Layer activations
relu function
tf_keras.activations.relu(x, alpha=0.0, max_value=None, threshold=0.0)
Applies the rectified linear unit activation function.
With default values, this returns the standard ReLU activation:
max(x, 0), the element-wise maximum of 0 and the input tensor.
Modifying default parameters allows you to use non-zero thresholds, change the max value of the activation, and to use a non-zero multiple of the input for values below the threshold.
Example
>>> foo = tf.constant([-10, -5, 0.0, 5, 10], dtype = tf.float32)
>>> tf.keras.activations.relu(foo).numpy()
array([ 0., 0., 0., 5., 10.], dtype=float32)
>>> tf.keras.activations.relu(foo, alpha=0.5).numpy()
array([-5. , -2.5, 0. , 5. , 10. ], dtype=float32)
>>> tf.keras.activations.relu(foo, max_value=5.).numpy()
array([0., 0., 0., 5., 5.], dtype=float32)
>>> tf.keras.activations.relu(foo, threshold=5.).numpy()
array([-0., -0., 0., 0., 10.], dtype=float32)
Arguments
- x: Input
tensororvariable. - alpha: A
floatthat governs the slope for values lower than the threshold. - max_value: A
floatthat sets the saturation threshold (the largest value the function will return). - threshold: A
floatgiving the threshold value of the activation function below which values will be damped or set to zero.
Returns
A Tensor representing the input tensor, transformed by the relu
activation function. Tensor will be of the same shape and dtype of
input x.
sigmoid function
tf_keras.activations.sigmoid(x)
Sigmoid activation function, sigmoid(x) = 1 / (1 + exp(-x)).
Applies the sigmoid activation function. For small values (<-5),
sigmoid returns a value close to zero, and for large values (>5)
the result of the function gets close to 1.
Sigmoid is equivalent to a 2-element Softmax, where the second element is assumed to be zero. The sigmoid function always returns a value between 0 and 1.
Example
>>> a = tf.constant([-20, -1.0, 0.0, 1.0, 20], dtype = tf.float32)
>>> b = tf.keras.activations.sigmoid(a)
>>> b.numpy()
array([2.0611537e-09, 2.6894143e-01, 5.0000000e-01, 7.3105860e-01,
1.0000000e+00], dtype=float32)
Arguments
- x: Input tensor.
Returns
- Tensor with the sigmoid activation:
1 / (1 + exp(-x)).
softmax function
tf_keras.activations.softmax(x, axis=-1)
Softmax converts a vector of values to a probability distribution.
The elements of the output vector are in range (0, 1) and sum to 1.
Each vector is handled independently. The axis argument sets which axis
of the input the function is applied along.
Softmax is often used as the activation for the last layer of a classification network because the result could be interpreted as a probability distribution.
The softmax of each vector x is computed as
exp(x) / tf.reduce_sum(exp(x)).
The input values in are the log-odds of the resulting probability.
Arguments
- x : Input tensor.
- axis: Integer, axis along which the softmax normalization is applied.
Returns
Tensor, output of softmax transformation (all values are non-negative and sum to 1).
Examples
Example 1: standalone usage
>>> inputs = tf.random.normal(shape=(32, 10))
>>> outputs = tf.keras.activations.softmax(inputs)
>>> tf.reduce_sum(outputs[0, :]) # Each sample in the batch now sums to 1
<tf.Tensor: shape=(), dtype=float32, numpy=1.0000001>
Example 2: usage in a Dense layer
>>> layer = tf.keras.layers.Dense(32,
... activation=tf.keras.activations.softmax)
softplus function
tf_keras.activations.softplus(x)
Softplus activation function, softplus(x) = log(exp(x) + 1).
Example Usage:
>>> a = tf.constant([-20, -1.0, 0.0, 1.0, 20], dtype = tf.float32)
>>> b = tf.keras.activations.softplus(a)
>>> b.numpy()
array([2.0611537e-09, 3.1326166e-01, 6.9314718e-01, 1.3132616e+00,
2.0000000e+01], dtype=float32)
Arguments
- x: Input tensor.
Returns
- The softplus activation:
log(exp(x) + 1).
softsign function
tf_keras.activations.softsign(x)
Softsign activation function, softsign(x) = x / (abs(x) + 1).
Example Usage:
>>> a = tf.constant([-1.0, 0.0, 1.0], dtype = tf.float32)
>>> b = tf.keras.activations.softsign(a)
>>> b.numpy()
array([-0.5, 0. , 0.5], dtype=float32)
Arguments
- x: Input tensor.
Returns
- The softsign activation:
x / (abs(x) + 1).
tanh function
tf_keras.activations.tanh(x)
Hyperbolic tangent activation function.
Example
>>> a = tf.constant([-3.0, -1.0, 0.0, 1.0, 3.0], dtype = tf.float32)
>>> b = tf.keras.activations.tanh(a)
>>> b.numpy()
array([-0.9950547, -0.7615942, 0., 0.7615942, 0.9950547], dtype=float32)
Arguments
- x: Input tensor.
Returns
- Tensor of same shape and dtype of input
x, with tanh activation:tanh(x) = sinh(x)/cosh(x) = ((exp(x) - exp(-x))/(exp(x) + exp(-x))).
selu function
tf_keras.activations.selu(x)
Scaled Exponential Linear Unit (SELU).
The Scaled Exponential Linear Unit (SELU) activation function is defined as:
if x > 0: return scale * xif x < 0: return scale * alpha * (exp(x) - 1)
where alpha and scale are pre-defined constants
(alpha=1.67326324 and scale=1.05070098).
Basically, the SELU activation function multiplies scale (> 1) with the
output of the tf.keras.activations.elu function to ensure a slope larger
than one for positive inputs.
The values of alpha and scale are
chosen so that the mean and variance of the inputs are preserved
between two consecutive layers as long as the weights are initialized
correctly (see tf.keras.initializers.LecunNormal initializer)
and the number of input units is "large enough"
(see reference paper for more information).
Example Usage:
>>> num_classes = 10 # 10-class problem
>>> model = tf.keras.Sequential()
>>> model.add(tf.keras.layers.Dense(64, kernel_initializer='lecun_normal',
... activation='selu'))
>>> model.add(tf.keras.layers.Dense(32, kernel_initializer='lecun_normal',
... activation='selu'))
>>> model.add(tf.keras.layers.Dense(16, kernel_initializer='lecun_normal',
... activation='selu'))
>>> model.add(tf.keras.layers.Dense(num_classes, activation='softmax'))
Arguments
- x: A tensor or variable to compute the activation function for.
Returns
- The scaled exponential unit activation:
scale * elu(x, alpha).
Notes:
- To be used together with the
tf.keras.initializers.LecunNormal initializer.
- To be used together with the dropout variant
tf.keras.layers.AlphaDropout (not regular dropout).
References
elu function
tf_keras.activations.elu(x, alpha=1.0)
Exponential Linear Unit.
The exponential linear unit (ELU) with alpha > 0 is:
x if x > 0 and
alpha * (exp(x) - 1) if x < 0
The ELU hyperparameter alpha controls the value to which an
ELU saturates for negative net inputs. ELUs diminish the
vanishing gradient effect.
ELUs have negative values which pushes the mean of the activations closer to zero. Mean activations that are closer to zero enable faster learning as they bring the gradient closer to the natural gradient. ELUs saturate to a negative value when the argument gets smaller. Saturation means a small derivative which decreases the variation and the information that is propagated to the next layer.
Example Usage:
>>> import tensorflow as tf
>>> model = tf.keras.Sequential()
>>> model.add(tf.keras.layers.Conv2D(32, (3, 3), activation='elu',
... input_shape=(28, 28, 1)))
>>> model.add(tf.keras.layers.MaxPooling2D((2, 2)))
>>> model.add(tf.keras.layers.Conv2D(64, (3, 3), activation='elu'))
>>> model.add(tf.keras.layers.MaxPooling2D((2, 2)))
>>> model.add(tf.keras.layers.Conv2D(64, (3, 3), activation='elu'))
Arguments
- x: Input tensor.
- alpha: A scalar, slope of negative section.
alphacontrols the value to which an ELU saturates for negative net inputs.
Returns
- The exponential linear unit (ELU) activation function:
xifx > 0andalpha * (exp(x) - 1)ifx < 0.
Reference
exponential function
tf_keras.activations.exponential(x)
Exponential activation function.
Example
>>> a = tf.constant([-3.0, -1.0, 0.0, 1.0, 3.0], dtype = tf.float32)
>>> b = tf.keras.activations.exponential(a)
>>> b.numpy()
array([0.04978707, 0.36787945, 1., 2.7182817 , 20.085537], dtype=float32)
Arguments
- x: Input tensor.
Returns
- Tensor with exponential activation:
exp(x).