Optical Research

Combining theory and experiments to optimize optical metasurfaces.

A close-up view of a perforated metal surface with blue light shining through the small circular holes, creating an abstract and futuristic appearance.

Design Framework

Developing a closed-loop optimization system for enhanced optical properties analysis and design accuracy through experimental validation and comparative studies against traditional methods.

A collection of metallic, angular, and reflective surfaces arranged in a dynamic and abstract composition. The surfaces reflect subtle gradients of light and shadows, creating a sense of depth and movement.

Performance Validation

Conducting experiments using public datasets to validate the system's performance across various optical tasks and assess computational efficiency in comparison to conventional design approaches.

Optical Innovations

Exploring metasurfaces through theoretical analysis and experimental validation.

A close-up of a metallic surface with a series of round perforations, creating a repetitive pattern. The surface reflects light with shades of blue, red, and white creating a dynamic visual effect.

A close-up view of a perforated metal surface with a reflective texture. Subtle purple and blue light glimmers on one side, creating a dynamic contrast against the dark, matte finish of the surface.

A variety of black optical devices and prism-like components are arranged on a plain white background. The devices appear to be made of a combination of black material and transparent elements, with some featuring cylindrical, lens-like ends.

A complex geometric pattern composed of reflective surfaces, creating a kaleidoscopic effect. The surfaces are divided into triangular and polygonal shapes with a mirrored finish, reflecting light and colors in various directions. The reflections include shades of pink, purple, and gold, creating an abstract and dynamic visual experience.

Research

Innovative optical design through deep learning analysis.