期刊
IEEE SIGNAL PROCESSING MAGAZINE
卷 39, 期 1, 页码 25-31出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/MSP.2021.3120981
关键词
Scanning electron microscopy; Codes; Transmission electron microscopy; Microscopy; Data integrity; Graphics processing units; Detectors
The emergence of high-frame-rate DEDs has enabled the use of 4D-STEM techniques, but requires data transmission and storage capabilities beyond commonly available computing infrastructures. Commercial DEDs now offer users the option to compromise on pixel bit depth, detector binning, or windowing to reduce file size and achieve higher frame rates, which may result in loss of potentially advantageous information during data analysis.
The arrival of direct electron detectors (DEDs) with high frame rates in the field of scanning transmission electron microscopy (TEM) has enabled many experimental techniques that require collection of a full diffraction pattern at each scan position, a field which is subsumed under the name four-dimensional scanning transmission electron microscopy (4D-STEM). DED frame rates approaching 100 kHz require data transmission rates and data storage capabilities that exceed those of the commonly available computing infrastructures. Current commercial DEDs allow the user to make compromises in pixel bit depth, detector binning, or windowing to reduce the per-frame file size and allow higher frame rates. This change in detector specifications requires decisions to be made before data acquisition that may reduce or lose information that could have been advantageous during data analysis.
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