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@@ -1,242 +1,824 @@
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-## 3.5
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-$$\cfrac{\partial E_{(w, b)}}{\partial w}=2\left(w \sum_{i=1}^{m} x_{i}^{2}-\sum_{i=1}^{m}\left(y_{i}-b\right) x_{i}\right)$$
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-[推导]:已知$E_{(w, b)}=\sum\limits_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}$,所以
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-$$\begin{aligned}
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-\cfrac{\partial E_{(w, b)}}{\partial w}&=\cfrac{\partial}{\partial w} \left[\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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-&= \sum_{i=1}^{m}\cfrac{\partial}{\partial w} \left[\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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+# 第3章 线性模型
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+
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+作为"西瓜书"介绍机器学习模型的开篇,线性模型也是机器学习中最为基础的模型,很多复杂模型均可认为由线性模型衍生而得,无论是曾经红极一时的支持向量机还是如今万众瞩目的神经网络,其中都有线性模型的影子。
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+
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+本章的线性回归和对数几率回归分别是回归和分类任务上常用的算法,因此属于重点内容,线性判别分析不常用,但是其核心思路和后续第10章将会讲到的经典降维算法主成分分析相同,因此也属于重点内容,且两者结合在一起看理解会更深刻。
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+
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+## 3.1 基本形式
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+
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+第1章的1.2基本术语中讲述样本的定义时,我们说明了"西瓜书"和本书中向量的写法,当向量中的元素用分号";"分隔时表示此向量为列向量,用逗号","分隔时表示为行向量。因此,式(3.2)中$\boldsymbol{w}=(w_{1};w_{2};...;w_{d})$和$\boldsymbol{x}=(x_{1};x_{2};...;x_{d})$均为$d$行1列的列向量。
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+
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+## 3.2 线性回归
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+
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+### 3.2.1 属性数值化
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+
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+为了能进行数学运算,样本中的非数值类属性都需要进行数值化。对于存在"序"关系的属性,可通过连续化将其转化为带有相对大小关系的连续值;对于不存在"序"关系的属性,可根据属性取值将其拆解为多个属性,例如"西瓜书"中所说的"瓜类"属性,可将其拆解为"是否是西瓜"、"是否是南瓜"、"是否是黄瓜"3个属性,其中每个属性的取值为1或0,1表示"是",0表示"否"。具体地,假如现有3个瓜类样本:$\boldsymbol{x}_1=(\text{甜度}=\text{高};\text{瓜类}=\text{西瓜}),\boldsymbol{x}_2=(\text{甜度}=\text{中};\text{瓜类}=\text{南瓜}),\boldsymbol{x}_3=(\text{甜度}=\text{低};\text{瓜类}=\text{黄瓜})$,其中"甜度"属性存在序关系,因此可将"高"、"中"、"低"转化为$\{1.0,0.5,0.0\}$,"瓜类"属性不存在序关系,则按照上述方法进行拆解,3个瓜类样本数值化后的结果为:$\boldsymbol{x}_1=(1.0;1;0;0),\boldsymbol{x}_1=(0.5;0;1;0),\boldsymbol{x}_1=(0.0;0;0;1)$。
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+
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+以上针对样本属性所进行的处理工作便是第1章1.2基本术语中提到的"特征工程"范畴,完成属性数值化以后通常还会进行缺失值处理、规范化、降维等一系列处理工作。由于特征工程属于算法实践过程中需要掌握的内容,待学完机器学习算法以后,再进一步学习特征工程相关知识即可,在此先不展开。
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+
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+### 3.2.2 式(3.4)的解释
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+
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+下面仅针对式(3.4)中的数学符号进行解释。首先解释一下符号"$\arg \min$",其中"arg"是"argument"(参数)的前三个字母,"min"
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+是"minimum"(最小值)的前三个字母,该符号表示求使目标函数达到最小值的参数取值。例如式(3.4)表示求出使目标函数$\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}$达到最小值的参数取值$(w^{*},b^{*})$,注意目标函数是以$(w,b)$为自变量的函数,$(x_{i},y_{i})$均是已知常量,即训练集中的样本数据。
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+
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+类似的符号还有"$\min$",例如将式(3.4)改为
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+
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+$$
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+\underset{(w,b)}{\min}\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}
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+$$
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+
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+则表示求目标函数的最小值。对比知道,"$\min$"和"$\arg \min$"的区别在于,前者输出目标函数的最小值,而后者输出使得目标函数达到最小值时的参数取值。
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+
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+若进一步修改式(3.4)为
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+
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+$$
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+\begin{aligned}
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+\underset{(w,b)}{\min} & \sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2} \\
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+\text{s.t.} & w > 0, \\
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+& b < 0.
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+\end{aligned}
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+$$
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+
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+则表示在$w>0,b<0$范围内寻找目标函数的最小值,"$\text{s.t.}$"是"subject
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+to"的简写,意思是"受约束于",即为约束条件。
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+
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+以上介绍的符号都是应用数学领域的一个分支------"最优化"中的内容,若想进一步了解可找一本最优化的教材(例如参考文献[1])进行系统性地学习。
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+
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+### 3.2.3 式(3.5)的推导
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+
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+"西瓜书"在式(3.5)左侧给出的凸函数的定义是最优化中的定义,与高等数学中的定义不同,本书也默认采用此种定义。由于一元线性回归可以看作是多元线性回归中元的个数为1时的情形,所以此处暂不给出$E_{(w, b)}$是关于$w$和$b$的凸函数的证明,在推导式(3.11)时一并给出,下面开始推导式(3.5)。
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+
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+已知$E_{(w, b)}=\sum\limits_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}$,所以
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+
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+$$
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+\begin{aligned}
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+\frac{\partial E_{(w, b)}}{\partial w}&=\frac{\partial}{\partial w} \left[\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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+&= \sum_{i=1}^{m}\frac{\partial}{\partial w} \left[\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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&= \sum_{i=1}^{m}\left[2\cdot\left(y_{i}-w x_{i}-b\right)\cdot (-x_i)\right] \\
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&= \sum_{i=1}^{m}\left[2\cdot\left(w x_{i}^2-y_i x_i +bx_i\right)\right] \\
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&= 2\cdot\left(w\sum_{i=1}^{m} x_{i}^2-\sum_{i=1}^{m}y_i x_i +b\sum_{i=1}^{m}x_i\right) \\
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&=2\left(w \sum_{i=1}^{m} x_{i}^{2}-\sum_{i=1}^{m}\left(y_{i}-b\right) x_{i}\right)
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-\end{aligned}$$
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-
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-## 3.6
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-$$\cfrac{\partial E_{(w, b)}}{\partial b}=2\left(m b-\sum_{i=1}^{m}\left(y_{i}-w x_{i}\right)\right)$$
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-[推导]:已知$E_{(w, b)}=\sum\limits_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}$,所以
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-$$\begin{aligned}
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-\cfrac{\partial E_{(w, b)}}{\partial b}&=\cfrac{\partial}{\partial b} \left[\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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-&=\sum_{i=1}^{m}\cfrac{\partial}{\partial b} \left[\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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+\end{aligned}
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+$$
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+
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+
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+### 3.2.4 式(3.6)的推导
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+
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+已知$E_{(w, b)}=\sum\limits_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}$,所以
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+
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+$$
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+\begin{aligned}
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+\frac{\partial E_{(w, b)}}{\partial b}&=\frac{\partial}{\partial b} \left[\sum_{i=1}^{m}\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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+&=\sum_{i=1}^{m}\frac{\partial}{\partial b} \left[\left(y_{i}-w x_{i}-b\right)^{2}\right] \\
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&=\sum_{i=1}^{m}\left[2\cdot\left(y_{i}-w x_{i}-b\right)\cdot (-1)\right] \\
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&=\sum_{i=1}^{m}\left[2\cdot\left(b-y_{i}+w x_{i}\right)\right] \\
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&=2\cdot\left[\sum_{i=1}^{m}b-\sum_{i=1}^{m}y_{i}+\sum_{i=1}^{m}w x_{i}\right] \\
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&=2\left(m b-\sum_{i=1}^{m}\left(y_{i}-w x_{i}\right)\right)
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-\end{aligned}$$
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-
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-## 3.7
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-$$ w=\cfrac{\sum_{i=1}^{m}y_i(x_i-\bar{x})}{\sum_{i=1}^{m}x_i^2-\cfrac{1}{m}(\sum_{i=1}^{m}x_i)^2} $$
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-[推导]:令公式(3.5)等于0
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-$$ 0 = w\sum_{i=1}^{m}x_i^2-\sum_{i=1}^{m}(y_i-b)x_i $$
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-$$ w\sum_{i=1}^{m}x_i^2 = \sum_{i=1}^{m}y_ix_i-\sum_{i=1}^{m}bx_i $$
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-由于令公式(3.6)等于0可得$b=\cfrac{1}{m}\sum_{i=1}^{m}(y_i-wx_i)$,又因为$\cfrac{1}{m}\sum_{i=1}^{m}y_i=\bar{y}$,$\cfrac{1}{m}\sum_{i=1}^{m}x_i=\bar{x}$,则$b=\bar{y}-w\bar{x}$,代入上式可得
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-$$\begin{aligned}
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+\end{aligned}
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+$$
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+
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+
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+### 3.2.5 式(3.7)的推导
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+
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+推导之前先重点说明一下"闭式解"或称为"解析解"。闭式解是指可以通过具体的表达式解出待解参数,例如可根据式(3.7)直接解得$w$。机器学习算法很少有闭式解,线性回归是一个特例,接下来推导式(3.7)。
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+
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+令式(3.5)等于0
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+
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+$$
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+0 = w\sum_{i=1}^{m}x_i^2-\sum_{i=1}^{m}(y_i-b)x_i
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+$$
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+
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+
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+$$
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+w\sum_{i=1}^{m}x_i^2 = \sum_{i=1}^{m}y_ix_i-\sum_{i=1}^{m}bx_i
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+$$
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+
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+由于令式(3.6)等于0可得$b=\frac{1}{m}\sum_{i=1}^{m}(y_i-wx_i)$,又因为$\frac{1}{m}\sum_{i=1}^{m}y_i=\bar{y}$,$\frac{1}{m}\sum_{i=1}^{m}x_i=\bar{x}$,则$b=\bar{y}-w\bar{x}$,代入上式可得
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+
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+$$
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+\begin{aligned}
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w\sum_{i=1}^{m}x_i^2 & = \sum_{i=1}^{m}y_ix_i-\sum_{i=1}^{m}(\bar{y}-w\bar{x})x_i \\
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w\sum_{i=1}^{m}x_i^2 & = \sum_{i=1}^{m}y_ix_i-\bar{y}\sum_{i=1}^{m}x_i+w\bar{x}\sum_{i=1}^{m}x_i \\
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w(\sum_{i=1}^{m}x_i^2-\bar{x}\sum_{i=1}^{m}x_i) & = \sum_{i=1}^{m}y_ix_i-\bar{y}\sum_{i=1}^{m}x_i \\
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-w & = \cfrac{\sum_{i=1}^{m}y_ix_i-\bar{y}\sum_{i=1}^{m}x_i}{\sum_{i=1}^{m}x_i^2-\bar{x}\sum_{i=1}^{m}x_i}
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-\end{aligned}$$
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-由于$\bar{y}\sum_{i=1}^{m}x_i=\cfrac{1}{m}\sum_{i=1}^{m}y_i\sum_{i=1}^{m}x_i=\bar{x}\sum_{i=1}^{m}y_i$,$\bar{x}\sum_{i=1}^{m}x_i=\cfrac{1}{m}\sum_{i=1}^{m}x_i\sum_{i=1}^{m}x_i=\cfrac{1}{m}(\sum_{i=1}^{m}x_i)^2$,代入上式即可得公式(3.7)
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-$$ w=\cfrac{\sum_{i=1}^{m}y_i(x_i-\bar{x})}{\sum_{i=1}^{m}x_i^2-\cfrac{1}{m}(\sum_{i=1}^{m}x_i)^2} $$
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-如果要想用Python来实现上式的话,上式中的求和运算只能用循环来实现,但是如果我们能将上式给向量化,也就是转换成矩阵(向量)运算的话,那么我们就可以利用诸如NumPy这种专门加速矩阵运算的类库来进行编写。下面我们就尝试将上式进行向量化,将$ \cfrac{1}{m}(\sum_{i=1}^{m}x_i)^2=\bar{x}\sum_{i=1}^{m}x_i $代入分母可得
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-$$\begin{aligned}
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-w & = \cfrac{\sum_{i=1}^{m}y_i(x_i-\bar{x})}{\sum_{i=1}^{m}x_i^2-\bar{x}\sum_{i=1}^{m}x_i} \\
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-& = \cfrac{\sum_{i=1}^{m}(y_ix_i-y_i\bar{x})}{\sum_{i=1}^{m}(x_i^2-x_i\bar{x})}
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-\end{aligned}$$
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-又因为$ \bar{y}\sum_{i=1}^{m}x_i=\bar{x}\sum_{i=1}^{m}y_i=\sum_{i=1}^{m}\bar{y}x_i=\sum_{i=1}^{m}\bar{x}y_i=m\bar{x}\bar{y}=\sum_{i=1}^{m}\bar{x}\bar{y} $,$\sum_{i=1}^{m}x_i\bar{x}=\bar{x}\sum_{i=1}^{m}x_i=\bar{x}\cdot m \cdot\frac{1}{m}\cdot\sum_{i=1}^{m}x_i=m\bar{x}^2=\sum_{i=1}^{m}\bar{x}^2$,则上式可化为
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-$$\begin{aligned}
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-w & = \cfrac{\sum_{i=1}^{m}(y_ix_i-y_i\bar{x}-x_i\bar{y}+\bar{x}\bar{y})}{\sum_{i=1}^{m}(x_i^2-x_i\bar{x}-x_i\bar{x}+\bar{x}^2)} \\
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-& = \cfrac{\sum_{i=1}^{m}(x_i-\bar{x})(y_i-\bar{y})}{\sum_{i=1}^{m}(x_i-\bar{x})^2}
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-\end{aligned}$$
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-若令$\boldsymbol{x}=(x_1,x_2,...,x_m)^T$,$\boldsymbol{x}_{d}=(x_1-\bar{x},x_2-\bar{x},...,x_m-\bar{x})^T$为去均值后的$\boldsymbol{x}$,$\boldsymbol{y}=(y_1,y_2,...,y_m)^T$,$\boldsymbol{y}_{d}=(y_1-\bar{y},y_2-\bar{y},...,y_m-\bar{y})^T$为去均值后的$\boldsymbol{y}$,其中$\boldsymbol{x}$、$\boldsymbol{x}_{d}$、$\boldsymbol{y}$、$\boldsymbol{y}_{d}$均为m行1列的列向量,代入上式可得
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-$$w=\cfrac{\boldsymbol{x}_{d}^T\boldsymbol{y}_{d}}{\boldsymbol{x}_d^T\boldsymbol{x}_{d}}$$
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-
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-## 3.9
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-$$\hat{\boldsymbol{w}}^{*}=\underset{\hat{\boldsymbol{w}}}{\arg \min }(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})^{\mathrm{T}}(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})$$
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-[推导]:公式(3.4)是最小二乘法运用在一元线性回归上的情形,那么对于多元线性回归来说,我们可以类似得到
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-$$\begin{aligned}
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- \left(\boldsymbol{w}^{*}, b^{*}\right)&=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(f\left(\boldsymbol{x}_{i}\right)-y_{i}\right)^{2} \\
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- &=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-f\left(\boldsymbol{x}_{i}\right)\right)^{2}\\
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- &=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\left(\boldsymbol{w}^\mathrm{T}\boldsymbol{x}_{i}+b\right)\right)^{2}
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-\end{aligned}$$
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+w & = \frac{\sum_{i=1}^{m}y_ix_i-\bar{y}\sum_{i=1}^{m}x_i}{\sum_{i=1}^{m}x_i^2-\bar{x}\sum_{i=1}^{m}x_i}
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+\end{aligned}
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+$$
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+
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+将$\bar{y}\sum_{i=1}^{m}x_i=\frac{1}{m}\sum_{i=1}^{m}y_i\sum_{i=1}^{m}x_i=\bar{x}\sum_{i=1}^{m}y_i$和$\bar{x}\sum_{i=1}^{m}x_i=\frac{1}{m}\sum_{i=1}^{m}x_i\sum_{i=1}^{m}x_i=\frac{1}{m}(\sum_{i=1}^{m}x_i)^2$代入上式,即可得式(3.7):
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+
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+$$
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+w=\frac{\sum_{i=1}^{m}y_i(x_i-\bar{x})}{\sum_{i=1}^{m}x_i^2-\frac{1}{m}(\sum_{i=1}^{m}x_i)^2}
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+$$
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+
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+如果要想用Python来实现上式的话,上式中的求和运算只能用循环来实现。但是如果能将上式向量化,也就是转换成矩阵(即向量)运算的话,我们就可以利用诸如NumPy这种专门加速矩阵运算的类库来进行编写。下面我们就尝试将上式进行向量化。
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+
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+将$\frac{1}{m}(\sum_{i=1}^{m}x_i)^2=\bar{x}\sum_{i=1}^{m}x_i$代入分母可得
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+
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+$$
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+\begin{aligned}
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+w & = \frac{\sum_{i=1}^{m}y_i(x_i-\bar{x})}{\sum_{i=1}^{m}x_i^2-\bar{x}\sum_{i=1}^{m}x_i} \\
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+& = \frac{\sum_{i=1}^{m}(y_ix_i-y_i\bar{x})}{\sum_{i=1}^{m}(x_i^2-x_i\bar{x})}
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+\end{aligned}
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+$$
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+
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+又因为$\bar{y}\sum_{i=1}^{m}x_i=\bar{x}\sum_{i=1}^{m}y_i=\sum_{i=1}^{m}\bar{y}x_i=\sum_{i=1}^{m}\bar{x}y_i=m\bar{x}\bar{y}=\sum_{i=1}^{m}\bar{x}\bar{y}$且$\sum_{i=1}^{m}x_i\bar{x}=\bar{x}\sum_{i=1}^{m}x_i=\bar{x}\cdot m \cdot\frac{1}{m}\cdot\sum_{i=1}^{m}x_i=m\bar{x}^2=\sum_{i=1}^{m}\bar{x}^2$,则有
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+
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+$$
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+\begin{aligned}
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+w & = \frac{\sum_{i=1}^{m}(y_ix_i-y_i\bar{x}-x_i\bar{y}+\bar{x}\bar{y})}{\sum_{i=1}^{m}(x_i^2-x_i\bar{x}-x_i\bar{x}+\bar{x}^2)} \\
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+& = \frac{\sum_{i=1}^{m}(x_i-\bar{x})(y_i-\bar{y})}{\sum_{i=1}^{m}(x_i-\bar{x})^2}
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+若令$\boldsymbol{x}=(x_1;x_2;...;x_m)$,$\boldsymbol{x}_{d}=(x_1-\bar{x};x_2-\bar{x};...;x_m-\bar{x})$为去均值后的$\boldsymbol{x}$;$\boldsymbol{y}=(y_1;y_2;...;y_m)$,$\boldsymbol{y}_{d}=(y_1-\bar{y};y_2-\bar{y};...;y_m-\bar{y})$为去均值后的$\boldsymbol{y}$, **($\boldsymbol{x}$、$\boldsymbol{x}_{d}$、$\boldsymbol{y}$、$\boldsymbol{y}_{d}$均为m行1列的列向量)** 代入上式可得
|
|
|
+
|
|
|
+$$
|
|
|
+w=\frac{\boldsymbol{x}_{d}^\mathrm{T}\boldsymbol{y}_{d}}{\boldsymbol{x}_d^\mathrm{T}\boldsymbol{x}_{d}}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+### 3.2.6 式(3.9)的推导
|
|
|
+
|
|
|
+式(3.4)是最小二乘法运用在一元线性回归上的情形,那么对于多元线性回归来说,我们可以类似得到
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+ \left(\boldsymbol{w}^{*}, b^{*}\right)&=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(f\left(\boldsymbol{x}_{i}\right)-y_{i}\right)^{2} \\
|
|
|
+ &=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-f\left(\boldsymbol{x}_{i}\right)\right)^{2}\\
|
|
|
+ &=\underset{(\boldsymbol{w}, b)}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\left(\boldsymbol{w}^\mathrm{T}\boldsymbol{x}_{i}+b\right)\right)^{2}
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
为便于讨论,我们令$\hat{\boldsymbol{w}}=(\boldsymbol{w};b)=(w_1;...;w_d;b)\in\mathbb{R}^{(d+1)\times 1},\hat{\boldsymbol{x}}_i=(x_{i1};...;x_{id};1)\in\mathbb{R}^{(d+1)\times 1}$,那么上式可以简化为
|
|
|
-$$\begin{aligned}
|
|
|
- \hat{\boldsymbol{w}}^{*}&=\underset{\hat{\boldsymbol{w}}}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\hat{\boldsymbol{w}}^\mathrm{T}\hat{\boldsymbol{x}}_{i}\right)^{2} \\
|
|
|
- &=\underset{\hat{\boldsymbol{w}}}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\hat{\boldsymbol{x}}_{i}^\mathrm{T}\hat{\boldsymbol{w}}\right)^{2} \\
|
|
|
-\end{aligned}$$
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+ \hat{\boldsymbol{w}}^{*}&=\underset{\hat{\boldsymbol{w}}}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\hat{\boldsymbol{w}}^\mathrm{T}\hat{\boldsymbol{x}}_{i}\right)^{2} \\
|
|
|
+ &=\underset{\hat{\boldsymbol{w}}}{\arg \min } \sum_{i=1}^{m}\left(y_{i}-\hat{\boldsymbol{x}}_{i}^\mathrm{T}\hat{\boldsymbol{w}}\right)^{2} \\
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
根据向量内积的定义可知,上式可以写成如下向量内积的形式
|
|
|
-$$\begin{aligned}
|
|
|
- \hat{\boldsymbol{w}}^{*}&=\underset{\hat{\boldsymbol{w}}}{\arg \min } \begin{bmatrix}
|
|
|
- y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} & \cdots & y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
- \end{bmatrix}
|
|
|
- \begin{bmatrix}
|
|
|
- y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
- \vdots \\
|
|
|
- y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
- \end{bmatrix} \\
|
|
|
-\end{aligned}$$
|
|
|
-其中
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+ \hat{\boldsymbol{w}}^{*}&=\underset{\hat{\boldsymbol{w}}}{\arg \min } \begin{bmatrix}
|
|
|
+ y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} & \cdots & y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
+ \end{bmatrix}
|
|
|
+ \begin{bmatrix}
|
|
|
+ y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
+ \vdots \\
|
|
|
+ y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
+ \end{bmatrix} \\
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+其中
|
|
|
+
|
|
|
$$
|
|
|
\begin{aligned}
|
|
|
\begin{bmatrix}
|
|
|
- y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
- \vdots \\
|
|
|
- y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
+ y_{1}-\hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
+ \vdots \\
|
|
|
+ y_{m}-\hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
\end{bmatrix}&=\begin{bmatrix}
|
|
|
- y_{1} \\
|
|
|
- \vdots \\
|
|
|
- y_{m}
|
|
|
+ y_{1} \\
|
|
|
+ \vdots \\
|
|
|
+ y_{m}
|
|
|
\end{bmatrix}-\begin{bmatrix}
|
|
|
- \hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
- \vdots \\
|
|
|
- \hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
+ \hat{\boldsymbol{x}}_{1}^\mathrm{T}\hat{\boldsymbol{w}} \\
|
|
|
+ \vdots \\
|
|
|
+ \hat{\boldsymbol{x}}_{m}^\mathrm{T}\hat{\boldsymbol{w}}
|
|
|
\end{bmatrix}\\
|
|
|
&=\boldsymbol{y}-\begin{bmatrix}
|
|
|
- \hat{\boldsymbol{x}}_{1}^\mathrm{T} \\
|
|
|
- \vdots \\
|
|
|
- \hat{\boldsymbol{x}}_{m}^\mathrm{T}
|
|
|
+ \hat{\boldsymbol{x}}_{1}^\mathrm{T} \\
|
|
|
+ \vdots \\
|
|
|
+ \hat{\boldsymbol{x}}_{m}^\mathrm{T}
|
|
|
\end{bmatrix}\cdot\hat{\boldsymbol{w}}\\
|
|
|
&=\boldsymbol{y}-\mathbf{X}\hat{\boldsymbol{w}}
|
|
|
\end{aligned}
|
|
|
$$
|
|
|
+
|
|
|
所以
|
|
|
-$$\hat{\boldsymbol{w}}^{*}=\underset{\hat{\boldsymbol{w}}}{\arg \min }(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})^{\mathrm{T}}(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})$$
|
|
|
|
|
|
-## 3.10
|
|
|
-$$\cfrac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}=2\mathbf{X}^{\mathrm{T}}(\mathbf{X}\hat{\boldsymbol w}-\boldsymbol{y})$$
|
|
|
-[推导]:将$E_{\hat{\boldsymbol w}}=(\boldsymbol{y}-\mathbf{X}\hat{\boldsymbol w})^{\mathrm{T}}(\boldsymbol{y}-\mathbf{X}\hat{\boldsymbol w})$展开可得
|
|
|
-$$E_{\hat{\boldsymbol w}}= \boldsymbol{y}^{\mathrm{T}}\boldsymbol{y}-\boldsymbol{y}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}-\hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\boldsymbol{y}+\hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}$$
|
|
|
+$$
|
|
|
+\hat{\boldsymbol{w}}^{*}=\underset{\hat{\boldsymbol{w}}}{\arg \min }(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})^{\mathrm{T}}(\boldsymbol{y}-\mathbf{X} \hat{\boldsymbol{w}})
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+### 3.2.7 式(3.10)的推导
|
|
|
+
|
|
|
+将$E_{\hat{\boldsymbol w}}=(\boldsymbol{y}-\mathbf{X}\hat{\boldsymbol w})^{\mathrm{T}}(\boldsymbol{y}-\mathbf{X}\hat{\boldsymbol w})$展开可得
|
|
|
+
|
|
|
+$$
|
|
|
+E_{\hat{\boldsymbol w}}= \boldsymbol{y}^{\mathrm{T}}\boldsymbol{y}-\boldsymbol{y}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}-\hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\boldsymbol{y}+\hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}
|
|
|
+$$
|
|
|
+
|
|
|
对$\hat{\boldsymbol w}$求导可得
|
|
|
-$$\cfrac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}= \cfrac{\partial \boldsymbol{y}^{\mathrm{T}}\boldsymbol{y}}{\partial \hat{\boldsymbol w}}-\cfrac{\partial \boldsymbol{y}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}}{\partial \hat{\boldsymbol w}}-\cfrac{\partial \hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\boldsymbol{y}}{\partial \hat{\boldsymbol w}}+\cfrac{\partial \hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}}{\partial \hat{\boldsymbol w}}$$
|
|
|
-由矩阵微分公式$\cfrac{\partial\boldsymbol{a}^{\mathrm{T}}\boldsymbol{x}}{\partial\boldsymbol{x}}=\cfrac{\partial\boldsymbol{x}^{\mathrm{T}}\boldsymbol{a}}{\partial\boldsymbol{x}}=\boldsymbol{a},\cfrac{\partial\boldsymbol{x}^{\mathrm{T}}\mathbf{A}\boldsymbol{x}}{\partial\boldsymbol{x}}=(\mathbf{A}+\mathbf{A}^{\mathrm{T}})\boldsymbol{x}$可得
|
|
|
-$$\cfrac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}= 0-\mathbf{X}^{\mathrm{T}}\boldsymbol{y}-\mathbf{X}^{\mathrm{T}}\boldsymbol{y}+(\mathbf{X}^{\mathrm{T}}\mathbf{X}+\mathbf{X}^{\mathrm{T}}\mathbf{X})\hat{\boldsymbol w}$$
|
|
|
-$$\cfrac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}=2\mathbf{X}^{\mathrm{T}}(\mathbf{X}\hat{\boldsymbol w}-\boldsymbol{y})$$
|
|
|
-
|
|
|
-## 3.27
|
|
|
-$$ \ell(\boldsymbol{\beta})=\sum_{i=1}^{m}(-y_i\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i+\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})) $$
|
|
|
-[推导]:将公式(3.26)代入公式(3.25)可得
|
|
|
-$$ \ell(\boldsymbol{\beta})=\sum_{i=1}^{m}\ln\left(y_ip_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})+(1-y_i)p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right) $$
|
|
|
-其中$ p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})=\cfrac{e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}},p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})=\cfrac{1}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}} $,代入上式可得
|
|
|
-$$\begin{aligned}
|
|
|
-\ell(\boldsymbol{\beta})&=\sum_{i=1}^{m}\ln\left(\cfrac{y_ie^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}+1-y_i}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}\right) \\
|
|
|
+
|
|
|
+$$
|
|
|
+\frac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}= \frac{\partial \boldsymbol{y}^{\mathrm{T}}\boldsymbol{y}}{\partial \hat{\boldsymbol w}}-\frac{\partial \boldsymbol{y}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}}{\partial \hat{\boldsymbol w}}-\frac{\partial \hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\boldsymbol{y}}{\partial \hat{\boldsymbol w}}+\frac{\partial \hat{\boldsymbol w}^{\mathrm{T}}\mathbf{X}^{\mathrm{T}}\mathbf{X}\hat{\boldsymbol w}}{\partial \hat{\boldsymbol w}}
|
|
|
+$$
|
|
|
+
|
|
|
+由矩阵微分公式$\frac{\partial\boldsymbol{a}^{\mathrm{T}}\boldsymbol{x}}{\partial\boldsymbol{x}}=\frac{\partial\boldsymbol{x}^{\mathrm{T}}\boldsymbol{a}}{\partial\boldsymbol{x}}=\boldsymbol{a},\frac{\partial\boldsymbol{x}^{\mathrm{T}}\mathbf{A}\boldsymbol{x}}{\partial\boldsymbol{x}}=(\mathbf{A}+\mathbf{A}^{\mathrm{T}})\boldsymbol{x}$ **(更多矩阵微分公式可查阅[2],矩阵微分原理可查阅[3])** 可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}} &= 0-\mathbf{X}^{\mathrm{T}}\boldsymbol{y}-\mathbf{X}^{\mathrm{T}}\boldsymbol{y}+(\mathbf{X}^{\mathrm{T}}\mathbf{X}+\mathbf{X}^{\mathrm{T}}\mathbf{X})\hat{\boldsymbol w} \\
|
|
|
+&=2\mathbf{X}^{\mathrm{T}}(\mathbf{X}\hat{\boldsymbol w}-\boldsymbol{y})
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+### 3.2.8 式(3.11)的推导
|
|
|
+
|
|
|
+首先铺垫讲解接下来以及后续内容将会用到的多元函数相关基础知识[1]。
|
|
|
+
|
|
|
+**$n$元实值函数**:含$n$个自变量,值域为实数域$\mathbb{R}$的函数称为$n$元实值函数,记为$f(\boldsymbol{x})$,其中$\boldsymbol{x}=(x_{1};x_{2};...;x_{n})$为$n$维向量。"西瓜书"和本书中的多元函数未加特殊说明均为实值函数。
|
|
|
+
|
|
|
+**凸集**:设集合$D\subset\mathbb{R}^n$为$n$维欧式空间中的子集,如果对$D$中任意的$n$维向量$\boldsymbol{x}\in D$和$\boldsymbol{y}\in D$与任意的$\alpha\in[0,1]$,有
|
|
|
+
|
|
|
+$$
|
|
|
+\alpha\boldsymbol{x}+(1-\alpha)\boldsymbol{y}\in D
|
|
|
+$$
|
|
|
+
|
|
|
+则称集合$D$是凸集。凸集的几何意义是:若两个点属于此集合,则这两点连线上的任意一点均属于此集合。常见的凸集有空集$\varnothing$,整个$n$维欧式空间$\mathbb{R}^n$。
|
|
|
+
|
|
|
+**凸函数**:设$D\subset\mathbb{R}^n$是非空凸集,$f$是定义在$D$上的函数,如果对任意的$\boldsymbol{x}^1,\boldsymbol{x}^2\in D,\alpha\in(0,1)$,均有
|
|
|
+
|
|
|
+$$
|
|
|
+f\left(\alpha\boldsymbol{x}^1+(1-\alpha)\boldsymbol{x}^2\right)\leqslant \alpha f(\boldsymbol{x}^1)+(1-\alpha)f(\boldsymbol{x}^2)
|
|
|
+$$
|
|
|
+
|
|
|
+则称$f$为$D$上的凸函数。若其中的$\leqslant$改为$<$也恒成立,则称$f$为$D$上的严格凸函数。
|
|
|
+
|
|
|
+**梯度**:若$n$元函数$f(\boldsymbol{x})$对$\boldsymbol{x}=(x_{1};x_{2};...;x_{n})$中各分量$x_{i}$的偏导数$\frac{\partial f(\boldsymbol{x})}{\partial x_{i}}(i=1,2,...,n)$都存在,则称函数$f(\boldsymbol{x})$在$\boldsymbol{x}$处一阶可导,并称以下列向量
|
|
|
+
|
|
|
+$$
|
|
|
+\nabla f(\boldsymbol{x})=\frac{\partial f(\boldsymbol{x})}{\partial \boldsymbol{x}}=\left[ \begin{array}{c}{\frac{\partial f(\boldsymbol{x})}{\partial x_{1}}} \\ {\frac{\partial f(\boldsymbol{x})}{\partial x_{2}}} \\ {\vdots} \\ {\frac{\partial f(\boldsymbol{x})}{\partial x_{n}}}\end{array}\right]
|
|
|
+$$
|
|
|
+
|
|
|
+为函数$f(\boldsymbol{x})$在$\boldsymbol{x}$处的一阶导数或梯度,易证梯度指向的方向是函数值增大速度最快的方向。$\nabla f(\boldsymbol{x})$也可写成行向量形式
|
|
|
+
|
|
|
+$$
|
|
|
+\nabla f(\boldsymbol{x})=\frac{\partial f(\boldsymbol{x})}{\partial \boldsymbol{x}^\mathrm{T}}=\left[{\frac{\partial f(\boldsymbol{x})}{\partial x_{1}}}, {\frac{\partial f(\boldsymbol{x})}{\partial x_{2}}},{\cdots},{\frac{\partial f(\boldsymbol{x})}{\partial x_{n}}}\right]
|
|
|
+$$
|
|
|
+
|
|
|
+我们称列向量形式为"分母布局",行向量形式为"分子布局",由于在最优化中习惯采用分母布局,因此"西瓜书"以及本书中也采用分母布局。为了便于区分当前采用何种布局,通常在采用分母布局时偏导符号$\partial$后接的是$\boldsymbol{x}$,采用分子布局时后接的是$\boldsymbol{x}^\mathrm{T}$。
|
|
|
+
|
|
|
+**Hessian矩阵**:若$n$元函数$f(\boldsymbol{x})$对$\boldsymbol{x}=(x_{1};x_{2};...;x_{n})$中各分量$x_{i}$的二阶偏导数$\frac{\partial^{2} f(\boldsymbol{x})}{\partial x_{i} \partial x_{j}}(i=1,2,...,n;j=1,2,...,n)$都存在,则称函数$f(\boldsymbol{x})$在$\boldsymbol{x}$处二阶阶可导,并称以下矩阵
|
|
|
+
|
|
|
+$$
|
|
|
+\nabla^2f(\boldsymbol x)=\frac{\partial^{2}f(\boldsymbol{x})}{\partial\boldsymbol{x}\partial\boldsymbol{x}^\mathrm{T}}=\left[ \begin{array}{cccc}{\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{1}^{2}}} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{1} \partial x_{2}}} & {\cdots} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{1} \partial x_{n}}} \\ {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{2} \partial x_{1}}} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{2}^{2}}} & {\cdots} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{2} \partial x_{n}}} \\ {\vdots} & {\vdots} & {\ddots} & {\vdots} \\ {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{n} \partial x_{1}}} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{n} \partial x_{2}}} & {\cdots} & {\frac{\partial^{2} f(\boldsymbol x)}{\partial x_{n}^{2}}}\end{array}\right]
|
|
|
+$$
|
|
|
+
|
|
|
+为函数$f(\boldsymbol{x})$在$\boldsymbol{x}$处的二阶导数或Hessian矩阵。若其中的二阶偏导数均连续,则
|
|
|
+
|
|
|
+$$
|
|
|
+\frac{\partial^{2} f(\boldsymbol{x})}{\partial x_{i} \partial x_{j}}=\frac{\partial^{2} f(\boldsymbol{x})}{\partial x_{j} \partial x_{i}}
|
|
|
+$$
|
|
|
+
|
|
|
+此时Hessian矩阵为对称矩阵。
|
|
|
+
|
|
|
+**定理3.1**:设$D\subset\mathbb{R}^n$是非空开凸集,$f(\boldsymbol{x})$是定义在$D$上的实值函数,且$f(\boldsymbol{x})$在$D$上二阶连续可微,如果$f(\boldsymbol{x})$的Hessian矩阵$\nabla^2f(\boldsymbol x)$在$D$上是半正定的,则$f(\boldsymbol{x})$是$D$上的凸函数;如果$\nabla^2f(\boldsymbol x)$在$D$上是正定的,则$f(\boldsymbol{x})$是$D$上的严格凸函数。
|
|
|
+
|
|
|
+**定理3.2**:若$f(\boldsymbol{x})$是凸函数,且$f(\boldsymbol{x})$一阶连续可微,则$\boldsymbol{x}^*$是全局解的充分必要条件是其梯度等于零向量,即$\nabla f(\boldsymbol x^*)=\boldsymbol{0}$。
|
|
|
+
|
|
|
+式(3.11)的推导思路如下:首先根据定理3.1推导出$E_{\hat{\boldsymbol{w}}}$是$\hat{\boldsymbol{w}}$的凸函数,接着根据定理3.2推导出式(3.11)。下面按照此思路进行推导。
|
|
|
+
|
|
|
+由于式(3.10)已推导出$E_{\hat{\boldsymbol{w}}}$关于$\hat{\boldsymbol{w}}$的一阶导数,接着基于此进一步推导出二阶导数,即Hessian矩阵。推导过程如下:
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\nabla^2E_{\hat{\boldsymbol{w}}} &= \frac{\partial}{\partial \hat{\boldsymbol w}^\mathrm{T}}\left(\frac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}\right)\\
|
|
|
+&=\frac{\partial}{\partial \hat{\boldsymbol w}^\mathrm{T}}\left[2\mathbf{X}^\mathrm{T}(\mathbf{X}\hat{\boldsymbol{w}}-\boldsymbol{y})\right]\\
|
|
|
+&=\frac{\partial}{\partial \hat{\boldsymbol{w}}^\mathrm{T}}\left( 2\mathbf{X}^\mathrm{T}\mathbf{X}\hat{\boldsymbol{w}}-2\mathbf{X}^\mathrm{T}\boldsymbol{y}\right)
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+由矩阵微分公式$\frac{\partial \mathbf{A}\boldsymbol{x}}{\boldsymbol{x}^\mathrm{T}}=\mathbf{A}$可得
|
|
|
+
|
|
|
+$$
|
|
|
+\nabla^2E_{\hat{\boldsymbol{w}}}=2\mathbf{X}^\mathrm{T}\mathbf{X}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+如"西瓜书"中式(3.11)上方的一段话所说,假定$\mathbf{X}^\mathrm{T}\mathbf{X}$为正定矩阵,根据定理3.1可知此时$E_{\hat{\boldsymbol{w}}}$是$\hat{\boldsymbol{w}}$的严格凸函数,接着根据定理3.2可知只需令$E_{\hat{\boldsymbol{w}}}$关于$\hat{\boldsymbol{w}}$的一阶导数等于零向量,即令式(3.10)等于零向量即可求得全局最优解$\hat{\boldsymbol{w}}^{*}$,具体求解过程如下:
|
|
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+
|
|
|
+$$
|
|
|
+\frac{\partial E_{\hat{\boldsymbol w}}}{\partial \hat{\boldsymbol w}}=2\mathbf{X}^\mathrm{T}(\mathbf{X}\hat{\boldsymbol{w}}-\boldsymbol{y})=\boldsymbol{0}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
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|
+2\mathbf{X}^\mathrm{T}\mathbf{X}\hat{\boldsymbol{w}}-2\mathbf{X}^\mathrm{T}\boldsymbol{y}=\boldsymbol{0}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+2\mathbf{X}^\mathrm{T}\mathbf{X}\hat{\boldsymbol{w}}=2\mathbf{X}^\mathrm{T}\boldsymbol{y}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\hat{\boldsymbol{w}}=(\mathbf{X}^\mathrm{T}\mathbf{X})^{-1}\mathbf{X}^\mathrm{T}\boldsymbol{y}
|
|
|
+$$
|
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|
+
|
|
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+令其为$\hat{\boldsymbol{w}}^{*}$即为式(3.11)。
|
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+
|
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+由于$\mathbf{X}$是由样本构成的矩阵,而样本是千变万化的,因此无法保证$\mathbf{X}^\mathrm{T}\mathbf{X}$一定是正定矩阵,极易出现非正定的情形。当$\mathbf{X}^\mathrm{T}\mathbf{X}$非正定矩阵时,除了"西瓜书"中所说的引入正则化外,也可用$\mathbf{X}^\mathrm{T}\mathbf{X}$的伪逆矩阵代入式(3.11)求解出$\hat{\boldsymbol{w}}^{*}$,只是此时并不保证求解得到的$\hat{\boldsymbol{w}}^{*}$一定是全局最优解。除此之外,也可用下一节将会讲到的"梯度下降法"求解,同样也不保证求得全局最优解。
|
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+
|
|
|
+## 3.3 对数几率回归
|
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+
|
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+对数几率回归的一般使用流程如下:首先在训练集上学得模型
|
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+
|
|
|
+$$
|
|
|
+y=\frac{1}{1+e^{-\left(\boldsymbol{w}^\mathrm{T}\boldsymbol{x}+b\right)}}
|
|
|
+$$
|
|
|
+
|
|
|
+然后对于新的测试样本$\boldsymbol{x}_{i}$,将其代入模型得到预测结果$y_{i}$,接着自行设定阈值$\theta$,通常设为$\theta=0.5$,如果$y_{i}\geqslant\theta$则判$\boldsymbol{x}_{i}$为正例,反之判为反例。
|
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+
|
|
|
+### 3.3.1 式(3.27)的推导
|
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+
|
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+将式(3.26)代入式(3.25)可得
|
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+
|
|
|
+$$
|
|
|
+\ell(\boldsymbol{\beta})=\sum_{i=1}^{m}\ln\left(y_ip_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})+(1-y_i)p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)
|
|
|
+$$
|
|
|
+
|
|
|
+其中$p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})=\frac{e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}},p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})=\frac{1}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}$,代入上式可得
|
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+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\ell(\boldsymbol{\beta})&=\sum_{i=1}^{m}\ln\left(\frac{y_ie^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}+1-y_i}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}\right) \\
|
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|
&=\sum_{i=1}^{m}\left(\ln(y_ie^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}+1-y_i)-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})\right)
|
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|
-\end{aligned}$$
|
|
|
-由于$ y_i $=0或1,则
|
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|
-$$ \ell(\boldsymbol{\beta}) =
|
|
|
+\end{aligned}
|
|
|
+$$
|
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|
+
|
|
|
+由于$y_i$=0或1,则
|
|
|
+
|
|
|
+$$
|
|
|
+\ell(\boldsymbol{\beta}) =
|
|
|
\begin{cases}
|
|
|
\sum_{i=1}^{m}(-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})), & y_i=0 \\
|
|
|
\sum_{i=1}^{m}(\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})), & y_i=1
|
|
|
-\end{cases} $$
|
|
|
+\end{cases}
|
|
|
+$$
|
|
|
+
|
|
|
两式综合可得
|
|
|
-$$ \ell(\boldsymbol{\beta})=\sum_{i=1}^{m}\left(y_i\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})\right) $$
|
|
|
-由于此式仍为极大似然估计的似然函数,所以最大化似然函数等价于最小化似然函数的相反数,也即在似然函数前添加负号即可得公式(3.27)。值得一提的是,若将公式(3.26)这个似然项改写为$p(y_i|\boldsymbol x_i;\boldsymbol w,b)=[p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{y_i}[p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{1-y_i}$,再将其代入公式(3.25)可得
|
|
|
-$$\begin{aligned}
|
|
|
+
|
|
|
+$$
|
|
|
+\ell(\boldsymbol{\beta})=\sum_{i=1}^{m}\left(y_i\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})\right)
|
|
|
+$$
|
|
|
+
|
|
|
+由于此式仍为极大似然估计的似然函数,所以最大化似然函数等价于最小化似然函数的相反数,即在似然函数前添加负号即可得式(3.27)。值得一提的是,若将式(3.26)改写为$p(y_i|\boldsymbol x_i;\boldsymbol w,b)=[p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{y_i}[p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{1-y_i}$,再代入式(3.25)可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
\ell(\boldsymbol{\beta})&=\sum_{i=1}^{m}\ln\left([p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{y_i}[p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})]^{1-y_i}\right) \\
|
|
|
&=\sum_{i=1}^{m}\left[y_i\ln\left(p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)+(1-y_i)\ln\left(p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)\right] \\
|
|
|
&=\sum_{i=1}^{m} \left \{ y_i\left[\ln\left(p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)-\ln\left(p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)\right]+\ln\left(p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)\right\} \\
|
|
|
-&=\sum_{i=1}^{m}\left[y_i\ln\left(\cfrac{p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})}{p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})}\right)+\ln\left(p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)\right] \\
|
|
|
-&=\sum_{i=1}^{m}\left[y_i\ln\left(e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}\right)+\ln\left(\cfrac{1}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}\right)\right] \\
|
|
|
+&=\sum_{i=1}^{m}\left[y_i\ln\left(\frac{p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})}{p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})}\right)+\ln\left(p_0(\hat{\boldsymbol x}_i;\boldsymbol{\beta})\right)\right] \\
|
|
|
+&=\sum_{i=1}^{m}\left[y_i\ln\left(e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}\right)+\ln\left(\frac{1}{1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i}}\right)\right] \\
|
|
|
&=\sum_{i=1}^{m}\left(y_i\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i-\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})\right)
|
|
|
-\end{aligned}$$
|
|
|
-显然,此种方式更易推导出公式(3.27)
|
|
|
-
|
|
|
-## 3.30
|
|
|
-$$\frac{\partial \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta}}=-\sum_{i=1}^{m}\hat{\boldsymbol x}_i(y_i-p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta}))$$
|
|
|
-[解析]:此式可以进行向量化,令$p_1(\hat{\boldsymbol x}_i;\boldsymbol{\beta})=\hat{y}_i$,代入上式得
|
|
|
-$$\begin{aligned}
|
|
|
-\frac{\partial \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta}} &= -\sum_{i=1}^{m}\hat{\boldsymbol x}_i(y_i-\hat{y}_i) \\
|
|
|
-& =\sum_{i=1}^{m}\hat{\boldsymbol x}_i(\hat{y}_i-y_i) \\
|
|
|
-& ={\mathbf{X}^{\mathrm{T}}}(\hat{\boldsymbol y}-\boldsymbol{y}) \\
|
|
|
-& ={\mathbf{X}^{\mathrm{T}}}(p_1(\mathbf{X};\boldsymbol{\beta})-\boldsymbol{y}) \\
|
|
|
-\end{aligned}$$
|
|
|
-
|
|
|
-## 3.32
|
|
|
-$$J=\cfrac{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w}$$
|
|
|
-[推导]:
|
|
|
-$$\begin{aligned}
|
|
|
- J &= \cfrac{\|\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{0}-\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{1}\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
- &= \cfrac{\|(\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{0}-\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{1})^{\mathrm{T}}\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
- &= \cfrac{\|(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
- &= \cfrac{\left[(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w\right]^{\mathrm{T}}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
- &= \cfrac{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w}
|
|
|
-\end{aligned}$$
|
|
|
-
|
|
|
-## 3.37
|
|
|
-$$\mathbf{S}_b\boldsymbol w=\lambda\mathbf{S}_w\boldsymbol w$$
|
|
|
-[推导]:由公式(3.36)可得拉格朗日函数为
|
|
|
-$$L(\boldsymbol w,\lambda)=-\boldsymbol w^{\mathrm{T}}\mathbf{S}_b\boldsymbol w+\lambda(\boldsymbol w^{\mathrm{T}}\mathbf{S}_w\boldsymbol w-1)$$
|
|
|
-对$\boldsymbol w$求偏导可得
|
|
|
-$$\begin{aligned}
|
|
|
-\cfrac{\partial L(\boldsymbol w,\lambda)}{\partial \boldsymbol w} &= -\cfrac{\partial(\boldsymbol w^{\mathrm{T}}\mathbf{S}_b\boldsymbol w)}{\partial \boldsymbol w}+\lambda \cfrac{\partial(\boldsymbol w^{\mathrm{T}}\mathbf{S}_w\boldsymbol w-1)}{\partial \boldsymbol w} \\
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+显然,此种方式更易推导出式(3.27)。
|
|
|
+
|
|
|
+"西瓜书"在式(3.27)下方有提到式(3.27)是关于$\boldsymbol{\beta}$的凸函数,其证明过程如下:由于若干半正定矩阵的加和仍为半正定矩阵,则根据定理3.1可知,若干凸函数的加和仍为凸函数。因此,只需证明式(3.27)求和符号后的式子$-y_i\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i+\ln(1+e^{\boldsymbol{\beta}^{\mathrm{T}}\hat{\boldsymbol x}_i})$(记为$f(\boldsymbol{\beta})$)为凸函数即可。根据式(3.31)可知,$f(\boldsymbol{\beta})$的二阶导数,即Hessian矩阵为
|
|
|
+
|
|
|
+$$
|
|
|
+\hat{\boldsymbol{x}}_{i} \hat{\boldsymbol{x}}_{i}^\mathrm{T} p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\left(1-p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\right)
|
|
|
+$$
|
|
|
+
|
|
|
+对于任意非零向量$\boldsymbol{y}\in\mathbb{R}^{d+1}$,恒有
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{y}^\mathrm{T}\cdot\hat{\boldsymbol{x}}_{i} \hat{\boldsymbol{x}}_{i}^\mathrm{T} p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\left(1-p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\right)\cdot\boldsymbol{y}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{y}^\mathrm{T}\hat{\boldsymbol{x}}_{i} \hat{\boldsymbol{x}}_{i}^\mathrm{T}\boldsymbol{y} p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\left(1-p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\right)
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\left(\boldsymbol{y}^\mathrm{T}\hat{\boldsymbol{x}}_{i}\right)^2 p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\left(1-p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\right)
|
|
|
+$$
|
|
|
+
|
|
|
+由于$p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)>0$,因此上式恒大于等于0,根据半正定矩阵的定义可知此时$f(\boldsymbol{\beta})$的Hessian矩阵为半正定矩阵,所以$f(\boldsymbol{\beta})$是关于$\boldsymbol{\beta}$的凸函数。
|
|
|
+
|
|
|
+### 3.3.2 梯度下降法
|
|
|
+
|
|
|
+不同于式(3.7)可求得闭式解,式(3.27)中的$\boldsymbol{\beta}$没有闭式解,因此需要借助其他工具进行求解。求解使得式(3.27)取到最小值的$\boldsymbol{\beta}$属于最优化中的"无约束优化问题",在无约束优化问题中最常用的求解算法有"梯度下降法"和"牛顿法"[1],下面分别展开讲解。
|
|
|
+
|
|
|
+梯度下降法是一种迭代求解算法,其基本思路如下:先在定义域中随机选取一个点$\boldsymbol{x}^{0}$,将其代入函数$f(\boldsymbol{x})$并判断此时$f(\boldsymbol{x}^{0})$是否是最小值,如果不是的话,则找下一个点$\boldsymbol{x}^{1}$,且保证$f(\boldsymbol{x}^{1})<f(\boldsymbol{x}^{0})$,然后接着判断$f(\boldsymbol{x}^{1})$是否是最小值,如果不是的话则重复上述步骤继续迭代寻找$\boldsymbol{x}^{2}$、$\boldsymbol{x}^{3}$、\...\...直到找到使得$f(\boldsymbol{x})$取到最小值的$\boldsymbol{x}^{*}$。
|
|
|
+
|
|
|
+显然,此算法要想行得通就必须解决在找到第$t$个点$\boldsymbol{x}^{t}$时,能进一步找到第$t+1$个点$\boldsymbol{x}^{t+1}$,且保证$f(\boldsymbol{x}^{t+1})<f(\boldsymbol{x}^{t})$。梯度下降法利用"梯度指向的方向是函数值增大速度最快的方向"这一特性,每次迭代时朝着梯度的反方向进行,进而实现函数值越迭代越小,下面给出完整的数学推导过程。
|
|
|
+
|
|
|
+根据泰勒公式可知,当函数$f(\boldsymbol{x})$在$\boldsymbol{x}^{t}$处一阶可导时,在其邻域内进行一阶泰勒展开恒有
|
|
|
+
|
|
|
+$$
|
|
|
+f(\boldsymbol{x})=f\left(\boldsymbol{x}^{t}\right)+\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)+o\left(\left\|\boldsymbol{x}-\boldsymbol{x}^{t}\right\|\right)
|
|
|
+$$
|
|
|
+
|
|
|
+其中$\nabla f\left(\boldsymbol{x}^{t}\right)$是函数$f(\boldsymbol{x})$在点$\boldsymbol{x}^{t}$处的梯度,$\left\|\boldsymbol{x}-\boldsymbol{x}^{t}\right\|$是指向量$\boldsymbol{x}-\boldsymbol{x}^{t}$的模。若令$\boldsymbol{x}-\boldsymbol{x}^{t}=a\boldsymbol{d}^{t}$,其中$a>0$,$\boldsymbol{d}^{t}$是模长为1的单位向量,则上式可改写为
|
|
|
+
|
|
|
+$$
|
|
|
+f(\boldsymbol{x}^{t}+a\boldsymbol{d}^{t})=f\left(\boldsymbol{x}^{t}\right)+a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}+o\left(\left\|\boldsymbol{d}^{t}\right\|\right)
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+f(\boldsymbol{x}^{t}+a\boldsymbol{d}^{t})-f\left(\boldsymbol{x}^{t}\right)=a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}+o\left(\left\|\boldsymbol{d}^{t}\right\|\right)
|
|
|
+$$
|
|
|
+
|
|
|
+观察上式可知,如果能保证$a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}<0$,则一定能保证$f(\boldsymbol{x}^{t}+a\boldsymbol{d}^{t})<f\left(\boldsymbol{x}^{t}\right)$,此时再令$\boldsymbol{x}^{t+1}=\boldsymbol{x}^{t}+a\boldsymbol{d}^{t}$,即可推得我们想要的$f(\boldsymbol{x}^{t+1})<f(\boldsymbol{x}^{t})$。所以,此时问题转化为了求解能使得$a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}<0$的$\boldsymbol{d}^t$,且$a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}$比0越小,相应地$f(\boldsymbol{x}^{t+1})$也会比$f(\boldsymbol{x}^{t})$越小,也更接近最小值。
|
|
|
+
|
|
|
+根据向量的内积公式可知
|
|
|
+
|
|
|
+$$
|
|
|
+a\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\boldsymbol{d}^{t}=a\times\|\nabla f\left(\boldsymbol{x}^{t}\right)\|\times\|\boldsymbol{d}^{t}\|\times\cos\theta^{t}
|
|
|
+$$
|
|
|
+
|
|
|
+其中$\theta^{t}$是向量$\nabla f\left(\boldsymbol{x}^{t}\right)$与向量$\boldsymbol{d}^{t}$之间的夹角。观察上式易知,此时$\|\nabla f\left(\boldsymbol{x}^{t}\right)\|$是固定常量,$\|\boldsymbol{d}^{t}\|=1$,所以当$a$也固定时,取$\theta^{t}=\pi$,即向量$\boldsymbol{d}^t$与向量$\nabla f\left(\boldsymbol{x}^{t}\right)$的方向刚好相反时,上式取到最小值。通常为了精简计算步骤,可直接令$\boldsymbol{d}^t=-\nabla f\left(\boldsymbol{x}^{t}\right)$,因此便得到了第$t+1$个点$\boldsymbol{x}^{t+1}$的迭代公式
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{x}^{t+1}=\boldsymbol{x}^{t}-a\nabla f\left(\boldsymbol{x}^{t}\right)
|
|
|
+$$
|
|
|
+
|
|
|
+其中$a$也称为"步长"或"学习率",是需要自行设定的参数,且每次迭代时可取不同值。
|
|
|
+
|
|
|
+除了需要解决如何找到$\boldsymbol{x}^{t+1}$以外,梯度下降法通常还需要解决如何判断当前点是否使得函数取到了最小值,否则的话迭代过程便可能会无休止进行。常用的做法是预先设定一个极小的阈值$\epsilon$,当某次迭代造成的函数值波动已经小于$\epsilon$时,即$|f(\boldsymbol{x}^{t+1})-f(\boldsymbol{x}^{t})|<\epsilon$,我们便近似地认为此时$f(\boldsymbol{x}^{t+1})$取到了最小值。
|
|
|
+
|
|
|
+### 3.3.3 牛顿法
|
|
|
+
|
|
|
+同梯度下降法,牛顿法也是一种迭代求解算法,其基本思路和梯度下降法一致,只是在选取第$t+1$个点$\boldsymbol{x}^{t+1}$时所采用的策略有所不同,即迭代公式不同。梯度下降法每次选取$\boldsymbol{x}^{t+1}$时,只要求通过泰勒公式在$\boldsymbol{x}^{t}$的邻域内找到一个函数值比其更小的点即可,而牛顿法则期望在此基础之上,$\boldsymbol{x}^{t+1}$还必须是$\boldsymbol{x}^{t}$的邻域内的极小值点。
|
|
|
+
|
|
|
+类似一元函数取到极值点的必要条件是一阶导数等于0,多元函数取到极值点的必要条件是其梯度等于零向量$\boldsymbol{0}$,为了能求解出$\boldsymbol{x}^{t}$的邻域内梯度等于$\boldsymbol{0}$的点,需要进行二阶泰勒展开,其展开式如下
|
|
|
+
|
|
|
+$$
|
|
|
+f(\boldsymbol{x}) = f\left(\boldsymbol{x}^{t}\right)+\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)+\frac{1}{2}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)^{\mathrm{T}} \nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)+o\left(\left\|\boldsymbol{x}-\boldsymbol{x}^{t}\right\|\right)
|
|
|
+$$
|
|
|
+
|
|
|
+为了后续计算方便,我们取其近似形式
|
|
|
+
|
|
|
+$$
|
|
|
+f(\boldsymbol{x}) \approx f\left(\boldsymbol{x}^{t}\right)+\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)+\frac{1}{2}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)^{\mathrm{T}} \nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)
|
|
|
+$$
|
|
|
+
|
|
|
+首先对上式求导
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial f(\boldsymbol{x})}{\partial \boldsymbol{x}}&=\frac{\partial f\left(\boldsymbol{x}^{t}\right)}{\partial \boldsymbol{x}}+\frac{\partial\nabla f\left(\boldsymbol{x}^{t}\right)^{\mathrm{T}}\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)}{\partial \boldsymbol{x}}+\frac{1}{2}\frac{\partial\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)^{\mathrm{T}} \nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)}{\partial \boldsymbol{x}} \\
|
|
|
+&=0+\nabla f\left(\boldsymbol{x}^{t}\right)+\frac{1}{2}\left(\nabla^{2} f\left(\boldsymbol{x}^{t}\right)+\nabla^{2} f\left(\boldsymbol{x}^{t}\right)^\mathrm{T}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+假设函数$f(\boldsymbol{x})$在$\boldsymbol{x}^{t}$处二阶可导,且偏导数连续,则$\nabla^{2} f\left(\boldsymbol{x}^{t}\right)$是对称矩阵,上式可写为
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial f(\boldsymbol{x})}{\partial \boldsymbol{x}}&=0+\nabla f\left(\boldsymbol{x}^{t}\right)+\frac{1}{2}\times2\times\nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)\\
|
|
|
+&=\nabla f\left(\boldsymbol{x}^{t}\right)+\nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+令上式等于$\boldsymbol{0}$
|
|
|
+
|
|
|
+$$
|
|
|
+\nabla f\left(\boldsymbol{x}^{t}\right)+\nabla^{2} f\left(\boldsymbol{x}^{t}\right)\left(\boldsymbol{x}-\boldsymbol{x}^{t}\right)=\boldsymbol{0}
|
|
|
+$$
|
|
|
+
|
|
|
+当$\nabla^{2} f\left(\boldsymbol{x}^{t}\right)$是可逆矩阵时,解得
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{x}=\boldsymbol{x}^{t}-\left[\nabla^{2} f\left(\boldsymbol{x}^{t}\right)\right]^{-1}\nabla f\left(\boldsymbol{x}^{t}\right)
|
|
|
+$$
|
|
|
+
|
|
|
+令上式为$\boldsymbol{x}^{t+1}$即可得到牛顿法的迭代公式
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{x}^{t+1}=\boldsymbol{x}^{t}-\left[\nabla^{2} f\left(\boldsymbol{x}^{t}\right)\right]^{-1}\nabla f\left(\boldsymbol{x}^{t}\right)
|
|
|
+$$
|
|
|
+
|
|
|
+通过上述推导可知,牛顿法每次迭代时需要求解Hessian矩阵的逆矩阵,该步骤计算量通常较大,因此有人基于牛顿法,将其中求Hessian矩阵的逆矩阵改为求计算量更低的近似逆矩阵,我们称此类算法为"拟牛顿法"。
|
|
|
+
|
|
|
+牛顿法虽然期望在每次迭代时能取到极小值点,但是通过上述推导可知,迭代公式是根据极值点的必要条件推导而得,因此并不保证一定是极小值点。
|
|
|
+
|
|
|
+无论是梯度下降法还是牛顿法,根据其终止迭代的条件可知,其都是近似求解算法,即使$f(\boldsymbol{x})$是凸函数,也并不一定保证最终求得的是全局最优解,仅能保证其接近全局最优解。不过在解决实际问题时,并不一定苛求解得全局最优解,在能接近全局最优甚至局部最优时通常也能很好地解决问题。
|
|
|
+
|
|
|
+### 3.3.4 式(3.29)的解释
|
|
|
+
|
|
|
+根据上述牛顿法的迭代公式可知,此式为式(3.27)应用牛顿法时的迭代公式。
|
|
|
+
|
|
|
+### 3.3.5 式(3.30)的推导
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta}} &=\frac{\partial \sum_{i=1}^{m}\left(-y_{i} \boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}+\ln \left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)\right)}{\partial \boldsymbol{\beta}} \\
|
|
|
+&=\sum_{i=1}^{m}\left(\frac{\partial\left(-y_{i} \boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}\right)}{\partial \boldsymbol{\beta}}+\frac{\partial \ln \left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)}{\partial \boldsymbol{\beta}}\right) \\
|
|
|
+&=\sum_{i=1}^{m}\left(-y_{i} \hat{\boldsymbol{x}}_{i}+\frac{1}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}} \cdot \hat{\boldsymbol{x}}_{i} e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right) \\
|
|
|
+&=-\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\left(y_{i}-\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}\right) \\
|
|
|
+&=-\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\left(y_{i}-p_{1}\left(\hat{\boldsymbol{x}}_{i} ; \boldsymbol{\beta}\right)\right)
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+此式也可以进行向量化,令$p_1(\hat{\boldsymbol{x}}_i;\boldsymbol{\beta})=\hat{y}_i$,代入上式得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta}} &= -\sum_{i=1}^{m}\hat{\boldsymbol{x}}_i(y_i-\hat{y}_i) \\
|
|
|
+& =\sum_{i=1}^{m}\hat{\boldsymbol{x}}_i(\hat{y}_i-y_i) \\
|
|
|
+& ={\mathbf{X}^{\mathrm{T}}}(\hat{\boldsymbol{y}}-\boldsymbol{y}) \\
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+其中$\hat{\boldsymbol{y}}=(\hat{y}_{1};\hat{y}_{2};...;\hat{y}_{m}),\boldsymbol{y}=(y_{1};y_{2};...;y_{m})$。
|
|
|
+
|
|
|
+### 3.3.6 式(3.31)的推导
|
|
|
+
|
|
|
+继续对上述式(3.30)中倒数第二个等号的结果求导
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial^{2} \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta} \partial \boldsymbol{\beta}^\mathrm{T}} &=-\frac{\partial \sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\left(y_{i}-\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}} \\
|
|
|
+&=-\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i} \frac{\partial\left(y_{i}-\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}} \\
|
|
|
+&=-\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\left(\frac{\partial y_{i}}{\partial \boldsymbol{\beta}^\mathrm{T}}-\frac{\partial\left(\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}}\right) \\
|
|
|
+&=\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\cdot\frac{\partial\left(\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}} \\
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+根据矩阵微分公式$\frac{\partial\boldsymbol{a}^{\mathrm{T}}\boldsymbol{x}}{\partial\boldsymbol{x}^\mathrm{T}}=\frac{\partial\boldsymbol{x}^{\mathrm{T}}\boldsymbol{a}}{\partial\boldsymbol{x}^\mathrm{T}}=\boldsymbol{a}^\mathrm{T}$,其中
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial\left(\frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}} &=\frac{\frac{\partial e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{\partial \boldsymbol{\beta}^\mathrm{T}} \cdot\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)-e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}} \cdot \frac{\partial\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)}{\partial \boldsymbol{\beta}^\mathrm{T}}}{\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)^{2}} \\
|
|
|
+&=\frac{\hat{\boldsymbol{x}}_{i}^\mathrm{T} e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}} \cdot\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)-e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}} \cdot \hat{\boldsymbol{x}}_{i}^\mathrm{T} e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)^{2}} \\
|
|
|
+&=\hat{\boldsymbol{x}}_{i}^\mathrm{T} e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\cdot\frac{\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)-e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)^{2}} \\
|
|
|
+&=\hat{\boldsymbol{x}}_{i}^\mathrm{T} e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\cdot\frac{1}{\left(1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}\right)^{2}} \\
|
|
|
+&=\hat{\boldsymbol{x}}_{i}^\mathrm{T} \cdot \frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}} \cdot \frac{1}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+所以
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial^{2} \ell(\boldsymbol{\beta})}{\partial \boldsymbol{\beta} \partial \boldsymbol{\beta}^\mathrm{T}} &=\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i}\cdot\hat{\boldsymbol{x}}_{i}^\mathrm{T} \cdot \frac{e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}} \cdot \frac{1}{1+e^{\boldsymbol{\beta}^\mathrm{T} \hat{\boldsymbol{x}}_{i}}} \\
|
|
|
+&=\sum_{i=1}^{m} \hat{\boldsymbol{x}}_{i} \hat{\boldsymbol{x}}_{i}^\mathrm{T} p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\left(1-p_{1}\left(\hat{\boldsymbol{x}}_{i};\boldsymbol{\beta}\right)\right)
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+## 3.4 线性判别分析
|
|
|
+
|
|
|
+线性判别分析的一般使用流程如下:首先在训练集上学得模型
|
|
|
+
|
|
|
+$$
|
|
|
+y=\boldsymbol{w}^\mathrm{T}\boldsymbol{x}
|
|
|
+$$
|
|
|
+
|
|
|
+由向量内积的几何意义可知,$y$可以看作是$\boldsymbol{x}$在$\boldsymbol{w}$上的投影,因此在训练集上学得的模型能够保证训练集中的同类样本在$\boldsymbol{w}$上的投影$y$很相近,而异类样本在$\boldsymbol{w}$上的投影$y$很疏远。然后对于新的测试样本$\boldsymbol{x}_{i}$,将其代入模型得到它在$\boldsymbol{w}$上的投影$y_{i}$,然后判别这个投影$y_{i}$与哪一类投影更近,则将其判为该类。
|
|
|
+
|
|
|
+最后,线性判别分析也是一种降维方法,但不同于第10章介绍的无监督降维方法,线性判别分析是一种监督降维方法,即降维过程中需要用到样本类别标记信息。
|
|
|
+
|
|
|
+### 3.4.1 式(3.32)的推导
|
|
|
+
|
|
|
+式(3.32)中$\|\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{0}-\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{1}\|_2^2$右下角的"2"表示求"2范数",向量的2范数即为模,右上角的"2"表示求平方数,基于此,下面推导式(3.32)。
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+ J &= \frac{\|\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{0}-\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{1}\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
+ &= \frac{\|(\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{0}-\boldsymbol w^{\mathrm{T}}\boldsymbol{\mu}_{1})^{\mathrm{T}}\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
+ &= \frac{\|(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w\|_2^2}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
+ &= \frac{\left[(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w\right]^{\mathrm{T}}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w} \\
|
|
|
+ &= \frac{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol w}{\boldsymbol w^{\mathrm{T}}(\boldsymbol{\Sigma}_{0}+\boldsymbol{\Sigma}_{1})\boldsymbol w}
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+### 3.4.2 式(3.37)到式(3.39)的推导
|
|
|
+
|
|
|
+由式(3.36),可定义拉格朗日函数为
|
|
|
+
|
|
|
+$$
|
|
|
+L(\boldsymbol w,\lambda)=-\boldsymbol w^{\mathrm{T}}\mathbf{S}_b\boldsymbol w+\lambda(\boldsymbol w^{\mathrm{T}}\mathbf{S}_w\boldsymbol w-1)
|
|
|
+$$
|
|
|
+
|
|
|
+对$\boldsymbol w$求偏导可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial L(\boldsymbol w,\lambda)}{\partial \boldsymbol w} &= -\frac{\partial(\boldsymbol w^{\mathrm{T}}\mathbf{S}_b\boldsymbol w)}{\partial \boldsymbol w}+\lambda \frac{\partial(\boldsymbol w^{\mathrm{T}}\mathbf{S}_w\boldsymbol w-1)}{\partial \boldsymbol w} \\
|
|
|
&= -(\mathbf{S}_b+\mathbf{S}_b^{\mathrm{T}})\boldsymbol w+\lambda(\mathbf{S}_w+\mathbf{S}_w^{\mathrm{T}})\boldsymbol w
|
|
|
-\end{aligned}$$
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
由于$\mathbf{S}_b=\mathbf{S}_b^{\mathrm{T}},\mathbf{S}_w=\mathbf{S}_w^{\mathrm{T}}$,所以
|
|
|
-$$\cfrac{\partial L(\boldsymbol w,\lambda)}{\partial \boldsymbol w} = -2\mathbf{S}_b\boldsymbol w+2\lambda\mathbf{S}_w\boldsymbol w$$
|
|
|
+
|
|
|
+$$
|
|
|
+\frac{\partial L(\boldsymbol w,\lambda)}{\partial \boldsymbol w} = -2\mathbf{S}_b\boldsymbol w+2\lambda\mathbf{S}_w\boldsymbol w
|
|
|
+$$
|
|
|
+
|
|
|
令上式等于0即可得
|
|
|
-$$-2\mathbf{S}_b\boldsymbol w+2\lambda\mathbf{S}_w\boldsymbol w=0$$
|
|
|
-$$\mathbf{S}_b\boldsymbol w=\lambda\mathbf{S}_w\boldsymbol w$$
|
|
|
-$$(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol{w}=\lambda\mathbf{S}_w\boldsymbol w$$
|
|
|
-若令$(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol{w}=\gamma$,则
|
|
|
-$$\gamma(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})=\lambda\mathbf{S}_w\boldsymbol w$$
|
|
|
-$$\boldsymbol{w}=\frac{\gamma}{\lambda}\mathbf{S}_{w}^{-1}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})$$
|
|
|
-由于最终要求解的$\boldsymbol{w}$不关心其大小,只关心其方向,所以其大小可以任意取值。由于$\boldsymbol{\mu}_{0}$和$\boldsymbol{\mu}_{1}$的大小是固定的,所以$\gamma$这个标量的大小只受$\boldsymbol{w}$的大小影响,因此可以调整$\boldsymbol{w}$的大小使得$\gamma=\lambda$,西瓜书中所说的“不妨令$\mathbf{S}_b\boldsymbol w=\lambda(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})$”也等价于令$\gamma=\lambda$,因此,此时$\frac{\gamma}{\lambda}=1$,求解出的$\boldsymbol{w}$即为公式(3.39)
|
|
|
-
|
|
|
-## 3.38
|
|
|
-$$\mathbf{S}_b\boldsymbol{w}=\lambda(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})$$
|
|
|
-[推导]:参见公式(3.37)
|
|
|
-
|
|
|
-## 3.39
|
|
|
-$$\boldsymbol{w}=\mathbf{S}_{w}^{-1}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})$$
|
|
|
-[推导]:参见公式(3.37)
|
|
|
-
|
|
|
-## 3.43
|
|
|
-$$\begin{aligned}
|
|
|
-\mathbf{S}_b &= \mathbf{S}_t - \mathbf{S}_w \\
|
|
|
-&= \sum_{i=1}^N m_i(\boldsymbol\mu_i-\boldsymbol\mu)(\boldsymbol\mu_i-\boldsymbol\mu)^{\mathrm{T}}
|
|
|
-\end{aligned}$$
|
|
|
-[推导]:由公式(3.40)、公式(3.41)、公式(3.42)可得:
|
|
|
-$$\begin{aligned}
|
|
|
+
|
|
|
+$$
|
|
|
+-2\mathbf{S}_b\boldsymbol w+2\lambda\mathbf{S}_w\boldsymbol w=0
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\mathbf{S}_b\boldsymbol w=\lambda\mathbf{S}_w\boldsymbol w
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol{w}=\lambda\mathbf{S}_w\boldsymbol w
|
|
|
+$$
|
|
|
+
|
|
|
+若令$(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})^{\mathrm{T}}\boldsymbol{w}=\gamma$,则有
|
|
|
+
|
|
|
+$$
|
|
|
+\gamma(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})=\lambda\mathbf{S}_w\boldsymbol w
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\boldsymbol{w}=\frac{\gamma}{\lambda}\mathbf{S}_{w}^{-1}(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})
|
|
|
+$$
|
|
|
+
|
|
|
+由于最终要求解的$\boldsymbol{w}$不关心其大小,只关心其方向,所以其大小可以任意取值。又因为$\boldsymbol{\mu}_{0}$和$\boldsymbol{\mu}_{1}$的大小是固定的,所以$\gamma$的大小只受$\boldsymbol{w}$的大小影响,因此可以通过调整$\boldsymbol{w}$的大小使得$\gamma=\lambda$,西瓜书中所说的"不妨令$\mathbf{S}_b\boldsymbol w=\lambda(\boldsymbol{\mu}_{0}-\boldsymbol{\mu}_{1})$"也可等价理解为令$\gamma=\lambda$,因此,此时$\frac{\gamma}{\lambda}=1$,求解出的$\boldsymbol{w}$即为式(3.39)。
|
|
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+
|
|
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+### 3.4.3 式(3.43)的推导
|
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+
|
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+由式(3.40)、式(3.41)、式(3.42)可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
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|
\mathbf{S}_b &= \mathbf{S}_t - \mathbf{S}_w \\
|
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|
&= \sum_{i=1}^m(\boldsymbol x_i-\boldsymbol\mu)(\boldsymbol x_i-\boldsymbol\mu)^{\mathrm{T}}-\sum_{i=1}^N\sum_{\boldsymbol x\in X_i}(\boldsymbol x-\boldsymbol\mu_i)(\boldsymbol x-\boldsymbol\mu_i)^{\mathrm{T}} \\
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&= \sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left((\boldsymbol x-\boldsymbol\mu)(\boldsymbol x-\boldsymbol\mu)^{\mathrm{T}}-(\boldsymbol x-\boldsymbol\mu_i)(\boldsymbol x-\boldsymbol\mu_i)^{\mathrm{T}}\right)\right) \\
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|
&= \sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left((\boldsymbol x-\boldsymbol\mu)(\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu^{\mathrm{T}})-(\boldsymbol x-\boldsymbol\mu_i)(\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu_i^{\mathrm{T}})\right)\right) \\
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-&= \sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left(\boldsymbol x\boldsymbol x^{\mathrm{T}} - \boldsymbol x\boldsymbol\mu^{\mathrm{T}}-\boldsymbol\mu\boldsymbol x^{\mathrm{T}}+\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}-\boldsymbol x\boldsymbol x^{\mathrm{T}}+\boldsymbol x\boldsymbol\mu_i^{\mathrm{T}}+\boldsymbol\mu_i\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right)\right) \\
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-&= \sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left(- \boldsymbol x\boldsymbol\mu^{\mathrm{T}}-\boldsymbol\mu\boldsymbol x^{\mathrm{T}}+\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+\boldsymbol x\boldsymbol\mu_i^{\mathrm{T}}+\boldsymbol\mu_i\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right)\right) \\
|
|
|
+&= \sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left(\boldsymbol x\boldsymbol x^{\mathrm{T}} - \boldsymbol x\boldsymbol\mu^{\mathrm{T}}-\boldsymbol\mu\boldsymbol x^{\mathrm{T}}+\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}-\boldsymbol x\boldsymbol x^{\mathrm{T}}+\boldsymbol x\boldsymbol\mu_i^{\mathrm{T}}+\boldsymbol\mu_i\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right)\right)\\
|
|
|
+&=\sum_{i=1}^N\left(\sum_{\boldsymbol x\in X_i}\left(- \boldsymbol x\boldsymbol\mu^{\mathrm{T}}-\boldsymbol\mu\boldsymbol x^{\mathrm{T}}+\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+\boldsymbol x\boldsymbol\mu_i^{\mathrm{T}}+\boldsymbol\mu_i\boldsymbol x^{\mathrm{T}}-\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right)\right) \\
|
|
|
&= \sum_{i=1}^N\left(-\sum_{\boldsymbol x\in X_i}\boldsymbol x\boldsymbol\mu^{\mathrm{T}}-\sum_{\boldsymbol x\in X_i}\boldsymbol\mu\boldsymbol x^{\mathrm{T}}+\sum_{\boldsymbol x\in X_i}\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+\sum_{\boldsymbol x\in X_i}\boldsymbol x\boldsymbol\mu_i^{\mathrm{T}}+\sum_{\boldsymbol x\in X_i}\boldsymbol\mu_i\boldsymbol x^{\mathrm{T}}-\sum_{\boldsymbol x\in X_i}\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right) \\
|
|
|
&= \sum_{i=1}^N\left(-m_i\boldsymbol\mu_i\boldsymbol\mu^{\mathrm{T}}-m_i\boldsymbol\mu\boldsymbol\mu_i^{\mathrm{T}}+m_i\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+m_i\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}+m_i\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}-m_i\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right) \\
|
|
|
&= \sum_{i=1}^N\left(-m_i\boldsymbol\mu_i\boldsymbol\mu^{\mathrm{T}}-m_i\boldsymbol\mu\boldsymbol\mu_i^{\mathrm{T}}+m_i\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+m_i\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right) \\
|
|
|
&= \sum_{i=1}^Nm_i\left(-\boldsymbol\mu_i\boldsymbol\mu^{\mathrm{T}}-\boldsymbol\mu\boldsymbol\mu_i^{\mathrm{T}}+\boldsymbol\mu\boldsymbol\mu^{\mathrm{T}}+\boldsymbol\mu_i\boldsymbol\mu_i^{\mathrm{T}}\right) \\
|
|
|
&= \sum_{i=1}^N m_i(\boldsymbol\mu_i-\boldsymbol\mu)(\boldsymbol\mu_i-\boldsymbol\mu)^{\mathrm{T}}
|
|
|
-\end{aligned}$$
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+### 3.4.4 式(3.44)的推导
|
|
|
+
|
|
|
+此式是式(3.35)的推广形式,证明如下。
|
|
|
|
|
|
-## 3.44
|
|
|
-$$\max\limits_{\mathbf{W}}\cfrac{
|
|
|
-\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})}{\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})}$$
|
|
|
-[解析]:此式是公式(3.35)的推广形式,证明如下:
|
|
|
设$\mathbf{W}=(\boldsymbol w_1,\boldsymbol w_2,...,\boldsymbol w_i,...,\boldsymbol w_{N-1})\in\mathbb{R}^{d\times(N-1)}$,其中$\boldsymbol w_i\in\mathbb{R}^{d\times 1}$为$d$行1列的列向量,则
|
|
|
-$$\left\{
|
|
|
+
|
|
|
+$$
|
|
|
+\left\{
|
|
|
\begin{aligned}
|
|
|
\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})&=\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_b \boldsymbol w_i \\
|
|
|
\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})&=\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_w \boldsymbol w_i
|
|
|
\end{aligned}
|
|
|
-\right.$$
|
|
|
-所以公式(3.44)可变形为
|
|
|
-$$\max\limits_{\mathbf{W}}\cfrac{
|
|
|
-\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_b \boldsymbol w_i}{\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_w \boldsymbol w_i}$$
|
|
|
-对比公式(3.35)易知上式即公式(3.35)的推广形式
|
|
|
-
|
|
|
-## 3.45
|
|
|
-$$\mathbf{S}_b\mathbf{W}=\lambda\mathbf{S}_w\mathbf{W}$$
|
|
|
-[推导]:同公式(3.35)一样,我们在此处也固定公式(3.44)的分母为1,那么公式(3.44)此时等价于如下优化问题
|
|
|
-$$\begin{array}{cl}\underset{\boldsymbol{w}}{\min} & -\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W}) \\
|
|
|
-\text { s.t. } & \operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})=1\end{array}$$
|
|
|
-根据拉格朗日乘子法可知,上述优化问题的拉格朗日函数为
|
|
|
-$$L(\mathbf{W},\lambda)=-\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})+\lambda(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})-1)$$
|
|
|
-根据矩阵微分公式$\cfrac{\partial}{\partial \mathbf{X}} \text { tr }(\mathbf{X}^{\mathrm{T}} \mathbf{B} \mathbf{X})=(\mathbf{B}+\mathbf{B}^{\mathrm{T}})\mathbf{X}$对上式关于$\mathbf{W}$求偏导可得
|
|
|
-$$\begin{aligned}
|
|
|
-\cfrac{\partial L(\mathbf{W},\lambda)}{\partial \mathbf{W}} &= -\cfrac{\partial\left(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})\right)}{\partial \mathbf{W}}+\lambda \cfrac{\partial\left(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})-1\right)}{\partial \mathbf{W}} \\
|
|
|
+\right.
|
|
|
+$$
|
|
|
+
|
|
|
+所以式(3.44)可变形为
|
|
|
+
|
|
|
+$$
|
|
|
+\max\limits_{\mathbf{W}}\frac{
|
|
|
+\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_b \boldsymbol w_i}{\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_w \boldsymbol w_i}
|
|
|
+$$
|
|
|
+
|
|
|
+对比式(3.35)易知,上式即式(3.35)的推广形式。
|
|
|
+
|
|
|
+除了式(3.35)以外,还有一种常见的优化目标形式如下
|
|
|
+
|
|
|
+$$
|
|
|
+\max\limits_{\mathbf{W}}\frac{
|
|
|
+\prod_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_b \boldsymbol w_i}{\prod_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_w \boldsymbol w_i}=\max\limits_{\mathbf{W}}\prod_{i=1}^{N-1}\frac{\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_b \boldsymbol w_i}{\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_w \boldsymbol w_i}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+无论是采用何种优化目标形式,其优化目标只要满足"同类样例的投影点尽可能接近,异类样例的投影点尽可能远离"即可。
|
|
|
+
|
|
|
+### 3.4.5 式(3.45)的推导
|
|
|
+
|
|
|
+同式(3.35),此处也固定式(3.44)的分母为1,那么式(3.44)此时等价于如下优化问题
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{array}{cl}\underset{\mathbf{w}}{\min} & -\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W}) \\
|
|
|
+\text { s.t. } & \operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})=1\end{array}
|
|
|
+$$
|
|
|
+
|
|
|
+根据拉格朗日乘子法,可定义上述优化问题的拉格朗日函数
|
|
|
+
|
|
|
+$$
|
|
|
+L(\mathbf{W},\lambda)=-\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})+\lambda(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})-1)
|
|
|
+$$
|
|
|
+
|
|
|
+根据矩阵微分公式$\frac{\partial}{\partial \mathbf{X}} \text { tr }(\mathbf{X}^{\mathrm{T}} \mathbf{B} \mathbf{X})=(\mathbf{B}+\mathbf{B}^{\mathrm{T}})\mathbf{X}$对上式关于$\mathbf{W}$求偏导可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial L(\mathbf{W},\lambda)}{\partial \mathbf{W}} &= -\frac{\partial\left(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})\right)}{\partial \mathbf{W}}+\lambda \frac{\partial\left(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})-1\right)}{\partial \mathbf{W}} \\
|
|
|
&= -(\mathbf{S}_b+\mathbf{S}_b^{\mathrm{T}})\mathbf{W}+\lambda(\mathbf{S}_w+\mathbf{S}_w^{\mathrm{T}})\mathbf{W}
|
|
|
-\end{aligned}$$
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
由于$\mathbf{S}_b=\mathbf{S}_b^{\mathrm{T}},\mathbf{S}_w=\mathbf{S}_w^{\mathrm{T}}$,所以
|
|
|
-$$\cfrac{\partial L(\mathbf{W},\lambda)}{\partial \mathbf{W}} = -2\mathbf{S}_b\mathbf{W}+2\lambda\mathbf{S}_w\mathbf{W}$$
|
|
|
+
|
|
|
+$$
|
|
|
+\frac{\partial L(\mathbf{W},\lambda)}{\partial \mathbf{W}} = -2\mathbf{S}_b\mathbf{W}+2\lambda\mathbf{S}_w\mathbf{W}
|
|
|
+$$
|
|
|
+
|
|
|
令上式等于$\mathbf{0}$即可得
|
|
|
-$$-2\mathbf{S}_b\mathbf{W}+2\lambda\mathbf{S}_w\mathbf{W}=\mathbf{0}$$
|
|
|
-$$\mathbf{S}_b\mathbf{W}=\lambda\mathbf{S}_w\mathbf{W}$$
|
|
|
+
|
|
|
+$$
|
|
|
+-2\mathbf{S}_b\mathbf{W}+2\lambda\mathbf{S}_w\mathbf{W}=\mathbf{0}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\mathbf{S}_b\mathbf{W}=\lambda\mathbf{S}_w\mathbf{W}
|
|
|
+$$
|
|
|
+
|
|
|
+此即为式(3.45),但是此式在解释为何要取$N-1$个最大广义特征值所对应的特征向量来构成$\mathbf{W}$时不够直观。因此,我们换一种更为直观的方式求解式(3.44),只需换一种方式构造拉格朗日函数即可。
|
|
|
+
|
|
|
+重新定义上述优化问题的拉格朗日函数
|
|
|
+
|
|
|
+$$
|
|
|
+L(\mathbf{W},\boldsymbol{\Lambda})=-\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})+\operatorname{tr}\left(\boldsymbol{\Lambda}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W}-\mathbf{I})\right)
|
|
|
+$$
|
|
|
+
|
|
|
+其中,$\mathbf{I} \in \mathbb{R}^{(N-1) \times (N-1)}$为单位矩阵,$\boldsymbol{\Lambda}=\operatorname{diag}(\lambda_1,\lambda_2,...,\lambda_{N-1})\in \mathbb{R}^{(N-1) \times (N-1)}$是由$N-1$个拉格朗日乘子构成的对角矩阵。根据矩阵微分公式$\frac{\partial}{\partial \mathbf{X}} \operatorname{tr}(\mathbf{X}^{\mathrm{T}}\mathbf{A}\mathbf{X})=(\mathbf{A}+\mathbf{A}^{\mathrm{T}})\mathbf{X},\frac{\partial}{\partial \mathbf{X}} \operatorname{tr}(\mathbf{X}\mathbf{A}\mathbf{X}^\mathrm{T}\mathbf{B})=\frac{\partial}{\partial \mathbf{X}} \operatorname{tr}(\mathbf{A}\mathbf{X}^\mathrm{T}\mathbf{B}\mathbf{X})=\mathbf{B}^\mathrm{T}\mathbf{X}\mathbf{A}^\mathrm{T}+\mathbf{B}\mathbf{X}\mathbf{A}$,对上式关于$\mathbf{W}$求偏导可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\frac{\partial L(\mathbf{W},\boldsymbol{\Lambda})}{\partial \mathbf{W}} &= -\frac{\partial\left(\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_b \mathbf{W})\right)}{\partial \mathbf{W}}+\frac{\partial\left(\operatorname{tr}\left(\boldsymbol{\Lambda}\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W}-\boldsymbol{\Lambda}\mathbf{I}\right)\right)}{\partial \mathbf{W}} \\
|
|
|
+&= -(\mathbf{S}_b+\mathbf{S}_b^{\mathrm{T}})\mathbf{W}+(\mathbf{S}_{w}^\mathrm{T}\mathbf{W}\boldsymbol{\Lambda}^\mathrm{T}+\mathbf{S}_w\mathbf{W}\boldsymbol{\Lambda})
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+由于$\mathbf{S}_b=\mathbf{S}_b^{\mathrm{T}},\mathbf{S}_w=\mathbf{S}_w^{\mathrm{T}},\boldsymbol{\Lambda}^\mathrm{T}=\boldsymbol{\Lambda}$,所以
|
|
|
+
|
|
|
+$$
|
|
|
+\frac{\partial L(\mathbf{W},\boldsymbol{\Lambda})}{\partial \mathbf{W}} = -2\mathbf{S}_b\mathbf{W}+2\mathbf{S}_w\mathbf{W}\boldsymbol{\Lambda}
|
|
|
+$$
|
|
|
+
|
|
|
+令上式等于$\mathbf{0}$即可得
|
|
|
+
|
|
|
+$$
|
|
|
+-2\mathbf{S}_b\mathbf{W}+2\mathbf{S}_w\mathbf{W}\boldsymbol{\Lambda}=\mathbf{0}
|
|
|
+$$
|
|
|
+
|
|
|
+
|
|
|
+$$
|
|
|
+\mathbf{S}_b\mathbf{W}=\mathbf{S}_w\mathbf{W}\boldsymbol{\Lambda}
|
|
|
+$$
|
|
|
+
|
|
|
+将$\mathbf{W}$和$\boldsymbol{\Lambda}$展开可得
|
|
|
+
|
|
|
+$$
|
|
|
+\mathbf{S}_b\boldsymbol{w}_i=\lambda_{i}\mathbf{S}_w\boldsymbol{w}_i, \quad i=1,2,...,N-1
|
|
|
+$$
|
|
|
+
|
|
|
+此时便得到了$N-1$个广义特征值问题。进一步地,将其代入优化问题的目标函数可得
|
|
|
+
|
|
|
+$$
|
|
|
+\begin{aligned}
|
|
|
+\underset{\mathbf{W}}{\min}-\operatorname{ tr }(\mathbf W^{\mathrm{T}} \mathbf{S}_{b} \mathbf W)&=\max\limits_{\mathbf W}\operatorname{ tr }(\mathbf W^{\mathrm{T}} \mathbf{S}_{b} \mathbf W) \\
|
|
|
+&=\max\limits_{\mathbf W}\sum_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_{b} \boldsymbol w_i \\
|
|
|
+&=\max\limits_{\mathbf W}\sum_{i=1}^{N-1}\lambda_{i}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_{w} \boldsymbol w_i
|
|
|
+\end{aligned}
|
|
|
+$$
|
|
|
+
|
|
|
+由于存在约束$\operatorname{tr}(\mathbf{W}^{\mathrm{T}}\mathbf{S}_w \mathbf{W})=\sum\limits_{i=1}^{N-1}\boldsymbol w_i^{\mathrm{T}}\mathbf{S}_{w} \boldsymbol w_i=1$,所以欲使上式取到最大值,只需取$N-1$个最大的$\lambda_{i}$即可。根据$\mathbf{S}_b\boldsymbol{w}_i=\lambda_{i}\mathbf{S}_w\boldsymbol{w}_i$可知,$\lambda_{i}$对应的便是广义特征值,$\boldsymbol{w}_i$是$\lambda_{i}$所对应的特征向量。**(广义特征值的定义和常用求解方法可查阅[3])**
|
|
|
+
|
|
|
+对于$N$分类问题,一定要求出$N-1$个$\boldsymbol{w}_{i}$吗?其实不然。之所以将$\mathbf{W}$定义为$d\times (N-1)$维的矩阵是因为当$d>(N-1)$时,实对称矩阵$\mathbf{S}_w^{-1}\mathbf{S}_b$的秩至多为$N-1$,所以理论上至多能解出$N-1$个非零特征值$\lambda_{i}$及其对应的特征向量$\boldsymbol{w}_i$。但是$\mathbf{S}_w^{-1}\mathbf{S}_b$的秩是受当前训练集中的数据分布所影响的,因此并不一定为$N-1$。此外,当数据分布本身就足够理想时,即使能求解出多个$\boldsymbol{w}_i$,但是实际可能只需要求解出1个$\boldsymbol{w}_i$便可将同类样本聚集,异类样本完全分离。
|
|
|
+
|
|
|
+当$d>(N-1)$时,实对称矩阵$\mathbf{S}_w^{-1}\mathbf{S}_b$的秩至多为$N-1$的证明过程如下:由于$\boldsymbol{\mu}=\frac{1}{N}\sum\limits_{i=1}^{N}m_i\boldsymbol{\mu}_i$,所以$\boldsymbol{\mu}_1-\boldsymbol{\mu}$一定可以由$\boldsymbol{\mu}$和$\boldsymbol{\mu}_2,...,\boldsymbol{\mu}_N$线性表示,因此矩阵$\mathbf{S}_b$中至多有$\boldsymbol{\mu}_2-\boldsymbol{\mu},...,\boldsymbol{\mu}_N-\boldsymbol{\mu}$共$N-1$个线性无关的向量,由于此时$d> (N-1)$,所以$\mathbf{S}_b$的秩$r(\mathbf{S}_b)$至多为$N-1$。同时假设矩阵$\mathbf{S}_w$满秩,即$r(\mathbf{S}_w)=r(\mathbf{S}_w^{-1})=d$,则根据矩阵秩的性质$r(\mathbf{A}\mathbf{B})\leqslant\min\{r(\mathbf{A}),r(\mathbf{B})\}$可知,$\mathbf{S}_w^{-1}\mathbf{S}_b$的秩也至多为$N-1$。
|
|
|
+
|
|
|
+## 3.5 多分类学习
|
|
|
+
|
|
|
+### 3.5.1 图3.5的解释
|
|
|
+
|
|
|
+图3.5中所说的"海明距离"是指两个码对应位置不相同的个数,"欧式距离"则是指两个向量之间的欧氏距离,例如图3.5(a)中第1行的编码可以视作为向量$(-1, +1, -1, +1, +1)$,测试示例的编码则为$(-1, -1, +1, -1, +1)$,其中第2个、第3个、第4个元素不相同,所以它们的海明距离为3,欧氏距离为$\sqrt{(-1-(-1))^2+(1-(-1))^2+(-1-1)^2+(1-(-1))^2+(1-1)^2}=\sqrt{0+4+4+4+0}=2\sqrt{3}$。需要注意的是,在计算海明距离时,与"停用类"不同算作0.5,例如图3.5(b)中第2行的海明距离计算公式为$0.5+0.5+0.5+0.5=2$。
|
|
|
+
|
|
|
+## 3.6 类别不平衡问题
|
|
|
+
|
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+对于类别不平衡问题,"西瓜书"2.3.1节中的"精度"通常无法满足该特殊任务的需求,例如"西瓜书"在本节第一段的举例:有998个反例和2个正例,若机器学习算法返回一个永远将新样本预测为反例的学习器则能达到99.8%的精度,显然虚高,因此在类别不平衡时常采用2.3节中的查准率、查全率和F1来度量学习器的性能。
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+
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+## 参考文献
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+[1] 王燕军. 最优化基础理论与方法. 复旦大学出版社, 2011.
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+
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+[2] Wikipedia contributors. Matrix calculus, 2022.
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+
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+[3] 张贤达. 矩阵分析与应用. 第 2 版. 清华大学出版社, 2013.
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