For OpenModelica and Dymola, the user should move to Simulation tab and by clicking the Simulate button. The model Examples/MicroGrid_Example.mo can be simulated in different manners, depending on the Modelica-compliant software being used.Other examples are available in Electrical/Examples and in Control/Examples. The microgrid example is within (1) Examples, named MicroGrid_Example.mo. The main package, MicroGrid, consists of six subpackages, named: (1) Examples, (2) Electrical, (3) Storage, (4) PhotoVoltaics, (5) Control and (6) Sensors.This act will load all the models into the Working tab in the Modelica-compliant software used. Go to folder MicroGrid and load the model package.mo.It contains models for batteries, photovoltaics modules, converters and control systems. Tools: Use predefined sensors, environments and photometric or color measurements easilyĮach item in the OPTIS Library comes with its dedicated, comprehensive information.Small library made as final project for the course Modeling and Simulation of Cyber-Physical Systems.Standards: Easily check the compliance of your products to official SAE or ECE regulations and standards on a virtual prototype.Cameras and lenses: Find all types of lenses and cameras to create or re-create any optical system with a click.Light sources: Improve your light performance and create appealing lighting fixtures with our ready-to-use LEDs, fluorescent, incandescent and HDI bulbs, and OLEDS.Materials: Pick and apply predefined materials to recreate any surface, texture and color.Benefit from the latest innovations in light, materials and related elements, with over 4,000 cutting-edge samples and items: It is the place for creative professionals to get inspired. Our library is a showroom of thousands of lights, materials and tools. Select source, material, sensor and standard models in this online resource to get a physically correct simulation of your digital product. You can easily assess the performance and robustness of your vision and detection systems on various scenarios, reducing the need for physical testing. This enables optical designers and embedded software developers to collaborate on the digital mockup. In addition to camera acquisition, you can visualize your field of view with pixel grids projected on the 3D environment to determine detection capabilities and to process simulated camera acquisition with image processing. Automatically calculate and understand the efficiency of your optical system, using dedicated tools for illuminance, luminance and intensity measurements. Simply simulate and optimize visible, near- and far-infrared systems (wavelength beyond 2000 nm), for active and passive detection. Model thermal radiation directly from the body temperature field.įar infrared extension provides unique capabilities dedicated to designing and analyzing vision, as well as detection systems used in the defense industry, for example on land systems, UAVs and satellites. The lens importer guarantees a unique continuity throughout the development of imaging systems, and the optical systems’ data can be imported into camera sensors in Ansys VRXPERIENCE for interactive testing and validation.Įxtend the optical simulation wavelength range up to the far infrared. It contains the optical data necessary to perform analyses, while protecting the imported system’s intellectual property (IP). The importer makes it possible to import any native, Zemax OpticStudio® or any SPEOS-generated optical system into SPEOS, in the form of a black box. SPEOS introduces a lens importer dedicated to ease the creation and analysis of imaging systems. Optical part design will increase your productivity and shorten your engineering development time, while accelerating convergence on style. It also allows you to build surfaces to collimate light rays that are impossible to create without approximations. Optical part design delivers unique geometrical modeling capabilities, so you can automatically create geometries with several dozen construction elements (e.g., a near-field lens) with just one click. Design the best beam sharp cutoff reflector shape, and model manufacturing constraints like drafting and milling. Create dedicated optical geometries for the design of lighting systems with the automated generation of prisms for light guide or pillow optics for reflective and refractive parts.
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