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小編這次要給大家分享的是詳解Keras中自定義損失函數,文章內容豐富,感興趣的小伙伴可以來了解一下,希望大家閱讀完這篇文章之后能夠有所收獲。
在Keras中可以自定義損失函數,在自定義損失函數的過程中需要注意的一點是,損失函數的參數形式,這一點在Keras中是固定的,須如下形式:
def my_loss(y_true, y_pred): # y_true: True labels. TensorFlow/Theano tensor # y_pred: Predictions. TensorFlow/Theano tensor of the same shape as y_true . . . return scalar #返回一個標量值
然后在model.compile中指定即可,如:
model.compile(loss=my_loss, optimizer='sgd')
具體參考Keras官方metrics的定義keras/metrics.py:
"""Built-in metrics.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import six
from . import backend as K
from .losses import mean_squared_error
from .losses import mean_absolute_error
from .losses import mean_absolute_percentage_error
from .losses import mean_squared_logarithmic_error
from .losses import hinge
from .losses import logcosh
from .losses import squared_hinge
from .losses import categorical_crossentropy
from .losses import sparse_categorical_crossentropy
from .losses import binary_crossentropy
from .losses import kullback_leibler_divergence
from .losses import poisson
from .losses import cosine_proximity
from .utils.generic_utils import deserialize_keras_object
from .utils.generic_utils import serialize_keras_object
def binary_accuracy(y_true, y_pred):
return K.mean(K.equal(y_true, K.round(y_pred)), axis=-1)
def categorical_accuracy(y_true, y_pred):
return K.cast(K.equal(K.argmax(y_true, axis=-1),
K.argmax(y_pred, axis=-1)),
K.floatx())
def sparse_categorical_accuracy(y_true, y_pred):
# reshape in case it's in shape (num_samples, 1) instead of (num_samples,)
if K.ndim(y_true) == K.ndim(y_pred):
y_true = K.squeeze(y_true, -1)
# convert dense predictions to labels
y_pred_labels = K.argmax(y_pred, axis=-1)
y_pred_labels = K.cast(y_pred_labels, K.floatx())
return K.cast(K.equal(y_true, y_pred_labels), K.floatx())
def top_k_categorical_accuracy(y_true, y_pred, k=5):
return K.mean(K.in_top_k(y_pred, K.argmax(y_true, axis=-1), k), axis=-1)
def sparse_top_k_categorical_accuracy(y_true, y_pred, k=5):
# If the shape of y_true is (num_samples, 1), flatten to (num_samples,)
return K.mean(K.in_top_k(y_pred, K.cast(K.flatten(y_true), 'int32'), k),
axis=-1)
# Aliases
mse = MSE = mean_squared_error
mae = MAE = mean_absolute_error
mape = MAPE = mean_absolute_percentage_error
msle = MSLE = mean_squared_logarithmic_error
cosine = cosine_proximity
def serialize(metric):
return serialize_keras_object(metric)
def deserialize(config, custom_objects=None):
return deserialize_keras_object(config,
module_objects=globals(),
custom_objects=custom_objects,
printable_module_name='metric function')
def get(identifier):
if isinstance(identifier, dict):
config = {'class_name': str(identifier), 'config': {}}
return deserialize(config)
elif isinstance(identifier, six.string_types):
return deserialize(str(identifier))
elif callable(identifier):
return identifier
else:
raise ValueError('Could not interpret '
'metric function identifier:', identifier)看完這篇關于詳解Keras中自定義損失函數的文章,如果覺得文章內容寫得不錯的話,可以把它分享出去給更多人看到。
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