Create python_numpy.py
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# _*_coding:utf-8-*_
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import numpy as np
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# 定义矩阵变量并输出变量的一些属性
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# 用np.array()生成矩阵
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arr=np.array([[1,2,3],
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[4,5,6]])
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print(arr)
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print('number of arr dimensions: ',arr.ndim)
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print('~ ~ ~ shape: ',arr.shape)
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print('~ ~ ~ size: ', arr.size)
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# 输出结果:
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[[1 2 3]
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[4 5 6]]
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number of arr dimensions: 2
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~ ~ ~ shape: (2, 3)
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~ ~ ~ size: 6
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# 定义一些特殊矩阵
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# 指定矩阵数据类型
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arr=np.array([[1,2,3],
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[4,5,6]],
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dtype=np.float64) # 我的电脑np.int是int32,还可以使用np.int32/np.int64/np.float32/np.float64
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print(arr.dtype)
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# 用np.zeros()生成全零矩阵
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arr_zeros=np.zeros( (2,3) )
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print(arr_zeros)
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# 用np.ones()生成全一矩阵
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arr_ones=np.ones( (2,3) )
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print(arr_ones)
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# 生成随机矩阵np.random.random()
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arr_random=np.random.random((2,3))
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print(arr_random)
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# 用np.arange()生成数列
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arr=np.arange(6,12)
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print(arr)
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# 用np.arange().reshape()将数列转成矩阵
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arr=np.arange(6,12).reshape( (2,3) )
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print(arr)
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# 用np.linspace(开始,结束,多少点划分线段),同样也可以用reshape()
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arr=np.linspace(1,5,3)
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print(arr)
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# 矩阵运算
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arr1=np.array([1,2,3,6])
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arr2=np.arange(4)
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# 矩阵减法,加法同理
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arr_sub=arr1-arr2
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print(arr1)
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print(arr2)
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print(arr_sub)
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# 矩阵乘法
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arr_multi=arr1**3 # 求每个元素的立方,在python中幂运算用**来表示
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print(arr_multi)
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arr_multi=arr1*arr2 # 元素逐个相乘
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print(arr_multi)
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arr_multi=np.dot(arr1, arr2.reshape((4,1))) # 维度1*4和4*1矩阵相乘
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print(arr_multi)
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arr_multi=np.dot(arr1.reshape((4,1)), arr2.reshape((1,4))) # 维度4*1和1*4矩阵相乘
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print(arr_multi)
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arr_multi=arr1.dot(arr2.reshape((4,1))) # 也可以使用矩阵名.doc(矩阵名)
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print(arr_multi)
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# 三角运算:np.sin()/np.cos()/np.tan()
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arr_sin=np.sin(arr1)
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print(arr_sin)
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# 逻辑运算
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print(arr1<3) # 查看arr1矩阵中哪些元素小于3,返回[ True True False False]
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# 矩阵求和,求矩阵最大最小值
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arr1=np.array([[1,2,3],
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[4,5,6]])
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print(arr1)
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print(np.sum(arr1)) # 矩阵求和
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print(np.sum(arr1,axis=0)) # 矩阵每列求和
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print(np.sum(arr1,axis=1).reshape(2,1)) # 矩阵每行求和
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print(np.min(arr1)) # 求矩阵最小值
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print(np.min(arr1,axis=0))
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print(np.min(arr1,axis=1))
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print(np.max(arr1)) # 求矩阵最大值
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print(np.mean(arr1)) # 输出矩阵平均值,也可以用arr1.mean()
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print(np.median(arr1)) # 输出矩阵中位数
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# 输出矩阵某些值的位置
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arr1=np.arange(2,14).reshape((3,4))
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print(arr1)
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print(np.argmin(arr1)) # 输出矩阵最小值的位置,0
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print(np.argmax(arr1)) # 输出矩阵最大值的位置,11
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print(np.cumsum(arr1)) # 输出前一个数的和,前两个数的和,等等
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print(np.diff(arr1)) # 输出相邻两个数的差值
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arr_zeros=np.zeros((3,4))
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print(np.nonzero(arr_zeros)) #输出矩阵非零元素位置,返回多个行向量,第i个行向量表示第i个维度
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print(np.nonzero(arr1))
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print(np.sort(arr1)) # 矩阵逐行排序
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print(np.transpose(arr1)) # 矩阵转置,也可以用arr1.T
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print(np.clip(arr1,5,9)) #将矩阵中小于5的数置5,大于9的数置9
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# numpy索引
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arr1=np.array([1,2,3,6])
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arr2=np.arange(2,8).reshape(2,3)
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print(arr1)
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print(arr1[0]) # 索引从0开始计数
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print(arr2)
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print(arr2[0][2]) # arr[行][列],也可以用arr[行,列]
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print(arr2[0,:]) # 用:来代表所有元素的意思
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print(arr2[0,0:3]) # 表示输出第0行,从第0列到第2列所有元素
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# 注意python索引一般是左闭右开
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# 通过for循环每次输出矩阵的一行
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for row in arr2:
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print(row)
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# 如果要每次输出矩阵的一列,就先将矩阵转置
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arr2_T=arr2.T
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print(arr2_T)
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for row in arr2_T:
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print(row)
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# 将矩阵压成一行逐个输出元素
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arr2_flat=arr2.flatten()
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print(arr2_flat)
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for i in arr2.flat: # 也可以用arr2.flatten()
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print(i)
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