Ghost imaging
Ghost imaging is a technique that produces an image of an object by combining information from two light detectors: a conventional, multi-pixel detector that does not view the object, and a single-pixel detector that does view the object. Two techniques have been demonstrated. A quantum method uses a source of pairs of entangled photons, each pair shared between the two detectors, while a classical method uses a pair of correlated coherent beams without exploiting entanglement. Both approaches may be understood within the framework of a single theory.
History
The first demonstration of ghost imaging, performed by T. B. Pittman, Y. H. Shih, D. V. Strekalov, and A. V. Sergienko in 1995, was based on quantum correlations between entangled photon pairs. One of the photons of the pair strikes the object and then the bucket detector while the other follows a different path to a camera. The camera is constructed to only record pixels from entangled photon pairs that hit both the bucket detector and the camera's image plane. Then a large number of registered entangled pairs gradually forms a full image.Later experiments indicated that the correlations between the light beam that hits the camera and the beam that hits the object may be explained by purely classical physics. If quantum correlations are present, the signal-to-noise ratio of the reconstructed image can be improved. In 2009 'pseudothermal ghost imaging' and 'ghost diffraction' were demonstrated by implementing the 'computational ghost-imaging' scheme, which relaxed the need to evoke quantum correlations arguments for the pseudothermal source case.
Recently, it was shown that the principles of 'Compressed-Sensing' can be directly utilized to reduce the number of measurements required for image reconstruction in ghost imaging. This technique allows an N pixel image to be produced with far less than N measurements and may have applications in LIDAR and microscopy.
Advances in military research
The U.S. Army Research Laboratory developed remote ghost imaging in 2007 with the goal of applying advanced technology to the ground, satellites and unmanned aerial vehicles. Ronald E. Meyers and Keith S. Deacon of ARL, received a patent in 2013 for their quantum imaging technology called, "System and Method for Image Enhancement and Improvement." The researchers received the Army Research and Development Achievement Award for outstanding research in 2009 with the first ghost image of a remote object.Mechanism
A simple example clarifies the basic principle of ghost imaging. Imagine two transparent boxes: one that is empty and one that has an object within it. The back wall of the empty box contains a grid of many pixels, while the back wall of the box with the object is a large single-pixel. Next, shine laser light into a beamsplitter and reflect the two resulting beams such that each passes through the same part of its respective box at the same time. For example, while the first beam passes through the empty box to hit the pixel in the top-left corner at the back of the box, the second beam passes through the filled box to hit the top-left corner of the bucket detector.Now imagine moving the laser beam around in order to hit each of the pixels at the back of the empty box, meanwhile moving the corresponding beam around the box with the object. While the first light beam will always hit a pixel at the back of the empty box, the second light beam will sometimes be blocked by the object and will not reach the bucket detector. A processor receiving a signal from both light detectors only records a pixel of an image when light hits both detectors at the same time. In this way, a silhouette image can be constructed, even though the light going towards the multi-pixel camera did not touch the object.
In this simple example, the two boxes are illuminated one pixel at a time. However, using quantum correlation between photons from the two beams, the correct image can also be recorded using complex light distributions. Also, the correct image can be recorded using only the single beam passing through a computer-controlled light modulator to a single-pixel detector.