3,061 research outputs found
Robot task specification and execution through relational positioning
This paper presents a relational positioning methodology for flexibly and intuitively specifying offline programmed robot tasks, and for assisting the execution of teleoperated tasks featuring precise or repetitive movements. By formulating an object positioning problem in terms of symbolic geometric constraints, the movements of an object can be restricted totally or partially, independently of its initial configuration. To solve the problem, a 3D sequential geometric constraint solver called PMF –Positioning Mobile with respect to Fixed– has been developed. PMF exploits the fact that in geometric constraint sets the rotational component can often be decoupled from the translational one and solved independently.Peer Reviewe
The real-time learning mechanism of the Scientific Research Associates Advanced Robotic System (SRAARS)
Scientific research associates advanced robotic system (SRAARS) is an intelligent robotic system which has autonomous learning capability in geometric reasoning. The system is equipped with one global intelligence center (GIC) and eight local intelligence centers (LICs). It controls mainly sixteen links with fourteen active joints, which constitute two articulated arms, an extensible lower body, a vision system with two CCD cameras and a mobile base. The on-board knowledge-based system supports the learning controller with model representations of both the robot and the working environment. By consecutive verifying and planning procedures, hypothesis-and-test routines and learning-by-analogy paradigm, the system would autonomously build up its own understanding of the relationship between itself (i.e., the robot) and the focused environment for the purposes of collision avoidance, motion analysis and object manipulation. The intelligence of SRAARS presents a valuable technical advantage to implement robotic systems for space exploration and space station operations
Description of a robotics-oriented relational positioning methodology
This paper presents a relational positioning methodology for flexibly and intuitively specifying offline programmed robot tasks, as well as for assisting the execution of teleoperated tasks demanding precise movements.
In relational positioning, the movements of an object can be restricted totally or partially by specifying its allowed positions in terms of a set of geometric constraints. These allowed positions are found by means of a 3D sequential geometric constraint solver called PMF – Positioning Mobile with respect to Fixed. PMF exploits the fact that in a set of geometric constraints, the rotational component can often be separated from the translational one and solved independently
A framework for robotized teleoperated tasks
"Premio al mejor artĂculo presentado en ROBOT 2011" atorgat pel Grupo de RobĂłtica, VisiĂłn y Control de la Universidad de Sevilla, la Universidad Pablo Olavide i el Centro Avanzado de TecnologĂas Aeroespaciales.Teleoperation systems allow the extension of the
human operator’s sensing and manipulative capability into a
remote environment to perform tasks at a distance, but the
time-delays in the communications affect the stability and
transparency of such systems. This work presents a teleoperation
framework in which some novel tools, such as nonlinear
controllers, relational positioning techniques, haptic guiding
and augmented reality, are used to increase the sensation
of immersion of the human operator in the remote site.
Experimental evidence supports the advantages of the proposed
framework.Award-winningPostprint (published version
Fourth Conference on Artificial Intelligence for Space Applications
Proceedings of a conference held in Huntsville, Alabama, on November 15-16, 1988. The Fourth Conference on Artificial Intelligence for Space Applications brings together diverse technical and scientific work in order to help those who employ AI methods in space applications to identify common goals and to address issues of general interest in the AI community. Topics include the following: space applications of expert systems in fault diagnostics, in telemetry monitoring and data collection, in design and systems integration; and in planning and scheduling; knowledge representation, capture, verification, and management; robotics and vision; adaptive learning; and automatic programming
SmartPM: automatic adaptation of dynamic processes at run-time
The research activity outlined in this thesis is devoted to define a general approach, a concrete architecture and a prototype Process Management System (PMS) for the automated adaptation of dynamic processes at run-time, on the basis of a declarative specification of process tasks and relying on well-established reasoning about actions and planning techniques. The purpose is to demonstrate that the combination of procedural and imperative models with declarative elements, along with the exploitation of techniques from the field of artificial intelligence (AI), such as Situation Calculus, IndiGolog and automated planning, can increase the ability of existing PMSs of supporting dynamic processes. To this end, a prototype PMS named SmartPM, which is specifically tailored for supporting collaborative work of process participants during pervasive scenarios, has been developed. The adaptation mechanism deployed on SmartPM is based on execution monitoring for detecting failures at run-time, which does not require the definition of the adaptation strategy in the process itself (as most of the current approaches do), and on automatic planning techniques for the synthesis of the recovery procedure
Graphical modelling of modular machines
This research is aimed at advancing machine design through specifying and implementing
(in "proof of concept" form) a set of tools which graphically model modular machines.
The tools allow mechanical building elements (or machine modules) to be selected and
configured together in a highly flexible manner so that operation of the chosen configuration
can be simulated and performance properties evaluated. Implementation of the tools
has involved an extension in capability of a proprietary robot simulation system. This research has resulted in a general approach to graphically modelling manufacturing machines
built from modular elements.
A focus of study has been on a decomposition of machine functionality leading to the establishment
of a library of modular machine primitives. This provides a useful source of
commonly required machine building elements for use by machine designers. Study has
also focussed on the generation of machine configuration tools which facilitate the construction
of a simulation model and ultimately the physical machine itself. Simulation aspects
of machine control are also considered which depict methods of manipulating a
machine model in the simulation phase. In addition methods of achieving machine programming
have been considered which specify the machine and its operational tasks.
Means of adopting common information data structures are also considered which can facilitate
interfacing with other systems, including the physical machine system constructed
as an issue of the simulation phase. Each of these study areas is addressed in its own context,
but collectively they provide a means of creating a complete modular machine design
environment which can provide significant assistance to machine designers.
Part of the methodology employed in the study is based on the use of the discrete event
simulation technique. To easily and effectively describe a modular machine and its activity
in a simulation model, a hierarchical ring and tree data structure has been designed and
implemented. The modularity and reconfigurability are accommodated by the data structure,
and homogeneous transformations are adopted to determine the spatial location and
orientation of each of the machine elements.
A three-level machine task programming approach is used to describe the machine's activities.
A common data format method is used to interface the machine design environment
with the physical machine and other building blocks of manufacturing systems (such as
CAD systems) where systems integration approaches can lead to enhanced product realisation.
The study concludes that a modular machine design environment can be created by employing
the graphical simulation approach together with a set of comprehensive configuration.
tools. A generic framework has been derived which outlines the way in which
machine design environments can be constructed and suggestions are made as to how the
proof of concept design environment implemented in this study can be advanced
The planning coordinator: A design architecture for autonomous error recovery and on-line planning of intelligent tasks
Developing a robust, task level, error recovery and on-line planning architecture is an open research area. There is previously published work on both error recovery and on-line planning; however, none incorporates error recovery and on-line planning into one integrated platform. The integration of these two functionalities requires an architecture that possesses the following characteristics. The architecture must provide for the inclusion of new information without the destruction of existing information. The architecture must provide for the relating of pieces of information, old and new, to one another in a non-trivial rather than trivial manner (e.g., object one is related to object two under the following constraints, versus, yes, they are related; no, they are not related). Finally, the architecture must be not only a stand alone architecture, but also one that can be easily integrated as a supplement to some existing architecture. This thesis proposal addresses architectural development. Its intent is to integrate error recovery and on-line planning onto a single, integrated, multi-processor platform. This intelligent x-autonomous platform, called the Planning Coordinator, will be used initially to supplement existing x-autonomous systems and eventually replace them
An overview of decision table literature 1982-1995.
This report gives an overview of the literature on decision tables over the past 15 years. As much as possible, for each reference, an author supplied abstract, a number of keywords and a classification are provided. In some cases own comments are added. The purpose of these comments is to show where, how and why decision tables are used. The literature is classified according to application area, theoretical versus practical character, year of publication, country or origin (not necessarily country of publication) and the language of the document. After a description of the scope of the interview, classification results and the classification by topic are presented. The main body of the paper is the ordered list of publications with abstract, classification and comments.
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