Your search keyword '"Rajalakshmi S"' showing total 7 results

1. Safety Device for Children Using IoT and Deep Learning Techniques

Author

Rajalakshmi, S., Angel Deborah, S., Soundarya, G., Varshitha, V., Shyam Sundhar, K., Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Suresh, P., editor, Saravanakumar, U., editor, and Hussein Al Salameh, Mohammed Saleh, editor

Published

2021

2. Eye Disease Detection in Retinal Images using Deep Transfer Learning Techniques.

Author

RAJALAKSHMI S., JASSEM M., MEER, AMAAN, and S., ANGEL DEBORAH

Subjects

ARTIFICIAL neural networks, MACHINE learning, CONVOLUTIONAL neural networks, IMAGE recognition (Computer vision), NOSOLOGY, DEEP learning

Abstract

Image processing with the help of machine learning algorithms is breaking barriers in various fields of study, especially in the medical field. Deep learning image classification algorithms have made disease detection based on images in an easy manner thus assists the medical professional to taking quick decisions. This paper discusses various deep learning algorithms and transfer learning methods used to classify various eye diseases. Kaggle Eye dataset is used for this purpose. We compared four deep learning algorithms, namely EfficientNetB3, Inception V3, VGG 19 and Convolutional Neural Network models. Various categories of eye diseases, namely Cataract, Diabetic Retinopathy, Glaucoma are considered for classification with normal eye with the help of the scanned images. The strengths and weaknesses of these models are compared based on Precision, Recall, Accuracy and F1 score. In an identical testing environment, EfficientNet B3 outperforms the other algorithms and provides better accuracy for the classification of eye diseases. [ABSTRACT FROM AUTHOR]

Published

2024

3. Optimal Deep Learning-Based Recognition Model for EEG Enabled Brain-Computer Interfaces Using Motor-Imagery.

Author

Rajalakshmi, S., AlMohimeed, Ibrahim, Sikkandar, Mohamed Yacin, and Sabarunisha Begum, S.

Subjects

*ELECTROENCEPHALOGRAPHY, *BRAIN-computer interfaces, *DEEP learning, *MOTOR imagery (Cognition), *DISCRIMINATION against overweight persons, *FEATURE extraction

Abstract

Brain-Computer Interfaces (BCIs) facilitate the translation of brain activity into actionable commands and act as a crucial link between the human brain and the external environment. Electroencephalography (EEG)-based BCIs, which focus on motor imagery, have emerged as an important area of study in this domain. They are used in neurorehabilitation, neuroprosthetics, and gaming, among other applications. Optimal Deep Learning-Based Recognition for EEG Signal Motor Imagery (ODLR-EEGSM) is a novel approach presented in this article that aims to improve the recognition of motor imagery from EEG signals. The proposed method includes several crucial stages to improve the precision and effectiveness of EEG-based motor imagery recognition. The pre-processing phase starts with the Variation Mode Decomposition (VMD) technique, which is used to improve EEG signals. The EEG signals are decomposed into different oscillatory modes by VMD, laying the groundwork for subsequent feature extraction. Feature extraction is a crucial component of the ODLR-EEGSM method. In this study, we use Stacked Sparse Auto Encoder (SSAE) models to identify significant patterns in the pre-processed EEG data. Our approach is based on the classification model using Deep Wavelet Neural Network (DWNN) optimized with Chaotic Dragonfly Algorithm (CDFA). CDFA optimizes the weight and bias values of the DWNN, significantly improving the classification accuracy of motor imagery. To evaluate the efficacy of the ODLR-EEGSM method, we use benchmark datasets to perform rigorous performance validation. The results show that our approach outperforms current methods in the classification of EEG motor imagery, confirming its promising performance. This study has the potential to make brain-computer interface applications in various fields more accurate and efficient, and pave the way for brain-controlled interactions with external systems and devices. [ABSTRACT FROM AUTHOR]

Published

2023

4. Exploiting drone images for forest fire detection using metaheuristics with deep learning model.

Author

Rajalakshmi, S., Sellam, V., Kannan, N., and Saranya, S.

Abstract

Forest fires are a global natural calamity causing significant economic damage and loss of lives. Professionals forecast that forest fires would raise in the future because of climate change. Early prediction and identification of fire spread would enhance firefighting and reduce affected zones. Several systems have been advanced to detect fire. Recently, Unmanned Aerial Vehicles (UAVs) can be used for forest fire detection due to their ability, high flexibility, and inexpensive to cover vast areas. But still, they are limited by difficulties like image degradation, small fire size, and background complexity. This study develops an automated Forest Fire Detection using Metaheuristics with Deep Learning (FFDMDL-DI) model. The presented FFDMDL-DI technique exploits the DL concepts on drone images to identify the occurrence of fire. To accomplish this, the FFDMDL-DI technique makes use of the Capsule Network (CapNet) model for feature extraction purposes with a biogeography-based optimization (BBO) algorithm-based hyperparameter optimizer. For accurate forest fire detection, the FFDMDL-DI technique uses a unified deep neural network (DNN) model. Finally, the tree growth optimization (TGO) technique is utilized for the parameter adjustment of the DNN method. To depict the enhanced detection efficiency of the FFDMDL-DI approach, a series of simulations were performed on the FLAME dataset, comprising 6000 samples. The experimental results stated the improvements in the FFDMDL-DI method over other DL models with maximum accuracy of 99.76%. [ABSTRACT FROM AUTHOR]

Published

2023

5. Hyperspectral Remote Sensing Image Classification Using Improved Metaheuristic with Deep Learning.

Author

Rajalakshmi, S., Nalini, S., Alkhayyat, Ahmed, and Malik, Rami Q.

Subjects

REMOTE sensing, REMOTE-sensing images, GEOPHYSICAL prospecting, EARTH (Planet), CONVOLUTIONAL neural networks, ARTIFICIAL neural networks

Abstract

Remote sensing image (RSI) classifier roles a vital play in earth observation technology utilizing Remote sensing (RS) data are extremely exploited from both military and civil fields. More recently, as novel DL approaches develop, techniques for RSI classifiers with DL have attained important breakthroughs, providing a new opportunity for the research and development of RSI classifiers. This study introduces an Improved Slime Mould Optimization with a graph convolutional network for the hyperspectral remote sensing image classification (ISMOGCN-HRSC) model. The ISMOGCN-HRSC model majorly concentrates on identifying and classifying distinct kinds of RSIs. In the presented ISMOGCN-HRSC model, the synergic deep learning (SDL) model is exploited to produce feature vectors. The GCN model is utilized for image classification purposes to identify the proper class labels of the RSIs. The ISMO algorithm is used to enhance the classification efficiency of the GCN method, which is derived by integrating chaotic concepts into the SMO algorithm. The experimental assessment of the ISMOGCN-HRSC method is tested using a benchmark dataset. [ABSTRACT FROM AUTHOR]

Published

2023

6. New controlled and unmonitored learning methods pulmonary and cancer progression characterisation.

Author

Deepa, S., Bhagyalakshmi, A., Rajalakshmi, S., and Ishwarya, M. V.

Subjects

DEEP learning, CANCER invasiveness, MACHINE learning, SUPERVISED learning, TUMOR classification, INDIVIDUALIZED medicine

Abstract

Radiological photographs can be more precise and quicker with machine diagnostic methods at the expense of stratification (characterization). Characterizing the tumor by these instruments may allow for the growth, prediction, and customized treatment planning of non-invasive cancer as a part of precision medicine. In this review, we suggest machine learning methods to enhance tumor identification under supervision and supervision. Our first framework focuses on supervised education, mainly through a 3D spinning neural network and transfer learning, which we achieve substantial gains with deep learning algorithms. Motivated by the observations of pathologists on the tests, we then can explain how a graphical, sparse, and multi-tasking learning experience integrates task-based function representations in the CAD system. In the second approach, we investigate the limited availability of classified training data, an unregulated learning algorithm that is a common problem in medical imagery applications. We propose to use proportion-SVM to classify tumors, motivated by learning about mark proportion approaches in machine view. The fundamental question of the goodness of "deep traits" for unmonitored tumor classification is also tried. To achieve state-of-the-art sensitivity and accuracy outcomes in both issues, we test our proposed supervised and unsupervised learning algorithms on two separate tump diagnostic challenges: pulmonary and pancreatic with 1018 CT and 171 MRI scans. [ABSTRACT FROM AUTHOR]

Published

2022

7. Identifying malignant nodules on chest X-rays: A validation study of radiologist versus artificial intelligence diagnostic accuracy

Author

Bassam Mahboub, Manoj Tadepalli, Tarun Raj, Rajalakshmi Santhanakrishnan, Mahmood Yaseen Hachim, Usama Bastaki, Rifat Hamoudi, Ehsan Haider, and Abdullah Alabousi

Subjects

artificial intelligence, chest x-rays, convolutional neural network, deep learning, malignant nodules, Medicine

Abstract

Background: Three and half million anonymous X-rays were gathered from 45 locations worldwide (in-hospital and outpatient settings). qXR was initially trained on this massive dataset. We used an independent dataset of 13,426 chest X-rays from radiologists’ reports. The test data set included 213,459 X-rays chosen at random from a pool of 3.5 million X-rays. The dataset (development) was developed using the remaining X-rays received from the remaining patients. Methods: qXR is a deep learning algorithm-enabled software that is used to study nodules and malignant nodules on X-rays. We observed moderate to a substantial agreement even when observations were made with normal X-rays. Results: qXR presented a high area under the curve (AUC) of 0.99 with a 95% confidence interval calculated with the Clopper–Pearson method. The specificity obtained with qXR was 0.90, and the sensitivity was 1 at the operating threshold. The sensitivity value of qXR in detecting nodules was 0.99, and the specificity ranged from 0.87 to 0.92, with AUC ranging between 0.98 and 0.99. The malignant nodules were detected with a sensitivity ranging from 0.95 to 1.00, specificity between 0.96 and 0.99, and AUC from 0.99 to 1. The sensitivity of radiologists 1 and 2 was between 0.74 and 0.76, with a specificity ranging from 0.98 to 0.99. In detecting the malignant nodules, specificity ranged between 0.98 and 0.99, and sensitivity fell between 0.88 and 0.94. Conclusion: Machine learning model can be used as a passive tool to find incidental cases of lung cancer or as a triaging tool, which accelerate the patient journey through standard care pipeline for lung cancer.

Published

2022