Non-uniform Deblurring for Shaken Images

Photographs taken in low-light conditions are often blurry as a result of camera shake, i.e. a motion of the camera while its shutter is open. Most existing deblurring methods model the observed blurry image as the convolution of a sharp image with a uniform blur kernel. However, we show that blur f...

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Veröffentlicht in:	International journal of computer vision 2012-06, Vol.98 (2), p.168-186
Hauptverfasser:	Whyte, Oliver, Sivic, Josef, Zisserman, Andrew, Ponce, Jean
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Analysis Applied sciences Approximation Artificial Intelligence Cameras Computer Imaging Computer Science Computer science control theory systems Detection, estimation, filtering, equalization, prediction Exact sciences and technology Image Processing and Computer Vision Image processing systems Information, signal and communications theory Kernels Mathematical models Pattern Recognition Pattern Recognition and Graphics Pattern recognition. Digital image processing. Computational geometry Rotational Shutters Signal and communications theory Signal, noise Social exclusion Studies Telecommunications and information theory Three dimensional Vision Vision systems
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container_title	International journal of computer vision
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creator	Whyte, Oliver Sivic, Josef Zisserman, Andrew Ponce, Jean
description	Photographs taken in low-light conditions are often blurry as a result of camera shake, i.e. a motion of the camera while its shutter is open. Most existing deblurring methods model the observed blurry image as the convolution of a sharp image with a uniform blur kernel. However, we show that blur from camera shake is in general mostly due to the 3D rotation of the camera, resulting in a blur that can be significantly non-uniform across the image. We propose a new parametrized geometric model of the blurring process in terms of the rotational motion of the camera during exposure. This model is able to capture non-uniform blur in an image due to camera shake using a single global descriptor, and can be substituted into existing deblurring algorithms with only small modifications. To demonstrate its effectiveness, we apply this model to two deblurring problems; first, the case where a single blurry image is available, for which we examine both an approximate marginalization approach and a maximum a posteriori approach, and second, the case where a sharp but noisy image of the scene is available in addition to the blurry image. We show that our approach makes it possible to model and remove a wider class of blurs than previous approaches, including uniform blur as a special case, and demonstrate its effectiveness with experiments on synthetic and real images.
doi_str_mv	10.1007/s11263-011-0502-7
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Most existing deblurring methods model the observed blurry image as the convolution of a sharp image with a uniform blur kernel. However, we show that blur from camera shake is in general mostly due to the 3D rotation of the camera, resulting in a blur that can be significantly non-uniform across the image. We propose a new parametrized geometric model of the blurring process in terms of the rotational motion of the camera during exposure. This model is able to capture non-uniform blur in an image due to camera shake using a single global descriptor, and can be substituted into existing deblurring algorithms with only small modifications. To demonstrate its effectiveness, we apply this model to two deblurring problems; first, the case where a single blurry image is available, for which we examine both an approximate marginalization approach and a maximum a posteriori approach, and second, the case where a sharp but noisy image of the scene is available in addition to the blurry image. 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subjects	Algorithms Analysis Applied sciences Approximation Artificial Intelligence Cameras Computer Imaging Computer Science Computer science control theory systems Detection, estimation, filtering, equalization, prediction Exact sciences and technology Image Processing and Computer Vision Image processing systems Information, signal and communications theory Kernels Mathematical models Pattern Recognition Pattern Recognition and Graphics Pattern recognition. Digital image processing. Computational geometry Rotational Shutters Signal and communications theory Signal, noise Social exclusion Studies Telecommunications and information theory Three dimensional Vision Vision systems
title	Non-uniform Deblurring for Shaken Images
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