Optical Design & Simulation Software

Create efficient, quick and accurate optical designs with 3DOptix’s online optical design and ray optics simulation software

Quickly plan and test any optical setup with of-the-shelf optomechanics, common light sources and a wide range of optical elements from the catalogs of leading industry vendors, or with your own customized optics

Create efficient, quick
and accurate optical designs

Discover the powerful capabilities of 3DOptix

Diffraction

The 3DOptix ray tracing and computational optics engine enables precise modeling and analysis of optical systems, making it a valuable tool for understanding and optimizing the impact of diffraction phenomena in intricate optical designs.

Interferometer

A comprehensive toolset for modeling and analyzing interferometric optical systems. Leveraging its advanced features, 3DOptix enables precise simulation of interferometric setups, providing valuable insights into interference patterns and aiding in the optimization of interferometer performance for diverse applications

Aberration

Model and analyze various aberrant optical systems comprehensively with advanced simulation tools, encompassing different kinds of optical aberrations, from spherical and chromatic aberrations to coma aberration, wavefront, and axial chromatic aberration. 3DOptix enables precise characterization of these optical aberrations, facilitating a deeper understanding and effective correction strategies for optical systems in diverse applications.

Complex systems

3DOptix demonstrates exceptional capabilities in simulating complex optical systems, offering advanced tools for modeling intricate setups with precision. The simulation platform provides a comprehensive environment for analyzing and optimizing a wide range of optical configurations, empowering researchers and engineers to explore and enhance the performance of complex optical systems for various applications.

Scattering

3DOptix GPU ray tracing engine, excelling in the precision of tracing scattered light. This advanced feature within the 3DOptix platform not only accurately models and analyzes the intricate behavior of scattered light in optical systems but also offers the capability to deploy various scattering models, including Gaussian, Lambertian, and others. This versatility provides researchers with powerful tools for in-depth exploration and optimization of diverse scattering phenomena.

Analysis and Simulation

High-end, fast and precise non-sequential optical simulations, allowing for the modeling of complex optical systems with efficiency. 3DOptix advanced simulation tools not only facilitate the rapid execution of simulations but also enable thorough analysis of the results, providing researchers and engineers with valuable insights for optimizing intricate optical designs.

Polarization

Robust optical simulation and computation capabilities, particularly in the realm of 3D polarization. Leveraging advanced algorithms, 3DOptix enables accurate modeling and analysis of intricate polarization effects within optical systems. This capability empowers researchers to explore and optimize the intricate interplay of light polarization in three-dimensional spaces, offering valuable insights for a wide range of applications in optics and photonics.
The 3DOptix ray tracing and computational optics engine enables precise modeling and analysis of optical systems, making it a valuable tool for understanding and optimizing the impact of diffraction phenomena in intricate optical designs.
A comprehensive toolset for modeling and analyzing interferometric optical systems. Leveraging its advanced features, 3DOptix enables precise simulation of interferometric setups, providing valuable insights into interference patterns and aiding in the optimization of interferometer performance for diverse applications.
Model and analyze various aberrant optical systems comprehensively with advanced simulation tools, encompassing different kinds of optical aberrations, from spherical and chromatic aberrations to coma aberration, wavefront, and axial chromatic aberration. 3DOptix enables precise characterization of these optical aberrations, facilitating a deeper understanding and effective correction strategies for optical systems in diverse applications.
3DOptix demonstrates exceptional capabilities in simulating complex optical systems, offering advanced tools for modeling intricate setups with precision. The simulation platform provides a comprehensive environment for analyzing and optimizing a wide range of optical configurations, empowering researchers and engineers to explore and enhance the performance of complex optical systems for various applications.
3DOptix GPU ray tracing engine, excelling in the precision of tracing scattered light. This advanced feature within the 3DOptix platform not only accurately models and analyzes the intricate behavior of scattered light in optical systems but also offers the capability to deploy various scattering models, including Gaussian, Lambertian, and others. This versatility provides researchers with powerful tools for in-depth exploration and optimization of diverse scattering phenomena.
High-end, fast and precise non-sequential optical simulations, allowing for the modeling of complex optical systems with efficiency. 3DOptix advanced simulation tools not only facilitate the rapid execution of simulations but also enable thorough analysis of the results, providing researchers and engineers with valuable insights for optimizing intricate optical designs.
Robust optical simulation and computation capabilities, particularly in the realm of 3D polarization. Leveraging advanced algorithms, 3DOptix enables accurate modeling and analysis of intricate polarization effects within optical systems. This capability empowers researchers to explore and optimize the intricate interplay of light polarization in three-dimensional spaces, offering valuable insights for a wide range of applications in optics and photonics.

What makes 3DOptix different?

Why use 3DOptix

At the heart of 3DOptix is a state-of-the-art GPU ray-tracing engine that operates in the cloud. This unique engine empowers users to perform complex photonics computations effortlessly. It calculates billions of rays per second in parallel, ensuring that simulated lighting is not only fast but also physically accurate. The result is a true-to-life scene with realistic outcomes, providing confidence in the optical designs.
3DOptix’s cloud-based approach means that it’s accessible via any web browser, eliminating the need for specific hardware or software installations. Users can seamlessly access the tool, work on optical designs, and run simulations from virtually anywhere with an internet connection.
One of the standout features of 3DOptix is its intuitive user experience. Whether you’re creating a simple optical apparatus or tackling a complex optical system, the software’s innovative UX simplifies the entire process. The sleek user interface (UI) coupled with an intuitive analysis portal ensures that users can easily verify the optical accuracy of their designs.
3DOptix offers an extensive library of optical elements and components sourced from leading industry vendors. Users have access to a wide range of options, including off-the-shelf optomechanical assemblies, common light sources, and even the flexibility to integrate their own customized optics. This versatility allows engineers to explore various optical configurations and solutions.
The integration of 3DOptix with CAD tools streamlines the workflow for testing virtual optical prototypes. This integration not only saves time but also shortens the design cycle significantly. Engineers can quickly plan and test optical designs, validate feasibility, and perform optical analyses with ease.
3DOptix serves as an interactive optomechanical, non-sequential cloud-based ray tracing software. It caters to various optical applications, including optical layout benches, optical system designs, feasibility validation, and optical analysis. Its versatility makes it an invaluable tool for optical engineers across industries.
At the heart of 3DOptix is a state-of-the-art GPU ray-tracing engine that operates in the cloud. This unique engine empowers users to perform complex photonics computations effortlessly. It calculates billions of rays per second in parallel, ensuring that simulated lighting is not only fast but also physically accurate. The result is a true-to-life scene with realistic outcomes, providing confidence in the optical designs.
3DOptix’s cloud-based approach means that it’s accessible via any web browser, eliminating the need for specific hardware or software installations. Users can seamlessly access the tool, work on optical designs, and run simulations from virtually anywhere with an internet connection.
One of the standout features of 3DOptix is its intuitive user experience. Whether you’re creating a simple optical apparatus or tackling a complex optical system, the software’s innovative UX simplifies the entire process. The sleek user interface (UI) coupled with an intuitive analysis portal ensures that users can easily verify the optical accuracy of their designs
3DOptix offers an extensive library of optical elements and components sourced from leading industry vendors. Users have access to a wide range of options, including off-the-shelf optomechanical assemblies, common light sources, and even the flexibility to integrate their own customized optics. This versatility allows engineers to explore various optical configurations and solutions.
The integration of 3DOptix with CAD tools streamlines the workflow for testing virtual optical prototypes. This integration not only saves time but also shortens the design cycle significantly. Engineers can quickly plan and test optical designs, validate feasibility, and perform optical analyses with ease.
3DOptix serves as an interactive optomechanical, non-sequential cloud-based ray tracing software. It caters to various optical applications, including optical layout benches, optical system designs, feasibility validation, and optical analysis. Its versatility makes it an invaluable tool for optical engineers across industries.
New!
OptiChat™

The world’s first optics AI search copilot

Discover off-the-shelf optical elements
Perform any optical calculation (such as EFL or refractive index) by asking in plain English
* More capabilities and copilots are coming soon
Example Questions

I have found 13 plano-convex lenses made from UVFS that should provide an effective focal length (EFL) of 22 mm at 730 nm.
Here are the search parameters I used:

  • Material: UVFS
  • Lens Subtype: Spherical Lens (Plano-Convex)
  • First Radius of Curvature (r1): Between 9.9 mm and 10.1 mm

You can view the results under the “Plano-Convex Lens Search” tab.

The top 5 materials with a refractive index closest to 1.67 at 750 nm are:

  1. S-LAL56 with a deviation of -1.91e-05
  2. D-LAK5 with a deviation of 0.00045
  3. LAKL12 with a deviation of 0.00045
  4. L-LAL12 with a deviation of 0.00046
  5. S-LAL12 with a deviation of 0.00055

I have found 243 results for convex-convex lenses with a diameter ranging from 9 mm to 11 mm.
You can view these results under the “Convex-Convex Lens Search” tab

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3DOptix works
only on desktop!

Please go to 3doptix.com on a
desktop device, using the
Chrome or Edge browser

Available on January 30th, 2023