Lectures
- 1. Overview
- 2. Linear Regression, Gradient Descent, Normal Equations
- 3. Locally Weighted Regression, Linear Regression, Logistic Regression
- 4. Newton's Method, Exponential Family, General Linear Models
- 5. Generative Algorithms, Gaussian Discriminant Analysis
- 6. Applications of Neural Network, Support Vector Machine
- 7. Optimal Margin Classifier, Karush-Kuhn-Tucker (KKT) Conditions, SVM Dual
- 8. Non-linear Decision Boundaries and Soft Margin SVM
- 9. Bias-variance Tradeoff, Empirical Risk Minimization, The Union Bound, Hoeffding Inequality
- 10. Uniform Convergence, VC Dimension, Model Selection
- 11. Bayesian Statistics and Regularization, Applying Machine Learning Algorithms
- 12. Unsupervised Learning, Mixtures of Gaussians and the EM Algorithm, Jensen's Inequality
- 13. Mixture of Gaussian, Mixture of Naive Bayes, Factor Analysis Model
- 14. Factor Analysis Model, EM for Factor Analysis, Principal Component Analysis
- 15. Independent Component Analysis (ICA)
- 16. Reinforcement Learning, Markov Decision Process, Value Function
- 17. Continuous States, Discretization & Curse of Dimensionality
- 18. State-action Rewards, Finite Horizon MDPs, Dynamical Systems
- 19. Debugging Reinforcement Learning (RL) Algorithm, Linear Quadratic Regularization (LQR),
- 20. Partially Observable MDPs, Reinforce Algorithm, Pegasus Algorithm
Machine Learning - Lecture 8
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Lecture 8 - Non-linear Decision Boundaries and Soft Margin SVM
Kernels, Mercer's Theorem, Non-linear Decision Boundaries and Soft Margin SVM, Coordinate Ascent Algorithm, The Sequential Minimization Optimization (SMO) Algorithm, Applications of SVM
Prof. Andrew Ng
CS229 Machine Learning (Stanford University: Stanford Engineering Everywhere) http://see.stanford.edu Date accessed: 2009-05-07 License: Creative Commons Attribution 3.0 |
