Geometric superresolution and field-of-view extension achieved using digital mirror devices

“…[5] we have demonstrated the basic concept in the visible regime and now we present its adaptation to the near infrared (IR) spectral range. The experimental setup we constructed is seen in Fig.…”

“…[5] the usage of DMDs allows obtaining geometric resolution improvement and a significant enhancement of the field of view (FOV). The idea behind the above-mentioned imaging features is to use the DMDs to properly encode the spatial frequency domain such that the multiplexed information of the imaged object can later on be separated and reconstructed.…”

“…Digital mirror devices (DMD) based optical configuration have a constantly increasing role in realization of integrated and high performance optical modules for optical scatter imaging [1], illumination purposes [2], fluorescent microscopy [3] and for super resolution and field of view extension [4,5]. On the other hand there are many techniques and applications for multiple pinhole coded aperture systems as well many designs of multi apertures cameras that have been investigated and implemented using computational approaches [6][7][8][9].…”

Computational imaging expansion from visible to infrared and to THz systems

“…[5] we have demonstrated the basic concept in the visible regime and now we present its adaptation to the near infrared (IR) spectral range. The experimental setup we constructed is seen in Fig.…”

“…[5] the usage of DMDs allows obtaining geometric resolution improvement and a significant enhancement of the field of view (FOV). The idea behind the above-mentioned imaging features is to use the DMDs to properly encode the spatial frequency domain such that the multiplexed information of the imaged object can later on be separated and reconstructed.…”

“…Digital mirror devices (DMD) based optical configuration have a constantly increasing role in realization of integrated and high performance optical modules for optical scatter imaging [1], illumination purposes [2], fluorescent microscopy [3] and for super resolution and field of view extension [4,5]. On the other hand there are many techniques and applications for multiple pinhole coded aperture systems as well many designs of multi apertures cameras that have been investigated and implemented using computational approaches [6][7][8][9].…”

Computational imaging expansion from visible to infrared and to THz systems

“…Precise modulations can be introduced in the form of exact sub-pixel translations using a motorized stage [4], patterned illumination [5], a sequence of controlled point spread functions [6], placing a coded mask in the aperture [7], random lenses [8], and many other techniques. Introducing a highresolution occlusive programmable mask somewhere into the arXiv:1810.08855v1 [eess.IV] 20 Oct 2018 optical pathway is a simple way of introducing high-resolution variability, and eliminates the need for fine mechanical movements.…”

“…Zlotnik et al used a combination of two digital micromirror devices (DMDs) in the aperture and intermediate image planes to realize a random operator for compressive sensing, where a DMD in the aperture was used to generate random point spread functions and a DMD in an intermediate image plane was used for pointwise coding [6]. This work addressed the possibility of pointwise modulating the scene with a DMD, but relied on fine mechanical positioning of the DMD relative to the sensor or a second DMD in the aperture to obtain high-resolution information.…”

A Hardware Realization of Superresolution Combining Random Coding and Blurring

Spatial super-resolution of colored images by micro mirrors