Abstract
The development of an efficient adaptively accelerated iterative deblurring algorithm based on Bayesian statistical concept has been reported. Entropy of an image has been used as a "prior" distribution and instead of additive form, used in conventional acceleration methods an exponent form of relaxation constant has been used for acceleration. Thus the proposed method is called hereafter as adaptively accelerated maximum a posteriori with entropy prior (AAMAPE). Based on empirical observations in different experiments, the exponent is computed adaptively using first-order derivatives of the deblurred image from previous two iterations. This exponent improves speed of the AAMAPE method in early stages and ensures stability at later stages of iteration. In AAMAPE method, we also consider the constraint of the nonnegativity and flux conservation. The paper discusses the fundamental idea of the Bayesian image deblurring with the use of entropy as prior, and the analytical analysis of superresolution and the noise amplification characteristics of the proposed method. The experimental results show that the proposed AAMAPE method gives lower RMSE and higher SNR in 44% lesser iterations as compared to nonaccelerated maximum a posteriori with entropy prior (MAPE) method. Moreover, AAMAPE followed by wavelet wiener filtering gives better result than the state-of-the-art methods.
Highlights
Image deblurring, process of restoration of an image from its blurred and noisy version, is an enduring linear inverse problem and is encountered in many application areas such as in remote sensing, medical imaging, seismology, and astronomy [1,2,3]
We describe three experiments demonstrating the performance of the accelerated maximum a posteriori with entropy prior (AAMAPE) method in comparison (e) with maximum a posteriori with entropy prior (MAPE) method
We proposed AAMAPE method for image deblurring
Summary
Process of restoration of an image from its blurred and noisy version, is an enduring linear inverse problem and is encountered in many application areas such as in remote sensing, medical imaging, seismology, and astronomy [1,2,3]. We describe the maximum a posteriori with entropy prior (MAPE) method for image deblurring in Bayesian framework This method is nonlinear and solved iteratively. The positivity of pixel intensity in the proposed acceleration method is automatically ensured since multiplicative correction term is always positive, while in other acceleration methods based on additive correction term, the positivity is enforced manually at the end of iteration Another important objective of this paper is to analyze the superresolution and the nature of noise amplification in the proposed AAMAPE method. We present general analytical interpretation of superresolving capability of the proposed AAMAPE method and confirmed it experimentally It is a well-known fact about the nonlinear methods based on maximum likelihood that the restored images begin to deteriorate after certain number of iterations.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
