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Full Description
Scope
This standard defines a common yet another next generation (YANG) (IETF RFC 7950) data model for IEEE 1906.1 nanoscale communication systems.
Purpose
The YANG data model defines a common network management and configuration data model fornanoscale communication systems. In so doing, it fulfills several purposes:- It enforces requirements to conform to IEEE Std 1906.1(TM)-2015.- It describes nanoscale communication systems.- It represents the fundamental physics impacting IEEE 1906.1 systems.- It defines configuration and management for simulation and analysis.- It defines a self-describing data structure used in repositories of nanoscale communication experimental data.A standard network, management, and configuration data model enables efficient understanding and use of IEEE 1906.1 systems and simulations. A standard data model is needed to ensure that systems and simulations conform to IEEE Std 1906.1-2015. A standard data model is also needed to serve as human and machine-readable documentation of IEEE 1906.1 systems. Because small-scale communication systems interact directly with nanoscale physics, a data model is needed that represents fundamental physics. A common data model is needed to accurately and fairly compare IEEE 1906.1 systems. Repositories of experimental data from small-scale communication systems require clear and accurate documentation for the data to be meaningful. This common data model provides a self-describing data model that addresses this purpose.
Abstract
New IEEE Standard - Active.A set of YANG modules describing nanoscale communication systems and their associated physical quantities in conformance with IEEE Std 1906.1-2015--a common framework for all nanoscale communication technologies--are comprised by this data model. Physics unique to the nanoscale are represented by the model. The physics are referred to as non-standard, required by IEEE Std 1906.1-2015. Remote configuration and management for remote simulation, operation, and analysis of nanoscale communication systems are defined by the model. A self-describing data structure is defined by the model for datastores and repositories of nanoscale communication experimental data enabling a common understanding of the data from a wide variety of nanoscale communication media and technologies. Augmentation of the IEEE Std 1906.1-2015 common core components with details specific to the physics of the nanoscale communication system is allowed by the model. Techniques used by the model facilitate reuse and augmentation. In addition, extensions to IEEE Std 802.1Q and Internet Engineering Task Force (IETF) interfaces--allowing reusability within existing networks, which implies a macroscale to nanoscale interface, and defines nanoscale communication as a feature for bridge ports as defined in IEEE Std 802.1--are provided. The model is composed of simple,required core components while allowing optional, device-specific components and metrics to be added. There is conformity with best practices as defined by the IEEE 802 YANG editorsa?? coordination committee and IETF RFC 6087, and consideration of coexistence and interoperability with existing domain models and tools, such as the Systems Biology Markup Language (SBML).