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References (32)
-
J. Onunga, R. Donaldson (1993)
A simple packet retransmission strategy for throughput and delay enhancement on power line communication channelsIEEE Transactions on Power Delivery, 8
-
R. Turner, S. Rode, D. Gagne (2014)
Distributed Context-Based Organization and Reorganization of Multi-AUV Systems, 2
-
M. Arcak (2007)
Passivity as a Design Tool for Group CoordinationIEEE Transactions on Automatic Control, 52
-
H. Bai, M. Arcak, J. Wen (2008)
Adaptive design for reference velocity recovery in motion coordinationSyst. Control. Lett., 57
-
Dr. Das, B. Subudhi, B. Pati (2014)
Adaptive sliding mode formation control of multiple underwater robotsArchives of Control Sciences, 24
-
Indraneel Kulkarni, D. Pompili (2010)
Task allocation for networked autonomous underwater vehicles in critical missionsIEEE Journal on Selected Areas in Communications, 28
-
B. Subudhi, S. Ge (2012)
Sliding-Mode-Observer-Based Adaptive Slip Ratio Control for Electric and Hybrid VehiclesIEEE Transactions on Intelligent Transportation Systems, 13
-
K. Xiong, L. Liu, Hanxin Zhang (2009)
Modified unscented Kalman filtering and its application in autonomous satellite navigationAerospace Science and Technology, 13
-
B. Sahu, B. Subudhi (2014)
Adaptive Tracking Control of an Autonomous Underwater VehicleInternational Journal of Automation and Computing, 11
-
Pan-Mook Lee, Seok-Won Hong, Yong-Kon Lim, Chong-moo Lee, B. Jeon, Jong-Won Park (1999)
Discrete-time quasi-sliding mode control of an autonomous underwater vehicleIEEE Journal of Oceanic Engineering, 24
-
J. Marshall, M. Broucke, B. Francis (2004)
Formations of vehicles in cyclic pursuitIEEE Transactions on Automatic Control, 49
-
N. Palomeras, J. Garcia, M. Prats, J. Fernandez, P. Sanz, P. Ridao (2010)
A distributed architecture for enabling autonomous underwater Intervention Missions2010 IEEE International Systems Conference
-
J. Zarei, E. Shokri (2014)
Robust sensor fault detection based on nonlinear unknown input observerMeasurement, 48
-
J. Kinsey, Qingjun Yang, J. Howland (2014)
Nonlinear Dynamic Model-Based State Estimators for Underwater Navigation of Remotely Operated VehiclesIEEE Transactions on Control Systems Technology, 22
-
P. Millán, L. Orihuela, I. Jurado, F. Rubio (2014)
Formation Control of Autonomous Underwater Vehicles Subject to Communication DelaysIEEE Transactions on Control Systems Technology, 22
-
T. Fossen (1994)
Guidance and control of ocean vehicles -
Naomi Leonard, D. Paley, F. Lekien, R. Sepulchre, David Fratantoni, R. Davis (2007)
Collective Motion, Sensor Networks, and Ocean SamplingProceedings of the IEEE, 95
-
J. Korhonen, Ye Wang (2005)
Effect of packet size on loss rate and delay in wireless linksIEEE Wireless Communications and Networking Conference, 2005, 3
-
B. Sahu, B. Subudhi, B. Dash (2012)
Flocking control of multiple autonomous underwater vehicles2012 Annual IEEE India Conference (INDICON)
-
R. Skjetne, S. Moi, T. Fossen (2002)
Nonlinear formation control of marine craftProceedings of the 41st IEEE Conference on Decision and Control, 2002., 2
-
Shuyong Liu, Danwei Wang, E. Poh, Yigang Wang (2005)
Dynamic positioning of AUVs in shallow water environment: observer and controller designProceedings, 2005 IEEE/ASME International Conference on Advanced Intelligent Mechatronics.
-
K. Reif, F. Sonnemann, R. Unbehauen (1998)
An EKF-Based Nonlinear Observer with a Prescribed Degree of StabilityAutom., 34
-
Y. Wang, Weisheng Yan, Jinglong Li (2012)
Passivity-based formation control of autonomous underwater vehiclesIet Control Theory and Applications, 6
-
G. Xia, C. Pang, Ju Liu (2013)
Neural-network-based adaptive observer design for autonomous underwater vehicle in shallow water2013 Ninth International Conference on Natural Computation (ICNC)
-
S. Negahdaripour, Sohyung Cho, Joon-Young Kim (2011)
Controller design for an autonomous underwater vehicle using nonlinear observers, 1
-
Dr. Das, B. Subudhi, B. Pati (2016)
Co-operative control coordination of a team of underwater vehicles with communication constraintsTransactions of the Institute of Measurement and Control, 38
-
Jin Cheng, J. Yi, Dongbin Zhao (2007)
Design of a sliding mode controller for trajectory tracking problem of marine vesselsIet Control Theory and Applications, 1
-
Shuyong Liu, Danwei Wang, E. Poh (2008)
Non-linear output feedback tracking control for AUVs in shallow wave disturbance conditionInternational Journal of Control, 81
-
Antonio Aguiar, J. Hespanha (2007)
Trajectory-Tracking and Path-Following of Underactuated Autonomous Vehicles With Parametric Modeling UncertaintyIEEE Transactions on Automatic Control, 52
-
R. Joshi, V. Thakar (2012)
Congestion control in communication networks using discrete sliding mode controlProceedings of the 31st Chinese Control Conference
-
W. Ren, N. Sorensen (2008)
Distributed coordination architecture for multi-robot formation controlRobotics Auton. Syst., 56
-
J. Cortés, S. Martínez, F. Bullo (2006)
Robust rendezvous for mobile autonomous agents via proximity graphs in arbitrary dimensionsIEEE Transactions on Automatic Control, 51
- Publisher
- Emerald Publishing
- Copyright
- Copyright © Emerald Group Publishing Limited
- ISSN
- 2049-6427
- DOI
- 10.1108/IJIUS-04-2015-0004
- Publisher site
- See Article on Publisher Site
Abstract
Purpose – The purpose of this paper is to propose development of a formation control algorithm by employing a nonlinear observer for compensating the delay in the sensor signal transmission to the controller arising due to packet dropout in acoustic medium. Design/methodology/approach – A robust control law is developed using the sliding mode approach integrated with a communication consensus algorithm for achieving cooperative motion of acoustic underwater vehicles in a group ensuring the transfer of information among the AUVs. In acoustic medium, inter-vehicle communication is challenging for a group of AUVs deployed in formation because underwater channel encounter a number of constraints such as low data rate, packet delays and dropouts. Findings – It is observed that the sliding mode control-unscented Kalman filter formation control exhibits superior control performance such as mitigating larger initial error of estimation and removing the use of the Jacobian matrices among the three controllers developed. The proposed nonlinear observer estimates the un-measureable states such as position in x , y and z -axes, heading, rudder and sturn angle, needed for generating the formation control. A simulation setup is realized to demonstrate the performance of the proposed observer-based formation controller. Simulations were performed in MATLAB and the obtained results are analysed and compared which envisage that the proposed control algorithm provides efficient formation control under the acoustic communication constraints. Originality/value – Development of observer for achieving formation control of AUVs in underwater area – common reference velocity and error signals being available to all cooperating AUVs – UKO performs better based on initial error estimation and tracking the same path in shallow water area.
Journal
International Journal of Intelligent Unmanned Systems – Emerald Publishing
Published: May 11, 2015