Not that this answer particularly addresses the original question, I thought of writing it because the same error occurs when trying to load a keras model that has a custom loss using `keras.models.load_model`

, and it's not been properly answered anywhere. Specifically, following the VAE example code in keras github repository, this error occurs when loading the VAE model after been saved with `model.save`

.

The solution is to save only the weights using `vae.save_weights('file.h5')`

instead of saving the full model. However, you would have to build and compile the model again before loading the weights using `vae.load_weights('file.h5')`

.

Following is an example implementation.

```
class VAE():
def build_model(self): # latent_dim and intermediate_dim can be passed as arguments
def sampling(args):
"""Reparameterization trick by sampling from an isotropic unit Gaussian.
# Arguments
args (tensor): mean and log of variance of Q(z|X)
# Returns
z (tensor): sampled latent vector
"""
z_mean, z_log_var = args
batch = K.shape(z_mean)[0]
dim = K.int_shape(z_mean)[1]
# by default, random_normal has mean = 0 and std = 1.0
epsilon = K.random_normal(shape=(batch, dim))
return z_mean + K.exp(0.5 * z_log_var) * epsilon
# original_dim = self.no_features
# intermediate_dim = 256
latent_dim = 8
inputs = Input(shape=(self.no_features,))
x = Dense(256, activation='relu')(inputs)
x = Dense(128, activation='relu')(x)
x = Dense(64, activation='relu')(x)
z_mean = Dense(latent_dim, name='z_mean')(x)
z_log_var = Dense(latent_dim, name='z_log_var')(x)
# use reparameterization trick to push the sampling out as input
# note that "output_shape" isn't necessary with the TensorFlow backend
z = Lambda(sampling, output_shape=(latent_dim,), name='z')([z_mean, z_log_var])
# instantiate encoder model
encoder = Model(inputs, [z_mean, z_log_var, z], name='encoder')
# build decoder model
latent_inputs = Input(shape=(latent_dim,), name='z_sampling')
x = Dense(32, activation='relu')(latent_inputs)
x = Dense(48, activation='relu')(x)
x = Dense(64, activation='relu')(x)
outputs = Dense(self.no_features, activation='linear')(x)
# instantiate decoder model
decoder = Model(latent_inputs, outputs, name='decoder')
# instantiate VAE model
outputs = decoder(encoder(inputs)[2])
VAE = Model(inputs, outputs, name='vae_mlp')
reconstruction_loss = mse(inputs, outputs)
reconstruction_loss *= self.no_features
kl_loss = 1 + z_log_var - K.square(z_mean) - K.exp(z_log_var)
kl_loss = K.sum(kl_loss, axis=-1)
kl_loss *= -0.5
vae_loss = K.mean(reconstruction_loss + kl_loss)
VAE.add_loss(vae_loss)
VAE.compile(optimizer='adam')
return VAE
```

Now,

```
vae_cls = VAE()
vae = vae_cls.build_model()
# vae.fit()
vae.save_weights('file.h5')
```

Load model and predict (if in a different script, you need to import the `VAE`

class),

```
vae_cls = VAE()
vae = vae_cls.build_model()
vae.load_weights('file.h5')
# vae.predict()
```

Finally, **The Difference**: [ref]

Keras `model.save`

saves,

- Model weights
- Model architecture
- Model compilation details (loss function(s) and metrics)
- Model optimizer and regularizer states

Keras `model.save_weights`

saves only the model weights. Keras `model.to_json()`

saves the model architecture.

Hope this helps someone experimenting with variational autoencoders.