Title :
CNN based dark signal non-uniformity estimation
Author :
Geese, Marc ; Ruhnau, Paul ; Jähne, Bernd
Author_Institution :
Robert Bosch GmbH, Leonberg, Germany
Abstract :
Image sensors come with a spatial inhomogeneity, known as Fixed Pattern Noise, that degrades the image quality. Especially the dark signal non uniformity (DSNU) component of the FPN drifts with time and depends highly on temperature and exposure time. In this paper we introduce a cellular neural network (CNN) to estimate the DSNU from a given set of recorded images. Therefore the foundations of a previously presented maximum likelihood estimation method are used. A rigorous mathematical derivation exploits the available sensor statistics and uses only well motivated statistical models to calculate the CNN´s synaptic weights. The advantages of the resulting CNN-method are continuous DSNU updates and a reduction of the computational complexity. Furthermore, a comparison based on ground truth correction patterns shows a significant performance increase to related methods.
Keywords :
cellular neural nets; computational complexity; image processing; image sensors; maximum likelihood estimation; noise; CNN based dark signal nonuniformity estimation; CNN synaptic weight; DSNU component; cellular neural network; computational complexity reduction; exposure time; fixed pattern noise; ground truth correction pattern; image quality degradation; image sensor; mathematical derivation; maximum likelihood estimation method; sensor statistics; spatial inhomogeneity; statistical model; temperature; Cameras; Least squares approximation; Manganese; Mathematical model; Maximum likelihood estimation; Random variables; Standards;
Conference_Titel :
Cellular Nanoscale Networks and Their Applications (CNNA), 2012 13th International Workshop on
Conference_Location :
Turin
Print_ISBN :
978-1-4673-0287-6
DOI :
10.1109/CNNA.2012.6331408
