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Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi
| Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi |
| Autore | Bertein Jean-Claude |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | London, United Kingdom : , : ISTE |
| Descrizione fisica | 1 online resource (301 p.) |
| Disciplina |
621.382/2
621.3822 |
| Collana | Digital signal and image processing series |
| Soggetto topico |
Signal processing - Mathematics
Digital filters (Mathematics) Stochastic processes |
| ISBN |
1-118-60035-5
1-299-18742-0 1-118-60048-7 1-118-60053-3 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Discrete Stochastic Processes and Optimal Filtering; Title Page; Copyright Page; Table of Contents; Preface; Introduction; Chapter 1. Random Vectors; 1.1. Definitions and general properties; 1.2. Spaces L1 (dP) and L2 (dP); 1.2.1. Definitions; 1.2.2. Properties; 1.3. Mathematical expectation and applications; 1.3.1. Definitions; 1.3.2. Characteristic functions of a random vector; 1.4. Second order random variables and vectors; 1.5. Linear independence of vectors of L2 (dP); 1.6. Conditional expectation (concerning random vectors with density function); 1.7. Exercises for Chapter 1
Chapter 2. Gaussian Vectors2.1. Some reminders regarding random Gaussian vectors; 2.2. Definition and characterization of Gaussian vectors; 2.3. Results relative to independence; 2.4. Affine transformation of a Gaussian vector; 2.5. The existence of Gaussian vectors; 2.6. Exercises for Chapter 2; Chapter 3. Introduction to Discrete Time Processes; 3.1. Definition; 3.2. WSS processes and spectral measure; 3.2.1. Spectral density; 3.3. Spectral representation of a WSS process; 3.3.1. Problem; 3.3.2. Results; 3.4. Introduction to digital filtering; 3.5. Important example: autoregressive process 3.6. Exercises for Chapter 3Chapter 4. Estimation; 4.1. Position of the problem; 4.2. Linear estimation; 4.3. Best estimate - conditional expectation; 4.4. Example: prediction of an autoregressive process AR (1); 4.5. Multivariate processes; 4.6. Exercises for Chapter 4; Chapter 5. The Wiener Filter; 5.1. Introduction; 5.1.1. Problem position; 5.2. Resolution and calculation of the FIR filter; 5.3. Evaluation of the least error; 5.4. Resolution and calculation of the IIR filter; 5.5. Evaluation of least mean square error; 5.6. Exercises for Chapter 5 Chapter 6. Adaptive Filtering: Algorithm of the Gradient and the LMS6.1. Introduction; 6.2. Position of problem; 6.3. Data representation; 6.4. Minimization of the cost function; 6.4.1. Calculation of the cost function; 6.5. Gradient algorithm; 6.6. Geometric interpretation; 6.7. Stability and convergence; 6.8. Estimation of gradient and LMS algorithm; 6.8.1. Convergence of the algorithm of the LMS; 6.9. Example of the application of the LMS algorithm; 6.10. Exercises for Chapter 6; Chapter 7. The Kalman Filter; 7.1. Position of problem; 7.2. Approach to estimation; 7.2.1. Scalar case 7.2.2. Multivariate case7.3. Kalman filtering; 7.3.1. State equation; 7.3.2. Observation equation; 7.3.3. Innovation process; 7.3.4. Covariance matrix of the innovation process; 7.3.5. Estimation; 7.3.6. Riccati's equation; 7.3.7. Algorithm and summary; 7.4. Exercises for Chapter 7; 7.5. Appendices; 7.6. Examples treated using Matlab software; Table of Symbols and Notations; Bibliography; Index |
| Record Nr. | UNINA-9910141486303321 |
Bertein Jean-Claude
|
||
| London, United Kingdom : , : ISTE | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi
| Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi |
| Autore | Bertein Jean-Claude |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | London, United Kingdom : , : ISTE |
| Descrizione fisica | 1 online resource (301 p.) |
| Disciplina |
621.382/2
621.3822 |
| Collana | Digital signal and image processing series |
| Soggetto topico |
Signal processing - Mathematics
Digital filters (Mathematics) Stochastic processes |
| ISBN |
1-118-60035-5
1-299-18742-0 1-118-60048-7 1-118-60053-3 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover; Discrete Stochastic Processes and Optimal Filtering; Title Page; Copyright Page; Table of Contents; Preface; Introduction; Chapter 1. Random Vectors; 1.1. Definitions and general properties; 1.2. Spaces L1 (dP) and L2 (dP); 1.2.1. Definitions; 1.2.2. Properties; 1.3. Mathematical expectation and applications; 1.3.1. Definitions; 1.3.2. Characteristic functions of a random vector; 1.4. Second order random variables and vectors; 1.5. Linear independence of vectors of L2 (dP); 1.6. Conditional expectation (concerning random vectors with density function); 1.7. Exercises for Chapter 1
Chapter 2. Gaussian Vectors2.1. Some reminders regarding random Gaussian vectors; 2.2. Definition and characterization of Gaussian vectors; 2.3. Results relative to independence; 2.4. Affine transformation of a Gaussian vector; 2.5. The existence of Gaussian vectors; 2.6. Exercises for Chapter 2; Chapter 3. Introduction to Discrete Time Processes; 3.1. Definition; 3.2. WSS processes and spectral measure; 3.2.1. Spectral density; 3.3. Spectral representation of a WSS process; 3.3.1. Problem; 3.3.2. Results; 3.4. Introduction to digital filtering; 3.5. Important example: autoregressive process 3.6. Exercises for Chapter 3Chapter 4. Estimation; 4.1. Position of the problem; 4.2. Linear estimation; 4.3. Best estimate - conditional expectation; 4.4. Example: prediction of an autoregressive process AR (1); 4.5. Multivariate processes; 4.6. Exercises for Chapter 4; Chapter 5. The Wiener Filter; 5.1. Introduction; 5.1.1. Problem position; 5.2. Resolution and calculation of the FIR filter; 5.3. Evaluation of the least error; 5.4. Resolution and calculation of the IIR filter; 5.5. Evaluation of least mean square error; 5.6. Exercises for Chapter 5 Chapter 6. Adaptive Filtering: Algorithm of the Gradient and the LMS6.1. Introduction; 6.2. Position of problem; 6.3. Data representation; 6.4. Minimization of the cost function; 6.4.1. Calculation of the cost function; 6.5. Gradient algorithm; 6.6. Geometric interpretation; 6.7. Stability and convergence; 6.8. Estimation of gradient and LMS algorithm; 6.8.1. Convergence of the algorithm of the LMS; 6.9. Example of the application of the LMS algorithm; 6.10. Exercises for Chapter 6; Chapter 7. The Kalman Filter; 7.1. Position of problem; 7.2. Approach to estimation; 7.2.1. Scalar case 7.2.2. Multivariate case7.3. Kalman filtering; 7.3.1. State equation; 7.3.2. Observation equation; 7.3.3. Innovation process; 7.3.4. Covariance matrix of the innovation process; 7.3.5. Estimation; 7.3.6. Riccati's equation; 7.3.7. Algorithm and summary; 7.4. Exercises for Chapter 7; 7.5. Appendices; 7.6. Examples treated using Matlab software; Table of Symbols and Notations; Bibliography; Index |
| Record Nr. | UNINA-9910830177303321 |
|
Bertein Jean-Claude
|
||
| London, United Kingdom : , : ISTE | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi
| Discrete stochastic processes and optimal filtering / / Jean-Claude Bertein, Roger Ceschi |
| Autore | Bertein Jean-Claude |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Newport Beach, California : , : ISTE, , 2007 |
| Descrizione fisica | 1 online resource (303 p.) |
| Disciplina | 621.382/2 |
| Collana | ISTE |
| Soggetto topico |
Signal processing - Mathematics
Digital filters (Mathematics) Stochastic processes |
| ISBN |
1-118-61549-2
1-280-84785-9 9786610847853 0-470-39493-5 0-470-61229-0 1-84704-624-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Discrete Stochastic Processes and Optimal Filtering; Table of Contents; Preface; Introduction; Chapter 1. Random Vectors; 1.1. Definitions and general properties; 1.2. Spaces L1(dP) and L2(dP); 1.2.1. Definitions; 1.2.2. Properties; 1.3. Mathematical expectation and applications; 1.3.1. Definitions; 1.3.2. Characteristic functions of a random vector; 1.4. Second order random variables and vectors; 1.5. Linear independence of vectors of L2(dP); 1.6. Conditional expectation (concerning random vectors with density function); 1.7. Exercises for Chapter 1; Chapter 2. Gaussian Vectors
2.1. Some reminders regarding random Gaussian vectors2.2. Definition and characterization of Gaussian vectors; 2.3. Results relative to independence; 2.4. Affine transformation of a Gaussian vector; 2.5. The existence of Gaussian vectors; 2.6. Exercises for Chapter 2; Chapter 3. Introduction to Discrete Time Processes; 3.1. Definition; 3.2. WSS processes and spectral measure; 3.2.1. Spectral density; 3.3. Spectral representation of a WSS process; 3.3.1. Problem; 3.3.2. Results; 3.3.2.1. Process with orthogonal increments and associated measurements; 3.3.2.2. Wiener stochastic integral 3.3.2.3. Spectral representation3.4. Introduction to digital filtering; 3.5. Important example: autoregressive process; 3.6. Exercises for Chapter 3; Chapter 4. Estimation; 4.1. Position of the problem; 4.2. Linear estimation; 4.3. Best estimate - conditional expectation; 4.4. Example: prediction of an autoregressive process AR (1); 4.5. Multivariate processes; 4.6. Exercises for Chapter 4; Chapter 5. The Wiener Filter; 5.1. Introduction; 5.1.1. Problem position; 5.2. Resolution and calculation of the FIR filter; 5.3. Evaluation of the least error 5.4. Resolution and calculation of the IIR filter5.5. Evaluation of least mean square error; 5.6. Exercises for Chapter 5; Chapter 6. Adaptive Filtering: Algorithm of the Gradient and the LMS; 6.1. Introduction; 6.2. Position of problem; 6.3. Data representation; 6.4. Minimization of the cost function; 6.4.1. Calculation of the cost function; 6.5. Gradient algorithm; 6.6. Geometric interpretation; 6.7. Stability and convergence; 6.8. Estimation of gradient and LMS algorithm; 6.8.1. Convergence of the algorithm of the LMS; 6.9. Example of the application of the LMS algorithm 6.10. Exercises for Chapter 6Chapter 7. The Kalman Filter; 7.1. Position of problem; 7.2. Approach to estimation; 7.2.1. Scalar case; 7.2.2. Multivariate case; 7.3. Kalman filtering; 7.3.1. State equation; 7.3.2. Observation equation; 7.3.3. Innovation process; 7.3.4. Covariance matrix of the innovation process; 7.3.5. Estimation; 7.3.6. Riccati's equation; 7.3.7. Algorithm and summary; 7.4. Exercises for Chapter 7; Table of Symbols and Notations; Bibliography; Index |
| Record Nr. | UNISA-996213244803316 |
|
Bertein Jean-Claude
|
||
| Newport Beach, California : , : ISTE, , 2007 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||