To my knowledge, this cannot be done by the common "API level" of Keras usage.
However, if you dig a bit deeper, there are some (ugly) ways to share the weights.
First of all, the weights of the
Conv2D layers are created inside the
build() function, by calling
self.kernel = self.add_weight(shape=kernel_shape,
For your provided usage (i.e., default
add_weight() does nothing special but appending the weight variables to
weight = K.variable(initializer(shape), dtype=dtype, name=name)
build() is only called inside
__call__() if the layer hasn't been built, shared weights between layers can be created by:
conv1.build() to initialize the
conv1.bias variables to be shared.
conv2.build() to initialize the layer.
- Finish model definition. Here
conv2.__call__() will be called; however, since
conv2 has already been built, the weights are not going to be re-initialized.
The following code snippet may be helpful:
def create_shared_weights(conv1, conv2, input_shape):
conv2.kernel = conv1.kernel
conv2.bias = conv1.bias
conv2._trainable_weights = 
# check if weights are successfully shared
input_img = Input(shape=(299, 299, 3))
conv1 = Conv2D(64, 3, padding='same')
conv2 = Conv2D(64, 3, padding='valid')
create_shared_weights(conv1, conv2, input_img._keras_shape)
print(conv2.weights == conv1.weights) # True
# check if weights are equal after model fitting
left = conv1(input_img)
right = conv2(input_img)
left = GlobalAveragePooling2D()(left)
right = GlobalAveragePooling2D()(right)
merged = concatenate([left, right])
output = Dense(1)(merged)
model = Model(input_img, output)
X = np.random.rand(5, 299, 299, 3)
Y = np.random.randint(2, size=5)
print([np.all(w1 == w2) for w1, w2 in zip(conv1.get_weights(), conv2.get_weights())]) # [True, True]
One drawback of this hacky weight-sharing is that the weights will not remain shared after model saving/loading. This will not affect prediction, but it may be problematic if you want to load the trained model for further fine-tuning.