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Informationen zum Autor Hua Loo-Keng (1910–1985), a self-taught mathematician, is remembered as one of the leading scholars of his time. Hua spent most of his working life in China and suffered at first hand the turbulence of twentieth-century Chinese politics – but he also travelled extensively. This included time spent at Cambridge in the 1930s, when he made notable contributions to number theory, and post-war visits to Russia and America. Hua was appointed a professor of mathematics at the University of Illinois in 1949, but he chose instead to return to China to train the next generation of mathematicians and became the first director of the Mathematical Institute of the Academia Sinica. He was later appointed vice-president of Academia Sinica and a science advisor to his government. He continued to study and lecture abroad until his death in Tokyo in 1985. Hua received honorary degrees from the University of Nancy (1980), the Chinese University of Hong Kong (1983) and the University of Illinois (1984). His work has been translated into many languages, and Hua was elected a foreign associate of the National Academy of Sciences in 1982 and a member of the Deutsche Akademie der Naturforscher Leopoldina (1983), the Academy of the Third World (1983) and the Bavarian Academy of Sciences (1985). Peter Shiu, now retired, was Reader in Pure Mathematics at Loughborough University. He has published widely on his own research interests and was the translator of Hua Loo-Keng's Introduction to Number Theory (1982) and Hua Loo-Keng by Wang Yuan (1998). Zusammenfassung Hua Loo-Keng (1910-1985) is remembered as one of the leading mathematicians of his generation. These volumes, containing both pure and applied mathematics, are based on his lectures at the University of Science and Technology of China. With hundreds of diagrams, examples and exercises, this is a wide-ranging reference text for university mathematics. Inhaltsverzeichnis Volume I: 1. Real and complex numbers; 2. Vector algebra; 3. Functions and graphs; 4. Limits; 5. The differential calculus; 6. Applications of the derivative; 7. Taylor expansions; 8. Approximate solutions to equations; 9. Indefinite integrals; 10. Definite integrals; 11. Applications of integral calculus; 12. Functions of several variables; 13. Sequences, series and integrals with variables; 14. Differential properties of curves; 15. Multiple integral; 16. Curvilinear integral and surface integral; 17. Scalar field and vector field; 18. Differential properties of curved surfaces; 19. Fourier series; 20. System of ordinary differential equations. Volume II: 1. Geometry of the complex plane; 2. Non-Euclidean geometry; 3. Definitions and examples of analytic and harmonic functions; 4. Harmonic functions; 5. Some basic concepts in point set theory and topology; 6. Analytic functions; 7. Residues and their application to definite integral; 8. Maximum modulus principle and the family of functions; 9. Entire function and meromorphic function; 10. Conformal transformation; 11. Summation; 12. Harmonic functions under various boundary conditions; 13. Weierstrass' elliptic function theory; 14. Jacobi's elliptic functions; 15. Systems of linear equations and determinants (review outline); 16. Equivalence of matrices; 17. Functions, sequences and series of square matrices; 18. Difference equations with constant coefficients and ordinary differential equations; 19. Asymptotic property of solutions; 20. Quadratic form; 21. Orthogonal groups and pair of quadratic forms; 22. Volumes; 23. Non-negative square matrices. Volume III: 1. The geometry of the complex plane; 2. Non-Euclidean geometry; 3. Definitions and examples of analytic functions and harmonic functions; 4. Harmonic functions; 5. Point set theory and preparations for topology; 6. Analytic functions; 7. The residue and its application to evaluation of definite integrals; 8. Maximum modulus theorem and families of ...
