A new linear transfer theory and characterization method for image detectors. Part I: Theory

A new generalized linear transfer theory describing the signal and noise transfer in image detectors is presented, which can be applied to calculate the pixelwise first and second statistical moment of arbitrary experimental images including correlation between pixels. Similar to the existing notion...

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Bibliographic Details
Published in:Ultramicroscopy 2012-04, Vol.115, p.68-77
Main Authors: Niermann, Tore, Lubk, Axel, Röder, Falk
Format: Article
Language:English
Subjects:
Detection quantum efficiency
Detector noise
Image detector
Modulation transfer function
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Summary:A new generalized linear transfer theory describing the signal and noise transfer in image detectors is presented, which can be applied to calculate the pixelwise first and second statistical moment of arbitrary experimental images including correlation between pixels. Similar to the existing notion of a point spread function describing the transfer of the first statistical moment (the average), a noise spread function is introduced to characterize the spatially resolved transfer and generation of noise (second central moment, covariance). It is also shown that previously used noise characteristics like the noise power spectrum and detection quantum efficiency, derived from plainly illuminated images, contain only partial information of the complete noise transfer. ► Linear transfer theory for the average output and the covariance of image detectors. ► The covariance is described by a new quantity, the noise spread function (NSF). ► Noise power spectrum and detection quantum efficiency are given by integrals of NSF. ► A new method for detector characterization is presented, and exploited in Part II.
ISSN:0304-3991
1879-2723
DOI:10.1016/j.ultramic.2012.01.012