Your search keyword '"Abdulhussain, Sadiq H."' showing total 3 results

1. 3D Object Recognition Using Fast Overlapped Block Processing Technique.

Author

Mahmmod, Basheera M., Abdulhussain, Sadiq H., Naser, Marwah Abdulrazzaq, Alsabah, Muntadher, Hussain, Abir, and Al-Jumeily, Dhiya

Subjects

*RECOGNITION (Psychology), *OBJECT recognition (Computer vision), *IMAGE processing, *FEATURE extraction, *SUPPORT vector machines, *COMPUTATIONAL complexity

Abstract

Three-dimensional (3D) image and medical image processing, which are considered big data analysis, have attracted significant attention during the last few years. To this end, efficient 3D object recognition techniques could be beneficial to such image and medical image processing. However, to date, most of the proposed methods for 3D object recognition experience major challenges in terms of high computational complexity. This is attributed to the fact that the computational complexity and execution time are increased when the dimensions of the object are increased, which is the case in 3D object recognition. Therefore, finding an efficient method for obtaining high recognition accuracy with low computational complexity is essential. To this end, this paper presents an efficient method for 3D object recognition with low computational complexity. Specifically, the proposed method uses a fast overlapped technique, which deals with higher-order polynomials and high-dimensional objects. The fast overlapped block-processing algorithm reduces the computational complexity of feature extraction. This paper also exploits Charlier polynomials and their moments along with support vector machine (SVM). The evaluation of the presented method is carried out using a well-known dataset, the McGill benchmark dataset. Besides, comparisons are performed with existing 3D object recognition methods. The results show that the proposed 3D object recognition approach achieves high recognition rates under different noisy environments. Furthermore, the results show that the presented method has the potential to mitigate noise distortion and outperforms existing methods in terms of computation time under noise-free and different noisy environments. [ABSTRACT FROM AUTHOR]

Published

2022

2. Face Recognition Algorithm Based on Fast Computation of Orthogonal Moments.

Author

Abdulhussain, Sadiq H., Mahmmod, Basheera M., AlGhadhban, Amer, and Flusser, Jan

Subjects

*HUMAN facial recognition software, *FACE perception, *FEATURE extraction, *ORTHOGONAL polynomials, *SUPPORT vector machines

Abstract

Face recognition is required in various applications, and major progress has been witnessed in this area. Many face recognition algorithms have been proposed thus far; however, achieving high recognition accuracy and low execution time remains a challenge. In this work, a new scheme for face recognition is presented using hybrid orthogonal polynomials to extract features. The embedded image kernel technique is used to decrease the complexity of feature extraction, then a support vector machine is adopted to classify these features. Moreover, a fast-overlapping block processing algorithm for feature extraction is used to reduce the computation time. Extensive evaluation of the proposed method was carried out on two different face image datasets, ORL and FEI. Different state-of-the-art face recognition methods were compared with the proposed method in order to evaluate its accuracy. We demonstrate that the proposed method achieves the highest recognition rate in different considered scenarios. Based on the obtained results, it can be seen that the proposed method is robust against noise and significantly outperforms previous approaches in terms of speed. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Robust Handwritten Numeral Recognition Using Hybrid Orthogonal Polynomials and Moments.

Author

Abdulhussain, Sadiq H., Mahmmod, Basheera M., Naser, Marwah Abdulrazzaq, Alsabah, Muntadher Qasim, Ali, Roslizah, Al-Haddad, S. A. R., and Park, Kang Ryoung

Subjects

*HANDWRITING recognition (Computer science), *NUMERALS, *CONVOLUTIONAL neural networks, *OPTICAL character recognition, *ORTHOGONAL polynomials, *SUPPORT vector machines

Abstract

Numeral recognition is considered an essential preliminary step for optical character recognition, document understanding, and others. Although several handwritten numeral recognition algorithms have been proposed so far, achieving adequate recognition accuracy and execution time remain challenging to date. In particular, recognition accuracy depends on the features extraction mechanism. As such, a fast and robust numeral recognition method is essential, which meets the desired accuracy by extracting the features efficiently while maintaining fast implementation time. Furthermore, to date most of the existing studies are focused on evaluating their methods based on clean environments, thus limiting understanding of their potential application in more realistic noise environments. Therefore, finding a feasible and accurate handwritten numeral recognition method that is accurate in the more practical noisy environment is crucial. To this end, this paper proposes a new scheme for handwritten numeral recognition using Hybrid orthogonal polynomials. Gradient and smoothed features are extracted using the hybrid orthogonal polynomial. To reduce the complexity of feature extraction, the embedded image kernel technique has been adopted. In addition, support vector machine is used to classify the extracted features for the different numerals. The proposed scheme is evaluated under three different numeral recognition datasets: Roman, Arabic, and Devanagari. We compare the accuracy of the proposed numeral recognition method with the accuracy achieved by the state-of-the-art recognition methods. In addition, we compare the proposed method with the most updated method of a convolutional neural network. The results show that the proposed method achieves almost the highest recognition accuracy in comparison with the existing recognition methods in all the scenarios considered. Importantly, the results demonstrate that the proposed method is robust against the noise distortion and outperforms the convolutional neural network considerably, which signifies the feasibility and the effectiveness of the proposed approach in comparison to the state-of-the-art recognition methods under both clean noise and more realistic noise environments. [ABSTRACT FROM AUTHOR]

Published

2021