Lamda Research TracePro 704 19: A Powerful Tool for Designing and Optimizing Optical Systems
If you are an optical engineer or designer, you know how important it is to have a reliable and accurate software for simulating and analyzing optical systems. You need a tool that can handle complex geometries, multiple sources, scattering, polarization, interference, diffraction, and more. You also need a tool that can help you optimize your design for performance, cost, and manufacturability.
That's why you need Lamda Research TracePro 704 19, the latest version of the award-winning optical and illumination simulation software. TracePro is a comprehensive and versatile tool that can help you with any optical project, from lighting and displays to biomedical and aerospace applications. TracePro lets you create and import 3D models of your optical system, assign optical properties to materials and surfaces, define sources and detectors, and run ray tracing simulations to evaluate the performance of your system. You can also use TracePro's optimization features to find the best design parameters for your system.
What's New in Lamda Research TracePro 704 19?
Lamda Research TracePro 704 19 is the most advanced and user-friendly version of TracePro ever. It comes with many new features and improvements that make it easier and faster to design and analyze optical systems. Some of the highlights include:
A new user interface that is more intuitive and customizable. You can now access all the tools and commands from the ribbon menu, dock or undock windows, and use keyboard shortcuts for common tasks.
A new ray tracing engine that is faster and more accurate. You can now run simulations with up to 64 cores on your computer, use adaptive sampling for better results with fewer rays, and apply advanced ray splitting methods for handling complex phenomena.
A new interactive optimizer that lets you optimize your system in real time. You can now see the effects of changing design parameters on your system performance as you drag sliders or enter values. You can also use multiple criteria and constraints for optimization.
A new report generator that lets you create professional reports of your simulation results. You can now customize the layout, content, and format of your reports, and export them as PDF or HTML files.
A new library of optical components that you can use in your system. You can now access hundreds of predefined components from various categories, such as lenses, mirrors, prisms, gratings, filters, LEDs, lasers, sensors, etc.
A new compatibility with Windows 11 (64-bit) operating system. You can now run TracePro on the latest version of Windows with improved performance and stability.
These are just some of the new features and improvements in Lamda Research TracePro 704 19. To learn more about TracePro and how it can help you with your optical projects, visit https://lambdares.com/tracepro or contact Lambda Research Corporation at +1 978-486-0766.
How to Use Lamda Research TracePro 704 19 for Optical Simulation and Analysis
Now that you know what Lamda Research TracePro 704 19 can do for you, you might be wondering how to use it for your optical projects. In this section, we will show you some of the basic steps and features of TracePro that will help you create and simulate your optical system.
Step 1: Create or Import Your Optical Model
The first step is to create or import your optical model in TracePro. You can use the new geometric modeler to create your own 3D geometry using various tools such as extrude, revolve, sweep, loft, etc. You can also import existing CAD files or lens designs from various formats such as STEP, IGES, SAT, Zemax, Code V, etc. TracePro supports both non-sequential and sequential ray tracing modes, so you can choose the one that suits your system best.
Step 2: Assign Optical Properties to Your Model
The next step is to assign optical properties to your model. You can use the new library of optical components to select from hundreds of predefined materials and surfaces with different properties such as refractive index, absorption, reflection, transmission, scattering, polarization, etc. You can also create your own custom materials and surfaces using TracePro's material and surface editors. You can also apply bulk scatter properties to the environment to simulate atmospheric effects such as fog, haze, etc.
Step 3: Define Sources and Detectors for Your System
The third step is to define sources and detectors for your system. You can use the new source editor to create various types of sources such as point sources, area sources, grid sources, file sources, etc. You can also import measured source data from various formats such as IESNA, EULUMDAT, Radiant Source Model (RSM), etc. You can also define detectors for your system such as photopic detectors, color detectors, irradiance detectors, illuminance detectors, etc. You can also import measured detector data from various formats such as CIE XYZ color matching functions.
Step 4: Run Ray Tracing Simulations and Analyze Your Results
The final step is to run ray tracing simulations and analyze your results. You can use the new ray tracing engine to run simulations with up to 64 cores on your computer, use adaptive sampling for better results with fewer rays, and apply advanced ray splitting methods for handling complex phenomena. You can also use the new interactive optimizer to optimize your system in real time by changing design parameters and seeing the effects on your system performance. You can also use the new report generator to create professional reports of your simulation results with customized layout, content, and format.
Some Examples of Lamda Research TracePro 704 19 Applications
Lamda Research TracePro 704 19 can be used for a wide range of optical and illumination applications, such as lighting, displays, biomedical, aerospace, solar, automotive, and more. In this section, we will show you some examples of how TracePro can help you with your specific application needs.
Lighting and Luminaire Design
TracePro can help you design and optimize lighting and luminaire systems for various indoor and outdoor scenarios. You can use TracePro to simulate the light distribution, intensity, color, glare, uniformity, efficiency, and photometric performance of your lighting system. You can also use TracePro to verify compliance to any lighting criteria or standards, such as ECE, SAE, FMVSS, StVZO, ABYC, etc. TracePro can also help you design and analyze solar simulators using modular LED arrays or arc lamps.
Display and Backlight Design
TracePro can help you design and optimize display and backlight systems for various types of displays, such as LCD, OLED, LED, DMD, etc. You can use TracePro to simulate the optical performance, brightness, contrast, color gamut, viewing angle, uniformity, and power consumption of your display system. You can also use TracePro to design and analyze optical components for your display system, such as lenses, mirrors, prisms, gratings, filters, polarizers, etc.
Biomedical and Life Science Applications
TracePro can help you design and optimize biomedical and life science devices and systems for various applications, such as imaging, diagnosis, therapy, surgery, etc. You can use TracePro to simulate the interaction of light with biological tissue and fluids using various models of absorption, scattering, fluorescence, polarization, birefringence, etc. You can also use TracePro to design and analyze optical components for your biomedical system, such as lenses, mirrors, prisms, gratings, filters, LEDs, lasers, sensors, etc. d282676c82