Special Matrices Of Mathematical Physics: Stochastic, Circulant And Bell MatricesWorld Scientific, 2001 M08 17 - 340 páginas This book expounds three special kinds of matrices that are of physical interest, centering on physical examples. Stochastic matrices describe dynamical systems of many different types, involving (or not) phenomena like transience, dissipation, ergodicity, nonequilibrium, and hypersensitivity to initial conditions. The main characteristic is growth by agglomeration, as in glass formation. Circulants are the building blocks of elementary Fourier analysis and provide a natural gateway to quantum mechanics and noncommutative geometry. Bell polynomials offer closed expressions for many formulas concerning Lie algebra invariants, differential geometry and real gases, and their matrices are instrumental in the study of chaotic mappings. |
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Resultados 1-5 de 84
Página xiii
... Definition and elementary properties 13.1.1 Formal examples 149 151 151 157 13.2 The matrix representation . 165 13.2.1 An important inversion formula . 169 13.3 The Lagrange inversion formula . 171 13.3.1 Inverting Bell matrices . 13.3 ...
... Definition and elementary properties 13.1.1 Formal examples 149 151 151 157 13.2 The matrix representation . 165 13.2.1 An important inversion formula . 169 13.3 The Lagrange inversion formula . 171 13.3.1 Inverting Bell matrices . 13.3 ...
Página 3
... defined as the set Sp [ M ] = { A1 , A2 , A3 , ......... , \ n } of all complex values of À for which the characteristic matrix ( AIM ) is not invertible . It is , consequently , the set of the roots of the characteristic polynomial . 3 ...
... defined as the set Sp [ M ] = { A1 , A2 , A3 , ......... , \ n } of all complex values of À for which the characteristic matrix ( AIM ) is not invertible . It is , consequently , the set of the roots of the characteristic polynomial . 3 ...
Página 5
... defined : * : V & V → V ; * ( a , b ) = a * b = c Є V. It is a Lie algebra if the operation is antisymmetric , a b = - b * a , and the Jacobi identity ( a * b ) * c + ( c * a ) * b + ( b * c ) * a = 0 = holds . Matrices provide ...
... defined : * : V & V → V ; * ( a , b ) = a * b = c Є V. It is a Lie algebra if the operation is antisymmetric , a b = - b * a , and the Jacobi identity ( a * b ) * c + ( c * a ) * b + ( b * c ) * a = 0 = holds . Matrices provide ...
Página 7
... defined by F ( M ) Σk Σm Cmλm Zk , or F ( M ) = ΣkF ( \ k ) Zk · ( 1.9 ) We say " formally " because there are , of course , necessary conditions to make of the above formula a meaningful , convergent expression . Notice on the other ...
... defined by F ( M ) Σk Σm Cmλm Zk , or F ( M ) = ΣkF ( \ k ) Zk · ( 1.9 ) We say " formally " because there are , of course , necessary conditions to make of the above formula a meaningful , convergent expression . Notice on the other ...
Página 8
... defined by a Taylor series . Suppose a function F ( X ) is given which can be expanded as a power series ∞ F ( X ) = Σck ( λ = 10 ) * ( 1-10 ) * k = 0 inside a convergence circle | A – λo | < r . Then the function F ( M ) , whose ...
... defined by a Taylor series . Suppose a function F ( X ) is given which can be expanded as a power series ∞ F ( X ) = Σck ( λ = 10 ) * ( 1-10 ) * k = 0 inside a convergence circle | A – λo | < r . Then the function F ( M ) , whose ...
Contenido
19 | |
CIRCULANT MATRICES | 79 |
BELL MATRICES | 147 |
Appendix A Formulary | 283 |
Bibliography | 309 |
Index | 315 |
Otras ediciones - Ver todas
Special Matrices of Mathematical Physics: Stochastic, Circulant, and Bell ... Ruben Aldrovandi Vista previa limitada - 2001 |
Special Matrices of Mathematical Physics: Stochastic, Circulant, and Bell ... Ruben Aldrovandi Vista previa limitada - 2001 |
Términos y frases comunes
alphabet basis Bell matrices Bell polynomials braid group canonical partition function characteristic polynomial circulant matrices circulant matrix classical cluster integrals column commutative components condition consequently continuum convolution corresponding cyclic defined derivative detailed balancing diagonal differential discrete distribution dynamical eigenvalues eigenvectors entries ep+1 equation equilibrium evolution example factor fermions finite formalism formula Fourier transformations Fredholm geometry given glass grand canonical partition Hamiltonian Hopf algebras identity imprimitive invariant inverse irreducible iterate leads Lie algebra Markov chain noncommutative notation obtained operator particles permutation phase space Phys physical Poisson bracket powers projectors properties QN(B Quantum Mechanics recursion representation Statistical Mechanics stochastic matrix summation symmetric functions symmetric group symplectic Taylor coefficients theorem theory totally regular unitary values variables vector virial Weyl-Wigner Wigner functions Σ Σ