Department Events
Machine Learning
The course will enable the students to
- Understand the basic concepts, approaches and techniques in Machine Learning
- Comprehend concept of supervised and unsupervised learning & other advanced learning models.
- Understand modern notions in data analysis oriented computing
- Learn to evaluate machine learning models
- Relate and apply the learned algorithms to a real-world problem, optimize the models learned and report on the expected accuracy that can be achieved by applying the models.
- Develop the basic skills necessary to pursue research in Machine Learning
Course Learning Outcomes (CLOs):
Learning Outcome (at course level) Students will be able to: | Learning and teaching strategies | Assessment Strategies |
| Approach in teaching: Interactive Lectures, Modeling, Discussions, implementing enquiry based learning, student centered approach, Research problem based discussions
Learning activities for the students: Experiential Learning, Presentations, Discussions, Quizzes and Assignments
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Machine Learning – Machine Learning Foundations-Overview – Applications – Types of Machine Learning – Basic Concepts in Machine Learning – Examples of Machine Learning, Perspectives/Issues in Machine Learning, AI vs. Machine Learning, Introduction to Python.
Introduction, Linear Models of Classification – Linear Regression – Logistic Regression – Bayesian Logistic Regression – Probabilistic Models Neural Network-Feed Forward Network Functions – Error Back Propagation – Regularization - Bayesian Neural Networks – Radial Basis Function Networks, Ensemble Methods – Random Forest – Bagging – Boosting. Experiments of Classification using Python.
Clustering – K-Means Clustering – EM (Expectation Maximization) – Mixtures of Gaussians – EM algorithm in General – The Curse of Dimensionality – Dimensionality Reduction – Factor Analysis – Principal Component Analysis – Probabilistic PCA – Independent Component Analysis. Challenges for Big Data Analytics. Experiments of Clustering using Python.
Directed Graphical Models – Bayesian Networks – Exploiting Independence Properties – From Distributions to Graphs – Examples – Markov Random Fields – Inference In Graphical Models – Learning - Naïve Bayes Classifiers – Markov Models – Hidden Markov Models. Undirected graphical Models – Markov Random Fields – Conditional Independence Properties.
Sampling – Basic Sampling Method – Monte Carlo, Reinforcement Learning-Introduction-The Learning Task, Elements of Reinforcement Learning, Difference between Reinforcement Learning and Supervised Learning, Applications of Reinforcement Learning, Model based learning, Semi-Supervised Learning, Computational Learning Theory.
- Christopher Bishop, “Pattern Recognition and Machine Learning”, Springer 2006
- EthemAlpaydin, “Introduction to Machine Learning”, Prentice Hall of India, 2005
- Joel Grus, “Data Science from Scratch- First Principles with Python”, O’Reilly, 2015
- Tom Mitchell, “ Machine Learning”, McGraw-Hill, 1997
- Stephen MarsLand, “Machine Learning-An Algorithmic Perspective”, CRC Press, 2009
- Kevin P. Murphy, “Machine Learning: A Probabilistic Perspective”, MIT Press, 2012
- M. Gopal, “Applied MACHINE LEARNING”, McGraw-Hill, 2018
- Mark Summerfield, “Programming in Python 3: A Complete Introduction to the Python Language”, Addison Wesley, 2010
