem A*x = lambda*x
to a full Section (**) - Discuss the exponentiation of a matrix, exp(A) (*)
- Add a Subsection on Pseudospectra (**)
- in general
, enhance the "sparse" aspect of the chapter
Chapter 4
- Add a new Section on Sparse FFT (following present Sec. 4.2),
add corresponding Exercise (**)
- Expand Subsection 4.6.2 on the Discrete Wavelet Transform
to a full Section, add Exercise (***)
- Add a Section on image denoising (**)
- Add Section on Radon transformation (**)
Chapter 5
- Rewrite Sections 5.1-5.5 to better distinguish between general
discussion of distributions and the techniques involving samples,
and to bring the notation in line with the book "Probability
for Physicists" (***)
- Introduce Bayesian data analysis and inference (***)
- Expand Subsection 5.5.8 on Non-linear Regression to a full Section,
add Exercises (**)
Chapter 6
- Expand Section 6.5
on Noise, add Exercise (**) - Add Section on Takens Theorem and its applications: phase space
reconstruction and optimal size determination (**) - Add discussion on signal entropies (**)
- Update discussion on autoregressive models (optimal order) (*)
- Add discussion on signal directionality / causality (**)
Chapter 7
- Expand Section 7.10 on Stiff Problems of ODE, add Exercise (**)
Chapter 8
- Expand Subsection 8.7.4 on Singular SL Problems to a Section,
add Exercise (**)
- Motivated by Section 8.8, write a new chapter on Inverse Problems (***)
Chapter 10
- Expand Section 10.8, add Exercise (**)
Chapter 11
- Expand Sections 11.7 and 11.8, add Exercises (**)
New Chapter on Inverse Methods (***)
New short Chapter or Appendix on minimization (**)
- with derivatives or without them
- with constraints or without them
- deterministic and quasi-deterministic (MC methods)
New Appendix on spline methods: B-splines, Bezier splines (**)
About the Author: Simon Sirca was born on February 27, 1969, in Ljubljana, Slovenia. He is Professorof Physics at the Faculty of Mathematics and Physics, University of Ljubljana, wherehe has been teaching courses on Probability for Physicists, Computational Physics andModel Analysis. He is head of the research group Structure of Hadronic Systems activein the OOPS and BLAST Collaborations at MIT, Hall A Collaboration at Thomas Jef-ferson National Accelerator Facility (USA) and the A1 Collaboration at MAMI in Mainz(Germany). His main research field is the study of hadronic structure and dynamics byscattering of electrons on light nuclei, exploiting polarized beams, polarized targets, andrecoil polarimetry. He is also involved in theoretical work on quark models of hadrons, with a focus on electroweak processes.
Martin Horvat was born on April 25, 1977, in Maribor, Slovenia. He is Assistant Pro-fessor at the Faculty of Mathematics and Physics, University of Ljubljana, where he hasled the Physical Laboratory Course and taught Basic Applied Mathematics and PhysicsI and II. His research work is devoted to classical and quantum non-linear dynamics, to transport properties in extended systems, to the quantum-classical correspondence, totheoretical and applied aspects of quantum mechanics on the classical phase space, as wellas to statistical mechanics and its origin in dynamics. He is also involved in the researchof relativistic global navigation satellite systems and in modeling of astrophysical bodies, mainly eclipsing binary stars and synthesis of their observables.
