Computational Prediction of Transposon Insertion Sites

Ayat, Maryam

04 April 2013

Transposons are DNA segments that can move or transpose themselves to new positions within the genome of an organism. Biologists need to predict preferred insertion sites of transposons to devise strategies in functional genomics and gene therapy studies. It has been found that the deformability property of the local DNA structure of the integration sites, called Vstep, is of significant importance in the target-site selection process. We considered the Vstep profiles of insertion sites and developed predictors based on Artificial Neural Networks (ANN) and Support Vector Machines (SVM). We trained our ANN and SVM predictors with the Sleeping Beauty transposonal data, and used them for identifying preferred individual insertion sites (each 12bp in length) and regions (each 100bp in length). Running a five-fold cross-validation showed that (1) Both ANN and SVM predictors are more successful in recognizing preferred regions than preferred individual sites; (2) Both ANN and SVM predictors have excellent performance in finding the most preferred regions (more than 90% sensitivity and specificity); and (3) The SVM predictor outperforms the ANN predictor in recognizing preferred individual sites and regions. The SVM has 83% sensitivity and 72% specificity in identifying preferred individual insertion sites, and 85% sensitivity and 90% specificity in recognizing preferred insertion regions.

Artificial Neural Networks

Support Vector Machines

Transposons

Insertion Site Prediction

Land cover classification using linear support vector machines /

Shakeel, Mohammad Danish.

January 2008

Thesis (M.S.)--Youngstown State University, 2008. / Includes bibliographical references (leaves 31-35). Also available via the World Wide Web in PDF format.

A precise robotic arm positioning using an SVM classification algorithm

Terrones, Michael.

January 2007

Thesis (M.S.)--State University of New York at Binghamton, Department of Systems Science and Industrial Engineering, Thomas J. Watson School of Engineering and Applied Science, 2007. / Includes bibliographical references.

An SVM ranking approach to stress assignment

Dou, Qing.

January 2009

Thesis (M.Sc.)--University of Alberta, 2009. / Title from PDF file main screen (viewed on July 30, 2009). "A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Master of Science, Department of Computing Science, University of Alberta." Includes bibliographical references.

Soft margin estimation for automatic speech recognition

Li, Jinyu.

January 2008

Thesis (Ph.D)--Electrical and Computer Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Dr. Chin-Hui Lee; Committee Member: Dr. Anthony Joseph Yezzi; Committee Member: Dr. Biing-Hwang (Fred) Juang; Committee Member: Dr. Mark Clements; Committee Member: Dr. Ming Yuan. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Support vector classification analysis of resting state functional connectivity fMRI

Craddock, Richard Cameron.

January 2009

Thesis (Ph.D)--Electrical and Computer Engineering, Georgia Institute of Technology, 2010. / Committee Chair: Hu, Xiaoping; Committee Co-Chair: Vachtsevanos, George; Committee Member: Butera, Robert; Committee Member: Gurbaxani, Brian; Committee Member: Mayberg, Helen; Committee Member: Yezzi, Anthony. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Protein secondary structure prediction using neural networks and support vector machines /

Tsilo, Lipontseng Cecilia.

January 2008

Thesis (M.Sc. (Statistics)) - Rhodes University, 2009. / A thesis submitted to Rhodes University in partial fulfillment of the requirements for the degree of Master of Science in Mathematical Statistics.

Support vector machines and particle swarm optimization applied to reliability prediction

LINS, Isis Didier

31 January 2009

Made available in DSpace on 2014-06-12T17:43:09Z (GMT). No. of bitstreams: 2 arquivo981_1.pdf: 1519617 bytes, checksum: 1476b8d5238437f951709f3c7a7be61b (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2009 / Conselho Nacional de Desenvolvimento Científico e Tecnológico / Confiabilidade é uma métrica crítica para as organizações, uma vez que ela influencia diretamente seus desempenhos face à concorrência e é essencial para a manutenção da disponibilidade de seus sistemas produtivos. A previsão dessa métrica quantitativa é então de grande interresse, pois ela pode antecipar o conhecimento de falhas do sistema e permitir que as organizações possam evitar ou superar essas situações indesejadas. A confiabilidade de sistemas depende tanto dos efeitos inerentes da idade assim como das condições operacionais a que o sistema é submetido. Isso pode tornar a modelagem da confiabilidade muito complexa de forma que processos estocásticos tradicionais falhem em prever de forma acurada o seu comportamento ao longo do tempo. Nesse contexto, métodos de aprendizado como Support Vector Machines surgem como alternativa para superar essa questão. Uma das principais vantagens de se utilizar SVMs é o fato de não ser necessário supor ou conhecer previamente a função ou o processo que mapeia as variáveis de entrada (input) em saída (output). No entanto, seu desempenho está associado a um conjunto de parâmetros que aparecem no problema de aprendizado. Isso dá origem ao problema de seleção de modelo para SVM, que consiste basicamente em escolher os valores apropriados para esses parâmetros. Nesse trabalho, tal problema é resolvido por meio de Otimização via Nuvens de Partículas (Particle Swarm Optimization - PSO), uma abordagem probabilística que é inspirada no comportamento de organismos biológicos que se movem em grupos. Além disso, é proposta uma metodologia PSO+SVM para resolver problemas de previsão de confiabilidade, que é validada por meio da resolução de exemplos da literatura baseados em dados de séries temporais. As soluções encontradas, comparadas às provenientes de outras ferramentas de previsão como Redes Neurais (Neural Networks - NNs), indicam que a metodologia proposta é capaz de fornecer previsões de confiabilidade competitivas ou até mesmo mais acuradas. Além disso, a metodologia proposta é utilizada para resolver um exemplo de aplicação envolvendo dados de poços de produção de petróleo

Previsão de Confiabilidade

Otimização via Nuvens de Partículas

Support Vector Machines

Machine Learning and Adaptive Signal Processing Methods for Electrocardiography Applications

Perumalla, Calvin A.

22 June 2017

This dissertation is directed towards improving the state of art cardiac monitoring methods and automatic diagnosis of cardiac anomalies through modern engineering approaches such as adaptive signal processing, and machine learning methods. The dissertation will describe the invention and associated methods of a cardiac rhythm monitor dubbed the Integrated Vectorcardiogram (iVCG). In addition, novel machine learning approaches are discussed to improve diagnoses and prediction accuracy of cardiac diseases. It is estimated that around 17 million people in the world die from cardiac related events each year. It has also been shown that many of such deaths can be averted with long-term continuous monitoring and actuation. Hence, there is a growing need for better cardiac monitoring solutions. Leveraging the improvements in computational power, communication bandwidth, energy efficiency and electronic chip size in recent years, the Integrated Vectorcardiogram (iVCG) was invented as an answer to this problem. The iVCG is a miniaturized, integrated version of the Vectorcardiogram that was invented in the 1930s. The Vectorcardiogram provides full diagnostic quality cardiac information equivalent to that of the gold standard, 12-lead ECG, which is restricted to in-office use due to its bulky, obtrusive form. With the iVCG, it is possible to provide continuous, long-term, full diagnostic quality information, while being portable and unobtrusive to the patient. Moreover, it is possible to leverage this ‘Big Data’ and create machine learning algorithms to deliver better patient outcomes in the form of patient specific machine diagnosis and timely alerts. First, we present a proof-of-concept investigation for a miniaturized vectorcardiogram, the iVCG system for ambulatory on-body applications that continuously monitors the electrical activity of the heart in three dimensions. We investigate the minimum distance between a pair of leads in the X, Y and Z axes such that the signals are distinguishable from the noise. The target dimensions for our prototype iVCG are 3x3x2 cm and based on our experimental results we show that it is possible to achieve these dimensions. Following this, we present a solution to the problem of transforming the three VCG component signals to the familiar 12-lead ECG for the convenience of cardiologists. The least squares (LS) method is employed on the VCG signals and the reference (training) 12-lead ECG to obtain a 12x3 transformation matrix to generate the real-time ECG signals from the VCG signals. The iVCG is portable and worn on the chest of the patient and although a physician or trained technician will initially install it in the appropriate position, it is prone to subsequent rotation and displacement errors introduced by the patient placement of the device. We characterize these errors and present a software solution to correct the effect of the errors on the iVCG signals. We also describe the design of machine learning methods to improve automatic diagnosis and prediction of various heart conditions. Methods very similar to the ones described in this dissertation can be used on the long term, full diagnostic quality ‘Big Data’ such that the iVCG will be able to provide further insights into the health of patients. The iVCG system is potentially breakthrough and disruptive technology allowing long term and continuous remote monitoring of patient’s electrical heart activity. The implications are profound and include 1) providing a less expensive device compared to the 12-lead ECG system (the “gold standard”); 2) providing continuous, remote tele-monitoring of patients; 3) the replacement of current Holter shortterm monitoring system; 4) Improved and economic ICU cardiac monitoring; 5) The ability for patients to be sent home earlier from a hospital since physicians will have continuous remote monitoring of the patients.

Neural Networks

Support Vector Machines

VCG

WBANs

IoT

Engineering

A comparison of machine learning techniques for hand shape recognition

Foster, Roland

January 2015

>Magister Scientiae - MSc / There are five fundamental parameters that characterize any sign language gesture. They are hand shape, orientation, motion and location, and facial expressions. The SASL group at the University of the Western Cape has created systems to recognize each of these parameters in an input video stream. Most of these systems make use of the Support Vector Machine technique for the classification of data due to its high accuracy. It is, however, unknown how other machine learning techniques compare to Support Vector Machines in the recognition of each of these parameters. This research lays the foundation for the process of determining optimum machine learning techniques for each parameter by comparing Support Vector Machines to Artificial Neural Networks and Random Forests in the context of South African Sign Language hand shape recognition. Li, a previous researcher at the SASL group, created a state-of-the-art hand shape recognition system that uses Support Vector Machines to classify hand shapes. This research re-implements Li’s feature extraction procedure but investigates the use of Artificial Neural Networks and Random Forests in the place of Support Vector Machines as a comparison. The machine learning techniques are optimized and trained to recognize ten SASL hand shapes and compared in terms of classification accuracy, training time, optimization time and classification time.

Optimization

Artificial neural networks

Hand shape recognition

Support vector machines