Your search keyword '"Chola, Channabasava"' showing total 11 results

1. Gender identification of Drosophila melanogaster based on morphological analysis of microscopic images

Author

Mestetskiy, Leonid M., Guru, D. S., Benifa, J. V. Bibal, Nagendraswamy, H. S., and Chola, Channabasava

Published

2023

2. An effective approach for Arabic document classification using machine learning

Author

Muaad, Abdullah Y., Kumar, G. Hemantha, Hanumanthappa, J., Benifa, J.V. Bibal, Mourya, M. Naveen, Chola, Channabasava, Pramodha, M., and Bhairava, R.

Published

2022

3. Detection and classification of sunspots via deep convolutional neural network

Author

Chola, Channabasava and Benifa, J V Biabl

Published

2022

4. Investigating the Impact of Preprocessing Techniques and Representation Models on Arabic Text Classification using Machine Learning.

Author

Masadeh, Mahmoud, A., Moustapha, B., Sharada, J., Hanumanthappa, K., Hemachandran, Chola, Channabasava, and Muaad, Abdullah Y.

Published

2024

5. Human Activity Prediction Based on Forecasted IMU Activity Signals by Sequence-to-Sequence Deep Neural Networks.

Author

Jaramillo, Ismael Espinoza, Chola, Channabasava, Jeong, Jin-Gyun, Oh, Ji-Heon, Jung, Hwanseok, Lee, Jin-Hyuk, Lee, Won Hee, and Kim, Tae-Seong

Subjects

*ARTIFICIAL neural networks, *DEEP learning, *HUMAN activity recognition, *INDUSTRIAL safety, *UNITS of measurement

Abstract

Human Activity Recognition (HAR) has gained significant attention due to its broad range of applications, such as healthcare, industrial work safety, activity assistance, and driver monitoring. Most prior HAR systems are based on recorded sensor data (i.e., past information) recognizing human activities. In fact, HAR works based on future sensor data to predict human activities are rare. Human Activity Prediction (HAP) can benefit in multiple applications, such as fall detection or exercise routines, to prevent injuries. This work presents a novel HAP system based on forecasted activity data of Inertial Measurement Units (IMU). Our HAP system consists of a deep learning forecaster of IMU activity signals and a deep learning classifier to recognize future activities. Our deep learning forecaster model is based on a Sequence-to-Sequence structure with attention and positional encoding layers. Then, a pre-trained deep learning Bi-LSTM classifier is used to classify future activities based on the forecasted IMU data. We have tested our HAP system for five daily activities with two tri-axial IMU sensors. The forecasted signals show an average correlation of 91.6% to the actual measured signals of the five activities. The proposed HAP system achieves an average accuracy of 97.96% in predicting future activities. [ABSTRACT FROM AUTHOR]

Published

2023

6. FMDNet: An Efficient System for Face Mask Detection Based on Lightweight Model during COVID-19 Pandemic in Public Areas.

Author

Benifa, J. V. Bibal, Chola, Channabasava, Muaad, Abdullah Y., Hayat, Mohd Ammar Bin, Bin Heyat, Md Belal, Mehrotra, Rajat, Akhtar, Faijan, Hussein, Hany S., Vargas, Debora Libertad Ramírez, Castilla, Ángel Kuc, Díez, Isabel de la Torre, and Khan, Salabat

Subjects

*COVID-19 pandemic, *PUBLIC spaces, *ARTIFICIAL intelligence, *MEDICAL masks, *DEEP learning, *SARS-CoV-2

Abstract

A new artificial intelligence-based approach is proposed by developing a deep learning (DL) model for identifying the people who violate the face mask protocol in public places. To achieve this goal, a private dataset was created, including different face images with and without masks. The proposed model was trained to detect face masks from real-time surveillance videos. The proposed face mask detection (FMDNet) model achieved a promising detection of 99.0% in terms of accuracy for identifying violations (no face mask) in public places. The model presented a better detection capability compared to other recent DL models such as FSA-Net, MobileNet V2, and ResNet by 24.03%, 5.0%, and 24.10%, respectively. Meanwhile, the model is lightweight and had a confidence score of 99.0% in a resource-constrained environment. The model can perform the detection task in real-time environments at 41.72 frames per second (FPS). Thus, the developed model can be applicable and useful for governments to maintain the rules of the SOP protocol. [ABSTRACT FROM AUTHOR]

Published

2023

7. A Hybrid Stacked Restricted Boltzmann Machine with Sobel Directional Patterns for Melanoma Prediction in Colored Skin Images.

Author

Alphonse, A. Sherly, Benifa, J. V. Bibal, Muaad, Abdullah Y., Chola, Channabasava, Heyat, Md Belal Bin, Murshed, Belal Abdullah Hezam, Abdel Samee, Nagwan, Alabdulhafith, Maali, and Al-antari, Mugahed A.

Subjects

BOLTZMANN machine, SKIN imaging, MELANOMA, IMAGE analysis, IMAGE processing

Abstract

Melanoma, a kind of skin cancer that is very risky, is distinguished by uncontrolled cell multiplication. Melanoma detection is of the utmost significance in clinical practice because of the atypical border structure and the numerous types of tissue it can involve. The identification of melanoma is still a challenging process for color images, despite the fact that numerous approaches have been proposed in the research that has been done. In this research, we present a comprehensive system for the efficient and precise classification of skin lesions. The framework includes preprocessing, segmentation, feature extraction, and classification modules. Preprocessing with DullRazor eliminates skin-imaging hair artifacts. Next, Fully Connected Neural Network (FCNN) semantic segmentation extracts precise and obvious Regions of Interest (ROIs). We then extract relevant skin image features from ROIs using an enhanced Sobel Directional Pattern (SDP). For skin image analysis, Sobel Directional Pattern outperforms ABCD. Finally, a stacked Restricted Boltzmann Machine (RBM) classifies skin ROIs. Stacked RBMs accurately classify skin melanoma. The experiments have been conducted on five datasets: Pedro Hispano Hospital (PH2), International Skin Imaging Collaboration (ISIC 2016), ISIC 2017, Dermnet, and DermIS, and achieved an accuracy of 99.8%, 96.5%, 95.5%, 87.9%, and 97.6%, respectively. The results show that a stack of Restricted Boltzmann Machines is superior for categorizing skin cancer types using the proposed innovative SDP. [ABSTRACT FROM AUTHOR]

Published

2023

8. Performance Analysis of Deep Learning Algorithms in Diagnosis of Malaria Disease.

Author

Hemachandran, K., Alasiry, Areej, Marzougui, Mehrez, Ganie, Shahid Mohammad, Pise, Anil Audumbar, Alouane, M. Turki-Hadj, and Chola, Channabasava

Subjects

MACHINE learning, DEEP learning, DIAGNOSIS, ARTIFICIAL neural networks, ERYTHROCYTES

Abstract

Malaria is predominant in many subtropical nations with little health-monitoring infrastructure. To forecast malaria and condense the disease's impact on the population, time series prediction models are necessary. The conventional technique of detecting malaria disease is for certified technicians to examine blood smears visually for parasite-infected RBC (red blood cells) underneath a microscope. This procedure is ineffective, and the diagnosis depends on the individual performing the test and his/her experience. Automatic image identification systems based on machine learning have previously been used to diagnose malaria blood smears. However, so far, the practical performance has been insufficient. In this paper, we have made a performance analysis of deep learning algorithms in the diagnosis of malaria disease. We have used Neural Network models like CNN, MobileNetV2, and ResNet50 to perform this analysis. The dataset was extracted from the National Institutes of Health (NIH) website and consisted of 27,558 photos, including 13,780 parasitized cell images and 13,778 uninfected cell images. In conclusion, the MobileNetV2 model outperformed by achieving an accuracy rate of 97.06% for better disease detection. Also, other metrics like training and testing loss, precision, recall, fi-score, and ROC curve were calculated to validate the considered models. [ABSTRACT FROM AUTHOR]

Published

2023

9. Arabic Document Classification: Performance Investigation of Preprocessing and Representation Techniques.

Author

Muaad, Abdullah Y., Davanagere, Hanumanthappa Jayappa, Guru, D.S., Benifa, J.V. Bibal, Chola, Channabasava, AlSalman, Hussain, Gumaei, Abdu H., and Al-antari, Mugahed A.

Subjects

FEATURE selection, NATURAL language processing, NAIVE Bayes classification, ARTIFICIAL intelligence, CLASSIFICATION algorithms, FEATURE extraction

Abstract

With the increasing number of online social posts, review comments, and digital documentations, the Arabic text classification (ATC) task has been hugely required for many spontaneous natural language processing (NLP) applications, especially within the coronavirus pandemics. The variations in the meaning of the same Arabic words could directly affect the performance of any AI-based framework. This work aims to identify the effectiveness of machine learning (ML) algorithms through preprocessing and representation techniques. This effectiveness is measured via different AI-based classification techniques. Basically, the ATC process is influenced by several factors such as stemming in preprocessing, method of feature extraction and selection, nature of datasets, and classification algorithm. To improve the overall classification performance, preprocessing techniques are mainly used to convert each Arabic word into its root and decrease the representation dimension among the datasets. Feature extraction and selection always play crucial roles to represent the Arabic text in a meaningful way and improve the classification accuracy rate. The selected classifiers in this study are performed based on various feature selection algorithms. The overall classification evaluation results are compared using different classifiers such as multinomial Naive Bayes (MNB), Bernoulli Naive Bayes (BNB), Stochastic Gradient Descent (SGD), Support Vector Classifier (SVC), Logistic Regression (LR), and Linear SVC. All of these AI classifiers are evaluated using five balanced and unbalanced benchmark datasets: BBC Arabic corpus, CNN Arabic corpus, Open-Source Arabic corpus (OSAc), ArCovidVac, and AlKhaleej. The evaluation results show that the classification performance strongly depends on the preprocessing technique, representation methods and classification technique, and the nature of datasets used. For the considered benchmark datasets, the linear SVC has outperformed other classifiers overall when prominent features are selected. [ABSTRACT FROM AUTHOR]

Published

2022

10. Gender Identification and Classification of Drosophila melanogaster Flies Using Machine Learning Techniques.

Author

Chola, Channabasava, Benifa, J. V. Bibal, Guru, D. S., Muaad, Abdullah Y., Hanumanthappa, J., Al-antari, Mugahed A., AlSalman, Hussain, and Gumaei, Abdu H.

Subjects

*MACHINE learning, *FLYING machines, *GENETIC code, *SUPPORT vector machines, *FLIES, *DROSOPHILA melanogaster, *CENTRAL nervous system

Abstract

Drosophila melanogaster is an important genetic model organism used extensively in medical and biological studies. About 61% of known human genes have a recognizable match with the genetic code of Drosophila flies, and 50% of fly protein sequences have mammalian analogues. Recently, several investigations have been conducted in Drosophila to study the functions of specific genes exist in the central nervous system, heart, liver, and kidney. The outcomes of the research in Drosophila are also used as a unique tool to study human-related diseases. This article presents a novel automated system to classify the gender of Drosophila flies obtained through microscopic images (ventral view). The proposed system takes an image as input and converts it into grayscale illustration to extract the texture features from the image. Then, machine learning (ML) classifiers such as support vector machines (SVM), Naive Bayes (NB), and K -nearest neighbour (KNN) are used to classify the Drosophila as male or female. The proposed model is evaluated using the real microscopic image dataset, and the results show that the accuracy of the KNN is 90%, which is higher than the accuracy of the SVM classifier. [ABSTRACT FROM AUTHOR]

Published

2022

11. BCNet: A Deep Learning Computer-Aided Diagnosis Framework for Human Peripheral Blood Cell Identification.

Author

Chola C, Muaad AY, Bin Heyat MB, Benifa JVB, Naji WR, Hemachandran K, Mahmoud NF, Samee NA, Al-Antari MA, Kadah YM, and Kim TS

Abstract

Blood cells carry important information that can be used to represent a person's current state of health. The identification of different types of blood cells in a timely and precise manner is essential to cutting the infection risks that people face on a daily basis. The BCNet is an artificial intelligence (AI)-based deep learning (DL) framework that was proposed based on the capability of transfer learning with a convolutional neural network to rapidly and automatically identify the blood cells in an eight-class identification scenario: Basophil, Eosinophil, Erythroblast, Immature Granulocytes, Lymphocyte, Monocyte, Neutrophil, and Platelet. For the purpose of establishing the dependability and viability of BCNet, exhaustive experiments consisting of five-fold cross-validation tests are carried out. Using the transfer learning strategy, we conducted in-depth comprehensive experiments on the proposed BCNet's architecture and test it with three optimizers of ADAM, RMSprop (RMSP), and stochastic gradient descent (SGD). Meanwhile, the performance of the proposed BCNet is directly compared using the same dataset with the state-of-the-art deep learning models of DensNet, ResNet, Inception, and MobileNet. When employing the different optimizers, the BCNet framework demonstrated better classification performance with ADAM and RMSP optimizers. The best evaluation performance was achieved using the RMSP optimizer in terms of 98.51% accuracy and 96.24% F1-score. Compared with the baseline model, the BCNet clearly improved the prediction accuracy performance 1.94%, 3.33%, and 1.65% using the optimizers of ADAM, RMSP, and SGD, respectively. The proposed BCNet model outperformed the AI models of DenseNet, ResNet, Inception, and MobileNet in terms of the testing time of a single blood cell image by 10.98, 4.26, 2.03, and 0.21 msec. In comparison to the most recent deep learning models, the BCNet model could be able to generate encouraging outcomes. It is essential for the advancement of healthcare facilities to have such a recognition rate improving the detection performance of the blood cells.

Published

2022