Your search keyword '"Yan-Yu Lam"' showing total 5 results

1. GA-SVM modeling of multiclass seizure detector in epilepsy analysis system using cloud computing

Author

Jeng-Wei Lin, Andy Yan-Yu Lam, Wei J. Chen, Weizhi Zhou, Chia-Ping Shen, Yi-Hui Kao, Feng-Sheng Lin, Hsiao-Ya Sung, Fang-Yie Leu, Feipei Lai, and Ming-Jang Chiu

Subjects

medicine.diagnostic_test, Computer science, business.industry, 0206 medical engineering, Detector, Computational intelligence, Pattern recognition, 02 engineering and technology, Electroencephalography, medicine.disease, 020601 biomedical engineering, Theoretical Computer Science, Support vector machine, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Parallel processing (DSP implementation), Feature (computer vision), medicine, Geometry and Topology, Artificial intelligence, business, 030217 neurology & neurosurgery, Software

Abstract

In this paper, we present an epilepsy analysis system, referred to as EAS, for long-term electroencephalography (EEG) monitoring of patients with epilepsy. In our previous works, a high accuracy seizure detection algorithm had been devised. Six support vector machines (SVMs) had been trained to collaboratively classify EEG data into four types, i.e., normal, spike, sharp wave, and seizure. The EAS had initially extracted a total of 980 features from raw EEG data of patients, and then, for each SVM, it used a naive genetic algorithm (GA) to determine a feature subset of the 980 features. However, the feature subsets still included some low-impact features for the EEG classification, and the training process of the seizure detector was time consuming. In this study, the GA is enhanced to further exclude low-impact features from the feature subsets and MapReduce parallel processing is adopted to speed up the training process. In the experiment, a 363-h clinical EEG records were acquired from 28 participants, 3 of which were normal, and 25 were patients with epilepsy. The experiment results show that average size of the feature subsets is reduced from 133.5 to 92.5 and the overall classification accuracy increases from 88.8 to 90.1 %. The new seizure detector processes a 10-s EEG record within 0.6 s, meaning that it meets the real-time requirement for online EEG monitoring gracefully. When the number of servers increases from 1 to 15, the training time of the detector is reduced from 38.3 to 4.9 h. Our new approach improves the EAS significantly.

Published

2015

2. Ultra-fast Epileptic seizure detection using EMD based on multichannel electroencephalogram

Author

Yan-Yu Lam, Ming-Jang Chiu, Jeng-Wei Lin, Wei Chen, Hsiao-Ya Sung, Chia-Ping Shen, and Feipei Lai

Subjects

medicine.diagnostic_test, Computer science, business.industry, Speech recognition, Gaussian, Linear model, Pattern recognition, Probability density function, Electroencephalography, medicine.disease, Hilbert–Huang transform, Epilepsy, symbols.namesake, medicine, symbols, Spike (software development), Epileptic seizure, Artificial intelligence, medicine.symptom, business

Abstract

We present a system to detect seizure and spike in Epilepsy Electroencephalogram (EEG) analysis and characterize different epilepsy EEG types. After extracting features from three EEG types, Normal, Seizure and Spike, with Empirical Mode Decomposition (EMD), we do Analysis of variance (ANOVA) to classify conspicuous features and low-resolution features, and build Gaussian distributions of conspicuous features for probability density function (PDF) to do classification. Using EMD, the recognition rate improved from 70% to 90%. With ANOVA, the recognition rate can reach 99%. The linear model accelerates the system from 2 hours to 90 seconds compare to the previous approach.

Published

2013

3. A high performance cloud computing platform for mRNA analysis

Author

Feipei Lai, Chia-Ping Shen, Yan-Yu Lam, Feng-Seng Lin, Jeng-Wei Lin, and Hsiao-Ya Sung

Subjects

Speedup, Time Factors, business.industry, Computer science, Cancer, Computational Biology, Cloud computing, Models, Theoretical, computer.software_genre, Machine learning, medicine.disease, Multiclass classification, Support vector machine, ComputingMethodologies_PATTERNRECOGNITION, Benchmark (computing), medicine, Humans, The Internet, Data mining, Artificial intelligence, RNA, Messenger, User interface, business, computer, Algorithms

Abstract

Multiclass classification is an important technique to many complex bioinformatics problems. However, their performance is limited by the computation power. Based on the Apache Hadoop design framework, this study proposes a two layer architecture that exploits the inherent parallelism of GA-SVM classification to speed up the work. The performance evaluations on an mRNA benchmark cancer dataset have reduced 86.55% features and raised accuracy from 97.53% to 98.03%. With a user-friendly web interface, the system provides researchers an easy way to investigate the unrevealed secrets in the fast-growing repository of bioinformatics data.

Published

2013

4. Epilepsy analytic system with cloud computing

Author

Feipei Lai, Wei Chen, Chia-Ping Shen, Weizhi Zhou, Ming-Jang Chiu, Jeng-Wei Lin, Feng-Seng Lin, Yan-Yu Lam, Hsiao-Ya Sung, and Ming-Kai Pan

Subjects

Decision support system, Support Vector Machine, Computer science, computer.internet_protocol, Big data, Wavelet Analysis, Cloud computing, Machine learning, computer.software_genre, User-Computer Interface, Humans, Internet, Epilepsy, business.industry, Electroencephalography, Signal Processing, Computer-Assisted, Service-oriented architecture, Term (time), Support vector machine, ComputingMethodologies_PATTERNRECOGNITION, The Internet, Artificial intelligence, Data mining, Web service, business, computer, Algorithms

Abstract

Biomedical data analytic system has played an important role in doing the clinical diagnosis for several decades. Today, it is an emerging research area of analyzing these big data to make decision support for physicians. This paper presents a parallelized web-based tool with cloud computing service architecture to analyze the epilepsy. There are many modern analytic functions which are wavelet transform, genetic algorithm (GA), and support vector machine (SVM) cascaded in the system. To demonstrate the effectiveness of the system, it has been verified by two kinds of electroencephalography (EEG) data, which are short term EEG and long term EEG. The results reveal that our approach achieves the total classification accuracy higher than 90%. In addition, the entire training time accelerate about 4.66 times and prediction time is also meet requirements in real time.

Published

2013

5. A physiology-based seizure detection system for multichannel EEG

Author

Chia-Ping Shen, Shih-Ting Liu, Wei-Zhi Zhou, Feng-Seng Lin, Andy Yan-Yu Lam, Hsiao-Ya Sung, Wei Chen, Jeng-Wei Lin, Ming-Jang Chiu, Ming-Kai Pan, Jui-Hung Kao, Jin-Ming Wu, and Feipei Lai

Subjects

Adult, Male, medicine.medical_specialty, Support Vector Machine, lcsh:Medicine, Neurological disorder, Biology, Electroencephalography, Audiology, EEG-fMRI, Models, Biological, Computer Applications, Epilepsy, Young Adult, Software Design, Diagnostic Medicine, Seizures, otorhinolaryngologic diseases, medicine, Humans, lcsh:Science, Aged, Clinical Neurophysiology, Aged, 80 and over, Multidisciplinary, medicine.diagnostic_test, Applied Mathematics, lcsh:R, Software Engineering, Middle Aged, medicine.disease, Seizure detection, Neurology, ROC Curve, Computer Science, Computer-Aided Design, Medicine, Female, lcsh:Q, Multichannel eeg, Algorithms, Mathematics, Research Article

Abstract

BACKGROUND: Epilepsy is a common chronic neurological disorder characterized by recurrent unprovoked seizures. Electroencephalogram (EEG) signals play a critical role in the diagnosis of epilepsy. Multichannel EEGs contain more information than do single-channel EEGs. Automatic detection algorithms for spikes or seizures have traditionally been implemented on single-channel EEG, and algorithms for multichannel EEG are unavailable. METHODOLOGY: This study proposes a physiology-based detection system for epileptic seizures that uses multichannel EEG signals. The proposed technique was tested on two EEG data sets acquired from 18 patients. Both unipolar and bipolar EEG signals were analyzed. We employed sample entropy (SampEn), statistical values, and concepts used in clinical neurophysiology (e.g., phase reversals and potential fields of a bipolar EEG) to extract the features. We further tested the performance of a genetic algorithm cascaded with a support vector machine and post-classification spike matching. PRINCIPAL FINDINGS: We obtained 86.69% spike detection and 99.77% seizure detection for Data Set I. The detection system was further validated using the model trained by Data Set I on Data Set II. The system again showed high performance, with 91.18% detection of spikes and 99.22% seizure detection. CONCLUSION: We report a de novo EEG classification system for seizure and spike detection on multichannel EEG that includes physiology-based knowledge to enhance the performance of this type of system.

Published

2013