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Line 1: {{Short description\|Reference model for military unmanned vehicles to identify and organize their software components}} [[File:4D-RCS reference model architecture for an individual vehicle.jpg\|thumb\|420px\|4D-RCS reference model architecture for an individual vehicle. It contains many layers of computational nodes each containing elements of sensory processing, world modeling, value judgment, and behavior generation.]] The '''4D/RCS Reference Model Architecture''' is a [[reference model]] for military [[unmanned vehicle]]s on how their [[software]] components should be identified and organized. Line 4 ⟶ 5: The 4D/RCS has been developed by the Intelligent Systems Division (ISD) of the [[National Institute of Standards and Technology]] (NIST) since the 1980s.<ref>Danil Prokhorov (2008) ''Computational Intelligence in Automotive Applications''. p. 315</ref> This reference model is based on the general [[Real-time Control System]] (RCS) Reference Model Architecture, and has been applied to many kinds of robot control, including autonomous vehicle control.<ref name="Albus06">Albus, J.S. et al. (2006). "[https://www.nist.gov/cgi-bin//get_pdf.cgi?pub_id=822702 Learning in a Hierarchical Control System: 4D/RCS in the DARPA LAGR Program]{{Dead link\|date=July 2023 \|bot=InternetArchiveBot \|fix-attempted=yes }}". NIST June 26, 2006. in: ''ICINCO 06 - International Conference in Control, Automation and Robotics, Setubal, Portugal, August 2006''</ref> ==Overview== Line 11 ⟶ 12: According to Balakirsky (2003) 4D/RCS is an example of deliberative [[agent architecture]]. These architectures "include all systems that plan to meet future goal or deadline. In general, these systems plan on a model of the world rather than planning directly on processed sensor output. This may be accomplished by real-time [[sensor]]s, [[A priori and a posteriori\|a priori]] information, or a combination of the two in order to create a picture or snapshot of the world that is used to update a world model".<ref name="SBB03">S.B. Balakirsky (2003). ''A framework for planning with incrementally created graphs in attributed problem spaces''. IOS Press. {{ISBN\|1-58603-370-0}}. p.10-11.</ref> The course of action of a deliberative agent architecture is based on the world model and the commanded mission goal, see image. This goal "may be a given system state or physical ___location. To meet the goal systems of this kind attempts to compute a path through a multi-dimensional space contained in the real world".<ref name="SBB03"/> The 4D/RCS is a hierarchical ~~deliverative~~deliberative architecture, that "plans up to the [[subsystem]] level to compute plans for an [[autonomous vehicle]] driving over rough terrain. In this system, the world model contains a pre-computed dictionary of possible vehicle trajectories known as an [[ego-graph]] as well as information from the real-time sensor processing. The trajectories are computed based on a discrete set of possible vehicle velocities and starting steering angles. All of the trajectories are guaranteed to be dynamically correct for the given velocity and steering angle. The systems runs under a fixed planning cycle, with the sensed information being updated into the world model at the beginning of the cycle. These update information include information on what area is currently under observation by the sensors, where detected obstacles exist, and vehicle status".<ref name="SBB03"/> ==History== The National Institute of Standards and ~~Technology’s~~Technology's (NIST) Intelligent Systems Division (ISD) has been developing the [[RCS reference model architecture]] for over 30 years. 4D/RCS is the most recent version of RCS developed for the Army Research Lab Experimental Unmanned Ground Vehicle program. The 4D in 4D/RCS signifies adding time as another dimension to each level of the three-dimensional (sensor processing, world modeling, behavior generation), hierarchical control structure. ISD has studied the use of 4D/RCS in defense mobility, transportation, robot cranes, manufacturing, and several other applications.<ref name="Albus06"/> 4D/RCS integrates the NIST Real-time Control System (RCS) architecture with the German ([[Bundeswehr University of Munich]]) [[Ernst Dickmanns\|VaMoRs 4-D approach]] to dynamic machine vision. It incorporates many concepts developed under the U.S. Department of Defense Demo I, Demo II, and Demo III programs, which demonstrated increasing levels of robotic vehicle autonomy. The theory embodied in 4D/RCS borrows heavily from cognitive psychology, semiotics, neuroscience, and artificial intelligence.<ref name="Albus02">Albus et al. (2002). ''4D-RCS A Reference Model Architecture For Unmanned Vehicle Systems Version 2.0''. National Institute of Standards and Technology, Gaithersburg, Maryland 20899Aug 2002.</ref> Three [[United States Government\|US Government]] funded military efforts known as Demo I (US Army), Demo II (DARPA), and Demo III ([[US Army]]), are currently underway. Demo III (2001)<ref>{{cite conference\|url=http://www.isd.mel.nist.gov/documents/albus/4DRCS.pdf \|format=PDF \|title=4-D/RCS reference model architecture for unmanned ground vehicles \|first=J.A. \|last=Albus \|~~booktitle~~book-title=Proc. of Symposium on Aerospace/Defense Sensing, Simulation and Controls \|___location=Orlando, FL \|year=2002 \|url-status=dead \|~~archiveurl~~archive-url=https://web.archive.org/web/20040725051856/http://www.isd.mel.nist.gov/documents/albus/4DRCS.pdf \|~~archivedate~~archive-date=2004-07-25 }}</ref> demonstrated the ability of unmanned ground vehicles to navigate miles of difficult off-road terrain, avoiding obstacles such as rocks and trees. [[James Albus]] at [[NIST]] provided the [[Real-time Control System]] which is a [[hierarchical control system]]. Not only were individual vehicles controlled (e.g. throttle, steering, and brake), but groups of vehicles had their movements automatically coordinated in response to high level goals. In 2002, the [[DARPA Grand Challenge]] competitions were announced. The [[DARPA Grand Challenge (2005)\|2004]] and [[DARPA Grand Challenge (2005)\|2005 DARPA competitions]] allowed international teams to compete in fully autonomous vehicle races over rough unpaved terrain and in a non-populated suburban setting. The [[DARPA Grand Challenge (2007)\|2007 DARPA challenge]], the DARPA urban challenge, involved autonomous cars driving in an urban setting. Line 53 ⟶ 54: # sensory processing, and # value judgment. There is also a [[knowledge base\|knowledge database]] that represents the ~~node’s~~node's best estimate of the state of the world at the range and resolution that are appropriate for the behavioral decisions that are the responsibility of that node. Line 84 ⟶ 85: ==External links== {{commons category~~\|4D-RCS Reference Model Architecture~~}} * [https://web.archive.org/web/20091010082639/http://www.isd.mel.nist.gov/projects/rcs/ RCS The Real-time Control Systems Architecture] NIST Homepage Line 90 ⟶ 91: [[Category:Control theory]] [[Category:Industrial computing]] [[Category:~~Unmanned~~Uncrewed vehicles]]