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Overfitting, Bias/Variance tradeoff. 2 Content of the presentation Bias and variance definitions Parameters that influence bias and variance Bias and.

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Presentation on theme: "Overfitting, Bias/Variance tradeoff. 2 Content of the presentation Bias and variance definitions Parameters that influence bias and variance Bias and."— Presentation transcript:

1 Overfitting, Bias/Variance tradeoff

2 2 Content of the presentation Bias and variance definitions Parameters that influence bias and variance Bias and variance reduction techniques

3 3 Content of the presentation Bias and variance definitions: –A simple regression problem with no input –Generalization to full regression problems –A short discussion about classification Parameters that influence bias and variance Bias and variance reduction techniques

4 4 Regression problem - no input Goal: predict as well as possible the height of a Belgian male adult More precisely: –Choose an error measure, for example the square error. –Find an estimation ŷ such that the expectation: over the whole population of Belgian male adult is minimized. 180

5 5 Regression problem - no input The estimation that minimizes the error can be computed by taking: So, the estimation which minimizes the error is E y {y}. It is called the Bayes model. But in practice, we cannot compute the exact value of E y {y} (this would imply to measure the height of every Belgian male adults).

6 6 Learning algorithm As p(y) is unknown, find an estimation y from a sample of individuals, LS={y 1,y 2,…,y N }, drawn from the Belgian male adult population. Example of learning algorithms: –, – (if we know that the height is close to 180)

7 7 Good learning algorithm As LS are randomly drawn, the prediction ŷ will also be a random variable A good learning algorithm should not be good only on one learning sample but in average over all learning samples (of size N)  we want to minimize: Let us analyse this error in more detail ŷ p LS (ŷ)

8 8 Bias/variance decomposition (1)

9 9 Bias/variance decomposition (2) E= E y {(y- E y {y}) 2 } + E LS {(E y {y}-ŷ) 2 } y var y {y} Ey{y}Ey{y} = residual error = minimal attainable error = var y {y}

10 10 Bias/variance decomposition (3)

11 11 Bias/variance decomposition (4) E= var y {y} + (E y {y}-E LS {ŷ}) 2 + … E LS {ŷ} = average model (over all LS) bias 2 = error between Bayes and average model ŷ Ey{y}Ey{y} E LS {ŷ} bias 2

12 12 Bias/variance decomposition (5) E= var y {y} + bias 2 + E LS {(ŷ-E LS {ŷ}) 2 } var LS {ŷ} = estimation variance = consequence of over-fitting ŷ var LS {ŷ} E LS {ŷ}

13 13 Bias/variance decomposition (6) E= var y {y} + bias 2 + var LS {ŷ} ŷ Ey{y}Ey{y}E LS {ŷ} bias 2 var y {y}var LS {ŷ}

14 14 Our simple example – From statistics, ŷ 1 is the best estimate with zero bias – So, the first one may not be the best estimator because of variance (There is a bias/variance tradeoff w.r.t. )

15 15 Regression problem – full (1) Actually, we want to find a function ŷ(x) of several inputs => average over the whole input space: The error becomes: Over all learning sets:

16 16 Regression problem – full (2) E LS {E y|x {(y-ŷ(x))^2}}=Noise(x)+Bias 2 (x)+Variance(x) Noise(x) = E y|x {(y-h B (x)) 2 } Quantifies how much y varies from h B (x) = E y|x {y}, the Bayes model. Bias 2 (x) = (h B (x)-E LS {ŷ(x)}) 2 : Measures the error between the Bayes model and the average model. Variance(x) = E LS {(ŷ(x)-E LS {ŷ(x)) 2 } : Quantify how much ŷ(x) varies from one learning sample to another.

17 17 Illustration (1) Problem definition: –One input x, uniform random variable in [0,1] –y=h(x)+ε where ε  N(0,1) h(x)=E y|x {y} x y

18 18 Illustration (2) Low variance, high bias method  underfitting E LS {ŷ(x)}

19 19 Illustration (3) Low bias, high variance method  overfitting E LS {ŷ(x)}

20 20 Classification problems (1) The mean misclassification error is: The best possible model is the Bayes model: The “average” model is: Unfortunately, there is no such decomposition of the mean misclassification error into a bias and a variance terms. Nevertheless, we observe the same phenomena

21 21 Classification problems (2) A full decision treeOne test node 0 1 01 0 1 01 LS 1 0 1 01 0 1 01 LS 2

22 22 Classification problems (3) Bias  systematic error component (independent of the learning sample) Variance  error due to the variability of the model with respect to the learning sample randomness There are errors due to bias and errors due to variance 0 1 01 One test nodeFull decision tree 0 1 01

23 23 Content of the presentation Bias and variance definitions Parameters that influence bias and variance –Complexity of the model –Complexity of the Bayes model –Noise –Learning sample size –Learning algorithm Bias and variance reduction techniques

24 24 Illustrative problem Artificial problem with 10 inputs, all uniform random variables in [0,1] The true function depends only on 5 inputs: y(x)=10.sin(π.x 1.x 2 )+20.(x 3 -0.5) 2 +10.x 4 +5.x 5 +ε, where ε is a N(0,1) random variable Experimentations: –E LS  average over 50 learning sets of size 500 –E x,y  average over 2000 cases  Estimate variance and bias (+ residual error)

25 25 Complexity of the model Usually, the bias is a decreasing function of the complexity, while variance is an increasing function of the complexity. E=bias 2 +var bias 2 var Complexity

26 26 Complexity of the model – neural networks Error, bias, and variance w.r.t. the number of neurons in the hidden layer

27 27 Complexity of the model – regression trees Error, bias, and variance w.r.t. the number of test nodes

28 28 Complexity of the model – k-NN Error, bias, and variance w.r.t. k, the number of neighbors

29 29 Learning problem Complexity of the Bayes model: –At fixed model complexity, bias increases with the complexity of the Bayes model. However, the effect on variance is difficult to predict. Noise: –Variance increases with noise and bias is mainly unaffected. –E.g. with (full) regression trees

30 30 Learning sample size (1) At fixed model complexity, bias remains constant and variance decreases with the learning sample size. E.g. linear regression

31 31 Learning sample size (2) When the complexity of the model is dependant on the learning sample size, both bias and variance decrease with the learning sample size. E.g. regression trees

32 32 Learning algorithms – linear regression Very few parameters : small variance Goal function is not linear : high bias MethodErr 2 Bias 2 +NoiseVariance Linear regr.7.06.80.2 k-NN (k=1)15.4510.4 k-NN (k=10)8.57.21.3 MLP (10)2.01.20.8 MLP (10 – 10)4.61.43.2 Regr. Tree10.23.56.7

33 33 Learning algorithms – k-NN Small k : high variance and moderate bias High k : smaller variance but higher bias MethodErr 2 Bias 2 +NoiseVariance Linear regr.7.06.80.2 k-NN (k=1)15.4510.4 k-NN (k=10)8.57.21.3 MLP (10)2.01.20.8 MLP (10 – 10)4.61.43.2 Regr. Tree10.23.56.7

34 34 Learning algorithms - MLP Small bias Variance increases with the model complexity MethodErr 2 Bias 2 +NoiseVariance Linear regr.7.06.80.2 k-NN (k=1)15.4510.4 k-NN (k=10)8.57.21.3 MLP (10)2.01.20.8 MLP (10 – 10)4.61.43.2 Regr. Tree10.23.56.7

35 35 Learning algorithms – regression trees Small bias, a (complex enough) tree can approximate any non linear function High variance MethodErr 2 Bias 2 +NoiseVariance Linear regr.7.06.80.2 k-NN (k=1)15.4510.4 k-NN (k=10)8.57.21.3 MLP (10)2.01.20.8 MLP (10 – 10)4.61.43.2 Regr. Tree10.23.56.7

36 36 Content of the presentation Bias and variance definition Parameters that influence bias and variance Decision/regression tree variance Bias and variance reduction techniques –Introduction –Dealing with the bias/variance tradeoff of one algorithm –Ensemble methods

37 37 Bias and variance reduction techniques In the context of a given method: –Adapt the learning algorithm to find the best trade-off between bias and variance. –Not a panacea but the least we can do. –Example: pruning, weight decay. Ensemble methods: –Change the bias/variance trade-off. –Universal but destroys some features of the initial method. –Example: bagging, boosting.

38 38 Variance reduction: 1 model (1) General idea: reduce the ability of the learning algorithm to fit the LS –Pruning reduces the model complexity explicitly –Early stopping reduces the amount of search –Regularization reduce the size of hypothesis space Weight decay with neural networks consists in penalizing high weight values

39 39 Variance reduction: 1 model (2) Selection of the optimal level of fitting –a priori (not optimal) –by cross-validation (less efficient): Bias 2  error on the learning set, E  error on an independent test set E=bias 2 +var bias 2 var Fitting Optimal fitting

40 40 Variance reduction: 1 model (3 ) Examples: –Post-pruning of regression trees –Early stopping of MLP by cross-validation MethodEBiasVariance Full regr. Tree (250)10.23.56.7 Pr. regr. Tree (45)9.14.34.8 Full learned MLP4.61.43.2 Early stopped MLP3.81.52.3 As expected, variance decreases but bias increases

41 41 Ensemble methods Combine the predictions of several models built with a learning algorithm in order to improve with respect to the use of a single model Two important families: –Averaging techniques Grow several models independantly and simply average their predictions Ex: bagging, random forests Decrease mainly variance –Boosting type algorithms Grows several models sequentially Ex: Adaboost, MART Decrease mainly bias

42 42 Conclusion (1) The notions of bias and variance are very useful to predict how changing the (learning and problem) parameters will affect the accuracy. E.g. this explains why very simple methods can work much better than more complex ones on very difficult tasks Variance reduction is a very important topic: –To reduce bias is easy, but to keep variance low is not as easy. –Especially in the context of new applications of machine learning to very complex domains: temporal data, biological data, Bayesian networks learning, text mining… All learning algorithms are not equal in terms of variance. Trees are among the worst methods from this criterion

43 43 Conclusion (2) Ensemble methods are very effective techniques to reduce bias and/or variance. They can transform a not so good method to a competitive method in terms of accuracy.

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