You need some TensorFlow to compute the symbolic gradient. Here is a toy example using Keras and then digging in a little bit to manually perform the step-wise descent in TensorFlow.

```
from keras.models import Sequential
from keras.layers import Dense, Activation
from keras import backend as k
from keras import losses
import numpy as np
import tensorflow as tf
from sklearn.metrics import mean_squared_error
from math import sqrt
model = Sequential()
model.add(Dense(12, input_dim=8, kernel_initializer='uniform', activation='relu'))
model.add(Dense(8, kernel_initializer='uniform', activation='relu'))
model.add(Dense(8, kernel_initializer='uniform', activation='sigmoid'))
model.compile(loss='binary_crossentropy', optimizer='adam', metrics=['accuracy'])
inputs = np.random.random((1, 8))
outputs = model.predict(inputs)
targets = np.random.random((1, 8))
rmse = sqrt(mean_squared_error(targets, outputs))
print("===BEFORE WALKING DOWN GRADIENT===")
print("outputs:\n", outputs)
print("targets:\n", targets)
print("RMSE:", rmse)
def descend(steps=40, learning_rate=100.0, learning_decay=0.95):
for s in range(steps):
# If your target changes, you need to update the loss
loss = losses.mean_squared_error(targets, model.output)
# ===== Symbolic Gradient =====
# Tensorflow Tensor Object
gradients = k.gradients(loss, model.trainable_weights)
# ===== Numerical gradient =====
# Numpy ndarray Objcet
evaluated_gradients = sess.run(gradients, feed_dict={model.input: inputs})
# For every trainable layer in the network
for i in range(len(model.trainable_weights)):
layer = model.trainable_weights[i] # Select the layer
# And modify it explicitly in TensorFlow
sess.run(tf.assign_sub(layer, learning_rate * evaluated_gradients[i]))
# decrease the learning rate
learning_rate *= learning_decay
outputs = model.predict(inputs)
rmse = sqrt(mean_squared_error(targets, outputs))
print("RMSE:", rmse)
if __name__ == "__main__":
# Begin TensorFlow
sess = tf.InteractiveSession()
sess.run(tf.initialize_all_variables())
descend(steps=5)
final_outputs = model.predict(inputs)
final_rmse = sqrt(mean_squared_error(targets, final_outputs))
print("===AFTER STEPPING DOWN GRADIENT===")
print("outputs:\n", final_outputs)
print("targets:\n", targets)
```

RESULTS:

```
===BEFORE WALKING DOWN GRADIENT===
outputs:
[[0.49995303 0.5000101 0.50001436 0.50001544 0.49998832 0.49991882
0.49994195 0.4999649 ]]
targets:
[[0.60111501 0.70807258 0.02058449 0.96990985 0.83244264 0.21233911
0.18182497 0.18340451]]
RMSE: 0.33518919408969455
RMSE: 0.05748867468895
RMSE: 0.03369414290610595
RMSE: 0.021872132066183464
RMSE: 0.015070048653579693
RMSE: 0.01164369828903875
===AFTER STEPPING DOWN GRADIENT===
outputs:
[[0.601743 0.707857 0.04268148 0.9536494 0.8448022 0.20864952
0.17241994 0.17464897]]
targets:
[[0.60111501 0.70807258 0.02058449 0.96990985 0.83244264 0.21233911
0.18182497 0.18340451]]
```