18. Tips, Tricks and Shortcuts to Improve Productivity and Efficiency with TracePro (March 2012)

TracePro is a powerful software tool for modeling imaging and non-imaging optical devices. Models are created by importing from a CAD program or directly creating the solid geometry. Light rays propagate through the model with portions of the flux of each ray allocated for absorption, specular reflection and transmission, fluorescence, and scattering.

• Model real scattering effects using full anisotropic properties and asymmetric BSDF
• Import from three popular optical design programs
• Model stray light from lens mounts, packaging, and thermal sources
• Analyze multiple paths using non-sequential ray tracing algorithms
• List absorbed and incident flux on every surface and object using flux reports
• Display flux by volume in laser cavities
• Export 3D flux data to third-party laser cavity design and analysis programs
• Visualize a laser cavity along any axis using the volume flux viewer
• Analyze flux for absorbed, incident, originated, or exiting radiation
• Analyze any material or bulk scatter sources for incident, originating, absorbed, and lost energy
• Define multiple sources using asymmetric surface emission, including user-defined properties
• Analyze birefringence in crystals, including splitting of rays into ordinary and extraordinary components
• Track full polarization effects using Stokes vectors and Mueller matrices

TracePro offers industrial designers the confidence that the simulation will accurately predict performance without costly prototype iterations for a wide variety of technologies, such as:

• Illumination for machine vision
• Laser cavities
• Consumer electronic devices
• Laboratory instruments and measuring devices

TracePro is used by the world’s top display manufacturers for display design. Modern display backlights must meet specifications for spatial and angular uniformity, brightness, and spectral characteristics. Quickly achieving these criteria with a manufacturable, cost-effective design requires powerful, easy-to-use, accurate software.

• Flux report for surfaces and bulk media
• Polarization effects
• Fluorescence effects of phosphors
• Birefringence effects
• CIE plots
• Candela plots
• Lit appearance
• Luminance maps
• Irradiance/illuminance maps

You can be confident that TracePro will accurately predict the performance and aesthetics of finished products with fewer costly prototypes. The software is used to design many types of products:

• Projection and flat-panel displays
• Edge-Lit and Direct-Lit televisions
• Liquid Crystal Displays (LCDs)
• Plasma Displays
• Field Emission Displays (FEDs)
• Organic LED Displays (OLEDs)
• Electroluminescent Displays
• 3D displays
• Head-Up Displays (HUD)
• Digital signage
• Consumer electronics
• Avionics
• Medical imaging
• Brightness Enhancing Films
• Dichroic and Hot Mirror Filters

TracePro and OSLO are robust tools for designing and analyzing optical systems for aerospace and defense applications. Both programs have been used to design and analyze many notable NASA optical systems, including:

• James Webb Space Telescope
• Mars Rover Spirit and Opportunity cameras (re-used on Curiosity rover)
• Mars Climate Sounder
• Galaxy Explorer
• Moon Mineralogy Mapper
• Lunar Orbiter Laser Altimeter

Designers of military, aviation, and homeland defense systems rely on TracePro for an accurate, state-of-the-art, comprehensive design environment.

When you need to analyze baffles for the suppression of stray light due to scattering, diffraction, ghost images, and self emission, TracePro is an invaluable tool.

TracePro can simulate many aspects of optical system performance, including:

• Stray light analysis and telescope baffle design
• PST, PSNIT, and OAR
• Ghost image analysis
• Simulation of spectrometers and other multi-spectral systems
• Polarization effects, including birefringence
• Thermal loading
• Narcissus effects
• Diffracted stray light

TracePro offers lighting designers the most accurate and comprehensive design environment available. Lighting system design requires strict adherence to performance criteria, including spatial and angular light distribution, uniformity, intensity, and spectral characteristics, along with aesthetic factors such as lit and unlit appearance. The result is a cost-effective design that is ready for manufacture.

 TracePro is a comprehensive, versatile software tool for modeling the propagation of light. Models are created by importing from a CAD program or by directly creating the solid geometry. Rays propagate through the model with portions of the flux of each ray allocated for absorption, specular reflection and transmission, fluorescence, and scattering.

Analyze:

• Light distributions in illumination and imaging systems
• Lumens exiting, absorbed, and incident at the component and system levels
• Candela distributions
• Illuminance distribution on any surface
• Optical efficiency, luminance, and radiance
• Photorealistic rendering
• Fluorescence effects of phosphors

Lighting system designers can be confident that TracePro will accurately predict the performance and aesthetics of finished products with fewer costly prototypes. The software is used to design many types of products:

• LEDs
• Lamps
• Luminaires and louvers
• Transportation signs and emergency lighting
• Daylighting
• Architectural lighting design
• Display lighting
• Consumer products
• Automotive lighting
• Avionics lighting
• Medical lighting
• Entertainment lighting

Automotive designers use TracePro to integrate LEDs, HID lamps, and incandescent lighting into cars, trucks, and commercial vehicles. LED-based headlamps are now used on many vehicles. These high-power LED systems must be analyzed to verify performance.

 LEDs have long been used for automotive ambient lighting. They also illuminate dashboard and gauge clusters using light pipes and light guides, which employ gentle curves to steer light by Total Internal Reflection (TIR). This is combined with beveled corners that act as mirrors, enabling designers to use fewer LEDs.

Designers of Head-Up Displays (HUDs), windshield systems, collision detection systems, rearview cameras, and backup illumination systems use TracePro to analyze their designs, including:

• Illuminance from any interior or display lighting
• Luminance maps, photorealistic renderings, and “lit appearance” of instrument panels and interior and exterior lighting
• 3D illuminance on any surface
• Candela plots on any surface

TracePro helps automotive designers visualize the effect of their LED layout, design, and placement through the use of photorealistic rendering of interior and exterior uses, including the illumination of:

• Instrument panels, consoles, and other controls
• Door handles and window openers
• Footwells and storage areas
• Trunks/boots and truck beds
• Headlamps and tail lights
• Warning Lamps
• HUD and windshield design
• Navigation, stereo and informational displays

TracePro’s Solar Emulator and optimization capabilities have helped manufacturers achieve even greater absorption and collection rates. Optimize your design to boost efficiency using collector optics, textured panels, new material layouts and pyramidal structures. The optimized design will achieve the ultimate goal of lowering the cost per watt. The Solar Emulator is the only tool for analyzing 3D designs and simulating performance using standardized definitions for geographical location (latitude, longitude, and elevation).

Analyze your design for a specified period of sun travel with multiaxial tracking and irradiance for both direct and indirect sun contribution. Analysis output includes irradiance, candela maps, turbidity calculations, total flux, and efficiency over time.

TracePro’s Solar Emulator and design, analysis, and optimization capabilities accurately predict total energy output when solar collector systems are in real-world conditions. Hundreds of research papers have been written by TracePro users detailing TracePro’s capabilities on solar collection systems.

TracePro’s Solar Emulator and optimization features ensure solar collectors perform at peak efficiency.

• Source modeling based on:
  – Direct and indirect solar radiation
  – Atmospheric scattering
  – Latitude, longitude, and elevation
  – Date and time
  – User-selectable wavelengths
• User-defined parameters also include step intervals, wavelength, entrance pupil, solar irradiance, number of rays to be traced
• Irradiance and candela mapping
• Total collected energy reported in graphical
  and tabular formats over a calculated period
• Flux Report based upon sun position
• Sun Tracking
  – Aim-to-sun
  – Uniaxial
  – Uniaxial coupled with aim-to-sun
• Global position
  – Predefined city list
  – Google Maps positioning
• Turbidity
  – Overcast through sunny definitions specified per period

TracePro is used extensively for stray light analysis and related applications, including:

• Baffle design for stray light suppression
• Analysis of stray light due to scattering, aperture diffraction, and ghost images
• Self-emission of infrared and longer wavelength systems
• Simulation of polarization effects including birefringence
• Simulation of spectrometers and other multi-spectral systems
• Thermal effects and loading
• Narcissus effects
• Diffraction gratings

Due to its generality, TracePro has been used to simulate optical systems operating at wavelengths ranging from the extreme ultraviolet, through the visible and infrared, to millimeter wavelengths. The intuitive user interface and accurate CAD file import reduce setup time needed for stray light analysis.

TracePro offers life sciences and medical device designers a powerful, complete simulation tool ideally suited to their needs. TracePro facilitates the design and development process by communicating across disciplines including optics, mechanics, materials, chemistry, and biology. This is extremely important for medical instrumentation and device designers who must communicate system level specifications and design elements to both scientists and engineers.

Medical system designers use TracePro to minimize the cost and time of iterative hardware prototyping and laboratory and clinical testing. Create models by directly creating the solid geometry in TracePro or by importing from a lens design program or a CAD program. Source rays propagate through the model with portions of the flux of each ray allocated for absorption, specular reflection and transmission, fluorescence, and scattering.

TracePro can simulate and analyze many aspects of optical systems including:

• • • Light distributions in illumination and imaging systems
    • Stray light, scattered light, and aperture diffraction
    • Throughput, loss, or system transmittance
    • Flux or power absorbed by surfaces and bulk media
    • Light scattering in biological tissue
    • Polarization effects
    • Fluorescence effects
    • Birefringence effects

   

• TracePro offers medical systems designers the confidence that the simulated design will predict the performance and accuracy of finished devices, such as:
• • • Fluorescence spectroscopy
    • UV, VIS, NIR, IR spectroscopy
    • Flow cytometry
    • Micro arrays and plate readers
    • Nucleic acid amplification
    • Assay, cell, and tissue-based imaging
    • Confocal laser scanning and fluorescence microscopy
    • Medical imaging and endoscopy
    • In-Vitro/in-vivo diagnostics
    • Biosensors
    • Molecular detection: quantum dots, nanocrystals, luminescent reporters
    • Laser and LED surgical devices
    • Laser beam delivery systems for surgical instrumentation
    • Laser Induced Fluorescence (LIF) Detection
    • Fluorescence Resonance Energy Transfer (FRET)

    For more information on Medical Device Design Using TracePro, view the Biomedical Brochure.