Python 如何在交叉验证中获得Keras scikit learn wrapper的培训和验证损失？_Python_Machine Learning_Keras_Scikit Learn_Cross Validation

Python 如何在交叉验证中获得Keras scikit learn wrapper的培训和验证损失？

python machine-learning keras scikit-learn

Python 如何在交叉验证中获得Keras scikit learn wrapper的培训和验证损失？,python,machine-learning,keras,scikit-learn,cross-validation,Python,Machine Learning,Keras,Scikit Learn,Cross Validation,我知道keras中的model.fit返回callbacks.History对象，我们可以从中获得损失和其他指标，如下所示 ... train_history = model.fit(X_train, Y_train, batch_size=batch_size, nb_epoch=nb_epoch, verbose=1, validation_data=(X_test, Y_test)) loss = train_

我知道keras中的model.fit返回callbacks.History对象，我们可以从中获得损失和其他指标，如下所示

...
train_history = model.fit(X_train, Y_train,
                    batch_size=batch_size, nb_epoch=nb_epoch,
                    verbose=1, validation_data=(X_test, Y_test))
loss = train_history.history['loss']
val_loss = train_history.history['val_loss']

然而，在我的新实验中，我使用kerasclassifier完整示例代码对keras模型进行交叉验证：

由于现在我使用交叉验证，我不确定如何获得训练和验证损失。

正如在中明确提到的，交叉验证分数包括一个评分参数，即

与交叉验证类似，但只允许使用单个度量

因此，它不能用于返回Keras model.fit的所有损失和度量信息

Keras的scikit学习包装是为了方便起见，前提是您对培训和验证损失和准确性等所有基本细节不感兴趣。如果不是这样，您应该恢复直接使用Keras。下面是如何使用链接到的示例和元素来实现此目的：

例如，在此之后，损失将为：

i、 e.一个n_拆分列表3，其中每一个包含每个历元的训练损失10。类似地，对于其他列表

# Wrap Keras model so it can be used by scikit-learn
neural_network = KerasClassifier(build_fn=create_network, 
                                 epochs=10, 
                                 batch_size=100, 
                                 verbose=1)

import numpy as np
from keras import models, layers
from sklearn.datasets import make_classification
from sklearn.model_selection import KFold

np.random.seed(0)

# Number of features
number_of_features = 100

# Generate features matrix and target vector
features, target = make_classification(n_samples = 10000,
                                       n_features = number_of_features,
                                       n_informative = 3,
                                       n_redundant = 0,
                                       n_classes = 2,
                                       weights = [.5, .5],
                                       random_state = 0)

def create_network():
    network = models.Sequential()
    network.add(layers.Dense(units=16, activation='relu', input_shape=(number_of_features,)))
    network.add(layers.Dense(units=16, activation='relu'))
    network.add(layers.Dense(units=1, activation='sigmoid'))

    network.compile(loss='binary_crossentropy', 
                    optimizer='rmsprop', 
                    metrics=['accuracy']) 

    return network

n_splits = 3
kf = KFold(n_splits=n_splits, shuffle=True)

loss = []
acc = []
val_loss = []
val_acc = []

# cross validate:
for train_index, val_index in kf.split(features):
    model = create_network()
    hist = model.fit(features[train_index], target[train_index],
                     epochs=10,
                     batch_size=100,
                     validation_data = (features[val_index], target[val_index]),
                     verbose=0)
    loss.append(hist.history['loss'])
    acc.append(hist.history['acc'])
    val_loss.append([hist.history['val_loss']])
    val_acc.append(hist.history['val_acc'])

[[0.7251979386058971,
  0.6640552306833333,
  0.6190941931069023,
  0.5602273066015956,
  0.48771809028534785,
  0.40796665995284814,
  0.33154681897220617,
  0.2698465999525444,
  0.227492357244586,
  0.1998490962115201],
 [0.7109123742507104,
  0.674812126485093,
  0.6452083222258479,
  0.6074533335751673,
  0.5627432800365635,
  0.51291748379345,
  0.45645068427406726,
  0.3928780094229408,
  0.3282097149542538,
  0.26993170230619656],
 [0.7191790426458682,
  0.6618405645963258,
  0.6253172250296091,
  0.5855853647883192,
  0.5438901918195831,
  0.4999895181964501,
  0.4495182811042725,
  0.3896359298090465,
  0.3210068798340545,
  0.25932698793518183]]