在详细了解神经网络中梯度消失与梯度爆炸的原理之前,先来回顾一下如下基本公式:
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\begin{aligned} &\mathbf{E}(\boldsymbol{X} * \boldsymbol{Y})=\boldsymbol{E}(\boldsymbol{X}) * \boldsymbol{E}(\boldsymbol{Y})\\ &\mathrm{D}(\boldsymbol{X})=\boldsymbol{E}\left(\mathrm{X}^{2}\right)-[\boldsymbol{E}(\boldsymbol{X})]^{2}\\ &\mathbf{D}(\boldsymbol{X}+\boldsymbol{Y})=\boldsymbol{D}(\boldsymbol{X})+\boldsymbol{D}(\boldsymbol{Y}) \end{aligned}
E ( X ∗ Y ) = E ( X ) ∗ E ( Y ) D ( X ) = E ( X 2 ) − [ E ( X ) ] 2 D ( X + Y ) = D ( X ) + D ( Y )
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\mathrm{D}(\mathrm{X} * \mathrm{Y})=\mathrm{D}(\mathrm{X}) * \mathrm{D}(\mathrm{Y})+\mathrm{D}(\mathrm{X}) *[\boldsymbol{E}(\boldsymbol{Y})]^{2}+\mathrm{D}(\mathrm{Y}) *[\boldsymbol{E}(\boldsymbol{X})]^{2}
D ( X ∗ Y ) = D ( X ) ∗ D ( Y ) + D ( X ) ∗ [ E ( Y ) ] 2 + D ( Y ) ∗ [ E ( X ) ] 2
面对如下结构的神经网络:
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\begin{aligned} \Delta \mathrm{W}_{2} &=\frac{\partial L \text { oss }}{\partial \mathrm{W}_{2}}=\frac{\partial L \text { oss }}{\partial o u t} * \frac{\partial o u t}{\partial H_{2}} * \frac{\partial H_{2}}{\partial w_{2}} \\ &=\frac{\partial L o s s}{\partial o u t} * \frac{\partial o u t}{\partial H_{2}} * H_{1} \end{aligned}
Δ W 2 = ∂ W 2 ∂ L oss = ∂ o u t ∂ L oss ∗ ∂ H 2 ∂ o u t ∗ ∂ w 2 ∂ H 2 = ∂ o u t ∂ L o s s ∗ ∂ H 2 ∂ o u t ∗ H 1
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\mathrm{H}_{2}=\mathrm{H}_{1} * \mathrm{W}_{2}
H 2 = H 1 ∗ W 2
由此可见,权重矩阵
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\begin{aligned} &\mathrm{H}_{1} \rightarrow 0 \Rightarrow \Delta \mathrm{W}_{2} \rightarrow 0\\ &\mathrm{H}_{1} \rightarrow \infty \Rightarrow \Delta \mathrm{W}_{2} \rightarrow \infty \end{aligned}
H 1 → 0 ⇒ Δ W 2 → 0 H 1 → ∞ ⇒ Δ W 2 → ∞
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\mathbf{H}_{\mathbf{1 1}}=\sum_{i=\mathbf{0}}^{\mathbf{n}} \boldsymbol{X}_{\boldsymbol{i}} * \boldsymbol{W}_{\mathbf{1} i}
H 1 1 = i = 0 ∑ n X i ∗ W 1 i 基础知识中的基本公式 ,即可求得第一层隐藏层第一个节点,在(符合某种概率分布初始化的)权重计算下的值的方差:
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\begin{aligned} \mathbf{D}\left(\mathbf{H}_{\mathbf{1 1}}\right) &=\sum_{i=0}^{n} D\left(X_{i}\right) * D\left(\boldsymbol{W}_{\mathbf{1 i}}\right) \\ &=\mathbf{n} *(1 * 1) \\ &=\mathbf{n} \end{aligned}
D ( H 1 1 ) = i = 0 ∑ n D ( X i ) ∗ D ( W 1 i ) = n ∗ ( 1 ∗ 1 ) = n
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D(X * Y)=D(X) * D(Y)
D ( X ∗ Y ) = D ( X ) ∗ D ( Y )
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\operatorname{std}\left(\mathrm{H}_{1}\right)=\sqrt{\mathrm{D}\left(\mathrm{H}_{11}\right)}=\sqrt{n}
s t d ( H 1 ) = D ( H 1 1 )
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那在层数加深的时候有没有什么解决办法呢?首先考虑最简单的方法,想到每一层的输出值的方差如果能维持不变,对后面没有增长或者降低的累积效应就好了,由此考虑某层输出值的方差是否能等于1,即
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\mathbf{D}\left(\mathbf{H}_{\mathbf{1}}\right)=\boldsymbol{n} * \boldsymbol{D}(\boldsymbol{X}) * \boldsymbol{D}(\boldsymbol{W})=\mathbf{1}
D ( H 1 ) = n ∗ D ( X ) ∗ D ( W ) = 1
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D(W)=\frac{1}{n} \Rightarrow \operatorname{std}(W)=\sqrt{\frac{1}{n}}
D ( W ) = n 1 ⇒ s t d ( W ) = n 1
概要 :面向饱和激活函数例如sigmoid与tanh的初始化方法。
Xavier在其论文Understanding the difficulty of training deep feedforward neural networks中详细探讨了神经网络具有激活函数时该如何进行初始化,主要利用方差一致性 原则(也就是让每个网络层输出值的方差尽可能为1),保持数据尺度维持在恰当范围。如下是从文章中得到的公式:
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\begin{aligned} &\boldsymbol{n}_{\boldsymbol{i}} * \boldsymbol{D}(\boldsymbol{W})=\mathbf{1}\\ &\boldsymbol{n}_{\boldsymbol{i}+\boldsymbol{1}} * \boldsymbol{D}(\boldsymbol{W})=\mathbf{1}\\ &\Rightarrow D(W)=\frac{2}{n_{i}+n_{i+1}} \end{aligned}
n i ∗ D ( W ) = 1 n i + 1 ∗ D ( W ) = 1 ⇒ D ( W ) = n i + n i + 1 2
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\begin{aligned} &\boldsymbol{W} \sim \boldsymbol{U}[-\boldsymbol{a}, \boldsymbol{a}]\\ &D(W)=\frac{(-a-a)^{2}}{12}=\frac{(2 a)^{2}}{12}=\frac{a^{2}}{3}\\ &\frac{2}{n_{i}+n_{i+1}}=\frac{a^{2}}{3} \Rightarrow a=\frac{\sqrt{6}}{\sqrt{n_{i}+n_{i+1}}}\\ &\Rightarrow W \sim U\left[-\frac{\sqrt{6}}{\sqrt{n_{i}+n_{i+1}}}, \frac{\sqrt{6}}{\sqrt{n_{i}+n_{i+1}}}\right] \end{aligned}
W ∼ U [ − a , a ] D ( W ) = 1 2 ( − a − a ) 2 = 1 2 ( 2 a ) 2 = 3 a 2 n i + n i + 1 2 = 3 a 2 ⇒ a = n i + n i + 1
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D ( W ) 均匀分布 来初始化权重,即可稳定梯度。但是注意,如果是非饱和激活函数,最后数据的尺度还是会越来越大,Xavier初始化则不再适用。
Xavier初始化在pytorch中调用语句就是torch.nn.init.xavier_uniform_()
概要 :针对relu及其变种激活函数的初始化方法
同样保持了方差一致性原则,保持数据尺度维持在恰当返回,令方差为1。通过公式推导,得出权值的方差应该为:
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D(W)=\frac{2}{n_i}
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\mathrm{D}(W)=\frac{2}{\left(1+a^{2}\right) * n_{i}}
D ( W ) = ( 1 + a 2 ) ∗ n i 2
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Kaiming初始化在pytorch中的调用语句是torch.nn.init.kaiming_normal_()
除上述方法外,还有Xavier均匀分布、Xavier正态分布、kaiming均匀分布、kaiming正态分布、均匀分布、正态分布、常数分布、正交矩阵初始化、单位矩阵初始化、稀疏矩阵初始化。无论使用哪种初始化方法,其核心都是尽力使得输出值方差为1。
