Abstract
Ghost imaging (GI) is an imaging technique that uses the correlation between two light beams to reconstruct the image of an object. Conventional GI algorithms require large memory space to store the measured data and perform complicated offline calculations, limiting practical applications of GI. Here we develop an instant ghost imaging (IGI) technique with a differential algorithm and an implemented high-speed on-chip IGI hardware system. This algorithm uses the signal between consecutive temporal measurements to reduce the memory requirements without degradation of image quality compared with conventional GI algorithms. The on-chip IGI system can immediately reconstruct the image once the measurement finishes; there is no need to rely on post-processing or offline reconstruction. This system can be developed into a realtime imaging system. These features make IGI a faster, cheaper, and more compact alternative to a conventional GI system and make it viable for practical applications of GI.
Highlights
Ghost imaging (GI) is an imaging technology which reconstructs the image of an object by calculating the correlation between two beams
The IGI hardware system is completely on-chip because the two CMOSs, the field-programmable gate array (FPGA), and the monitor are integrated on a printed circuit board (PCB)
We demonstrate this correlation by conducting the Hanbury Brown and Twiss (HBT) experiment, which takes the form
Summary
Ghost imaging (GI) is an imaging technology which reconstructs the image of an object by calculating the correlation between two beams (test and reference). To demonstrate the validity and the hardware feasibility of the SDGI algorithm, we developed a prototype on-chip hardware system using a single field-programmable gate array (FPGA), without any external memory; it can process 500 measurements per second online. This system was named instant ghost imaging (IGI) due to one significant advantage of this system: its image reconstruction time is almost zero and the image is formed immediately once the temporal measurement is complete. These features make IGI a faster, cheaper, and more compact alternative to a conventional GI system and make it viable for practical applications of GI
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