Bayesian Inverse Problems
Fundamentals and Engineering Applications
Herausgeber: Chiachio-Ruano, Juan; Sankararaman, Shankar; Chiachio-Ruano, Manuel
Bayesian Inverse Problems
Fundamentals and Engineering Applications
Herausgeber: Chiachio-Ruano, Juan; Sankararaman, Shankar; Chiachio-Ruano, Manuel
- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
This book is devoted to a special class of engineering problems called Bayesian inverse problems. These problems comprise not only the probabilistic Bayesian formulation of engineering problems, but also the associated stochastic simulation methods needed to solve them.
Andere Kunden interessierten sich auch für
- Regularization and Bayesian Methods for Inverse Problems in Signal and Image Processing184,99 €
- Smart Healthcare Monitoring Using IoT with 5G184,99 €
- Handbook of Measurements253,99 €
- Robert B PojasekOrganizational Risk Management and Sustainability160,99 €
- Thomas J DayThe Triumvirate Approach to Systems Engineering, Technology Management and Engineering Management351,99 €
- Extenics and Innovation Methods249,99 €
- N.V. KorovkinInverse Problems in Electric Circuits and Electromagnetics119,99 €
-
-
-
This book is devoted to a special class of engineering problems called Bayesian inverse problems. These problems comprise not only the probabilistic Bayesian formulation of engineering problems, but also the associated stochastic simulation methods needed to solve them.
Produktdetails
- Produktdetails
- Verlag: Taylor and Francis
- Seitenzahl: 232
- Erscheinungstermin: 11. November 2021
- Englisch
- Abmessung: 254mm x 178mm x 16mm
- Gewicht: 653g
- ISBN-13: 9781138035850
- ISBN-10: 1138035858
- Artikelnr.: 60020399
- Verlag: Taylor and Francis
- Seitenzahl: 232
- Erscheinungstermin: 11. November 2021
- Englisch
- Abmessung: 254mm x 178mm x 16mm
- Gewicht: 653g
- ISBN-13: 9781138035850
- ISBN-10: 1138035858
- Artikelnr.: 60020399
Juan Chiachío-Ruano is an Associate Professor of Structural Engineering at University of Granada (Spain), and a researcher at the Andalusian Research Institute in Data Science and Computational Intelligence (DaSCI). He has devoted his research career to the study and development of Bayesian methods in application to a wide range of Mechanical and Structural Engineering problems. Prior to joining University of Granada, he has developed a significant international research career working at top academic institutions in the UK and the USA. Manuel Chiachío-Ruano holds a PhD in Structural Engineering (2014) by the University of Granada (Spain). Currently, he is Associate Professor and Head of the Intelligent Prognostics and Cyber-physical Structural Systems Laboratory (iPHMLab) at the University of Granada. He has developed a significant part of his research in collaboration with the California Institute of Technology (USA), the University of Nottingham (UK) and NASA Ames Research Center (USA), during his stays at these institutions. Shankar Sankararaman received his PhD in Civil Engineering from Vanderbilt University, Nashville, TN, USA, in 2012. Soon after, he joined NASA Ames Research Center, where he developed Machine Learning algorithms and Bayesian methods for system health monitoring, prognostics, decision-making, and uncertainty management. Dr Sankararaman has co-authored a book on prognostics and published over 100 technical articles in international journals and conferences. Presently, Shankar is a scientist at Intuit AI, where he focuses on implementing cutting edge research in products and solutions for Intuit's customers.
Part 1 Fundamentals 1. Introduction to Bayesian Inverse Problems 2. Solving
Inverse Problems by Approximate Bayesian Computation 3. Fundamentals of
Sequential System Monitoring and Prognostics Methods 4. Parameter
Identification Based on Conditional Expectation Part 2 Engineering
Applications 5. Sparse Bayesian Learning and its Application in Bayesian
System Identification 6. Ultrasonic Guided-waves Based Bayesian Damage
Localisation and Optimal Sensor Configuration 7. Fast Bayesian Approach for
Stochastic Model Updating using Modal Information from Multiple Setups 8. A
Worked-out Example of Surrogate-based Bayesian Parameter and Field
Identification Methods
Inverse Problems by Approximate Bayesian Computation 3. Fundamentals of
Sequential System Monitoring and Prognostics Methods 4. Parameter
Identification Based on Conditional Expectation Part 2 Engineering
Applications 5. Sparse Bayesian Learning and its Application in Bayesian
System Identification 6. Ultrasonic Guided-waves Based Bayesian Damage
Localisation and Optimal Sensor Configuration 7. Fast Bayesian Approach for
Stochastic Model Updating using Modal Information from Multiple Setups 8. A
Worked-out Example of Surrogate-based Bayesian Parameter and Field
Identification Methods
Part 1 Fundamentals 1. Introduction to Bayesian Inverse Problems 2. Solving
Inverse Problems by Approximate Bayesian Computation 3. Fundamentals of
Sequential System Monitoring and Prognostics Methods 4. Parameter
Identification Based on Conditional Expectation Part 2 Engineering
Applications 5. Sparse Bayesian Learning and its Application in Bayesian
System Identification 6. Ultrasonic Guided-waves Based Bayesian Damage
Localisation and Optimal Sensor Configuration 7. Fast Bayesian Approach for
Stochastic Model Updating using Modal Information from Multiple Setups 8. A
Worked-out Example of Surrogate-based Bayesian Parameter and Field
Identification Methods
Inverse Problems by Approximate Bayesian Computation 3. Fundamentals of
Sequential System Monitoring and Prognostics Methods 4. Parameter
Identification Based on Conditional Expectation Part 2 Engineering
Applications 5. Sparse Bayesian Learning and its Application in Bayesian
System Identification 6. Ultrasonic Guided-waves Based Bayesian Damage
Localisation and Optimal Sensor Configuration 7. Fast Bayesian Approach for
Stochastic Model Updating using Modal Information from Multiple Setups 8. A
Worked-out Example of Surrogate-based Bayesian Parameter and Field
Identification Methods