决策树(Decision Trees)

决策树(Decision Trees)

1. Training and Visualizing a Decision Tree

can perform both classification and regression tasks, and even multioutput tasks

tree_clf = DecisionTreeClassifier(max_depth=2)
export_graphviz(
	tree_clf,
	out_file=image_path("iris_tree.dot"),
	feature_names=iris.feature_names[2:],
	class_names=iris.target_names,
	rounded=True,
	filled=True
)
$ dot -Tpng iris_tree.dot -o iris_tree.png

2. Making Predictions

  • require very little data preparation.
  • don’t require feature scaling or centering at all
  • algorithm
    CART, binary trees
    ID3, mul-children trees
  • etimating class probabilities
    根据叶子节点的value,就可以输出每个分类的概率 p k p_k pk
  • gini 节点的纯洁程度,0最纯洁
    G i n i i = 1 − ∑ k = 1 n p i , k 2 Gini_i=1-\sum_{k=1}^{n}p_{i,k}^2 Ginii=1k=1npi,k2
    p i , k p_{i,k} pi,k表示第i个节点上,第k类出现的概率

3. The CART Training Algorithm

递归的为每个节点寻找最好的划分特征k和划分特征的阈值t,CART Cost Function For classification
J ( k , t k ) = m l e f t m G l e f t + m r i g h t m G r i g h t      ( G    m e a s u r e s    t h e    i m p u r i t y    o f    t h e    s u b s e t ) J(k, t_k)=\frac{m_{left}}{m}G_{left} + \frac{m_{right}}{m}G_{right} \;\; (G \; measures \; the \; impurity \; of \; the \; subset) J(k,tk)=mmleftGleft+mmrightGright(Gmeasurestheimpurityofthesubset)
处了GINI指数可以作为G,香农信息熵也是一种方法
H i = − ∑ k = 1 , p i , k ≠ 0 n p i , k l o g ( p i , k ) H_i=-\sum_{k=1,p_{i,k}\neq 0}^{n}p_{i,k}log(p_{i,k}) Hi=k=1,pi,k=0npi,klog(pi,k)
默认选择GINI指数,计算复杂度低一些,二者训练出来的树差不多,Gini impurity tends to isolate the most frequent class in its own branch of the tree, while entropy tends to produce slightly more balanced trees

  • CART 全称是 Classifcation And Regression Tree
  • CART is a greedy algorithm 贪心算法
    1. A greedy algorithm often produces a reasonably good solution,
    2. but it is not guaranteed to be the optimal solution.
    3. finding the optimal tree is known to be an NP-Complete problem
    4. it requires O(exp(m)) time
  • mathematical question
    1. P is the set of problems that can be solved in polynomial time
    2. NP is the set of problems whose solutions can be verified in polynomial time
    3. NP-Hard problem is a problem to which any NP problem can be reduced in polynomial time.
    4. An NP-Complete problem is both NP and NP-Hard

4. Regularization Hyperparameters

  • a nonparametric model
    the number of parameters is not determined prior to training
  • a few parameters restrict the shape of the Decision Tree
    1. min_samples_split
    2. min_samples_leaf
    3. min_weight_fraction_leaf, same as min_samples_leaf but expressed as a fraction of the total number of eighted instances
    4. max_leaf_nodes
    5. max_features, maximum number of features that are evaluated for splitting at each node
  • increasing min_* hyperparameters or reducing max_* hyperparameters will regularize the model
  • 另可以先不加任何约束训练一棵树,完成后再对树进行裁剪的方式正则化
  • The computational complexity of training a Decision Tree is O(n × m log(m))

5. Regression

将混乱程度修改为均值平方差

from sklearn.tree import DecisionTreeRegressor
# setting min_samples_leaf=10 to obviously overfitting
tree_reg = DecisionTreeRegressor(max_depth=2)
tree_reg.fit(X, y)

返回的value值,是这一个区间内的所有samples的平均值

6. Instability 不确定性

  • 优点 a lot going
    1. simple to understand and interpret
    2. easy to use
    3. versatile, and powerful
  • 缺点 a few limitations
    1. orthogonal decision boundaries 对非线性的样本不好处理
    2. very sensitive to small variations in the training data

@ 学必求其心得,业必贵其专精

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