Zemax opticstudio

Tag：ZEMAXOptical Zemax OPTICSTUDIO 24.12024-03-01views(1153)Ansys Zemax OpticStudio is a comprehensive optical design software used for the design and analysis of a wide range of o...Optical Ansys Zemax OPTICSTUDIO 2022 r2.012022-10-14views(2690)Zemax OpticStudio and Ansys Zemax OpticsBuilder, to design and simulate an end-to-end optical system. Ansys Zemax OpticS...Optical Zemax OPTICSTUDIO 22.12022-04-30views(2092)OpticStudio is the standard for optical, illumination, and laser system design in universities around the world, and in ...Optical Zemax OPTICSTUDIO 21.32021-10-02views(2579)Zemax 21.3 Supports Modeling Complex Geometries Required for the Miniaturization of Next-generation Optical Systems Opti...Optical Zemax OPTICSTUDIO 20.32021-02-02views(2338)OpticStudio’s intuitive user interface includes easy-to-learn tools and wizards which enable efficient simulation and de...Optical Zemax OPTICSTUDIO 20.22020-08-22views(2296)OpticStudio® is the world’s leading optical, illumination, and laser system design software. Top companies in aerospace,...Optical Zemax OpticStudio 20.12020-05-16views(2524)OpticStudio 20.1now features tolerance presets from Asphericon, Edmund Optics, LaCroix Optics, and Optimaxin the Toleran...Optical Zemax.OpticStudio.V19.42020-01-21views(4223)1. Set up your system OpticStudio’s intuitive user interface includes easy-to-learn tools and wizards which enable effic...Knowledge Zemax OpticStudio 18.1 Installation Guide2019-09-03views(2258)Product: Zemax OpticStudio 18.1 Installation Guide Version: Zemax OpticStudio 18.1 Language: english Supported Operating...Optical Zemax.OpticStudio.V18.92018-12-24views(3591)Product: Zemax.OpticStudio.V18.9 Version: 2018_v18.9 Supported Architectures: x64 Language: english Supported Operating ...

In this example, we introduce a simulation workflow to analyze the image quality of a camera system from a combination of an optical system and a CMOS imager within a specific environment with different lighting conditions. This example covers mainly the Ansys Speos part of the overall workflow. The optical system is designed with Ansys Zemax OpticStudio and exported to Ansys Speos for system-level analysis. The CMOS imager is designed with Ansys Lumerical and exported to Ansys Speos. download example OverviewUnderstand the simulation workflow and key resultsIn camera systems, CMOS (complementary metal oxide semiconductor) imager is an electronic component where incident absorbed photons generate a photocurrent that can be digitally processed. In this example, we used Ansys complete optical solution and imported the optical system information from Zemax OpticStudio and CMOS imager from Lumerical into Speos to do a full camera system analysis in a 3D scene and simulate the electronic map, and final image generated by the imager. This interoperability workflow takes into consideration the interplay between the macroscopic camera lens and the microstructure of the CMOS image sensor when simulating the entire optical system. With the Speos capabilities of handling realistic illumination and photometric/radiometric physics-based rendering, users can easily optimize the components and construct an accurate view of the final electronic map and final image as recorded by the image sensor to design application-based cameras.There are four main tools needed for this virtual solution : Zemax OpticStudio to export lens model designed in Zemax OpticStudio to be used by Speos Speos to generate spectral exposure map in front of the CMOS imager Lumerical FDTD (Finite Difference Time Domain) and CHARGE to compute the quantum efficiency of the sensor as a function of incidence angle and wavelength Speos Sensor System Exporter to combine Speos and Lumerical results and generate the electronic map captured by the sensor as well as the final imageAs this example requires Lumerical, Zemax OpticStudio and Speos simulation, we mainly limited ourselves to Speos simulations here as described by the following steps:Step 1: Lens system design with Zemax OpticStudio (not covered in this article)In this step, we design the camera lens system in Zemax OpticStudio and export the reduced order model of the lens system using the " Export Reduced Order Model to Speos " feature from OpticStudio (*.OPTdistortion file). The reduced order model (ROM) generated lens model is called Speos Lens System (SLS). This operation is done once for the lens system which enables us to perform fast ray tracing camera simulations in Speos afterward.Here we use a compact and efficient lens system for mobile phone cameras designed with Zemax OpticStudio. The incident angle at the sensor surface increases to 35 degrees at about 2 mm distance from the center of the sensor and then decreases to 25 degrees at the corner of the sensor.SLS can be generated by Zemax OpticStudio automatically for symmetric lens system or can be created from Chief ray angle curve information from a datasheet information. (if the lens design information

Coordinate system" option of the Surface Sag, Slope, and Curvature maps. 1.5 Source File: IES TM-25 (All editions)OpticStudio now supports save/load of IES TM-25 rayfiles.The Source File object in non-sequential mode now accepts TM-25 files as the input for measured or simulated source data. OpticStudio can also export rays from a non-sequential ray trace to TM-25 ray files. In addition to the data defined by TM-25, OpticStudio also includes electric field and phase data when exporting TM-25 ray files. Several other OpticStudio features now support TM-25 ray files, such as the Source Viewer, Flux vs. Wavelength and Light Source Analysis. 1.6 Automated Installer (All editions)The Automated Installer is now ready for 2024 R2.The Ansys Automated Installer allows users to install Zemax OpticStudio along with many other Ansys products from a single window. The convenience of using a single location for installing all Ansys products allows users to quickly find what they need and execute simultaneous downloads without having to click between multiple locations. 1.7 Learning and Support tab (All editions)New Learning and Support tab.The Learning and Support tab includes access to Ansys Innovation courses, Ansys Learning Hub, Ansys Zemax Learning Forum and links to our Customer Portal and Ansys Zemax Knowledge. This new tab offers users an easy way to find all resources in one location, directly within Ansys Zemax OpticStudio.1.8 Product usage intelligence from APIP (Ansys Product Improvement Program) (All editions)Improved product usage intelligence.We have replaced the mechanism of collecting basic product usage data – such as number of opened application sessions and overall feature usage – from our Zemax-specific solution to the Ansys Product Improvement Program (APIP). This optional feature allows Ansys to understand what features matter most to customers to aid in speed and usability improvements.Users will be prompted to opt into the Program via a pop-up window (Shown in the screenshot above) when launching OpticStudio. To stop participating in APIP, go to the” Setup -> OpticStudio Preferences -> Privacy” tab.1.9 ZOS File Format deprecation (All editions)The .ZOS file format has been discontinued.The .ZOS file format has been retired. This change ensures the continuity of the Ansys Optics user experience by simplifying workflows and aligning with the needs of long-term customers who require the human-readable aspect of the .ZMX file format. Users will always be able to open .ZOS files inside of OpticStudio. However, as part of the transition away from the .ZOS file format, .ZMX data

Simulated EQE data saved in a *.json file was used. For more guidance on learning about Speos Sensor System Exporter and executing a practical example, refer to the getting started with Speos Sensor System Exporter and running your first example article. Run and ResultsInstructions for running the model and discussion of key results.To explore the camera performance, we tested the system under different ambient illumination conditions as day and night with/without a lamp. Step 1: Lens system design with Zemax OpticStudio - (not covered in this article)The lens system is designed in Zemax OpticStudio and exported via “Export to Speos Lens System” tool in Zemax OpticStudio to be used by Speos.If you want to explore the lens system which is designed in Zemax OpticStudio and its corresponding ROM (*.OPTdistortion file) , which can be used in Speos, you can find the relevant files located in the Input from Zemax Lens system folder.More information about “Export to Speos Lens System” tool in Zemax OpticStudio can be found in Using the Export to Speos Lens System tool article.Step 2: Speos SimulationIn Speos 2024 R2, open Speos simulation file Security-camera_demo.scdocxRight click on the 'Camera.Day' simulation from simulation tree and select GPU compute or Compute for CPU compute. Note: the simulation time on CPU is about 15min with 16 physical cores.Click on the 'Camera.Day' simulation in the simulation panel. The simulation results include an Exposure.xmp result file which is the Exposure map captured by the Camera sensor from the scene with Daylight source. Double-click the Exposure.xmp result to open the exposure map in the Virtual Photometric Lab.Reproduce steps 2 to 3 for 'Camera.Night' and 'CameraNight.with.lamp' simulations.Inside the Virtual Photometric Lab, change the 'True Color' to 'Black to white Color' to review the luminous exposure values at different positions.To view the results in radiometric units instead of photometric units, you can simply select the ‘Radiometric Units’ option from the View menu in the XMP results. This will enable you to visualize the irradiance/exposure results in the appropriate radiometric units.Click on the 'Level' tool to see the legend bar for the radiometric exposure value.Click the 'Measures' tool and modify the area of interest, to measure the average exposure value on the desired area. You can also import template, Full_Sensor_Area_Measurement_Template by navigating to the file menu and selecting "import template" in the XMP viewer from Speos Output files folder and then select the measures icon. This will enable you to accurately measure the exposure captured by the whole sensor area. Result with Daytime source: It shows the measured exposure value from the 3D scene during the day with a scale bar on the right side.The measurement area of interest at the sensor can be defined using a different shape such as rectangular shape capturing the light from the scene to the sensor. In this example, the measurement area of interest covers the whole area of the sensor. Inside the measurement information table, the average exposure value captured by the whole area of the sensor with 0.05s integration