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inference_code.py
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inference_code.py
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def inference_model(LSTM_cell, densor, n_x = 78, n_a = 64, Ty = 100):
"""
Uses the trained "LSTM_cell" and "densor" from model() to generate a sequence of values.
Arguments:
LSTM_cell -- the trained "LSTM_cell" from model(), Keras layer object
densor -- the trained "densor" from model(), Keras layer object
n_x -- number of unique values
n_a -- number of units in the LSTM_cell
Ty -- number of time steps to generate
Returns:
inference_model -- Keras model instance
"""
# Define the input of your model with a shape
x0 = Input(shape=(1, n_x))
# Define s0, initial hidden state for the decoder LSTM
a0 = Input(shape=(n_a,), name='a0')
c0 = Input(shape=(n_a,), name='c0')
a = a0
c = c0
x = x0
### START CODE HERE ###
# Step 1: Create an empty list of "outputs" to later store your predicted values (≈1 line)
outputs = []
# Step 2: Loop over Ty and generate a value at every time step
for t in range(Ty):
# Step 2.A: Perform one step of LSTM_cell (≈1 line)
a, _, c = LSTM_cell(x, initial_state=[a, c])
# Step 2.B: Apply Dense layer to the hidden state output of the LSTM_cell (≈1 line)
out = densor(a)
# Step 2.C: Append the prediction "out" to "outputs" (≈1 line)
outputs.append(out)
# Step 2.D: Set the prediction "out" to be the next input "x". You will need to use RepeatVector(1). (≈1 line)
x = RepeatVector(1)(out)
# Step 3: Create model instance with the correct "inputs" and "outputs" (≈1 line)
inference_model = Model(inputs=[x0, a0, c0], outputs=outputs)
### END CODE HERE ###
return inference_model
inference_model = inference_model(LSTM_cell, densor)
x1 = np.zeros((1, 1, 78))
x1[:,:,35] = 1
a1 = np.zeros((1, n_a))
c1 = np.zeros((1, n_a))
predicting = inference_model.predict([x1, a1, c1])
indices = np.argmax(predicting, axis = -1)
results = to_categorical(indices, num_classes=78)