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Support Vector Machines

Support Vector Machines. Notation. Assume a binary classification problem. Instances are represented by vector x   n . Training examples: x = ( x 1 , x 2 , …, x m ) S = {( x 1 , y 1 ), ( x 2 , y 2 ), ..., ( x m , y m ) | ( x i , y i )  n {+1, -1 }}

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Support Vector Machines

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  1. Support Vector Machines

  2. Notation • Assume a binary classification problem. • Instances are represented by vector xn. • Training examples: x = (x1,x2, …,xm) S = {(x1, y1), (x2, y2), ..., (xm, ym) | (xi, yi) n{+1, -1}} • Hypothesis: A functionh: n{+1, -1}. h(x) = h(x1,x2, …,xn) {+1, -1}

  3. Here, assume positive and negative instances are to be separated by the hyperplane Equation of line: x2 x1

  4. Intuition: the best hyperplane (for future generalization) will “maximally” separate the examples.

  5. Definition of Margin

  6. Definition of Margin Vapnik (1979) showed that the hyperplane maximizing the margin of S will have minimal VC dimension in the set of all consistent hyperplanes, and will thus be optimal.

  7. Definition of Margin Vapnik (1979) showed that the hyperplane maximizing the margin of S will have minimal VC dimension in the set of all consistent hyperplanes, and will thus be optimal. This is an optimization problem!

  8. Note that the hyperplane is defined as • To make the optimization easier, we will impose the following constraints:

  9. Geometry of the Margin (www.svms.org/tutorials/Hearst-etal1998.pdf) -

  10. In this case, the margin is • So to maximize the margin, we need to minimize .

  11. Minimizing ||w|| Find w and b by doing the following minimization: This is a quadratic optimization problem. Use “standard optimization tools” to solve it.

  12. Dual formulation: It turns out that w can be expressed as a linear combination of a small subset of the training examples xi: those that lie exactly on margin (minimum distance to hyperplane): where αi≥ 0 and where the examples xi for which αi> 0 are those that lie exactly on the margin. • These training examples are called “support vectors”. They carry all relevant information about the classification problem.

  13. The results of the SVM training algorithm (involving solving a quadratic programming problem) are the i and the bias b. • The support vectors are all xi such that i > 0.

  14. For a new example x, We can now classify x using the support vectors: • This is the resulting SVM classifier.

  15. In-class exercise

  16. SVM review • Equation of line: w1x1 + w2x2 + b = 0 • Define margin using: • Margin distance: • To maximize the margin, we minimize ||w|| • subject to the constraint that positive examples • fall on one side of the margin, and negative • examples on the other side: • We can relax this constraint using “slack variables”

  17. SVM review • To do the optimization, we use the dual formulation: • The results of the optimization “black box” are • and b, where i≥ 0. • The support vectors are all xisuch that i> 0.

  18. SVM review • Once the optimization is done, we can classify a new • example x as follows: • That is, classification is done entirely through a linear • combination of dot products with training examples. • This is a “kernel” method.

  19. Example 2 1 1 2 -2 -1 -1 -2

  20. Example Input to SVM optimzer: x1 x2 class 1 1 1 1 2 1 2 1 1 -1 0 -1 0 -1 -1 -1 -1 -1 2 1 1 2 -2 -1 -1 -2

  21. Example Input to SVM optimzer: x1 x2 class 1 1 1 1 2 1 2 1 1 -1 0 -1 0 -1 -1 -1 -1 -1 Output from SVM optimzer: Support vectoryα (-1, 0) -.208 (1, 1) .416 (0, -1) -.208 b = -.376 2 1 1 2 -2 -1 -1 -2

  22. Example Input to SVM optimzer: x1 x2 class 1 1 1 1 2 1 2 1 1 -1 0 -1 0 -1 -1 -1 -1 -1 Output from SVM optimzer: Support vectoryα (-1, 0) -.208 (1, 1) .416 (0, -1) -.208 b = -.376 2 1 1 2 -2 -1 Weight vector: -1 -2

  23. Example Input to SVM optimzer: x1 x2 class 1 1 1 1 2 1 2 1 1 -1 0 -1 0 -1 -1 -1 -1 -1 Output from SVM optimzer: Support vectoryα (-1, 0) -.208 (1, 1) .416 (0, -1) -.208 b = -.376 2 1 1 2 -2 -1 Weight vector: -1 -2 Separation line:

  24. Example 2 1 1 2 -2 -1 -1 Classifying a new point: -2

  25. Non-linearly separable training examples • What if the training examples are not linearly separable?

  26. Non-linearly separable training examples • What if the training examples are not linearly separable? • Use old trick: find a function that maps points to a higher dimensional space (“feature space”) in which they are linearly separable, and do the classification in that higher-dimensional space.

  27. x2 Need to find a function  that will perform such a mapping: : n F Then can find hyperplane in higher dimensional feature space F, and do classification using that hyperplane in higher dimensional space. x2 x1 x1 x3

  28. Example Find a 3-dimensional feature space in which XOR is linearly separable. x2 x2 (0, 1) (1, 1) (1, 0) x1 x3 (0, 0) x1

  29. Problem: • Recall that classification of instance x is expressed in terms of dot products of x and support vectors. • The quadratic programming problem of finding the support vectors and coefficients also depends only on dot products between training examples, rather than on the training examples outside of dot products.

  30. So if each xi is replaced by (xi) in these procedures, we will have to calculate (xi) for each i as well as calculate a lot of dot products, (xi)(xj) • But in general, if the feature space F is high dimensional, (xi) (xj) will be expensive to compute.

  31. Second trick: • Suppose that there were some magic function, k(xi, xj) = (xi) (xj) such that k is cheap to compute even though (xi) (xj) is expensive to compute. • Then we wouldn’t need to compute the dot product directly; we’d just need to compute k during both the training and testing phases. • The good news is: such k functions exist! They are called “kernel functions”, and come from the theory of integral operators.

  32. Example: Polynomial kernel: Suppose x = (x1, x2) andz= (z1,z2).

  33. Example Does the degree-2 polynomial kernel make XOR linearly separable? (0, 1) (1, 1) x2 (1, 0) (0, 0) x1

  34. Recap of SVM algorithm Given training set S = {(x1, y1), (x2, y2), ..., (xm, ym) | (xi, yi)n{+1, -1} • Choose a map : nF, which maps xi to a higher dimensional feature space. (Solves problem that X might not be linearly separable in original space.) • Choose a cheap-to-compute kernel function k(x,z)=(x) (z) (Solves problem that in high dimensional spaces, dot products are very expensive to compute.)

  35. Apply quadratic programming procedure (using the kernel function k) to find a hyperplane (w,b), such that where the (xi)’s are support vectors, the i’s are coefficients, andbis a bias, such that (w, b) is the hyperplane maximizing the margin of the training set in feature space F.

  36. Wednesday, April 24 • Discussion of Decision Tree Homework • Finish SVM slides • SVM exercises • Jens Burger, Phoneme Recognition with Large Hierarchical ReservoirsDian Chase, Support vector machines combined with feature selection for breast cancer diagnosis • Midterm review

  37. 5. Now, given a new instance, x, find the classification of x by computing

  38. More on Kernels • So far we’ve seen kernels that map instances in nto instances in z where z > n. • One way to create a kernel: Figure out appropriate feature space Φ(x), and find kernel function k which defines inner product on that space. • More practically, we usually don’t know appropriate feature space Φ(x). • What people do in practice is either: • Use one of the “classic” kernels (e.g., polynomial), or • Define their own function that is appropriate for their task, and show that it qualifies as a kernel.

  39. How to define your own kernel • Given training data (x1, x2, ..., xn) • Algorithm for SVM learning uses kernel matrix (also called Gram matrix): • We can choose some function k, and compute the kernel matrix K using the training data. • We just have to guarantee that our kernel defines an inner product on some feature space. • Not as hard as it sounds.

  40. What counts as a kernel? • Mercer’s Theorem: If the kernel matrix K is “symmetric positive definite”, it defines a kernel, that is, it defines an inner product in some feature space. • We don’t even have to know what that feature space is!

  41. Kernel Functions as Similarity Measures • Note that the dot product gives a measure of similarity between two vectors: Xi θ So, often we can interpret a kernel function as measuring similarity between a test vector xand a training vector xi in feature space. In this view, SVM classification of x amounts to a weighted sum of similarities between x and support vectors in feature space. Xj

  42. Structural Kernels • In domains such as natural language processing and bioinformatics, the similarities we want to capture are often structural (e.g., parse trees, formal grammars). • An important area of kernel methods is defining structural kernels that capture this similarity (e.g., sequence alignment kernels, tree kernels, graph kernels, etc.)

  43. From www.cs.pitt.edu/~tomas/cs3750/kernels.ppt: • Design criteria - we want kernels to be • valid – Satisfy Mercer condition of positive semidefiniteness • good – embody the “true similarity” between objects • appropriate – generalize well • efficient– the computation of k(x,x’) is feasible

  44. Example: Watson used tree kernels and SVMs to classify question types for Jeopardy! questions From Moschitti et al., 2011

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