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Motivation
The following equation provides the basic model for a blurry observation:
The FTVd algorithm quickly reconstructs a clear image from a noisy, blurry image for a given blur kernel. Our objective is to study the efficacy of the Fast Total Variation deconvolution (FTVd) algorithm for recovering images affected by common types of blur.
Problem
While blur can be used as an artistic effect, much of photography distills down to practices that minimize blur. For instance, there are techniques for holding the camera steady to minimize shake or movement of the focal plane. High shutter speeds are used to “freeze” object motion. Furthermore, manufacturers design high-end lenses with “image stabilization” or “vibration reduction” features, and some design the sensor in the camera body to resist forms of camera shake. But as cameras become increasingly integrated with small form factor devices, their size and lack of heft make them more susceptible to blur caused by camera shake or movement between the shooter and the subject. As a result, the techniques and equipment that are used in digital SLR photography present a less practical solution to a growing photography community.
Even with the right equipment, however, blur is an unavoidable reality in images. Also, that same integrated circuits and small devices in that same equipment will introduce different kinds of noise that further corrupt the received signal. For a photographer trying to capture the moment in which an event occurs, a blurry image can be an opportunity lost forever. For the photographer shooting a dim scene without a steady hand, blurry pictures are the norm. Post-processing of these photos may present an avenue for salvaging blurry photos that are otherwise useless.
Objective
We will use the following two images to test the FTVd algorithms.
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