Using only a piece of ground glass and a monochrome sensor, the
scientists created multi-coloured images by 'reverse engineering' the light
that is scattered by the translucent matt surface of the ground glass, thus
obtaining the original image that was projected on to it.
Since different wavelengths of light are scattered differently by the
ground glass, the NTU scientists created an algorithm to reconstruct the image.
To do this they created a library of 'speckle patterns' linked to each
wavelength of light, including those in the infrared and ultraviolet spectrums
which are not visible to the naked eye.
In a conventional camera, optics made from glass or plastic lenses
capture light and guide it onto the colour filters and camera sensor to obtain
sharp colour images. These lenses are usually bulky in size and expensive due
to the precision manufacturing required.
By removing the need for a lens and colour filters and replacing them
with ground glass, this innovation could potentially be applied to compact
cameras and smart phones to make them slimmer.
Assistant Professor Steve Cuong Dang from the NTU School of Electrical
and Electronic Engineering who led the research, said their new imaging
technique could help to improve imaging applications in biomedical and
scientific applications as well as opening new doors for other industries.
"Our technology can also reconstruct images in other multiple wavelengths
invisible to the naked eye, like infrared and ultraviolet, which are used in
imaging purposes for medicine, surveillance and astrophysics. It can also
reconstruct images taken at the microscopic scale," explained Prof Dang.
"Our multispectral imaging technique uses a monochromic (black and
white) camera coupled with a simple piece of ground glass, making it very
cost-effective compared to existing multispectral cameras on the market.
"The unique feature of our camera is that it can capture any range of
light spectrum, unlike existing cameras on the market which are pre-fixed. It
is also less affected by optical alignment issues like conventional cameras,
because there are no moving parts and no focusing optics."
An interdisciplinary research project
Professor Yoon Soon Fatt, Chair of NTU's School of Electrical and
Electronic Engineering said the innovation was the result of interdisciplinary
research involving both physics and photonics engineering.
"How light interacts with objects change with varying wavelengths,
so our scientists had to think out of the box, in order to design a camera not
limited by the typical red, green and blue spectrums. This research is an
example of how advanced photonics research can lead to potential improvements
to diagnostics, sensing and surveillance technologies." Prof Yoon said.
This interdisciplinary project took Prof Dang and his researchers Dr
Sujit Kumar Sahoo, and Dr Tang Dongliang, over a year of research and
development.
"There are other potential areas of application where our technique
could be useful. For instance, it could be used for food safety, where one can
take a photo of fruits or meat in particular spectra to look for spots that are
associated with chemicals or bacterial activity leading to spoilage," said
Dr Sahoo, who is the first author of the paper.
The research team used their technique to distinguish between two
different apple juices which look identical to the naked eye, but have
different colour spectrums signalling their difference in ingredient or
freshness, for instance.
It could also be used for forensics, as the camera could be tuned to
capture a wide spectrum, including near infrared and ultraviolet, to reveal
clues or evidence invisible under normal circumstances.
With only a snapshot picture and a computational algorithm, this
multispectral imaging technique combines the strengths of vision technology and
spectroscopy to do multiple analysis at very high speeds.
A patent has been filed for this new technology by NTU's innovation and
enterprise arm, NTUitive, and the research team will be engaging industry
partners to see how they can adapt their technology for real-world
applications.
Supported by NTUitive and the LUX Photonics Consortium, the team
received keen interest from industry players and potential adopters to further
develop this technology in the fields of vision correction and chemical
sensing. This innovation was featured on the cover of the scientific journal
Optica in Oct 2017.
Story Source:
Materials provided by Nanyang Technological
University. Note: Content may be edited for style and length.
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