Localizability-Constrained Deployment of Mobile Robotic Networks with Noisy Range Measurements

When nodes in a mobile network use relative noisy measurements with respect to their neighbors to estimate their positions, the overall connectivity and geometry of the measurement network has a critical influence on the achievable localization accuracy. This paper considers the problem of deploying a mobile robotic network implementing a cooperative localization scheme based on range measurements only, while attempting to maintain a network geometry that is favorable to estimating the robots' positions with high accuracy. The quality of the network geometry is measured by a “localizability” function serving as potential field for robot motion planning. This function is built from the Cramér-Rao bound, which provides for a given geometry a lower bound on the covariance matrix achievable by any unbiased position estimator that the robots might implement using their relative measurements. We describe gradient descent-based motion planners for the robots that attempt to optimize or constrain different variations of the network's localizability function, and discuss ways of implementing these controllers in a distributed manner. Finally, the paper also establishes formal connections between our statistical point of view and maintaining a form of weighted rigidity for the graph capturing the relative range measurements.

[1]  B. Roth Rigid and Flexible Frameworks , 1981 .

[2]  R.L. Moses,et al.  Locating the nodes: cooperative localization in wireless sensor networks , 2005, IEEE Signal Processing Magazine.

[3]  Paul Keng-Chieh Wang Navigation strategies for multiple autonomous mobile robots moving in formation , 1991, J. Field Robotics.

[4]  B. C. Ng,et al.  On the Cramer-Rao bound under parametric constraints , 1998, IEEE Signal Processing Letters.

[5]  Mani B. Srivastava,et al.  Dynamic fine-grained localization in Ad-Hoc networks of sensors , 2001, MobiCom '01.

[6]  R.M. Taylor,et al.  Computing the recursive posterior Cramer-Rao bound for a nonlinear nonstationary system , 2003, 2003 IEEE International Conference on Acoustics, Speech, and Signal Processing, 2003. Proceedings. (ICASSP '03)..

[7]  G.B. Giannakis,et al.  Localization via ultra-wideband radios: a look at positioning aspects for future sensor networks , 2005, IEEE Signal Processing Magazine.

[8]  Amir Asif,et al.  Decentralized sensor selection based on the distributed posterior Cramér-Rao lower bound , 2012, 2012 15th International Conference on Information Fusion.

[9]  Brian D. O. Anderson,et al.  Sensor network localization with imprecise distances , 2006, Syst. Control. Lett..

[10]  Brian D. O. Anderson,et al.  Rigidity, computation, and randomization in network localization , 2004, IEEE INFOCOM 2004.

[11]  David C. Moore,et al.  Robust distributed network localization with noisy range measurements , 2004, SenSys '04.

[12]  Siddhartha S. Srinivasa,et al.  Decentralized estimation and control of graph connectivity in mobile sensor networks , 2008, 2008 American Control Conference.

[13]  Hongyan Wang,et al.  Social potential fields: A distributed behavioral control for autonomous robots , 1995, Robotics Auton. Syst..

[14]  Jang-Ping Sheu,et al.  Distributed Localization Scheme for Mobile Sensor Networks , 2010, IEEE Transactions on Mobile Computing.

[15]  Oussama Khatib,et al.  Real-Time Obstacle Avoidance for Manipulators and Mobile Robots , 1986 .

[16]  Y. Bar-Shalom,et al.  Multisensor resource deployment using posterior Cramer-Rao bounds , 2004, IEEE Transactions on Aerospace and Electronic Systems.

[17]  Gordon F. Royle,et al.  Algebraic Graph Theory , 2001, Graduate texts in mathematics.

[18]  George J. Pappas,et al.  Adaptive Deployment of Mobile Robotic Networks , 2013, IEEE Transactions on Automatic Control.

[19]  Francesco Bullo,et al.  Distributed Control of Robotic Networks , 2009 .

[20]  Alejandro Ribeiro,et al.  Adaptive Communication-Constrained Deployment of Unmanned Vehicle Systems , 2012, IEEE Journal on Selected Areas in Communications.

[21]  Antonio Franchi,et al.  Decentralized rigidity maintenance control with range measurements for multi-robot systems , 2013, Int. J. Robotics Res..

[22]  F. Pukelsheim Optimal Design of Experiments , 1993 .

[23]  D. Ucinski Optimal measurement methods for distributed parameter system identification , 2004 .

[24]  T. Minka Old and New Matrix Algebra Useful for Statistics , 2000 .

[25]  Antonio Franchi,et al.  Rigidity Maintenance Control for Multi-Robot Systems , 2012, Robotics: Science and Systems.

[26]  Mireille E. Broucke,et al.  Stabilisation of infinitesimally rigid formations of multi-robot networks , 2009, Int. J. Control.