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Hyperspectral imaging technology enables photographers obtain super fine detailed images by capturing the spectrum for each pixel in an image of a scene. The technology has wide reach and is being applied in fields such as military combat, astronomy, agriculture, biomedical imaging and geo-science. Scientists, for instance, rely on hyperspectral imaging to observe and analyze materials for mining and geology, or for various applications in the medical field. However, these hyperspectral imaging systems are expensive and require complex specialized hardware to operate.
A team of computer scientists from KAIST, South Korea, and Universidad de Zaragoza, Spain, has now devised a way for low-cost accurate hyperspectral imaging, ridding of expensive equipment and complex coding. This novel, compact single-shot hyperspectral imaging method captures images using a conventional DSLR camera equipped with just an ordinary refractive prism placed in front of the lens. The new, user-friendly method was tested on a variety of natural scenes, and the results, according to the researchers, compared well with current state-of-the-art hyperspectral imaging systems, achieving quality images without compromising accuracy.
The team presented their new method at SIGGRAPH Asia 2017 in Bangkok from November 27 to November 30. This annual conference and exhibition showcases the world’s leading professionals, academics and creative minds at the forefront of computer graphics and interactive techniques. The research team comprises of Lead author Min H. Kim, an associate professor of computer science at KAIST; Diego Gutierrez, an associate professor at Universidad de Zaragoza; Seung-Hwan Baek, computer science PhD student at KAIST; and Incheol Kim, researcher at KAIST in Min H. Kim’s lab.
Hyperspectral imaging systems are generally built for specific purposes such as aerial remote sensing, or military applications, and as such are neither affordable nor practical for ordinary users. The new KAIST system requires no advanced skills, and is able to obtain hyperspectral images at virtually full resolution while making hyperspectral imaging practical.
A hyperspectral image can be described as a three-dimensional cube. The imaging technique involves capturing the spectrum for each pixel in an image; as a result, the digital images produce detailed characterizations of the scene or object. Since the researchers’ new setup operates without the typical coded aperture mask and professional setup with large optical components, available spectral cues are limited. To this end, the researchers developed an image formulation model that predicts the perspective projection of dispersion (splitting light into a spectrum), yielding the dispersion direction and magnitude of each wavelength at every pixel.
Their technique also comprises a novel calibration method to estimate the spatially varying dispersion of the prism. It enables users to capture spectral information without requiring a large system setup with various optical components. Lastly, their reconstruction algorithm estimates the full spectral information of a scene from sparse information, addressing edge restoration of the scene being captured, gradient estimation and the spectral resolution of the image.
In the study, the researchers compare the predictions of their dispersion model with those of professional optics simulation software. They placed a prism in front of a 50 mm lens of a digital camera, and captured a point at a distance of 700 mm. Dispersion at every pixel was accurately predicted by their method, producing comparable results to professional physical simulation of light transport. In future work, the team plans to address the system’s current sensitivity to noise as well as performance limitations due to lighting and surfaces without edges of a scene or object.