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Multisensor Attitude Estimation: Fundamental Concepts and Applications [Kõva köide]

Edited by (University Grenoble Alpes, France), Edited by
  • Formaat: Hardback, 606 pages, kõrgus x laius: 254x178 mm, kaal: 1244 g, 36 Tables, black and white; 28 Illustrations, color; 218 Illustrations, black and white
  • Sari: Devices, Circuits, and Systems
  • Ilmumisaeg: 15-Aug-2016
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1498745717
  • ISBN-13: 9781498745710
Teised raamatud teemal:
Multisensor Attitude Estimation: Fundamental Concepts and ApplicationsSuurem pilt
  • Formaat: Hardback, 606 pages, kõrgus x laius: 254x178 mm, kaal: 1244 g, 36 Tables, black and white; 28 Illustrations, color; 218 Illustrations, black and white
  • Sari: Devices, Circuits, and Systems
  • Ilmumisaeg: 15-Aug-2016
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1498745717
  • ISBN-13: 9781498745710
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781498745710.html
Märksõnad:
There has been an increasing interest in multi-disciplinary research on multisensor attitude estimation technology driven by its versatility and diverse areas of application, such as sensor networks, robotics, navigation, video, biomedicine, etc. Attitude estimation consists of the determination of rigid bodies orientation in 3D space. This research area is a multilevel, multifaceted process handling the automatic association, correlation, estimation, and combination of data and information from several sources. Data fusion for attitude estimation is motivated by several issues and problems, such as data imperfection, data multi-modality, data dimensionality, processing framework, etc. While many of these problems have been identified and heavily investigated, no single data fusion algorithm is capable of addressing all the aforementioned challenges. The variety of methods in the literature focus on a subset of these issues to solve, which would be determined based on the application in hand. Historically, the problem of attitude estimation has been introduced by Grace Wahba in 1965 within the estimate of satellite attitude and aerospace applications.

This book intends to provide the reader with both a generic and comprehensive view of contemporary data fusion methodologies for attitude estimation, as well as the most recent researches and novel advances on multisensor attitude estimation task. It explores the design of algorithms and architectures, benefits, and challenging aspects, as well as a broad array of disciplines, including: navigation, robotics, biomedicine, motion analysis, etc. A number of issues that make data fusion for attitude estimation a challenging task, and which will be discussed through the different chapters of the book, are related to: 1) The nature of sensors and information sources (accelerometer, gyroscope, magnetometer, GPS, inclinometer, etc.); 2) The computational ability at the sensors; 3) The theoretical developments and convergence proofs; 4) The system architecture, computational resources, fusion level.
Preface xv
Editors xvii
Contributors xix
Historical Note xxv
SECTION I Preliminaries on Attitude Representations and Rotations
Chapter 1 What Are Quaternions and Why Haven't I Heard of Them?
3(12)
Herb Klitzner
Chapter 2 Rotation in 3D Space
15(22)
Ayman F. Habib
Chapter 3 Attitude Parametrization, Kinematics, and Dynamics
37(20)
Lotfi Benziane
Abdelaziz Benallegue
Yacine Chitour
SECTION II Multisensor Filtering for Attitude Estimation: Theories and Applications
Chapter 4 Stable Estimation of Rigid Body Motion Based on the Lagrange-d Alembert Principle
57(20)
Amit K. Sanyal
Maziar Izadi
Chapter 5 The Additive and Multiplicative Approaches to Quaternion Kalman Filtering
77(20)
Renato Zanetti
Robert H. Bishop
Chapter 6 Spacecraft Attitude Determination
97(18)
Yaguang Yang
Chapter 7 How to Deal with the External Acceleration When Estimating the Attitude Using Inertial Measurement Units: A Linear Kalman-Based Filtering Approach
115(14)
Gabriele Ligorio
Angelo Maria Sabatini
Chapter 8 From Attitude Estimation to Pose Estimation Using Dual Quaternions
129(16)
Nuno Filipe
Michail Kontitsis
Panagiotis Tsiotras
Chapter 9 Distributed Estimation for Spatial Rigid Motion Based on Dual Quaternions
145(18)
Yue Zu
Ran Dai
Chapter 10 A Quaternion Orientation from Earth Field Observations Using the Algebraic Quaternion Algorithm: Analysis and Applications in Fusion Algorithms
163(18)
Roberto G. Volenti
Ivan Dryanovski
Jizhong Xiao
Chapter 11 Recent Nonlinear Attitude Estimation Algorithms
181(18)
Seid H. Pourtakdoust
M. Kiani
Chapter 12 Low Complexity Sensor Fusion Solution for Accurate Estimation of Gravity and Linear Acceleration
199(20)
Ramasamy Kannan
Chapter 13 Deterministic Attitude Estimation
219(14)
Abraham P. Vinod
Arun D. Mahindrakar
Chapter 14 Attitude Estimations with Intermittent Observations
233(28)
Naeem Khan
Chapter 15 Estimation of Attitude from a Single-Direction Sensor
261(16)
Lionel Magnis
Nicolas Petit
Chapter 16 Cooperative Attitude Estimation Based on Remote-Access Observations
277(14)
Chao Gao
Guorong Zhao
Jianhua Lu
Chapter 17 Nonlinear Observer for Attitude, Position, and Velocity: Theory and Experiments
291(24)
Havard Fjoer Grip
Thor I. Fossen
Tor A. Johansen
Ali Saberi
Chapter 18 Spacecraft Attitude Estimation Using Sparse Grid Quadrature Filtering
315(16)
Yang Cheng
Chapter 19 Attitude Estimation for Small, Low-Cost UAVs: A Tutorial Approach
331(20)
Gabriel Hugh Elkaim
Demoz Gebre-Egziabher
Chapter 20 3D Orientation Estimation Using Wearable MEMS Inertial/Magnetic Sensors
351(16)
Shaghayegh Zihajehzadeh
Jung Keun Lee
Reynold Hoskinson
Edward J. Park
Chapter 21 Adaptive Data Fusion of Multiple Sensors for Vehicle Pose Estimation
367(24)
Farhad Aghili
Alessio Salerno
Chapter 22 Optimal Invariant Observers Theory for Nonlinear State Estimation
391(18)
Cedric Seren
Jean-Philippe Condomines
Gautier Hattenberger
Chapter 23 Design and Implementation of Low-Cost Attitude Heading References Systems for Micro Aerial Vehicles
409(18)
Jose Fermi Guerrero-Castellanos
German Ardul Munoz-Hernandez
Carlos A. Gracios-Marin
Bernardino Benito Salmeron-Quiroz
Chapter 24 Small Satellite Attitude Determination
427(18)
Demoz Gebre-Egziabher
Chuck S. Hisamoto
Suneel I. Sheikh
Chapter 25 A Hybrid Data Fusion Approach for Robust Attitude Estimation
445(18)
Pedro Santana
Renato Vilela Lopes
Geovany Borges
Brian Williams
Chapter 26 Integration of Single-Frame and Filtering Methods for Nanosatellite Attitude Estimation
463(22)
Halil Ersin Soken
Demet Cilden
Chingiz Hajiyev
Chapter 27 Ego-Motion Tracking in Dynamic Environments Using Wearable Visual-Inertial Sensors
485(28)
Jindong Tan
Hongsheng He
Ya Tian
Yong Guan
William R. Hamel
Chapter 28 Attitude Estimation for a Small-Scale Flybarless Helicopter
513(28)
Mohammad K. S. Al-Sharman
Chapter 29 A Comparison of Multisensor Attitude Estimation Algorithms
529
Andrea Cirillo
Pasquale Cirillo
Giuseppe De Maria
Ciro Natale
Salvatore Pirozzi
Chapter 30 Low-Cost and Accurate Reconstruction of Postures via IMU
541(12)
Gaspare Santaera
Emanule Luberto
Marco Gabiccini
Chapter 31 Attitude Estimation of a UAV Using Optical Flow
553(12)
Lianhua Zhang
Zongying Shi
Yisheng Zhong
Index 565
Hassen Fourati, PhD, is currently an associate professor of the electrical engineering and computer science at the University of Grenoble Alpes, Grenoble, France, and a member of the Networked Controlled Systems Team (NeCS), affiliated to the Automatic Control Department of the GIPSA-Lab. He earned his Bachelor of Engineering degree in Electrical Engineering at the National Engineering School of Sfax, Tunisia in 2006; his Master's degree in Automated Systems and Control at the University of Claude Bernard, Lyon, France in 2007; and his PhD degree in Automatic Control at the University of Strasbourg, France in 2010. His research interests include nonlinear filtering and estimation and multisensor fusion with applications in navigation, robotics, and traffic management. Dr. Fourati has published several research papers in scientific journals, international conferences, and book chapters. He can be reached at hassen.fourati@gipsa-lab.fr.



Djamel Eddine Chouaib Belkhiat, PhD, is an associate professor in the department of physics at the Ferhat Abbas University, Setif 1, Algeria where he is also a member of Intelligent Systems Laboratory. He received the Bachelor of Engineering degree in Electrical Engineering from the Ferhat Abbas University, Setif 1, Algeria in 2007, the Master degree in Automatic Control from the University of Poitiers, France in 2008, and the Ph.D. degree in Automatic Control from the University of Reims Champagne Ardenne, France in 2011. His research interests lie in the area of monitoring and diagnosis of Hybrid Systems. Dr. Belkhiat has published several research papers in scientific journals, international conferences and book chapters. He can be reached at djamel.belkhiat@yahoo.fr.