2位二进制输入或非逻辑门感知器算法的实现
在机器学习领域,感知器是一种用于二元分类器的监督学习算法。感知器模型实现以下函数:
![\[ \begin{array}{c} \hat{y}=\Theta\left(w_{1} x_{1}+w_{2} x_{2}+\ldots+w_{n} x_{n}+b\right) \\ =\Theta(\mathbf{w} \cdot \mathbf{x}+b) \\ \text { where } \Theta(v)=\left\{\begin{array}{cc} 1 & \text { if } v \geqslant 0 \\ 0 & \text { otherwise } \end{array}\right. \end{array} \]](https://mangodoc.oss-cn-beijing.aliyuncs.com/geek8geeks/Implementation_of_Perceptron_Algorithm_for_NOR_Logic_Gate_with_2-bit_Binary_Input_0.png "由 QuickLaTeX.com 渲染")
对于权重向量的特定选择
和偏置参数
,模型预测输出
对于相应的输入向量
.
2位二进制变量的NOR逻辑函数真值表,即输入向量
和相应的输出
–
 |  |  |
|---|---|---|
| 0 | 0 | 1 |
| 0 | 1 | 0 |
| 1 | 0 | 0 |
| 1 | 1 | 0 |
我们可以观察到, 
现在对于相应的权重向量
输入向量的
到 OR 节点,相关的感知函数可以定义为:
![\[$\boldsymbol{\hat{y}\prime} = \Theta\left(w_{1} x_{1}+w_{2} x_{2}+b_{OR}\right)$ \]](https://mangodoc.oss-cn-beijing.aliyuncs.com/geek8geeks/Implementation_of_Perceptron_Algorithm_for_NOR_Logic_Gate_with_2-bit_Binary_Input_13.png "由 QuickLaTeX.com 渲染")
稍后,OR节点的输出
是具有权重的 NOT 节点的输入
.然后对应的输出
是 NOR 逻辑函数的最终输出,相关的感知函数可以定义为:
![\[$\boldsymbol{\hat{y}} = \Theta\left(w_{NOT} \boldsymbol{\hat{y}\prime}+b_{NOT}\right)$\]](https://mangodoc.oss-cn-beijing.aliyuncs.com/geek8geeks/Implementation_of_Perceptron_Algorithm_for_NOR_Logic_Gate_with_2-bit_Binary_Input_17.png "由 QuickLaTeX.com 渲染")
对于实现,考虑的权重参数是
和偏置参数是
.
Python实现:
# importing Python library
import numpy as np
# define Unit Step Function
def unitStep(v):
if v >= 0:
return 1
else:
return 0
# design Perceptron Model
def perceptronModel(x, w, b):
v = np.dot(w, x) + b
y = unitStep(v)
return y
# NOT Logic Function
# wNOT = -1, bNOT = 0.5
def NOT_logicFunction(x):
wNOT = -1
bNOT = 0.5
return perceptronModel(x, wNOT, bNOT)
# OR Logic Function
# w1 = 1, w2 = 1, bOR = -0.5
def OR_logicFunction(x):
w = np.array([1, 1])
bOR = -0.5
return perceptronModel(x, w, bOR)
# NOR Logic Function
# with OR and NOT
# function calls in sequence
def NOR_logicFunction(x):
output_OR = OR_logicFunction(x)
output_NOT = NOT_logicFunction(output_OR)
return output_NOT
# testing the Perceptron Model
test1 = np.array([0, 1])
test2 = np.array([1, 1])
test3 = np.array([0, 0])
test4 = np.array([1, 0])
print("NOR({}, {}) = {}".format(0, 1, NOR_logicFunction(test1)))
print("NOR({}, {}) = {}".format(1, 1, NOR_logicFunction(test2)))
print("NOR({}, {}) = {}".format(0, 0, NOR_logicFunction(test3)))
print("NOR({}, {}) = {}".format(1, 0, NOR_logicFunction(test4)))
输出:
NOR(0, 1) = 0
NOR(1, 1) = 0
NOR(0, 0) = 1
NOR(1, 0) = 0
这里,模型预测输出( 
) 每个测试输入都与 NOR 逻辑门常规输出 ( 
) 根据 2 位二进制输入的真值表。
因此,验证了 NOR 逻辑门的感知器算法是正确实现的。