Filtering and Performance Evaluation for Restoration of Grayscale Image Corrupted by Salt & Pepper Noise Using Low Pass Filtering Schemes | IEEE Conference Publication | IEEE Xplore
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Filtering and Performance Evaluation for Restoration of Grayscale Image Corrupted by Salt & Pepper Noise Using Low Pass Filtering Schemes

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Chandra Sekhar Panda; Srikanta Patnaik
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Abstract:

In this paper, different novel low pass filtering schemes are investigated to restore a gray scale image corrupted by Salt & Pepper noise. The filtering methods with diff...Show More

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Abstract:

In this paper, different novel low pass filtering schemes are investigated to restore a gray scale image corrupted by Salt & Pepper noise. The filtering methods with different window sizes are applied to corrupted images with varying strengths and different noise probability. We have proposed both subjective and objective methods to evaluate the performance of different filtering techniques for noise removal with an aim to find an efficient filter which will be suitable for real time image restoration applications. Subjective methods have been performed by visually comparing the different restoration characteristics in the output image. The mean square error, signal to noise ratio, peak signal to noise ratio and signal to noise ratio improvement have been used for objective evaluation of the different filtering schemes. Finally, to validate the efficiency of filtering schemes, simulation study has been carried out using MATLAB 5.0.
Published in: 2009 Second International Conference on Emerging Trends in Engineering & Technology
Date of Conference: 16-18 December 2009
Date Added to IEEE Xplore: 22 January 2010
ISBN Information:

ISSN Information:

DOI: 10.1109/ICETET.2009.103
Conference Location: Nagpur, India
References is not available for this document.
Contents

I. Introduction

When images are captured optically or electronically and processed, the original image signal is usually degraded. The degradation effect may be seen in the form of sensor noise, blur due to out of focus of camera, relative object camera motion, lens and film non linearity, impulse due to faulty storage and transmission media and many other factors. Noise is a high frequency component in an image, so we require low pass filter to denoise it. Noise removal using different types of low pass filtering techniques is an important area of research in digital image and signal processing. Denoising a corrupted image is known as image restoration. The objective of the restoration scheme is to recover the original image from the observed degraded image. Image restoration methods are used to model the degradation process and apply an approximately inverse process to the degraded image to recover the original image [1]. The effectiveness of such restoration techniques depends on the availability and completeness of knowledge about the impulse degradation process as well as on the structure of the filtering scheme. The linear filter is adequate in removing noise for a bandwidth limited additive noise like Gaussian noise from the corrupted images. However, it is observed in many situations that due to presence of impulse noise, linear filter produces more smoothing and poor performance [2]. To overcome these shortcomings, non-linear filters like median filter is used to denoise the Salt & Pepper noise from the corrupted image. In linear filter, the value of the output pixel is calculated using the weighted sum of input pixels, but non linear filter assigns a value to the output pixel which is directly based on the values of the pixel in the neighborhood. The median filter is a computationally efficient non linear filter for denoising impulse noise and also preserves edges. Different image restoration schemes have been proposed in the literature on digital image processing [3], [4]. Median filtering is a nonlinear signal processing technique developed by Tukey that is useful for noise suppression in images [5]. To improve the restoration performance several fast median filtering algorithms are described as in [6], [7], [8]. Different literatures are available for denoising Salt & Pepper noise by average filter as in [9], [10]. To denoise salt & Pepper noise from gray scale image by Rank order filtering, different efficient schemes are proposed in [11]–[14]. The outlier technique works on a principle in which the center pixel in a window is replaced by the average of its ‘k’ neighbors whose amplitudes are closest to the center pixel as discussed in [15]. Another variant of the outlier algorithm called the sigma filter has been suggested in [16]. Objective and subjective estimation of image restoration by different filtering techniques are reported as in [17], [18], [19].

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