机器学习练习4 朴素贝叶斯
代码修改并注释:黄海广
代码下载:
https://github.com/fengdu78/WZU-machine-learning-course
1.朴素贝叶斯法是典型的生成学习方法。生成方法由训练数据学习联合概率分布 ,然后求得后验概率分布 。具体来说,利用训练数据学习 和 的估计,得到联合概率分布:
=
概率估计方法可以是极大似然估计或贝叶斯估计。
2.朴素贝叶斯法的基本假设是条件独立性,
这是一个较强的假设。由于这一假设,模型包含的条件概率的数量大为减少,朴素贝叶斯法的学习与预测大为简化。因而朴素贝叶斯法高效,且易于实现。其缺点是分类的性能不一定很高。
3.朴素贝叶斯法利用贝叶斯定理与学到的联合概率模型进行分类预测。
将输入 分到后验概率最大的类 。
后验概率最大等价于0-1损失函数时的期望风险最小化。
模型:
- 高斯模型
- 多项式模型
- 伯努利模型
import numpy as np
import pandas as pd
from sklearn.datasets import load_iris
from sklearn.model_selection import train_test_split
from collections import Counter
import math
# 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, :])
# print(data)
return data[:, :-1], data[:, -1]
X, y = create_data()
X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.3)
X_test[0], y_test[0]
(array([5.1, 3.8, 1.9, 0.4]), 0.0)
参考:https://machinelearningmastery.com/naive-bayes-classifier-scratch-python/
GaussianNB 高斯朴素贝叶斯
特征的可能性被假设为高斯
概率密度函数:
数学期望(mean):
方差:
class NaiveBayes:
def __init__(self):
self.model = None
# 数学期望
@staticmethod
def mean(X):
return sum(X) / float(len(X))
# 标准差(方差)
def stdev(self, X):
avg = self.mean(X)
return math.sqrt(sum([pow(x - avg, 2) for x in X]) / float(len(X)))
# 概率密度函数
def gaussian_probability(self, x, mean, stdev):
exponent = math.exp(-(math.pow(x - mean, 2) /
(2 * math.pow(stdev, 2))))
return (1 / (math.sqrt(2 * math.pi) * stdev)) * exponent
# 处理X_train
def summarize(self, train_data):
summaries = [(self.mean(i), self.stdev(i)) for i in zip(*train_data)]
return summaries
# 分类别求出数学期望和标准差
def fit(self, X, y):
labels = list(set(y))
data = {label: [] for label in labels}
for f, label in zip(X, y):
data[label].append(f)
self.model = {
label: self.summarize(value)
for label, value in data.items()
}
return 'gaussianNB train done!'
# 计算概率
def calculate_probabilities(self, input_data):
# summaries:{0.0: [(5.0, 0.37),(3.42, 0.40)], 1.0: [(5.8, 0.449),(2.7, 0.27)]}
# input_data:[1.1, 2.2]
probabilities = {}
for label, value in self.model.items():
probabilities[label] = 1
for i in range(len(value)):
mean, stdev = value[i]
probabilities[label] *= self.gaussian_probability(
input_data[i], mean, stdev)
return probabilities
# 类别
def predict(self, X_test):
# {0.0: 2.9680340789325763e-27, 1.0: 3.5749783019849535e-26}
label = sorted(self.calculate_probabilities(X_test).items(),
key=lambda x: x[-1])[-1][0]
return label
def score(self, X_test, y_test):
right = 0
for X, y in zip(X_test, y_test):
label = self.predict(X)
if label == y:
right += 1
return right / float(len(X_test))
model = NaiveBayes()
model.fit(X_train, y_train)
'gaussianNB train done!'
print(model.predict([4.4, 3.2, 1.3, 0.2]))
0.0
model.score(X_test, y_test)
1.0
scikit-learn实例
from sklearn.naive_bayes import GaussianNB, BernoulliNB, MultinomialNB
# 高斯模型、伯努利模型和多项式模型
clf = GaussianNB()
clf.fit(X_train, y_train)
GaussianNB(priors=None, var_smoothing=1e-09)
clf.score(X_test, y_test)
1.0
clf.predict([[4.4, 3.2, 1.3, 0.2]])
array([0.])
参考
- Prof. Andrew Ng. Machine Learning. Stanford University
- 李航,《统计学习方法》,清华大学出版社
