Quantum breakthrough advances radar tech
10 Feb 2020
A new imaging method which exploits the unique properties of quantum-entangled photons to reveal hidden information could help move forward the developing field of quantum radar.
Physicists from the University of Glasgow’s Optics Group describe in a paper published in Science Advances how they have utilised a technique known as quantum illumination to image through noise.
Thomas Gregory, of the Optics Group at the University of Glasgow, said: “We’ve constructed a system in which the correlations in position between pairs of entangled photons may be exploited to improve the resulting image when compared to the corresponding classical case.”
Light is comprised of photons and the method in which an image is captured classically is to use all of the photons detected on the camera to form an image. When enough background noise is added to the image, either through natural phenomena or by a deliberate attempt to obscure the image from an observer, it can become impossible to separate the ‘true’ image from the noise.
Using quantum illumination the quantum correlations between entangled photons may be used to allow an observer to preferentially filter out false information and noise from an image, allowing the ‘true’ image to be revealed. One potential application for the process is quantum radar, which would use quantum light to make it impossible for objects to be obscured from radar detection by spoofing a signal – a valuable advance for both military and civilian operations.
The groups set-up uses a special non-linear crystal to generate entangled photon-pairs. Of these photon-pairs one photon illuminates the ‘true’ image, in this case a bird, prior to detection by the camera, while the second one is detected directly on the camera and acts as a reference for the purposes of exploiting the correlations.
At the same time, photons produced by a conventional light bulb illuminate the ‘spoof’ image’, in this case a cage, and are detected on the same region of the camera as the bird thereby resulting in the classical image comprising a hybrid ‘false’ image of the bird imprisoned within a cage.
Through exploiting correlations between the entangled photon-pairs, the correlated events are preferentially selected and the noise rejected. The end result is a quantum image in which quantum bird is released from its classical cage of noise.
“The achievements of this work in developing a system that uses a multipixel camera detector is a great step towards developing a quantum system that is capable of performing imaging in an optically hostile environment,” said Gregory.