%A Karch,Barry K. %A Hardie,Russell C. %D 2015 %J Frontiers in Physics %C %F %G English %K super-resolution,image processing,image restoration,Image Enhancement,Color Filter Array Demosaicing %Q %R 10.3389/fphy.2015.00028 %W %L %M %P %7 %8 2015-April-24 %9 Original Research %+ Barry K. Karch,Air Force Research Laboratory, AFRL/RYMT, Wright-Patterson Air Force Base,OH, USA,barry.karch@us.af.mil %+ Barry K. Karch,Department of Electrical and Computer Engineering, University of Dayton,Dayton, OH, USA,barry.karch@us.af.mil %# %! Robust SR by fusion of interpolated frames %* %< %T Robust super-resolution by fusion of interpolated frames for color and grayscale images %U https://www.frontiersin.org/articles/10.3389/fphy.2015.00028 %V 3 %0 JOURNAL ARTICLE %@ 2296-424X %X Multi-frame super-resolution (SR) processing seeks to overcome undersampling issues that can lead to undesirable aliasing artifacts in imaging systems. A key factor in effective multi-frame SR is accurate subpixel inter-frame registration. Accurate registration is more difficult when frame-to-frame motion does not contain simple global translation and includes locally moving scene objects. SR processing is further complicated when the camera captures full color by using a Bayer color filter array (CFA). Various aspects of these SR challenges have been previously investigated. Fast SR algorithms tend to have difficulty accommodating complex motion and CFA sensors. Furthermore, methods that can tolerate these complexities tend to be iterative in nature and may not be amenable to real-time processing. In this paper, we present a new fast approach for performing SR in the presence of these challenging imaging conditions. We refer to the new approach as Fusion of Interpolated Frames (FIF) SR. The FIF SR method decouples the demosaicing, interpolation, and restoration steps to simplify the algorithm. Frames are first individually demosaiced and interpolated to the desired resolution. Next, FIF uses a novel weighted sum of the interpolated frames to fuse them into an improved resolution estimate. Finally, restoration is applied to improve any degrading camera effects. The proposed FIF approach has a lower computational complexity than many iterative methods, making it a candidate for real-time implementation. We provide a detailed description of the FIF SR method and show experimental results using synthetic and real datasets in both constrained and complex imaging scenarios. Experiments include airborne grayscale imagery and Bayer CFA image sets with affine background motion plus local motion.