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  • 实验四、决策树算法及应用

    实验三 朴素贝叶斯算法及应用

    博客班级 机器学习18级
    作业要求 https://edu.cnblogs.com/campus/ahgc/machinelearning/homework/12086
    学号 3180701315
    实验目的
    1.理解决策树算法原理,掌握决策树算法框架;
    2.理解决策树学习算法的特征选择、树的生成和树的剪枝;
    3.能根据不同的数据类型,选择不同的决策树算法;
    4.针对特定应用场景及数据,能应用决策树算法解决实际问题。

    实验内容
    1.设计算法实现熵、经验条件熵、信息增益等方法。
    2.实现ID3算法。
    3.熟悉sklearn库中的决策树算法;
    4.针对iris数据集,应用sklearn的决策树算法进行类别预测。
    5.针对iris数据集,利用自编决策树算法进行类别预测。

    实验报告要求
    1.对照实验内容,撰写实验过程、算法及测试结果;
    2.代码规范化:命名规则、注释;
    3.分析核心算法的复杂度;
    4.查阅文献,讨论ID3、5算法的应用场景;

    实验内容以及结果
    In [1]:

    import numpy as np
    import pandas as pd
    import matplotlib.pyplot as plt
    %matplotlib inline
    from sklearn.datasets import load_iris
    from sklearn.model_selection import train_test_split
    from collections import Counter
    import math
    from math import log
    import pprint
    

    In [2]:

    # 书上题目5.1
    def create_data():
        datasets = [['青年', '否', '否', '一般', '否'],
                    ['青年', '否', '否', '好', '否'],
                    ['青年', '是', '否', '好', '是'],
                    ['青年', '是', '是', '一般', '是'],
                    ['青年', '否', '否', '一般', '否'],
                    ['中年', '否', '否', '一般', '否'],
                    ['中年', '否', '否', '好', '否'],
                    ['中年', '是', '是', '好', '是'],
                    ['中年', '否', '是', '非常好', '是'],
                    ['中年', '否', '是', '非常好', '是'],
                    ['老年', '否', '是', '非常好', '是'],
                    ['老年', '否', '是', '好', '是'],
                    ['老年', '是', '否', '好', '是'],
                    ['老年', '是', '否', '非常好', '是'],
                    ['老年', '否', '否', '一般', '否'],
                    ]
        labels = [u'年龄', u'有工作', u'有自己的房子', u'信贷情况', u'类别']
        # 返回数据集和每个维度的名称
        return datasets, labels
    

    In [3]:

    datasets, labels = create_data()
    

    In [4]:

    train_data = pd.DataFrame(datasets, columns=labels)
    

    In [5]:

    train_data
    

    In [6]:

    # 熵
    def calc_ent(datasets):
        data_length = len(datasets)
        label_count = {}
        for i in range(data_length):
            label = datasets[i][-1]
            if label not in label_count:
                label_count[label] = 0
            label_count[label] += 1
        ent = -sum([(p / data_length) * log(p / data_length, 2)
                for p in label_count.values()])
        return ent
    # def entropy(y):
    # """
    # Entropy of a label sequence
    # """
    # hist = np.bincount(y)
    # ps = hist / np.sum(hist)
    # return -np.sum([p * np.log2(p) for p in ps if p > 0])
    # 经验条件熵
    def cond_ent(datasets, axis=0):
        data_length = len(datasets)
        feature_sets = {}
        for i in range(data_length):
            feature = datasets[i][axis]
            if feature not in feature_sets:
                feature_sets[feature] = []
            feature_sets[feature].append(datasets[i])
        cond_ent = sum(
            [(len(p) / data_length) * calc_ent(p) for p in feature_sets.values()])
        return cond_ent
    # 信息增益
    def info_gain(ent, cond_ent):
        return ent - cond_ent
    
    def info_gain_train(datasets):
        count = len(datasets[0]) - 1
        ent = calc_ent(datasets)
        # ent = entropy(datasets)
        best_feature = []
        for c in range(count):
            c_info_gain = info_gain(ent, cond_ent(datasets, axis=c))
            best_feature.append((c, c_info_gain))
            print('特征({}) - info_gain - {:.3f}'.format(labels[c], c_info_gain))
        # 比较大小
        best_ = max(best_feature, key=lambda x: x[-1])
        return '特征({})的信息增益最大,选择为根节点特征'.format(labels[best_[0]])
    

    In [7]:

    info_gain_train(np.array(datasets))
    

    In[8]:

    # 定义节点类 二叉树
    class Node:
        def __init__(self, root=True, label=None, feature_name=None, feature=None):
            self.root = root
            self.label = label
            self.feature_name = feature_name
            self.feature = feature
            self.tree = {}
            self.result = {
                'label:': self.label,
                'feature': self.feature,
                'tree': self.tree
            }
        def __repr__(self):
            return '{}'.format(self.result)
        def add_node(self, val, node):
            self.tree[val] = node
        def predict(self, features):
            if self.root is True:
                return self.label
            return self.tree
    class DTree:
        def __init__(self, epsilon=0.1):
            self.epsilon = epsilon
            self._tree = {}
        # 熵   
        @staticmethod
        def calc_ent(datasets):
            data_length = len(datasets)
            label_count = {}
            for i in range(data_length):
                label = datasets[i][-1]
                if label not in label_count:
                    label_count[label] = 0
                label_count[label] += 1
            ent = -sum([(p / data_length) * log(p / data_length, 2)
                        for p in label_count.values()])
            return ent 
        # 经验条件熵
        def cond_ent(self, datasets, axis=0):
            data_length = len(datasets)
            feature_sets = {}
            for i in range(data_length):
                feature = datasets[i][axis]
                if feature not in feature_sets:
                    feature_sets[feature] = []
                feature_sets[feature].append(datasets[i])
            cond_ent = sum([(len(p) / data_length) * self.calc_ent(p)
                        for p in feature_sets.values()])
            return cond_ent
        
        # 信息增益
        @staticmethod
        def info_gain(ent, cond_ent):
            return ent - cond_ent
        
        def info_gain_train(self, datasets):
            count = len(datasets[0]) - 1
            ent = self.calc_ent(datasets)
            best_feature = []
            for c in range(count):
                c_info_gain = self.info_gain(ent, self.cond_ent(datasets, axis=c))
                best_feature.append((c, c_info_gain))
            # 比较大小
            best_ = max(best_feature, key=lambda x: x[-1])
            return best_
        
        def train(self, train_data):
            """
            input:数据集D(DataFrame格式),特征集A,阈值eta
            output:决策树T
            """
            _, y_train, features = train_data.iloc[:, :
                                                    -1], train_data.iloc[:,
                                                                        -1], train_data.columns[:
                                                                                               -1]
            # 1,若D中实例属于同一类Ck,则T为单节点树,并将类Ck作为结点的类标记,返回T
            if len(y_train.value_counts()) == 1:
                return Node(root=True, label=y_train.iloc[0])
            # 2, 若A为空,则T为单节点树,将D中实例树最大的类Ck作为该节点的类标记,返回T
            if len(features) == 0:
                return Node(
                    root=True,
                    label=y_train.value_counts().sort_values(
                        ascending=False).index[0])
    
            # 3,计算最大信息增益 同5.1,Ag为信息增益最大的特征
            max_feature, max_info_gain = self.info_gain_train(np.array(train_data))
            max_feature_name = features[max_feature]
    
            # 4,Ag的信息增益小于阈值eta,则置T为单节点树,并将D中是实例数最大的类Ck作为该节点的类标记,返
            if max_info_gain < self.epsilon:
                return Node(
                    root=True,
                    label=y_train.value_counts().sort_values(
                        ascending=False).index[0])
            # 5,构建Ag子集
            node_tree = Node(
                root=False, feature_name=max_feature_name, feature=max_feature)
    
            feature_list = train_data[max_feature_name].value_counts().index
            for f in feature_list:
                sub_train_df = train_data.loc[train_data[max_feature_name] ==
                                            f].drop([max_feature_name], axis=1)
    
                # 6, 递归生成树
                sub_tree = self.train(sub_train_df)
                node_tree.add_node(f, sub_tree)
            # pprint.pprint(node_tree.tree)
            return node_tree
    
        def fit(self, train_data):
            self._tree = self.train(train_data)
            return self._tree
        def predict(self, X_test):
            return self._tree.predict(X_test)
    

    In[9]:

    data_df = pd.DataFrame(datasets, columns=labels)
    dt = DTree()
    tree = dt.fit(data_df)
    

    In [10]:

    tree
    


    In[11]:

    dt.predict(['老年', '否', '否', '一般'])
    

    scikit-learn实例
    In [12]:

    # data
    def create_data():
      iris = load_iris()
      df = pd.DataFrame(iris.data, columns=iris.feature_names)
      df['label'] = iris.target
      df.columns = [
        'sepal length', 'sepal width', 'petal length', 'petal width', 'label'
      ]
      data = np.array(df.iloc[:100, [0, 1, -1]])
      # print(data)
      return data[:, :2], data[:, -1]
    X, y = create_data()
    X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.3)
    

    In [13]:

    from sklearn.tree import DecisionTreeClassifier
    from sklearn.tree import export_graphviz
    import graphviz
    

    In [14]:

    clf = DecisionTreeClassifier()
    clf.fit(X_train, y_train,)
    

    Out[14]:

    DecisionTreeClassifier()
    

    In [15]:

    clf.score(X_test, y_test)
    

    Out[15]:0.9666666666666667
    In [16]:

    tree_pic = export_graphviz(clf, out_file="mytree.pdf")
    with open('mytree.pdf') as f:
      dot_graph = f.read()
    

    In [19]:

    graphviz.Source(dot_graph)
    

    Out[19]:


    实验小结
    决策树算法首先对数据进行处理,利用归纳算法生成可读的规则和决策树,然后使用决策对新数据进行分析。
    优点是分类精度高、生成的模式简单。

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  • 原文地址:https://www.cnblogs.com/lizhen666/p/14951283.html
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