insikt - Imaging Technology - # Hyperspectral 3D Imaging

Dispersed Structured Light for Hyperspectral 3D Imaging: Low-Cost Method

Q: How can DSL be optimized for faster capture in dynamic scenes

To optimize DSL for faster capture in dynamic scenes, several strategies can be implemented. One approach is to enhance the light efficiency of the system by increasing the intensity of first-order diffractions. This can be achieved by using more powerful projectors or optimizing the diffraction grating film to maximize the dispersion effect. Additionally, implementing advanced algorithms for real-time processing and reconstruction can help reduce the time required for capturing and analyzing hyperspectral 3D data. By improving hardware components and software algorithms, DSL can be optimized to handle dynamic scenes with faster capture speeds.

Q: What are the limitations of using first-order diffractions in DSL

Using first-order diffractions in DSL introduces certain limitations that need to be addressed. One limitation is related to the low intensity of first-order diffracted light, which may restrict the working depth range of DSL systems. The limited intensity could lead to challenges in capturing accurate spectral information at greater distances from the camera-projector setup. Another limitation is potential interference from higher-order diffractions that are not utilized in DSL but may still impact image quality and accuracy. Managing these limitations effectively is crucial for ensuring reliable performance when utilizing first-order diffractions in DSL.

Q: How can the principles of DSL be applied to non-visible spectra

The principles of Dispersed Structured Light (DSL) can be applied beyond visible spectra by adapting the system components and parameters accordingly. For non-visible spectra applications such as infrared or ultraviolet imaging, different types of diffraction gratings with appropriate characteristics tailored to those spectra ranges would need to be used. Calibration procedures would also have to account for specific emission functions corresponding to those wavelengths. By adjusting key elements like diffraction grating properties, camera response functions, projector emission functions, and calibration methods according to non-visible spectra requirements, similar hyperspectral 3D imaging techniques based on dispersed structured light could be developed for a wide range of applications outside of visible light scenarios.

Centrala begrepp

Dispersed Structured Light (DSL) enables accurate hyperspectral 3D imaging with low cost and high quality.

Sammanfattning

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.

Statistik

DSL achieves spectral accuracy of 18.8 nm FWHM and depth error of 1 mm.

Citat

"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."

Viktiga insikter från

Dispersed Structured Light for Hyperspectral 3D Imaging

by Suhyun Shin,... på arxiv.org 03-26-2024

https://arxiv.org/pdf/2311.18287.pdf

Dispersed Structured Light for Hyperspectral 3D Imaging

Djupare frågor

How can DSL be optimized for faster capture in dynamic scenes

To optimize DSL for faster capture in dynamic scenes, several strategies can be implemented. One approach is to enhance the light efficiency of the system by increasing the intensity of first-order diffractions. This can be achieved by using more powerful projectors or optimizing the diffraction grating film to maximize the dispersion effect. Additionally, implementing advanced algorithms for real-time processing and reconstruction can help reduce the time required for capturing and analyzing hyperspectral 3D data. By improving hardware components and software algorithms, DSL can be optimized to handle dynamic scenes with faster capture speeds.

What are the limitations of using first-order diffractions in DSL

Using first-order diffractions in DSL introduces certain limitations that need to be addressed. One limitation is related to the low intensity of first-order diffracted light, which may restrict the working depth range of DSL systems. The limited intensity could lead to challenges in capturing accurate spectral information at greater distances from the camera-projector setup. Another limitation is potential interference from higher-order diffractions that are not utilized in DSL but may still impact image quality and accuracy. Managing these limitations effectively is crucial for ensuring reliable performance when utilizing first-order diffractions in DSL.

How can the principles of DSL be applied to non-visible spectra

The principles of Dispersed Structured Light (DSL) can be applied beyond visible spectra by adapting the system components and parameters accordingly. For non-visible spectra applications such as infrared or ultraviolet imaging, different types of diffraction gratings with appropriate characteristics tailored to those spectra ranges would need to be used. Calibration procedures would also have to account for specific emission functions corresponding to those wavelengths.
By adjusting key elements like diffraction grating properties, camera response functions, projector emission functions, and calibration methods according to non-visible spectra requirements, similar hyperspectral 3D imaging techniques based on dispersed structured light could be developed for a wide range of applications outside of visible light scenarios.

Dispersed Structured Light for Hyperspectral 3D Imaging: Low-Cost Method