Focusing on the intersection of pure mathematics and practical applications, this textbook introduces constructive methods for solving numerical problems with accurate approximations. It emphasizes the impact of data errors, finite-precision calculations, and approximation formulas on results. Additionally, it serves as a primer on scientific programming in MATLAB, featuring a range of theoretical and computational exercises. A standout aspect is the inclusion of interval analysis as a tool for rigorous computation and computer-assisted proofs, enhancing traditional numerical analysis concepts.
This book introduces mathematicians, physicists, and philosophers to a new, coherent approach to theory and interpretation of quantum physics, in which classical and quantum thinking live peacefully side by side and jointly fertilize the intuition. The formal, mathematical core of quantum physics is cleanly separated from the interpretation issues. The book demonstrates that the universe can be rationally and objectively understood from the smallest to the largest levels of modeling. The thermal interpretation featured in this book succeeds without any change in the theory. It involves one radical step, the reinterpretation of an assumption that was virtually never questioned before - the traditional eigenvalue link between theory and observation is replaced by a q-expectation link: Objective properties are given by q-expectations of products of quantum fields and what is computable from these. Averaging over macroscopic spacetime regions produces macroscopic quantities with negligible uncertainty, and leads to classical physics. - Reflects the actual practice of quantum physics. - Models the quantum-classical interface through coherent spaces. - Interprets both quantum mechanics and quantum field theory. - Eliminates probability and measurement from the foundations. - Proposes a novel solution of the measurement problem.
