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Software AUTONOM

Early implementations of the CIP rules for computer detection and specification of chirality were described for the LHASA [105], CHIRON [106], and CACTVS [107] software packages. Recently, several commercial molecular editors and visualizers (e.g., CambridgeSoft s ChemOffice, ACD s I-Lab, Accelrys WebLab, and MDL s AutoNom) have also implemented the CIP rules. [Pg.79]

Chcm3D is much more than a molecule viewer. This autonomous software module from the ChemOffice package provides simple molecule editor tools to create structures, but is mainly used as a molecular modeling tool. [Pg.147]

MDL Information Services, Inc. offers free software downloads at http // www.mdli.com/cgi/dynamic/downloadsect.html7uid= key= id = 1. These include AutoNom Standard (automatic nomenclature), which generates IUPAC chemical names directly from graphical structures created in ISIS/Draw or registered in ISIS/ Base. [Pg.149]

As noted before, in order to replace conventional power components with hydrogen technologies in renewable energy-based autonomous power systems, an oveidimensioning of RE equipment is usually necessary. Nevertheless, the results of Fair Isle s wind-hydrogen system optimisation revealed that there is no need for additional wind turbines on the island, due to the fact that in the existing wind-diesel power system the wind turbines were already oversized. More specifically, the first preliminary runs conducted with HOMER software demonstrated that the size of the wind turbines to be considered in the analysis will also be 100 kW and 60 kW, respectively. [Pg.117]

The HOMER software tool was also used for the techno-economic analysis of both the existing diesel-based autonomous power system and the envisaged wind-hydrogen system of Rauhelleren. The detailed results and respective discussion of power system analysis performed are given in the following sections. [Pg.121]

Autonomic computing technologies encapsulate the complexity of the underlying information technology components (hardware components and software components) and also enable automatic operation and management of the IT system with dynamic adaptation to changes without (or with minimal) human intervention so that the IT system as a whole can be used as a black box. The conceptual biomedical informatics architecture is depicted in the Figure 8.6. [Pg.353]

In the traditional approach to model a business into software engineering, a business operation is decomposed into autonomous functional units, the business functional units are mapped to software components, and the interfaces are specified for the software components to receive input data and to produce output data, and all the business rules, functional behavior, and business processes associated with the components are embedded within the functional components. [Pg.378]

In fact, in its latest version 5.2, the software lUCLID 5, which is the software used to collect data about chemical substances, specifically indicates the nano form of the chemical substance. The guide titles lUCLJD 5 Guidance and Support, Nanomaterials in lUCLID 5.2, ECHA, June 2010 specifies that records of specific studies must be created for each form of a substance developed in the registration dossier. This imphes that the industries are involved in a non-autonomous registration of their nanomaterials and assess the specific the nano form of the substance. [Pg.352]

Nissen, M E., Mehra, A. (1999). Some intelligent software supply chain agents. In Proceedings of Autonomous Agents 99, Seattle, WA. [Pg.192]

Avionics and Navigation. Condensed from the term aviation electronics, the term avionics has come to include the generation of intelligent software systems and sensors to control unmanned aerial vehicles (UAVs), which may operate autonomously. Avionics also deals with various subsystems such as radar and communications, as well as navigation equipment, and is closely linked to the disciplines of flight dynamics, controls, and navigation. [Pg.14]

Because OOIAXES is a systems language, its semantics is more general than a software language. For example, 001 AXES defined systems could run on a computer, person, autonomous robot, or an organization whereas the content of the types (or classes) in a software language is based on a computer that runs software. [Pg.2033]


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See also in sourсe #XX -- [ Pg.55 , Pg.56 , Pg.57 , Pg.58 , Pg.59 , Pg.60 , Pg.61 , Pg.62 ]




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AutoNom

Autonomation

Autonomic

Autonomous

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