Skip to content

Latest commit

 

History

History
33 lines (28 loc) · 2.7 KB

README.md

File metadata and controls

33 lines (28 loc) · 2.7 KB

Machine Learning Specialization on Coursea

Instructor: Andrew Ng

Current status of the repo:

✅ Week 1
✅ Week 2 + Exercise session 1
✅ Week 3 + Exercise session 2
✅ Week 4 + Exercise session 3
✅ Week 5 + Exercise session 4
✅ Week 6 + Exercise session 5
✅ Week 7 + Exercise session 6
✅ Week 8 + Exercise session 7
✅ Week 9 + Exercise session 8
✅ Week 10
✅ Week 11

Introduction

This repository tracks all my work for this specialisation course. This includes my answers to the programming exercises, some notes and thoughts about the exercises. All exercises are solved in Octave; an open-source implementation of MatLab.

Course Introduction

The course summary as stated on the course website is given below.

Machine learning is the science of getting computers to act without being explicitly programmed. In the past decade, machine learning has given us self-driving cars, practical speech recognition, effective web search, and a vastly improved understanding of the human genome. Machine learning is so pervasive today that you probably use it dozens of times a day without knowing it. Many researchers also think it is the best way to make progress towards human-level AI. In this class, you will learn about the most effective machine learning techniques, and gain practice implementing them and getting them to work for yourself. More importantly, you'll learn about not only the theoretical underpinnings of learning, but also gain the practical know-how needed to quickly and powerfully apply these techniques to new problems. Finally, you'll learn about some of Silicon Valley's best practices in innovation as it pertains to machine learning and AI.

This course provides a broad introduction to machine learning, datamining, and statistical pattern recognition. Topics include: (i) Supervised learning (parametric/non-parametric algorithms, support vector machines, kernels, neural networks). (ii) Unsupervised learning (clustering, dimensionality reduction, recommender systems, deep learning). (iii) Best practices in machine learning (bias/variance theory; innovation process in machine learning and AI). The course will also draw from numerous case studies and applications, so that you'll also learn how to apply learning algorithms to building smart robots (perception, control), text understanding (web search, anti-spam), computer vision, medical informatics, audio, database mining, and other areas.