Główne pojęcia
Dispersed Structured Light (DSL) enables accurate hyperspectral 3D imaging with low cost and high quality.
Streszczenie
The article introduces Dispersed Structured Light (DSL) as a method for accurate hyperspectral 3D imaging. It modifies a traditional projector-camera system by adding a diffraction grating film, enabling the dispersion of structured light patterns based on wavelength. The DSL method allows for compact, low-cost, and high-quality hyperspectral 3D imaging. The content is structured into sections covering Introduction, Related Work, Dispersive Projection Image Formation, Hyperspectral 3D Reconstruction, Calibration, Assessment, Conclusion, References.
Introduction
- Hyperspectral 3D imaging aims to capture depth and spectrum per pixel.
- Existing methods are often impractical due to high costs and low accuracy.
- DSL introduces dispersed structured light for accurate hyperspectral 3D imaging.
Related Work
- Previous work combines hyperspectral imaging with depth imaging.
- Various methods have been explored for hyperspectral 3D imaging with different setups.
Dispersive Projection Image Formation
- DSL modifies the projector-camera system using a diffraction grating film.
- Image formation involves zero-order and first-order diffractions.
- Correspondence mapping is crucial for first-order diffractions.
Hyperspectral 3D Reconstruction
- Depth estimation is done using binary-code structured light patterns.
- Hyperspectral reconstruction is achieved through scanline structured light patterns.
- Optimization is used for accurate hyperspectral image reconstruction.
Calibration
- Calibration involves diffraction efficiency, spectral response functions, emission functions, and correspondence models.
Assessment
- DSL achieves accurate hyperspectral 3D imaging with spectral FWHM of 18.8 nm and depth error of 1 mm.
- Results show successful reconstruction of spectral curves and color differences in samples.
Conclusion
- DSL offers a step towards practical hyperspectral 3D imaging with its accuracy and affordability.
- Future work includes improving capture speed for dynamic scenes and increasing working depth range.
Statystyki
DSL achieves spectral accuracy of 18.8 nm FWHM and depth error of 1 mm.
Cytaty
"The proposed DSL enables accurate hyperspectral 3D imaging with an average depth error of 1 mm."
"DSL promises accurate and practical hyperspectral 3D imaging for diverse application domains."