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3D-Printed Hyperspectral Imagers Designed for UAVs

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Researchers used 3D printing and low-cost parts to create an inexpensive hyperspectral imager that is light enough to use on drones. The visible-wavelength hyperspectral imager (HSI) weighs less than half a pound and, according to researchers, can be built for as little $700 (USD). In a recent paper the team provides directions for creating the HSI.

DYI HSI is lightweight, low-cost. UNIS, Norway.
Researchers used 3D printing to create hyperspectral imagers that are light enough to use on a drone. The imager is the small protrusion on the bottom of the drone's body. Courtesy of João Fortuna, Norwegian University of Science and Technology.

The imagers, created by a research team from the University Centre in Svalbard, employ the push-broom technique, an approach that uses precise line-scanning to build up a spectral image. The researchers added a stabilization system to their setup so that a drone’s movement would not distort the image as it was being generated.

“Push-broom hyperspectral imagers typically require expensive orientation stabilization,” said researcher Fred Sigernes. “However, you can now buy very inexpensive gyroscope-based, electronically stabilizing systems. The advent of these new systems made it possible for us to make inexpensive hyperspectral imagers.”

The dispersive element housings were printed using a thermoplastic 3D printer combined with S-mount optical components and commercial off-the-shelf camera heads. The 3D printer eased the process of making the custom optics holders needed for the imagers.

DIY HSI is lightweight enough for drone, UNIS, Norway.
Researchers used 3D printing to make the holder (black rectangular piece) for the optics used to create an inexpensive and small hyperspectral imager. Feasibility tests showed that 3D printing can be used to produce prototype parts accurate enough for optical systems. Courtesy of Fred Sigernes, University Centre in Svalbard.

“Making items in metal is time-consuming and can be very expensive,” said Sigernes. “However, 3D printing with plastic is inexpensive and very effective for making even complex parts, such as the piece needed to hold the grating that disperses the light. I was able to print several versions and try them out.”

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Four models were constructed, each with a mass less than 200 g and a spectral range in the VIS to NIR part of the electromagnetic spectrum. The bandpass ranged from 1.4  to 5 nm.

Researchers tested one of their prototypes aboard an octocopter drone equipped with a two-axis electronic stabilizing system. The hyperspectral imager performed well and was able to detect landscape features, such as vegetation and bodies of water. Three test experiments with motorized gimbals to stabilize attitude showed that the instruments were capable of push-broom spectral imaging from various platforms, including airborne drone to handheld operations and three-axis electronic stabilizing systems. For one experiment, researchers swept the imager across a computer screen displaying a fruit collection, acquiring 571 spectrograms in 22 s.

These feasibility tests showed that 3D printing could provide the level of accuracy needed to produce prototype parts for optical systems. The printed plastic parts were lightweight and strong enough to keep the overall system light and small. Researchers suggest that after testing, metal versions of 3D printed parts could be ordered if desired to create imagers that would be more durable.

Traditional hyperspectral imagers can cost tens of thousands of dollars and are bulky and heavy.

Although the new, DIY imagers don’t provide the sensitivity of traditional hyperspectral imagers, their performance is sufficient for mapping terrain or detecting ocean color in daylight. The researchers are now working to improve their imager’s sensitivity by making slightly larger versions of the instruments that would still be small and light enough for use on drones. Improving the sensitivity of the imagers would result in higher-quality data.

“There are many ways to use data acquired by hyperspectral imagers,” said Sigernes. “By lowering the cost of these instruments, we hope that more people will be able to use this analytical technique and develop it further.”

The research was published in Optics Express, a publication of OSA, The Optical Society (doi:10.1364/OE.26.006021).

Published: March 2018
Glossary
hyperspectral imaging
Hyperspectral imaging is an advanced imaging technique that captures and processes information from across the electromagnetic spectrum. Unlike traditional imaging systems that record only a few spectral bands (such as red, green, and blue in visible light), hyperspectral imaging collects data in numerous contiguous bands, covering a wide range of wavelengths. This extended spectral coverage enables detailed analysis and characterization of materials based on their spectral signatures. Key...
visible spectrum
That region of the electromagnetic spectrum to which the retina is sensitive and by which the eye sees. It extends from about 400 to 750 nm in wavelength.
Research & TechnologyeducationNorwayImaginghyperspectral imagingHSIdronescamerasvisible spectrumenvironmentTech Pulse

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