标签:权重 而且 action min 获得 home http 需要 arch
在scikit-learn中,RF的分类类是RandomForestClassifier,回归类是RandomForestRegressor。当然RF的变种Extra Trees也有, 分类类ExtraTreesClassifier,回归类ExtraTreesRegressor。由于RF和Extra Trees的区别较小,调参方法基本相同,本文只关注于RF的调参。
和GBDT的调参类似,RF需要调参的参数也包括两部分,第一部分是Bagging框架的参数,第二部分是CART决策树的参数。下面我们就对这些参数做一个介绍。
首先我们关注于RF的Bagging框架的参数。这里可以和GBDT对比来学习。在scikit-learn 梯度提升树(GBDT)调参小结中我们对GBDT的框架参数做了介绍。GBDT的框架参数比较多,重要的有最大迭代器个数,步长和子采样比例,调参起来比较费力。但是RF则比较简单,这是因为bagging框架里的各个弱学习器之间是没有依赖关系的,这减小的调参的难度。换句话说,达到同样的调参效果,RF调参时间要比GBDT少一些。
下面我来看看RF重要的Bagging框架的参数,由于RandomForestClassifier和RandomForestRegressor参数绝大部分相同,这里会将它们一起讲,不同点会指出。
1) n_estimators: 也就是弱学习器的最大迭代次数,或者说最大的弱学习器的个数。一般来说n_estimators太小,容易欠拟合,n_estimators太大,计算量会太大,并且n_estimators到一定的数量后,再增大n_estimators获得的模型提升会很小,所以一般选择一个适中的数值。默认是100。
2) oob_score :即是否采用袋外样本来评估模型的好坏。默认识False。个人推荐设置为True,因为袋外分数反应了一个模型拟合后的泛化能力。
3) criterion: 即CART树做划分时对特征的评价标准。分类模型和回归模型的损失函数是不一样的。分类RF对应的CART分类树默认是基尼系数gini,另一个可选择的标准是信息增益。回归RF对应的CART回归树默认是均方差mse,另一个可以选择的标准是绝对值差mae。一般来说选择默认的标准就已经很好的。
从上面可以看出, RF重要的框架参数比较少,主要需要关注的是 n_estimators,即RF最大的决策树个数。
下面我们再来看RF的决策树参数,它要调参的参数基本和GBDT相同,如下:
1) RF划分时考虑的最大特征数max_features: 可以使用很多种类型的值,默认是"None",意味着划分时考虑所有的特征数;如果是"log2"意味着划分时最多考虑log
2) 决策树最大深度max_depth: 默认可以不输入,如果不输入的话,决策树在建立子树的时候不会限制子树的深度。一般来说,数据少或者特征少的时候可以不管这个值。如果模型样本量多,特征也多的情况下,推荐限制这个最大深度,具体的取值取决于数据的分布。常用的可以取值10-100之间。
3) 内部节点再划分所需最小样本数min_samples_split: 这个值限制了子树继续划分的条件,如果某节点的样本数少于min_samples_split,则不会继续再尝试选择最优特征来进行划分。 默认是2.如果样本量不大,不需要管这个值。如果样本量数量级非常大,则推荐增大这个值。
4) 叶子节点最少样本数min_samples_leaf: 这个值限制了叶子节点最少的样本数,如果某叶子节点数目小于样本数,则会和兄弟节点一起被剪枝。 默认是1,可以输入最少的样本数的整数,或者最少样本数占样本总数的百分比。如果样本量不大,不需要管这个值。如果样本量数量级非常大,则推荐增大这个值。
5)叶子节点最小的样本权重和min_weight_fraction_leaf:这个值限制了叶子节点所有样本权重和的最小值,如果小于这个值,则会和兄弟节点一起被剪枝。 默认是0,就是不考虑权重问题。一般来说,如果我们有较多样本有缺失值,或者分类树样本的分布类别偏差很大,就会引入样本权重,这时我们就要注意这个值了。
6) 最大叶子节点数max_leaf_nodes: 通过限制最大叶子节点数,可以防止过拟合,默认是"None”,即不限制最大的叶子节点数。如果加了限制,算法会建立在最大叶子节点数内最优的决策树。如果特征不多,可以不考虑这个值,但是如果特征分成多的话,可以加以限制,具体的值可以通过交叉验证得到。
7) 节点划分最小不纯度min_impurity_split: 这个值限制了决策树的增长,如果某节点的不纯度(基于基尼系数,均方差)小于这个阈值,则该节点不再生成子节点。即为叶子节点 。一般不推荐改动默认值1e-7。
上面决策树参数中最重要的包括最大特征数max_features, 最大深度max_depth, 内部节点再划分所需最小样本数min_samples_split和叶子节点最少样本数min_samples_leaf。
这里仍然使用GBDT调参时同样的数据集来做RF调参的实例,数据的下载地址在这。本例我们采用袋外分数来评估我们模型的好坏。
首先,我们载入需要的类库:
import pandas as pd
import numpy as np
from sklearn.ensemble import RandomForestClassifier
from sklearn.grid_search import GridSearchCV
from sklearn import cross_validation, metrics
import matplotlib.pylab as plt
%matplotlib inline
接着,我们把解压的数据用下面的代码载入,顺便看看数据的类别分布。
train = pd.read_csv(‘train_modified.csv‘)
target=‘Disbursed‘ # Disbursed的值就是二元分类的输出
IDcol = ‘ID‘
train[‘Disbursed‘].value_counts()
可以看到类别输出如下,也就是类别0的占大多数。
0 19680
1 320
Name: Disbursed, dtype: int64
接着我们选择好样本特征和类别输出。
x_columns = [x for x in train.columns if x not in [target, IDcol]]
X = train[x_columns]
y = train[‘Disbursed‘]
不管任何参数,都用默认的,我们拟合下数据看看:
rf0 = RandomForestClassifier(oob_score=True, random_state=10)
rf0.fit(X,y)
print rf0.oob_score_
y_predprob = rf0.predict_proba(X)[:,1]
print "AUC Score (Train): %f" % metrics.roc_auc_score(y, y_predprob)
输出如下,可见袋外分数已经很高,而且AUC分数也很高。相对于GBDT的默认参数输出,RF的默认参数拟合效果对本例要好一些。
0.98005
AUC Score (Train): 0.999833
我们首先对n_estimators进行网格搜索:
param_test1 = {‘n_estimators‘:range(10,71,10)}
gsearch1 = GridSearchCV(estimator = RandomForestClassifier(min_samples_split=100,
min_samples_leaf=20,max_depth=8,max_features=‘sqrt‘ ,random_state=10),
param_grid = param_test1, scoring=‘roc_auc‘,cv=5)
gsearch1.fit(X,y)
gsearch1.grid_scores_, gsearch1.best_params_, gsearch1.best_score_
输出结果如下:
([mean: 0.80681, std: 0.02236, params: {‘n_estimators‘: 10},
mean: 0.81600, std: 0.03275, params: {‘n_estimators‘: 20},
mean: 0.81818, std: 0.03136, params: {‘n_estimators‘: 30},
mean: 0.81838, std: 0.03118, params: {‘n_estimators‘: 40},
mean: 0.82034, std: 0.03001, params: {‘n_estimators‘: 50},
mean: 0.82113, std: 0.02966, params: {‘n_estimators‘: 60},
mean: 0.81992, std: 0.02836, params: {‘n_estimators‘: 70}],
{‘n_estimators‘: 60},
0.8211334476626017)
这样我们得到了最佳的弱学习器迭代次数,接着我们对决策树最大深度max_depth和内部节点再划分所需最小样本数min_samples_split进行网格搜索。
param_test2 = {‘max_depth‘:range(3,14,2), ‘min_samples_split‘:range(50,201,20)}
gsearch2 = GridSearchCV(estimator = RandomForestClassifier(n_estimators= 60,
min_samples_leaf=20,max_features=‘sqrt‘ ,oob_score=True, random_state=10),
param_grid = param_test2, scoring=‘roc_auc‘,iid=False, cv=5)
gsearch2.fit(X,y)
gsearch2.grid_scores_, gsearch2.best_params_, gsearch2.best_score_
输出如下:
([mean: 0.79379, std: 0.02347, params: {‘min_samples_split‘: 50, ‘max_depth‘: 3},
mean: 0.79339, std: 0.02410, params: {‘min_samples_split‘: 70, ‘max_depth‘: 3},
mean: 0.79350, std: 0.02462, params: {‘min_samples_split‘: 90, ‘max_depth‘: 3},
mean: 0.79367, std: 0.02493, params: {‘min_samples_split‘: 110, ‘max_depth‘: 3},
mean: 0.79387, std: 0.02521, params: {‘min_samples_split‘: 130, ‘max_depth‘: 3},
mean: 0.79373, std: 0.02524, params: {‘min_samples_split‘: 150, ‘max_depth‘: 3},
mean: 0.79378, std: 0.02532, params: {‘min_samples_split‘: 170, ‘max_depth‘: 3},
mean: 0.79349, std: 0.02542, params: {‘min_samples_split‘: 190, ‘max_depth‘: 3},
mean: 0.80960, std: 0.02602, params: {‘min_samples_split‘: 50, ‘max_depth‘: 5},
mean: 0.80920, std: 0.02629, params: {‘min_samples_split‘: 70, ‘max_depth‘: 5},
mean: 0.80888, std: 0.02522, params: {‘min_samples_split‘: 90, ‘max_depth‘: 5},
mean: 0.80923, std: 0.02777, params: {‘min_samples_split‘: 110, ‘max_depth‘: 5},
mean: 0.80823, std: 0.02634, params: {‘min_samples_split‘: 130, ‘max_depth‘: 5},
mean: 0.80801, std: 0.02637, params: {‘min_samples_split‘: 150, ‘max_depth‘: 5},
mean: 0.80792, std: 0.02685, params: {‘min_samples_split‘: 170, ‘max_depth‘: 5},
mean: 0.80771, std: 0.02587, params: {‘min_samples_split‘: 190, ‘max_depth‘: 5},
mean: 0.81688, std: 0.02996, params: {‘min_samples_split‘: 50, ‘max_depth‘: 7},
mean: 0.81872, std: 0.02584, params: {‘min_samples_split‘: 70, ‘max_depth‘: 7},
mean: 0.81501, std: 0.02857, params: {‘min_samples_split‘: 90, ‘max_depth‘: 7},
mean: 0.81476, std: 0.02552, params: {‘min_samples_split‘: 110, ‘max_depth‘: 7},
mean: 0.81557, std: 0.02791, params: {‘min_samples_split‘: 130, ‘max_depth‘: 7},
mean: 0.81459, std: 0.02905, params: {‘min_samples_split‘: 150, ‘max_depth‘: 7},
mean: 0.81601, std: 0.02808, params: {‘min_samples_split‘: 170, ‘max_depth‘: 7},
mean: 0.81704, std: 0.02757, params: {‘min_samples_split‘: 190, ‘max_depth‘: 7},
mean: 0.82090, std: 0.02665, params: {‘min_samples_split‘: 50, ‘max_depth‘: 9},
mean: 0.81908, std: 0.02527, params: {‘min_samples_split‘: 70, ‘max_depth‘: 9},
mean: 0.82036, std: 0.02422, params: {‘min_samples_split‘: 90, ‘max_depth‘: 9},
mean: 0.81889, std: 0.02927, params: {‘min_samples_split‘: 110, ‘max_depth‘: 9},
mean: 0.81991, std: 0.02868, params: {‘min_samples_split‘: 130, ‘max_depth‘: 9},
mean: 0.81788, std: 0.02436, params: {‘min_samples_split‘: 150, ‘max_depth‘: 9},
mean: 0.81898, std: 0.02588, params: {‘min_samples_split‘: 170, ‘max_depth‘: 9},
mean: 0.81746, std: 0.02716, params: {‘min_samples_split‘: 190, ‘max_depth‘: 9},
mean: 0.82395, std: 0.02454, params: {‘min_samples_split‘: 50, ‘max_depth‘: 11},
mean: 0.82380, std: 0.02258, params: {‘min_samples_split‘: 70, ‘max_depth‘: 11},
mean: 0.81953, std: 0.02552, params: {‘min_samples_split‘: 90, ‘max_depth‘: 11},
mean: 0.82254, std: 0.02366, params: {‘min_samples_split‘: 110, ‘max_depth‘: 11},
mean: 0.81950, std: 0.02768, params: {‘min_samples_split‘: 130, ‘max_depth‘: 11},
mean: 0.81887, std: 0.02636, params: {‘min_samples_split‘: 150, ‘max_depth‘: 11},
mean: 0.81910, std: 0.02734, params: {‘min_samples_split‘: 170, ‘max_depth‘: 11},
mean: 0.81564, std: 0.02622, params: {‘min_samples_split‘: 190, ‘max_depth‘: 11},
mean: 0.82291, std: 0.02092, params: {‘min_samples_split‘: 50, ‘max_depth‘: 13},
mean: 0.82177, std: 0.02513, params: {‘min_samples_split‘: 70, ‘max_depth‘: 13},
mean: 0.82415, std: 0.02480, params: {‘min_samples_split‘: 90, ‘max_depth‘: 13},
mean: 0.82420, std: 0.02417, params: {‘min_samples_split‘: 110, ‘max_depth‘: 13},
mean: 0.82209, std: 0.02481, params: {‘min_samples_split‘: 130, ‘max_depth‘: 13},
mean: 0.81852, std: 0.02227, params: {‘min_samples_split‘: 150, ‘max_depth‘: 13},
mean: 0.81955, std: 0.02885, params: {‘min_samples_split‘: 170, ‘max_depth‘: 13},
mean: 0.82092, std: 0.02600, params: {‘min_samples_split‘: 190, ‘max_depth‘: 13}],
{‘max_depth‘: 13, ‘min_samples_split‘: 110},
0.8242016800050813)
我们看看我们现在模型的袋外分数:
rf1 = RandomForestClassifier(n_estimators= 60, max_depth=13, min_samples_split=110,
min_samples_leaf=20,max_features=‘sqrt‘ ,oob_score=True, random_state=10)
rf1.fit(X,y)
print rf1.oob_score_
输出结果为:
0.984
可见此时我们的袋外分数有一定的提高。也就是时候模型的泛化能力增强了。
对于内部节点再划分所需最小样本数min_samples_split,我们暂时不能一起定下来,因为这个还和决策树其他的参数存在关联。下面我们再对内部节点再划分所需最小样本数min_samples_split和叶子节点最少样本数min_samples_leaf一起调参。
param_test3 = {‘min_samples_split‘:range(80,150,20), ‘min_samples_leaf‘:range(10,60,10)}
gsearch3 = GridSearchCV(estimator = RandomForestClassifier(n_estimators= 60, max_depth=13,
max_features=‘sqrt‘ ,oob_score=True, random_state=10),
param_grid = param_test3, scoring=‘roc_auc‘,iid=False, cv=5)
gsearch3.fit(X,y)
gsearch3.grid_scores_, gsearch3.best_params_, gsearch3.best_score_
输出如下:
([mean: 0.82093, std: 0.02287, params: {‘min_samples_split‘: 80, ‘min_samples_leaf‘: 10},
mean: 0.81913, std: 0.02141, params: {‘min_samples_split‘: 100, ‘min_samples_leaf‘: 10},
mean: 0.82048, std: 0.02328, params: {‘min_samples_split‘: 120, ‘min_samples_leaf‘: 10},
mean: 0.81798, std: 0.02099, params: {‘min_samples_split‘: 140, ‘min_samples_leaf‘: 10},
mean: 0.82094, std: 0.02535, params: {‘min_samples_split‘: 80, ‘min_samples_leaf‘: 20},
mean: 0.82097, std: 0.02327, params: {‘min_samples_split‘: 100, ‘min_samples_leaf‘: 20},
mean: 0.82487, std: 0.02110, params: {‘min_samples_split‘: 120, ‘min_samples_leaf‘: 20},
mean: 0.82169, std: 0.02406, params: {‘min_samples_split‘: 140, ‘min_samples_leaf‘: 20},
mean: 0.82352, std: 0.02271, params: {‘min_samples_split‘: 80, ‘min_samples_leaf‘: 30},
mean: 0.82164, std: 0.02381, params: {‘min_samples_split‘: 100, ‘min_samples_leaf‘: 30},
mean: 0.82070, std: 0.02528, params: {‘min_samples_split‘: 120, ‘min_samples_leaf‘: 30},
mean: 0.82141, std: 0.02508, params: {‘min_samples_split‘: 140, ‘min_samples_leaf‘: 30},
mean: 0.82278, std: 0.02294, params: {‘min_samples_split‘: 80, ‘min_samples_leaf‘: 40},
mean: 0.82141, std: 0.02547, params: {‘min_samples_split‘: 100, ‘min_samples_leaf‘: 40},
mean: 0.82043, std: 0.02724, params: {‘min_samples_split‘: 120, ‘min_samples_leaf‘: 40},
mean: 0.82162, std: 0.02348, params: {‘min_samples_split‘: 140, ‘min_samples_leaf‘: 40},
mean: 0.82225, std: 0.02431, params: {‘min_samples_split‘: 80, ‘min_samples_leaf‘: 50},
mean: 0.82225, std: 0.02431, params: {‘min_samples_split‘: 100, ‘min_samples_leaf‘: 50},
mean: 0.81890, std: 0.02458, params: {‘min_samples_split‘: 120, ‘min_samples_leaf‘: 50},
mean: 0.81917, std: 0.02528, params: {‘min_samples_split‘: 140, ‘min_samples_leaf‘: 50}],
{‘min_samples_leaf‘: 20, ‘min_samples_split‘: 120},
0.8248650279471544)
最后我们再对最大特征数max_features做调参:
param_test4 = {‘max_features‘:range(3,11,2)}
gsearch4 = GridSearchCV(estimator = RandomForestClassifier(n_estimators= 60, max_depth=13, min_samples_split=120,
min_samples_leaf=20 ,oob_score=True, random_state=10),
param_grid = param_test4, scoring=‘roc_auc‘,iid=False, cv=5)
gsearch4.fit(X,y)
gsearch4.grid_scores_, gsearch4.best_params_, gsearch4.best_score_
输出如下:
([mean: 0.81981, std: 0.02586, params: {‘max_features‘: 3},
mean: 0.81639, std: 0.02533, params: {‘max_features‘: 5},
mean: 0.82487, std: 0.02110, params: {‘max_features‘: 7},
mean: 0.81704, std: 0.02209, params: {‘max_features‘: 9}],
{‘max_features‘: 7},
0.8248650279471544)
用我们搜索到的最佳参数,我们再看看最终的模型拟合:
rf2 = RandomForestClassifier(n_estimators= 60, max_depth=13, min_samples_split=120,
min_samples_leaf=20,max_features=7 ,oob_score=True, random_state=10)
rf2.fit(X,y)
print rf2.oob_score_
此时的输出为:
0.984
可见此时模型的袋外分数基本没有提高,主要原因是0.984已经是一个很高的袋外分数了,如果想进一步需要提高模型的泛化能力,我们需要更多的数据。
本文转自刘建平Pinard博客园博客,原文链接:http://www.cnblogs.com/pinard/p/6160412.html,如需转载请自行联系原作者
标签:权重 而且 action min 获得 home http 需要 arch
原文地址:https://www.cnblogs.com/fengff/p/11139773.html