ETSI
ETSI
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Technical committeeTypeAcronymETSI TS 103 735CommitteePublished year2021Description
Standardize the IoT system for Smart Lifts. It includes : -the identification of the relevant roles; -the Information models in the Smart Lift system, including signals, alarms and commands; -the mapping to Semantic model of oneM2M (SDT) and ETSI SAREF; -the communication system;
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Technical committeeTypeAcronymETSI TS 103 268-4 V1.1.1 (2017-04)CommitteePublished year2017KeywordsDescription
The present document provides the Test Suite Structure and Test Purposes (TSS & TP) for Conformance test specifications for Smart Appliances testing as defined in ETSI TS 103 268-1 [3] and ETSI TS 118 115 [5] in compliance with the relevant requirements and in accordance with the relevant guidance given in ISO/IEC 9646-7 [4]
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Technical committeeTypeAcronymETSI TS 103 268-3 V1.1.1 (2017-04)CommitteePublished year2017Description
The present document contains the Abstract Test Suite (ATS) for SmartAppliances as defined in ETSI TS 103 264 [1] and ETSI TS 103 267 [2] in compliance with the relevant requirements and in accordance with the relevant guidance given in ISO/IEC 9646-7 [6]. The objective of the present document is to provide a basis for conformance tests for SmartAppliances equipment giving a high probability of inter-operability between different manufacturer's equipment
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Technical committeeTypeAcronymETSI TS 103 268-2 V1.1.1 (2017-04)CommitteePublished year2017KeywordsDescription
The present document provides the Protocol Implementation Conformance Statement (PICS) pro forma for Conformance test specifications for Smart Appliances testing as defined in ETSI TS 103 268-1 [6] and ETSI TS 118 115 [8] in compliance with the relevant requirements and in accordance with the relevant guidance given in ISO/IEC 9646-7 [7].
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Technical committeeTypeAcronymETSI TS 103 268-1 V1.1.1 (2017-04)CommitteePublished year2017KeywordsDescription
The scope of the present document is to support Smart Appliance common ontology and communication framework testing needs. It specifies a global methodology for testing for Smart Appliances, based oneM2M specifications. It analyses the overall testing needs and identifies and defines the additional documentation required. The testing framework proposed in the present document provides methodology for development of conformance and interoperability test strategies, test systems and the resulting test specifications for SAP
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Technical committeeTypeAcronymETSI TS 103 267 V2.1.1 (2020-02)CommitteePublished year2020KeywordsDescription
The present document defines a framework for Smart Applications communication based on oneM2M specifications. It also provides adjustments as required by the interested stakeholders. The present document includes: An introduction to the oneM2M framework and its relation with the ETSI M2M one. The specification of the interworking framework for Smart Applications with normative reference to oneM2M specifications. The specification about how to interwork with the oneM2M framework.
will also provide adjustments as required by the interested stakeholders. The document includes: An introduction to the oneM2M framework and its relation with the ETSI M2M one. The specification of the interworking framework for Smart Appliances with normative reference to oneM2M specifications. The specification about how to interwork with the oneM2M frameworkTechnology -
Technical committeeTypeAcronymETSI TS 103 264 V3.1.1 (2020-02)CommitteePublished year2020Description
The present document provides a standardized framework for the Smart Applications REFerence ontology based on the results of a European Commission Study Group on Smart Appliances ontologies and of different Specialist Task Forces that have supported the maintenance and evolution of the ontology taking into account all the interest of the relevant
stakeholders. This reference ontology contains recurring concepts that are used in several domains and is a basis for
extensions in particular domains.Technology -
Technical committeeTypeAcronymETSI TS 102 887-2 V1.1.1 (2013-09)CommitteePublished year2013KeywordsDescription
The present document is the second part of the Smart Metering Wireless Access Protocol describing the data structures and functional operation of Smart Metering and other applications intending to use spectrum resources covered by TS 102 887-1 [1] Physical Layer. TS 102 887-1 [1] is derived from IEEE 802.15.4g-2012™ [5] and the present document is derived from IEEE 802 15.4-2011™ [3], IEEE 802.15.4e-2012™ [4] and ANSI/TIA-4957-200 [2] together with specific enhancements or adaptations for the European context.
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Technical committeeTypeAcronymETSI TS 102 887-2CommitteePublished year2013Description
The present document, together with its associated PHY Technical Specification [1], provide radio communications connectivity for continuously powered or battery operated Smart Metering devices which, when coupled with suitable transport protocols, support advanced metering and other energy related applications. The MAC/PHY combination is also suitable for a wide range of sensor and Machine-to-Machine applications characterised by low device duty cycle and operation in shared spectrum.
This wide range of applications requires efficient connectivity protocol support for intermittent bi-directional data exchanges between devices in both low density (e.g. rural) and high density (e.g. urban) environments covering operations as simple as discovery and connection between one pair of devices (e.g. for walk-by meter reading) up to networks of many devices sharing a Network Point of Attachment to an external wide area network.
Spectrum sharing imposes additional requirements on the lower layer communications protocols governed by regulations limiting power and duty cycle among other characteristics. Such regulations taken into account by the present document include those governing the operation of Short Range Devices. Simple and low density deployments may be supported by distributed or cluster-based control algorithms, e.g. as found in [3] and [4], operating on a single channel. Frequency agility to select or change operating channel to minimise interference is advantageous for these applications but not essential for their operation.
Dense deployments and more complex applications may be constrained by spectrum sharing rules designed to limit the interference to other devices or services from the data traffic generated. In these cases the optimum control algorithms spread the population of devices uniformly over the available spectrum (channels) to minimise the number of devices on any given channel thereby minimising interference from their generated traffic. Device behaviour defined in [2] automatically distributes devices over the available channels by using device-centric pseudo-random channel hopping but also supports single channel operation via a degenerate hopping algorithm always returning the same channel number.
Both approaches to systems design may be deployed using the same PHY protocol and in the same frequency range and it is therefore necessary to include facilities to discriminate between information belonging to each MAC approach. Nothing prevents an implementation choosing to use only one of the alternate approaches or supporting both and the present document provides the necessary data structure encoding to identify each unit of information in its correct context. -
Technical committeeTypeAcronymETSI TS 102 887-1 V1.1.1 (2013-07)CommitteePublished year2013KeywordsDescription
The present document provides adaptations to IEEE Std 802.15.4g-2012 [2] in order to comply with the European regulations for Short Range Devices (SRDs).
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