Difference between revisions of "Machine Learning"

Types of Machine Learning

• Supervised Learning
  • Regression Problem: Continuous valued output.
  • Classification Problem: Discrete valued output.
• Unsupervised Learning
  • Clustering

Linear Regression

Terminologies

• $x^{(i)}_j$ feature vectors
• $y^{(i)}$ outcomes
• $h_\theta(x)$ the hypothesis
• $J(\theta)$ the cost function
• $\alpha$ the learning rate

Advanced Optimization Algorithms

There are advanced algorithms (from numerical computing) to minimize the cost function other than the gradient descent. For all of the following algorithms all we need to supply to the algorithm is a code to compute the function $J(\theta)$ (the cost function) and the partial derivatives of the cost function $\frac{\partial}{\partial \theta_i} J(\theta)$.

1. Conjugate gradient
2. BFGS
3. L-BFGS

Advantages

• No need to manually pick $\alpha$ (the learning rate in gradient descent)
• Often faster than gradient descent

Disadvantages

• More complex

Classification Problem

Logistic Regression

• $h_\theta(x) = 1 / (1 + e^{-\theta^T x})$. Note $f(z) = 1 / (1 + e^{-z})$ is called the sigmoid function / logistic function.
• $J(\theta) = - y \cdot \log h_\theta(x) - (1 - y) \cdot \log (1-h_\theta(x))$. This comes from Maximum Likelihood Estimation in Statistics.

Multi-class Classification

• One-vs-all (one-vs-rest): For $n$-class classification, train a logistic regression classifier $h_\theta^{(i)} (x)$ for each class $i = 1, \ldots, n$ to predict the probability that $y = i$. To make a prediction on a new input $x$, pick the class $i$ that maximizes $h_\theta^{(i)} (x)$.

Cocktail Party Problem

• Algorithm
  • [W, s, v] = svd((repmat(sum(x.*x, 1), size(x, 1), 1).*x)*x');

Overfitting

Terminologies

• "underfitting" or "high bias": not fitting the training set well
• "overfitting" or "high variance": too many features, fails to generalize to new examples

Regularization

• Modify the cost function to penalize large parameters. $J(\theta) = \frac{1}{2m} \big[ \sum_{i = 1}^m (h_\theta(x^{(i)}) - y^{(i)})^2 + \lambda \sum_{j = 1}^n \theta_j^2 \big]$. $\lambda$ is the regularization parameter. Note that the index $j$ starts from $1$ which means we don't penalize the constant term (by convention).

Regularized Linear Regression

Gradient Descent

For a learning rate $\alpha > 0$ and a regularization parameter $\lambda > 0$,

• $\theta_0 := \theta_0 - \alpha \frac{1}{m} \sum_{i = 1}^m (h_\theta(x^{(i)}) - y^{(i)}) x_0^{(i)}$
• $\theta_j := \theta_j(1 - \alpha \frac{\lambda}{m}) - \alpha \frac{1}{m} \sum_{i = 1}^m (h_\theta(x^{(i)}) - y^{(i)}) x_j^{(i)}$ for $j > 0$

Normal Equation

• Normal equation: $\theta = (X^T X)^{-1} X^T y$
• Normal equation with regularization: $\theta = (X^T X + \lambda K )X^T y$, where $K$ is a diagonal matrix whose first diagonal entry is $0$ and the rest of the diagonal is $1$.

Regularized Logistic Regression