Distributed Cooperative Communication and Link Prediction in Cloud Robotics

While deploying large scale heterogeneous robots in a wide geographical area, communicating among robots and robots with a central entity pose a major challenge due to robotic motion, distance and environmental constraints. In a cloud robotics scenario, communication challenges result in computational challenges as the computation is being performed at the cloud. Therefore fog nodes are introduced which shorten the distance between the robots and cloud and reduce the communication challenges. Fog nodes also reduce the computation challenges with extra compute power. However in the above scenario, maintaining continuous communication between the cloud and the robots either directly or via fog nodes is difficult. Therefore we propose a Distributed Cooperative Multi-robots Communication (DCMC) model where Robot to Robot (R2R), Robot to Fog (R2F) and Fog to Cloud (F2C) communications are being realized. Once the DCMC framework is formed, each robot establishes communication paths to maintain a consistent communication with the cloud. Further, due to mobility and environmental condition, maintaining link with a particular robot or a fog node becomes difficult. This requires pre-knowledge of the link quality such that appropriate R2R or R2F communication can be made possible. In a scenario where Global Positioning System (GPS) and continuous scanning of channels are not advisable due to energy or security constraints, we need an accurate link prediction mechanism. In this paper we propose a Collaborative Robotic based Link Prediction (CRLP) mechanism which predicts reliable communication and quantify link quality evolution in R2R and R2F communications without GPS and continuous channel scanning. We have validated our proposed schemes using joint Gazebo/Robot Operating System (ROS), MATLAB and Network Simulator (NS3) based simulations. Our schemes are efficient in terms of energy saving and accurate link prediction.

[1]  Pieter Abbeel,et al.  Image Object Label 3 D CAD Model Candidate Grasps Google Object Recognition Engine Google Cloud Storage Select Feasible Grasp with Highest Success Probability Pose EstimationCamera Robots Cloud 3 D Sensor , 2014 .

[2]  Wolfram Burgard,et al.  Probabilistic Robotics (Intelligent Robotics and Autonomous Agents) , 2005 .

[3]  Anantha P. Chandrakasan,et al.  An application-specific protocol architecture for wireless microsensor networks , 2002, IEEE Trans. Wirel. Commun..

[4]  Luca Maria Gambardella,et al.  A fully distributed communication-based approach for spatial clustering in robotic swarms , 2012, AAMAS 2012.

[5]  Robert Tappan Morris,et al.  a high-throughput path metric for multi-hop wireless routing , 2003, MobiCom '03.

[6]  Aiguo Song,et al.  An empirical analysis for evaluating the link quality of robotic sensor networks , 2009, 2009 International Conference on Wireless Communications & Signal Processing.

[7]  Jyotirmoy Karjee,et al.  Energy Aware Node Selection for Cluster-based Data Accuracy Estimation in Wireless Sensor Networks , 2011, ArXiv.

[8]  David E. Culler,et al.  Evaluation of Efficient Link Reliability Estimators for Low-Power Wireless Networks , 2004 .

[9]  Luca Maria Gambardella,et al.  A mobility-controlled link quality learning protocol for multi-robot coordination tasks , 2014, 2014 IEEE International Conference on Robotics and Automation (ICRA).

[10]  Jyotirmoy Karjee,et al.  Data Accuracy Estimation for Cluster with Spatially Correlated Data in Wireless Sensor Networks , 2012, 2012 International Conference on Communication Systems and Network Technologies.

[11]  Ali Marjovi,et al.  Robotic clusters: Multi-robot systems as computer clusters: A topological map merging demonstration , 2012, Robotics Auton. Syst..

[12]  Sateesh Addepalli,et al.  Fog computing and its role in the internet of things , 2012, MCC '12.

[13]  Bernhard Plattner,et al.  Pattern matching based link quality prediction in wireless mobile ad hoc networks , 2006, MSWiM '06.

[14]  Hugh F. Durrant-Whyte,et al.  Simultaneous localization and mapping: part I , 2006, IEEE Robotics & Automation Magazine.

[15]  Chih-Ming Wang Location Estimation and Uncertainty Analysis for Mobile Robots , 1990, Autonomous Robot Vehicles.

[16]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[17]  T. Başar,et al.  A New Approach to Linear Filtering and Prediction Problems , 2001 .

[18]  Jindong Tan,et al.  Maintaining Communication Links Using a Team of Mobile Robots , 2012, Int. J. Comput. Commun. Control.

[19]  Alfred O. Hero,et al.  Using proximity and quantized RSS for sensor localization in wireless networks , 2003, WSNA '03.