The Thing Description (TD) ontology is an RDF axiomatization of the TD information model, one of the building blocks of the Web of Things (WoT). Besides providing an alternative to the standard JSON representation format for TD documents, the TD ontology can also be used to process contextual information on Things and for alignments with other WoT-related ontologies.
This document provides the basic concepts for IoT systems semantic interoperability, as described in the facet model of ISO/IEC 21823-1, including: - requirements of the core ontologies for semantic interoperability; - best practices and guidance on how to use ontologies and to develop domain-specific applications, including the need to allow for extensibility and connection to external ontologies; - cross-domain specification and formalization of ontologies to provide harmonized utilization of existing ontologies; - relevant IoT ontologies along with comparative study of the characteristics and approaches in terms of modularity, extensibility, reusability, scalability, interoperability with upper ontologies, and so on, and; - use cases and service scenarios that exhibit necessities and requirements of semantic interoperability.
This document provides guidance on safety measures for the design and integration of end-effectors used for robot systems. The integration includes the following:— the manufacturing, design and integration of end-effectors. — the necessary information for use.This document provides additional safety guidance on the integration of robot systems, as described in ISO 10218‑2:2011.
This Technical Specification specifies safety requirements for collaborative industrial robot systems and the work environment, and supplements the requirements and guidance on collaborative industrial robot operation given in ISO 10218-1 and ISO 10218-2 [ANSI/RIA R15.06-2012].This Technical Specification applies to industrial robot systems as described in ISO 10218-1 and ISO 10218-2 [ANSI/RIA R15.06-2012]. It does not apply to non-industrial robots, although the safety principles presented can be useful to other areas of robotics.
This technical report is written for users of industrial robots or robot systems that comply with ANSI/RIA R15.06-2012 Part 1, a responsibility of the robot manufacturer; and of industrial robot systems that comply with ANSI/RIA R15.06-2012 Part 2, a responsibility of the integrator. This technical report explains some user responsibilities and provides guidance to the user of robot systems to enable the safe use of the robot system(s) in their facilities. Compliance with this technical report is only achievable when using robot and robot systems that are compliant with ANSI/RIA R15.06-2012.
TR 506 explains how to take the 2012 R15.06 standard into account for existing robot systems, rather than the all-new robot installation that is the primary topic of the 2012 R15.06. The TR 506 document as published in 2014 continues to be the current active version.
The purpose of this technical report is to provide interpretation of certain provisions of ANSI/RIA R15.06-1999 and to present examples of current industry practices for teaching (programming) multiple industrial robots that share a common safeguarded space. This information is in addition to the requirements contained in ANSI/RIA R15.06-1999 and the committee considers the examples to comply with the safety standard.
The purpose of the protocol is to validate the safety skill “limit range of movement” for an angular motion of a single joint of an exoskeleton or a restrained-type rehabilitation robot. The range of motion is measured using an electro-goniometer.
The specific purpose of this protocol is to validate the safety skill “limit interaction energy” by measurement. The skill “limit interaction energy” protects bystanders from injuries caused by collision with the exoskeleton. This protocol is therefore not focusing on the safety of the person attached to the exoskeleton but rather of persons in close proximity of the exoskeleton. For the execution of this protocol it is required that the reader has a bio-fidelic force and pressure measurement device available.
This protocol describes a method for validating the safety skill “Maintain proper alignment” for joint axis alignment (both translational as well as rotational) for exoskeleton type rehabilitation robots as well as exoskeleton type robots used in other domains. This protocol uses an instrumented artificial limb, by which the joint angles, contact forces as well as the forces and torques in the joint can be determined, to validate the skill.