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-## 16.2
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-$$
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-Q_{n}(k)=\frac{1}{n}\left((n-1)\times Q_{n-1}(k)+v_{n}\right)
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-$$
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-
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-[推导]:
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-$$
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-Q_{n}(k)=\frac{1}{n}\sum_{i=1}^{n}v_{i}=\frac{1}{n}\left(\sum_{i=1}^{n-1}v_{i}+v_{n}\right)=\frac{1}{n}\left((n-1)Q_{n-1}(k)+v_{n}\right)
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-$$
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-
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-## 16.4
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-
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-$$
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-P(k)=\frac{e^{\frac{Q(k)}{\tau }}}{\sum_{i=1}^{K}e^{\frac{Q(i)}{\tau}}}
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-$$
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-
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-$$
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-\tau越小则平均奖赏高的摇臂被选取的概率越高
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-$$
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-
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-[解析]:
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-$$
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-P(k)=\frac{e^{\frac{Q(k)}{\tau }}}{\sum_{i=1}^{K}e^{\frac{Q(i)}{\tau}}}\propto e^{\frac{Q(k)}{\tau }}\propto\frac{Q(k)}{\tau }\propto\frac{1}{\tau}
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-$$
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-
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-## 16.7
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-
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-$$
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-\begin{aligned}
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-V_{T}^{\pi}(x)&=\mathbb{E}_{\pi}[\frac{1}{T}\sum_{t=1}^{T}r_{t}\mid x_{0}=x]\\
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-&=\mathbb{E}_{\pi}[\frac{1}{T}r_{1}+\frac{T-1}{T}\frac{1}{T-1}\sum_{t=2}^{T}r_{t}\mid x_{0}=x]\\
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-&=\sum_{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(\frac{1}{T}R_{x\rightarrow x{}'}^{a}+\frac{T-1}{T}\mathbb{E}_{\pi}[\frac{1}{T-1}\sum_{t=1}^{T-1}r_{t}\mid x_{0}=x{}'])\\
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-&=\sum_{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(\frac{1}{T}R_{x\rightarrow x{}'}^{a}+\frac{T-1}{T}V_{T-1}^{\pi}(x{}')])
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-\end{aligned}
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-$$
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-
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-[解析]:
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-
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-因为
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-$$
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-\pi(x,a)=P(state=x\mid action=a)
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-$$
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-表示在状态 **x**下选择动作 **a**的概率,
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-
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-又因为动作事件之间两两互斥且和为动作空间,由全概率展开公式
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-$$
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-P(A)=\sum_{i=1}^{\infty}P(B_{i})P(A\mid B_{i})
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-$$
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-可得
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-$$
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-\begin{aligned}
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-&=\mathbb{E}_{\pi}[\frac{1}{T}r_{1}+\frac{T-1}{T}\frac{1}{T-1}\sum_{t=2}^{T}r_{t}\mid x_{0}=x]\\
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-&=\sum_{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(\frac{1}{T}R_{x\rightarrow x{}'}^{a}+\frac{T-1}{T}\mathbb{E}_{\pi}[\frac{1}{T-1}\sum_{t=1}^{T-1}r_{t}\mid x_{0}=x{}'])
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-\end{aligned}
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-$$
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-其中
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-$$
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-r_{1}=\pi(x,a)P_{x\rightarrow x{}'}^{a}R_{x\rightarrow x{}'}^{a}
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-$$
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-最后一个等式用到了递归形式。
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-
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-
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-
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-## 16.8
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-
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-$$
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-V_{\gamma }^{\pi}(x)=\sum _{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(R_{x\rightarrow x{}'}^{a}+\gamma V_{\gamma }^{\pi}(x{}'))
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-$$
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-
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-[推导]:
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-$$
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-\begin{aligned}
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-V_{\gamma }^{\pi}(x)&=\mathbb{E}_{\pi}[\sum_{t=0}^{\infty }\gamma^{t}r_{t+1}\mid x_{0}=x]\\
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-&=\mathbb{E}_{\pi}[r_{1}+\sum_{t=1}^{\infty}\gamma^{t}r_{t+1}\mid x_{0}=x]\\
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-&=\mathbb{E}_{\pi}[r_{1}+\gamma\sum_{t=1}^{\infty}\gamma^{t-1}r_{t+1}\mid x_{0}=x]\\
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-&=\sum _{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(R_{x\rightarrow x{}'}^{a}+\gamma \mathbb{E}_{\pi}[\sum_{t=0}^{\infty }\gamma^{t}r_{t+1}\mid x_{0}=x{}'])\\
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-&=\sum _{a\in A}\pi(x,a)\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{a}(R_{x\rightarrow x{}'}^{a}+\gamma V_{\gamma }^{\pi}(x{}'))
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-\end{aligned}
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-$$
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-
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-## 16.16
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-
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-$$
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-V^{\pi}(x)\leq V^{\pi{}'}(x)
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-$$
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-
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-[推导]:
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-$$
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-\begin{aligned}
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-V^{\pi}(x)&\leq Q^{\pi}(x,\pi{}'(x))\\
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-&=\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{\pi{}'(x)}(R_{x\rightarrow x{}'}^{\pi{}'(x)}+\gamma V^{\pi}(x{}'))\\
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-&\leq \sum_{x{}'\in X}P_{x\rightarrow x{}'}^{\pi{}'(x)}(R_{x\rightarrow x{}'}^{\pi{}'(x)}+\gamma Q^{\pi}(x{}',\pi{}'(x{}')))\\
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-&=\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{\pi{}'(x)}(R_{x\rightarrow x{}'}^{\pi{}'(x)}+\gamma \sum_{x{}'\in X}P_{x{}'\rightarrow x{}'}^{\pi{}'(x{}')}(R_{x{}'\rightarrow x{}'}^{\pi{}'(x{}')}+\gamma V^{\pi}(x{}')))\\
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-&=\sum_{x{}'\in X}P_{x\rightarrow x{}'}^{\pi{}'(x)}(R_{x\rightarrow x{}'}^{\pi{}'(x)}+\gamma V^{\pi{}'}(x{}'))\\
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-&=V^{\pi{}'}(x)
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-\end{aligned}
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-$$
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-其中,使用了动作改变条件
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-$$
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-Q^{\pi}(x,\pi{}'(x))\geq V^{\pi}(x)
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-$$
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-以及状态-动作值函数
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-$$
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-Q^{\pi}(x{}',\pi{}'(x{}'))=\sum_{x{}'\in X}P_{x{}'\rightarrow x{}'}^{\pi{}'(x{}')}(R_{x{}'\rightarrow x{}'}^{\pi{}'(x{}')}+\gamma V^{\pi}(x{}'))
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-$$
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-于是,当前状态的最优值函数为
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-
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-$$
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-V^{\ast}(x)=V^{\pi{}'}(x)\geq V^{\pi}(x)
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-$$
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-
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-
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-
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-## 16.31
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-
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-$$
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-Q_{t+1}^{\pi}(x,a)=Q_{t}^{\pi}(x,a)+\alpha (R_{x\rightarrow x{}'}^{a}+\gamma Q_{t}^{\pi}(x{}',a{}')-Q_{t}^{\pi}(x,a))
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-$$
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-
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-[推导]:对比公式16.29
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-$$
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-Q_{t+1}^{\pi}(x,a)=Q_{t}^{\pi}(x,a)+\frac{1}{t+1}(r_{t+1}-Q_{t}^{\pi}(x,a))
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-$$
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-以及由
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-$$
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-\frac{1}{t+1}=\alpha
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-$$
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-可知
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-$$
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-r_{t+1}=R_{x\rightarrow x{}'}^{a}+\gamma Q_{t}^{\pi}(x{}',a{}')
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-$$
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-而由γ折扣累积奖赏可估计得到。
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-
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