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Photopia optical design software is a monte-carlo raytracing software which allows optical engineers to fully prototype optical systems directly inside of Rhino and Solidworks. https://www.ltioptics.com
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Optical Design Software For SOLIDWORKS and Rhino
About Photopia Photopia is optic design software used by optical engineers to virtually prototype the performance of non-imaging optical systems before building physical prototypes. Photopia’s monte-carlo raytracing engine works inside of Solidworks or Rhino and is compatible with Inventor, Fusion, Catia, Creo, Pro/E and many other CAD softwares. https://www.ltioptics.com/
About LTI Optics LTI Optics is the company that creates and sells Photopia optical design software. We are a small company located in Westminster Colorado supporting our software around the entire globe. Members of our team have been working on Photopia and its predecessor since the 1990’s, continually improving and refining our raytracing and optical design engines. https://www.ltioptics.com/
Illumination – Light Guides – Optical Sensors Some of the range of optical systems you can design and model with Photopia.
Simulation Accuracy - LED Collimator Lens Photo of Actual Beam Image Photopia’s Simulated Beam Image
Parametric Free-Form Reflector Design Tools – Aiming & Weighting Factors
Parametric Free-Form Lens Design Tools Prismatic/Smooth, Profile Mapping, Aiming & Weighting
Optimization Using Galapagos in Grasshopper Multi-parameter genetic algorithm optimization in Rhino. Showing various designs recorded along the progression, with beam angles getting closer to the desired 40°.
Aspherical Free-Form Lens Fit Tool with Grasshopper VPL in Photopia for Rhino Determine aspheric lens parameters for a free-form lens shape using the Grasshopper VPL in Photopia for Rhino.
Lamp Library with Source Geometry & Optical Properties Cree XHP-70 Model Geometry
Lamp Library with Source Geometry & Optical Properties Cree XHP-70 Model Spectral Properties Color Over Angle Variations
Photopia LED Source Models Geometry + Variable Spectrum Over Emission Angle Cree XP-L 3000K Color Lamp Model
Photopia Source Library - LASERS Osram – TO56 450nm laser diode SLD Laser – phosphor converted white 633nm HeNe laser
“Ray Set” Problems - Source Modeling “Ray Set” Source Model for Rebel LED Photopia Source Model for Rebel LED Model from Lumileds Website. Rays emit from behind the chip and behind the entire emitter package. LED geometry provided as a reference only. Rays emit from actual LED geometry.
“Ray Set” Source Modeling Problems Luxeon 3030 Midpower LED “Ray Set” from Lumileds Website
“Ray Set” Source Model Performance Ray Set Model Measured Ray Set Model Measured Photopia Source Model Performance Photopia Model Photopia Model Measured Measured Intensity Distribution Comparisons
Measured Measured Photopia Model Ray Set Model Photopia Source Model Performance “Ray Set” Source Model Performance Intensity Distribution Comparisons
Material Scattering Via Measured BRDF/BTDF Data Physical and Simulated Views of Bright View Technologies E0160PE7 Elliptical Anisotropic Diffuser Simulation of laser through material at 4 orientations (0, 30, 60 & 90°) with respect to the linear microstructure orientation. 2nd image matches image from physical laser. Laser shining through sample, about 30° from linear microstructure orientation.
Custom Built HDR Imaging Based BSDF Measurement Device View of Camera & Screen on Rotating Ring
Custom Built HDR Imaging Based BSDF Measurement Device Scatter Distributions Projected onto a Hemisphere Transmitted data (BTDF). An additional screen position can cover more of the hemisphere when the light source is below the table. Reflected data (BRDF). Some of the hemisphere needs to be filled in from surrounding data due to the gap required to let the light source illuminate the sample.
View of BSDF Data from Glossy White Plastic Spherical plot of relative intensity distribution for 40° incidence angle. Spherical plot of relative intensity distribution for 35° incidence angle.
Particle Scattering Distributions Particle scattering distribution from diffuse opaque sphere. Particle scattering from TiO2 in acrylic.
Volumetric Scattering in Refractor Materialswith Spectral Conversion (Phosphor modeling) Blue laser directed into a light guide with a low density of phosphor particles. Blue laser directed a into light guide with a medium density of phosphor particles. Blue laser directed into a light guide with a high density of phosphor particles.
OptiColor PMMA & PC Diffusers with Variable % Loading A wide range of diffuser loading percentages have been modeled for various grades of PMMA & PC from OptiColor
LED Package Design Phosphor Infused Silicone LED Emitter Modeling Phosphor Converted White LEDs Using Blue LED Emitting into Phosphor Infused Silicone Using Volumetric Scattering
Luminous & Spectral Performance of Mid-Power LED Package LED Package Cross Section Emission Face View Lamp model based on blue LED and phosphor infused silicone. Raytrace is modeling the scattering and wavelength conversion of the phosphor particles.
LED Headlight Reflectors Upper Half - Low Beam Reflector Lower Half - High Beam Reflector Reflectors Designed in Rhino
LED Headlight Reflectors Low beam uses a 5 chip 6000K Samsung LED package High beam uses a 4 chip 6000K Samsung LED package
Low Beam High Beam Low Beam + High Beam Beam Projections on a Vertical Plane Sample beams, not fully compliant.
H+L Beam Luminous Views 6 viewing angles were run in a single simulation, separated by 10° rotations horizontally and vertically. The projected images are upside down from the reflector orientation, so the lower part in the image is the upper reflector for the low beam.
H+L Beam Luminous View at H0 V0 Rhino’s standard shaded view on the left and the photometrically accurate luminous view on the right based on the image projection.
H+L Beam Luminous View at H-10 V0 Rhino’s standard shaded view on the left and the photometrically accurate luminous view on the right based on the image projection.
