0000000000082979

AUTHOR

Craig Schlenoff

showing 8 related works from this author

Ontology-based state representations for intention recognition in human–robot collaborative environments

2013

In this paper, we describe a novel approach for representing state information for the purpose of intention recognition in cooperative human-robot environments. States are represented by a combination of spatial relationships in a Cartesian frame along with cardinal direction information. This approach is applied to a manufacturing kitting operation, where humans and robots are working together to develop kits. Based upon a set of predefined high-level state relationships that must be true for future actions to occur, a robot can use the detailed state information described in this paper to infer the probability of subsequent actions occurring. This would allow the robot to better help the …

Computer sciencebusiness.industryGeneral MathematicsTemplate matchingFrame (networking)Ontology (information science)Human–robot interactionComputer Science ApplicationsTask (project management)Control and Systems EngineeringRobotArtificial intelligenceState (computer science)Set (psychology)businessSoftwareRobotics and Autonomous Systems
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Evaluating State-Based Intention Recognition Algorithms against Human Performance

2014

In this paper, we describe a novel intention recognition approach based on the representation of state information in a cooperative human-robot environment. We compare the output of the intention recognition algorithms to those of an experiment involving humans attempting to recognize the same intentions in a manufacturing kitting domain. States are represented by a combination of spatial relationships in a Cartesian frame along with cardinal direction information. Based upon a set of predefined high-level states relationships that must be true for future actions to occur, a robot can use the approaches described in this paper to infer the likelihood of subsequent actions occurring. This wo…

Computer sciencebusiness.industryFrame (networking)RoboticsMachine learningcomputer.software_genreDomain (software engineering)RobotArtificial intelligenceState (computer science)Representation (mathematics)Set (psychology)businesscomputerCardinal direction
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Inferring intentions through state representations in cooperative human-robot environments

2014

Humans and robots working safely and seamlessly together in a cooperative environment is one of the future goals of the robotics community. When humans and robots can work together in the same space, a whole class of tasks becomes amenable to automation, ranging from collaborative assembly to parts and material handling to delivery. Proposed standards exist for collaborative human-robot safety, but they focus on limiting the approach distances and contact forces between the human and the robot. These standards focus on reactive processes based only on current sensor readings. They do not consider future states or task-relevant information. A key enabler for human-robot safety in cooperative…

Human-robot collaborationOntology[INFO.INFO-OH]Computer Science [cs]/Other [cs.OH]Intention recognitionBayesian[INFO.INFO-OH] Computer Science [cs]/Other [cs.OH]KittingReconnaissance de l'intentionManufacturingState relationsRCC8[ INFO.INFO-OH ] Computer Science [cs]/Other [cs.OH]SimulationUSARSim
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Intention recognition in manufacturing applications

2015

In this article, we present a novel approach to intention recognition, based on the recognition and representation of state information in a cooperative human-robot environment. States are represented by a combination of spatial relations along with cardinal direction information. The output of the Intention Recognition Algorithms will allow a robot to help a human perform a perceived operation or, minimally, not cause an unsafe situation to occur. We compare the results of the Intention Recognition Algorithms to those of an experiment involving human subjects attempting to recognize the same intentions in a manufacturing kitting domain. In almost every case, results show that the Intention…

Human-robot collaborationOntologybusiness.industryComputer scienceGeneral MathematicsManufacturing kittingRoboticsIntention recognitionRoboticsOntology (information science)Industrial and Manufacturing EngineeringComputer Science ApplicationsDomain (software engineering)Task (project management)Spatial relationControl and Systems EngineeringHuman–computer interactionRobotArtificial intelligenceState recognitionbusinessRepresentation (mathematics)SoftwareCardinal directionRobotics and Computer-Integrated Manufacturing
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Ontology-based state representation for intention recognition in cooperative human-robot environments

2012

In this paper, we describe a novel approach for representing state information for the purpose of intention recognition in cooperative human-robot environments. States are represented by a combination of spatial relationships in a Cartesian frame along with cardinal direction information. This approach is applied to a manufacturing kitting operation, where humans and robots are working together to develop kits. Based upon a set of predefined high-level states relationships that must be true for future actions to occur, a robot can use the detailed state information presented in this paper to infer the probability of subsequent actions occurring. This would enable the robot to better help th…

business.industryComputer scienceFrame (networking)RobotRoboticsArtificial intelligenceOntology (information science)Set (psychology)businessHuman–robot interaction
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A literature review of sensor ontologies for manufacturing applications

2013

The purpose of this paper is to review existing sensor and sensor network ontologies to understand whether they can be reused as a basis for a manufacturing perception sensor ontology, or if the existing ontologies hold lessons for the development of a new ontology. We develop an initial set of requirements that should apply to a manufacturing perception sensor ontology. These initial requirements are used in reviewing selected existing sensor ontologies. Additionally, we present our developed sensor ontology thus far that incorporates a refined list of requirements. This paper describes 1) extending and refining the requirements; 2) proposing hierarchical structures for verifying the purpo…

Ontology Inference LayerDatabaseComputer sciencebusiness.industrycomputer.internet_protocolOntology-based data integrationProcess ontologySuggested Upper Merged OntologyOntology (information science)computer.software_genreOWL-SUpper ontologySoftware engineeringbusinesscomputerOntology alignment2013 IEEE International Symposium on Robotic and Sensors Environments (ROSE)
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Fuzzy-logic-based approach for identifying objects of interest in the PRIDE framework

2008

On-road autonomous vehicle navigation requires real-time motion planning in the presence of static and moving objects. Based on sensed data of the environment and the current traffic situation, an autonomous vehicle has to plan a path by predicting the future location of objects of interest. In this context, an object of interest is a moving or stationary object in the environment that has a reasonable probability of intersecting the path of the autonomous vehicle within a predetermined time frame. This paper investigates the identification of objects of interest within the PRIDE (PRediction In Dynamic Environments) framework. PRIDE is a multi-resolutional, hierarchical framework that predi…

Collision avoidance (spacecraft)Situation awarenessComputer sciencebusiness.industryReal-time computingContext (language use)Object (computer science)Fuzzy logicIdentification (information)RobotComputer visionMotion planningArtificial intelligencebusinessProceedings of the 8th Workshop on Performance Metrics for Intelligent Systems
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Performance evaluation of robotic knowledge representation (PERK)

2012

In this paper, we explore some ways in which symbolic knowledge representations have been evaluated in the past and provide some thoughts on what should be considered when applying and evaluating these types of knowledge representations for real-time robotics applications. The emphasis of this paper is that the robotic applications require real-time access to information, which has not been one of the aspects measured in traditional symbolic representation evaluation approaches.

Descriptive knowledgeAccess to informationKnowledge representation and reasoningComputer scienceHuman–computer interactionbusiness.industryRepresentation (systemics)RoboticsRobotic paradigmsArtificial intelligencebusinessProceedings of the Workshop on Performance Metrics for Intelligent Systems
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