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added hw3 answers
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ISLR Sixth Printing.pdf
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ISLR Sixth Printing.pdf
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hw1/.RData
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hw1/.RData
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hw1/.Rhistory
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hw1/.Rhistory
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hw1/Auto.data
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hw1/Auto.data
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hw1/answers
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hw1/answers
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hw1/assigned
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hw1/assigned
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hw1/auto_pairs.png
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hw1/auto_pairs.png
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hw2/.RData
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hw2/answers
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Part B: Choose one of Questions 10 or 11
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5. We now examine the differences between LDA and QDA.
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(a) If the Bayes decision boundary is linear, do we expect LDA
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or QDA to perform better on the training set? On the test set?
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The QDA has more flexibility, so it will match the training
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set more closely than the LDA. The LDA will perform better
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on the test set because the real relationship is linear, so
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the QDA would have additional bias.
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(b) If the Bayes decision boundary is non-linear, do we expect
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LDA or QDA to perform better on the training set? On the test
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set?
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QDA will still perform better on the training set, but now
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should also perform better than LDA on the test set, since
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QDA will account for the additional degree of freedom in the
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real relationship.
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(c) In general, as the sample size n increases, do we expect the
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test prediction accuracy of QDA relative to LDA to improve,
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decline, or be unchanged? Why?
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Definitely increase. The LDA has an advantage when the
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training set is small because it is less sensitive to the
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fluctuations of those few data. As the size of the training
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set grows, the QDA is able to optimize its coefficients
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well, and assuming the real relationship is not linear, the
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QDA should eventually out-perform the LDA.
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(d) True or False: Even if the Bayes decision boundary for a
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given problem is linear, we will probably achieve a superior
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test error rate using QDA rather than LDA because QDA is
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flexible enough to model a linear decision boundary. Justify
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your answer.
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False. The QDA will likely be biased because it will fit to
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training data that don't completely represent the
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relationship that will be observed in test data.
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8. Suppose that we take a data set, divide it into equally-sized
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training and test sets, and then try out two different
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classification procedures. First we use logistic regression and
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get an error rate of 20 % on the training data and 30 % on the
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test data. Next we use 1-nearest neighbors (i.e. K = 1) and get
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an average error rate (averaged over both test and training data
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sets) of 18 %. Based on these results, which method should we
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prefer to use for classification of new observations? Why?
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Definitely 1-nearest neighbor. The logistic regression
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performed more poorly on the training data, to which it has
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been optimized as much as possible, and yet the nearest
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neighbor model performs better over the entire dataset.
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Considering the logistic regression performed even worse on
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the test data, the average error rate of the logistic
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regression over the training and test data is 25%. This
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suggests that the relationship may not even be linear, and
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the nearest-neighbor is a very solid method for modeling
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non-linear classifications, so if the real relationship is
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not linear, it easily explains why the nearest-neighbor
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method would do so much better. Everything here seems to
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point at using the nearest-neighbor.
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9. This problem has to do with odds.
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(a) On average, what fraction of people with an odds of 0.37 of
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defaulting on their credit card payment will in fact default?
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(b) Suppose that an individual has a 16 % chance of defaulting
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on her credit card payment. What are the odds that she will de-
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fault?
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11. In this problem, you will develop a model to predict whether a
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given car gets high or low gas mileage based on the Auto data
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set.
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(a) Create a binary variable, mpg01 , that contains a 1 if mpg
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contains a value above its median, and a 0 if mpg contains a
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value below its median. You can compute the median using the
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median() function. Note you may find it helpful to use the
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data.frame() function to create a single data set containing
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both mpg01 and the other Auto variables.
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(b) Explore the data graphically in order to investigate the
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associ- ation between mpg01 and the other features. Which of the
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other features seem most likely to be useful in predicting mpg01
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? Scat- terplots and boxplots may be useful tools to answer this
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ques- tion. Describe your findings.
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(c) Split the data into a training set and a test set.
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(d) Perform LDA on the training data in order to predict mpg01
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using the variables that seemed most associated with mpg01 in
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(b). What is the test error of the model obtained?
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(e) Perform QDA on the training data in order to predict mpg01
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using the variables that seemed most associated with mpg01 in
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(b). What is the test error of the model obtained?
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(f) Perform logistic regression on the training data in order to
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pre- dict mpg01 using the variables that seemed most associated
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with mpg01 in (b). What is the test error of the model obtained?
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(g) Perform KNN on the training data, with several values of K,
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in order to predict mpg01 . Use only the variables that seemed
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most associated with mpg01 in (b). What test errors do you
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obtain? Which value of K seems to perform the best on this data
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set?
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lab2/.RData
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lab2/.RData
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lab2/.Rhistory
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lab2/.Rhistory
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lab2/Figure.pdf
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lab2/Figure.pdf
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lab2/lab.r
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lab2/lab.r
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lab2/program
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lab2/program
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project/ideas
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project/ideas
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usingR.pdf
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usingR.pdf
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