Wrong range of values in Time-series forecasting TensorFlow

Question

I have a dataset of prices with 36619 samples and 6 features. The distributions of the features vary significantly, so I create the following function to adapt a normalization layer and create a TensorFlow (TF) dataset. The description of each step is on the function as well as the parameters.tensorflow.__version__=2.8.2

WINDOW_JUMP = 24
WINDOW_SIZE = 24*7
SHIFT = 1
TARGET = 1
BATCH_SIZE = 128
SHUFFLE_BUFFER = 10000
SERIES_SHAPE = [WINDOW_SIZE,6]

WINDOW_SIZE results in the dataset having samples of shape 168 x 6 and the targets will be 24 ( WINDOW_JUMP) time-steps ahead.

def windowed_dataset(series,
    window_size, 
    window_jump, 
    target, 
    batch_size,
    shuffle_buffer,
    dim_target = 0,
    shift=1,
    processing = None):
    """Generates dataset windows

    Args:
      series (array of float) - contains the values of the time series
      window_size (int) - the number of time steps to include in the feature
      window_jump (int) - number of time steps ahead to predict
      target (int) - number of targets to predict from window_size to window_jump
      batch_size (int)
      shuffle_buffer(int) - buffer size to use for the shuffle method
      dim_target (int) - Case of a multivariate dataset, the number of the column from which to extract the targets
      shift (int) - jump between windows
      Processing (Keras.layers.preprocessing Object) - If passed, Preprocessing layer to adapt

    Returns:
      dataset (TF Dataset) - TF Dataset containing time windows and targets
    """
    print('--> Generate a TF Dataset from the series values')
    dataset = tf.data.Dataset.from_tensor_slices(series)

    if processing != None:
      print('\t --> Adapting the preprocessed layer to the data')
      processed = dataset.window(window_size, shift=shift, drop_remainder=True)
      processed = processed.flat_map(lambda window: window.batch(window_size))
      processing.adapt(processed)

    print('--> Window the data but only take those with the specified size')
    dataset = dataset.window(window_size + window_jump, shift=shift, drop_remainder=True)
    
    print('--> Flatten the windows by putting its elements in a single batch')
    dataset = dataset.flat_map(lambda window: window.batch(window_size + window_jump))
    
    print('--> Create tuples with features and labels')
    dataset = dataset.map(lambda window: (window[:-window_jump], window[-target:][:,dim_target]))
    
    print('--> Shuffle the windows')
    dataset = dataset.shuffle(shuffle_buffer)
    
    print('--> Create batches of windows')
    dataset = dataset.batch(batch_size).prefetch(1)
    
    if processing != None:
      print('Returning dataset and adapted layer')
      return dataset,processing
    else:
      print('Returning dataset')
      return dataset

The dataset was split into Train (90%), Validation (5%), and Test (5%) sets. I obtained the Train and Validation set to fit the model with the function above. In this step, I verified the values of the targets contained in each set and are in the desired range of values.

# Train set
train_series, normalizer_layer = windowed_dataset(train_set,
                                WINDOW_SIZE,WINDOW_JUMP,TARGET,BATCH_SIZE,SHUFFLE_BUFFER,
                                processing= tf.keras.layers.Normalization(input_shape=SERIES_SHAPE))

Finally, I created, compiled, and fitted the model.

# Train the model
def compile_fit_model(model,epochs,train_series,validation_series,lr_schedule):
  # Initialize the optimizer
  print('\nCreating optimizer with scheduler')
  optimizer = tf.keras.optimizers.Adam(lr_schedule)

  # Set the training parameters
  model.compile(loss='mse', optimizer=optimizer, metrics=['mae'])

  print('\nFitting the model')
  history = model.fit(train_series, epochs=epochs)#,validation_data=validation_series)

  return history

def get_uncompile_model(input_shape,norm=None):
    '''Model with the changes proposed by Pranav Raikote'''
    model = tf.keras.models.Sequential()
    if norm != None:
        model.add(norm)
    model.add(tf.keras.layers.Conv1D(filters=64, kernel_size=3,
                      strides=1,
                      activation="relu",
                      padding='causal',))
    model.add(tf.keras.layers.Bidirectional(tf.keras.layers.LSTM(64,input_shape=input_shape,return_sequences=True)))
    model.add(tf.keras.layers.LSTM(32))
    model.add(tf.keras.layers.Dense(16))
    model.add(tf.keras.layers.Dropout(0.2))
    model.add(tf.keras.layers.Dense(6))
    model.add(tf.keras.layers.Lambda(lambda x: x*norm.mean))
    model.add(tf.keras.layers.Dense(1,activation='linear'))
    model.summary()
    return model

model = get_uncompile_model(SERIES_SHAPE,normalizer_layer)
history = compile_fit_model(model,3,train_series,val_series,1e-8)

I am getting the following prediction from the validation data, I don't expect it to be accurate, after all, I haven't tuned It. However, It should at least be able to get into the range of correct values, right? I have tried the linear activation function in the last layer and various configurations for the Neural Network but nothing worked. I have followed the TF tutorial on Regression for beginners but I can't find anything wrong.

Can someone please help me to identify what I am doing wrong?. I am relatively new to Time-Series and TensorFlow. If you find any annotations to add different from the question, feel free to tell me, I will be grateful.

Note

This is the prediction of the validation set with the new model, It has more Dense and Dropout layers before the output(Ten Epochs). Before I used the same model excluding the Dropout, Dense(6), and Lambda layers, the results were slightly different from the first image.