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Currently i think i'm experiencing a systematic offset in a LSTM model, between the predictions and the ground truth values. What's the best approach to continue further from now on?

The model architecture, along with the predictions & ground truth values are shown below. This is a regression problem where the historical data of the target plus 5 other correlated features X are used to predict the target y. Currently the input sequence n_input is of length 256, where the output sequence n_out is one. Simplified, the previous 256 points are used to predict the next target value.

X is normalized. The mean squared error is used as the loss function. Adam with a cosine annealing learning rate is used as the optimizer (min_lr=1e-7, max_lr=6e-2).

_________________________________________________________________
Layer (type)                 Output Shape              Param #   
=================================================================
cu_dnnlstm_8 (CuDNNLSTM)     (None, 256)               270336    
_________________________________________________________________
batch_normalization_11 (Batc (None, 256)               1024      
_________________________________________________________________
leaky_re_lu_11 (LeakyReLU)   (None, 256)               0         
_________________________________________________________________
dropout_11 (Dropout)         (None, 256)               0         
_________________________________________________________________
dense_11 (Dense)             (None, 1)                 257       
=================================================================
Total params: 271,617
Trainable params: 271,105
Non-trainable params: 512
_________________________________________________________________

Increasing the node size in the LSTM layer, adding more LSTM layers (with return_sequences=True) or adding dense layers after the LSTM layer(s) only seems to lower the accuracy. Any advice would be appreciated.

enter image description here

Additional information on the image. The y-axis is a value, x-axis is the time (in days). NaNs have been replaced with zero, because the ground truth value in this case can never reach zero. That's why the odd outliers are in the data.

Edit: I made some changes to the model, which increased accuracy. The architecture is the same, however the features used have changed. Currently only the historical data of the target sequence itself is used as a feature. Along with this, n_input got changed so 128. Switched Adam for SGD, mean squared error with the mean absolute error and finally the NaNs have been interpolated instead of being replaced with 0.

One step ahead predictions on the validation set look fine:

enter image description here

However, the offset on the validation set remains:

enter image description here

It might be worth noting that this offset also appears on the train set for x < ~430: enter image description here

  • Your seq-length is too large, did you try another variant of this? What your data-size? – Ankish Bansal Jan 25 at 18:18
  • The total dataset is 1427 timesteps, split into 50% train, 20% val and 30% test. I'll go try a smaller input sequence now, will post updates as soon as i got them. – deKeijzer Jan 25 at 19:48
  • Alright so here is the update. Forward filling all NaNs instead of replacing them with 0 increased the accuracy by relatively a lot. Removing all other features but the historical sequence of the target also helped. For the input sequence length, longer gives better results. However, the offset still remains and currently is about +15% from the ground truth, while the shape of the predictions look exactly in agreement with the ground truth. – deKeijzer Jan 27 at 3:04
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    I presume you might be experiencing a problem similar to the one described in this answer. – rvinas Jan 28 at 16:42
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+50

It looks like your model is overfitting and is simply always returning the value from the last timestep as a prediction. Your dataset is probably too small to have a model with this amount of parameters converge. You'll need to resort to techniques that combat overfitting: agressive dropout, adding more data, or try simpler, less overparameterized methods.

This phenomenon (LSTMs returning a shifted version of the input) has been a recurring theme in many stackoverflow questions. The answers there might contain some useful information:

LSTM Sequence Prediction in Keras just outputs last step in the input

LSTM model just repeats the past in forecasting time series

LSTM NN produces “shifted” forecast (low quality result)

Keras network producing inverse predictions

Stock price predictions of keras multilayer LSTM model converge to a constant value

Keras LSTM predicted timeseries squashed and shifted

Finally, be aware that, depending on the nature of your dataset, there simply might be no pattern to be discovered in your data at all. You see this a lot with people trying to predict the stock market with LSTMs (there is a question on stackoverflow on how to predict the lottery numbers).

  • Thank you very much, it was kind of hard to find this answer. Almost all tutorials, blogs and papers focus on one step ahead forecasting and simply ignore the problems with multi steps ahead forecasting. To anyone else having this problem: it seems like CNNs give more promising results. – deKeijzer Jan 31 at 15:12

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