作用：去均值和方差归一化。且是针对每一个特征维度来做的，而不是针对样本。
【注：】
并不是所有的标准化都能给estimator带来好处。
“Standardization of a dataset is a common requirement for many machine learning estimators: they might behave badly if the individual feature do not more or less look like standard normally distributed data (e.g. Gaussian with 0 mean and unit variance).”

实例代码

# coding=utf-8

# 统计训练集的 mean 和　std 信息

from sklearn.preprocessing import StandardScaler

import numpy as np

def test_algorithm():

    np.random.seed(123)

    print('use sklearn')

    # 注：shape of data: [n_samples, n_features]

    data = np.random.randn(10, 4)

    scaler = StandardScaler()

    scaler.fit(data)

    trans_data = scaler.transform(data)

    print('original data: ')

    print data

    print('transformed data: ')

    print trans_data

    print('scaler info: scaler.mean_: {}, scaler.var_: {}'.format(scaler.mean_, scaler.var_))

    print('\n')

    print('use numpy by self')

    mean = np.mean(data, axis=0)

    std = np.std(data, axis=0)

    var = std * std

    print('mean: {}, std: {}, var: {}'.format(mean, std, var))

    # numpy 的广播功能

    another_trans_data = data - mean

    # 注：是除以标准差

    another_trans_data = another_trans_data / std

    print('another_trans_data: ')

    print another_trans_data

if __name__ == '__main__':

    test_algorithm()

程序的输出如下：

use sklearn

    original data:

    [[-1.0856306   0.99734545  0.2829785 - 1.50629471]

     [-0.57860025  1.65143654 - 2.42667924 - 0.42891263]

    [1.26593626 - 0.8667404 - 0.67888615 - 0.09470897]

    [1.49138963 - 0.638902 - 0.44398196 - 0.43435128]

    [2.20593008

    2.18678609

    1.0040539

    0.3861864]

    [0.73736858  1.49073203 - 0.93583387  1.17582904]

    [-1.25388067 - 0.6377515

    0.9071052 - 1.4286807]

    [-0.14006872 - 0.8617549 - 0.25561937 - 2.79858911]

    [-1.7715331 - 0.69987723

    0.92746243 - 0.17363568]

    [0.00284592  0.68822271 - 0.87953634  0.28362732]]

    transformed

    data:

    [[-0.94511643  0.58665507  0.5223171 - 0.93064483]

     [-0.53659117  1.16247784 - 2.13366794  0.06768082]

    [0.9495916 - 1.05437488 - 0.42049501

    0.3773612]

    [1.13124423 - 0.85379954 - 0.19024378  0.06264126]

    [1.70696485

    1.63376764

    1.22910949

    0.8229693]

    [0.52371324  1.02100318 - 0.67235312  1.55466934]

    [-1.08067913 - 0.85278672

    1.13408114 - 0.858726]

    [-0.18325687 - 1.04998594 - 0.00561227 - 2.1281129]

    [-1.49776284 - 0.9074785

    1.15403514

    0.30422599]

    [-0.06810748  0.31452186 - 0.61717074  0.72793583]]

    scaler info: scaler.mean_: [0.08737571  0.33094968 - 0.24989369 - 0.50195303], scaler.var_: [1.54038781  1.29032409

                                                                                          1.04082479  1.16464894]

    use numpy by self

    mean: [0.08737571  0.33094968 - 0.24989369 - 0.50195303], std: [1.24112361  1.13592433  1.02020821

                                                                    1.07918902], var: [1.54038781  1.29032409

                                                                                       1.04082479  1.16464894]

    another_trans_data:

    [[-0.94511643  0.58665507  0.5223171 - 0.93064483]

     [-0.53659117  1.16247784 - 2.13366794  0.06768082]

    [0.9495916 - 1.05437488 - 0.42049501

    0.3773612]

    [1.13124423 - 0.85379954 - 0.19024378  0.06264126]

    [1.70696485

    1.63376764

    1.22910949

    0.8229693]

    [0.52371324  1.02100318 - 0.67235312  1.55466934]

    [-1.08067913 - 0.85278672

    1.13408114 - 0.858726]

    [-0.18325687 - 1.04998594 - 0.00561227 - 2.1281129]

    [-1.49776284 - 0.9074785

    1.15403514

    0.30422599]

    [-0.06810748  0.31452186 - 0.61717074  0.72793583]]