52 Responses toLSTM for Time Series Prediction in PyTorch

1. 

   eliasnemoMarch 16, 2023 at 3:24 am#

   Forgive me, there must be an error somewhere:
   print(X_train.shape, y_train.shape)
   print(X_test.shape, y_test.shape)
   torch.Size([95, 1]) torch.Size([95, 1])
   torch.Size([47, 1]) torch.Size([47, 1])

   Reply
   • 

     James CarmichaelMarch 16, 2023 at 7:05 am#

     Hi Eliasnemo…What is the error you are referring to?

     Reply
     • 

       eliasnemoMarch 17, 2023 at 9:58 am#

       Hi James, I apologize I wrote the comment too hastily, the error was mine, the shape of my timeseries was (432,) while yours is (432,1) this generated in the create_dataset(dataset, lookback) function an incorrect tensor shape: torch.Size([95, 1]) torch.Size([95, 1]) torch.Size([47, 1]) torch.Size([47, 1]) and not the correct one: torch.Size([95, 1, 1]) torch.Size([95, 1, 1]) torch.Size([47, 1, 1]) torch.Size([47, 1, 1]) as in your example.
       I just added X=np.array(X) and y np.array(y) before return torch.tensor(X), torch.tensor(y) to avoid the message “UserWarning: Creating a tensor from a list of numpy.ndarrays is extremely slow…”. Thank you for sharing your excellent work.

       Reply
2. 

   tqrahmanMarch 23, 2023 at 3:22 pm#

   Hi, this post is informative! In line 65-68, should it be X_batch and y_batch instead of X_train and y_train?

   Reply
   • 

     James CarmichaelMarch 24, 2023 at 6:09 am#

     Hi tqrahman…I do not see an error. What is your results by changing the code to that for which you suggested?

     Reply
     • 

       BotMarch 4, 2025 at 2:24 pm#

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       Reply
       • 

         James CarmichaelMarch 5, 2025 at 9:31 am#

         Thank you Bot! No bots in place in this forum!

         Reply
         • 

           James CarmichaelMarch 5, 2025 at 9:32 am#

           And you the spelling is “signals” 🙂
3. 

   guestApril 9, 2023 at 11:37 pm#

   do you have example for predict next x day graph plot

   Reply
   • 

     James CarmichaelApril 10, 2023 at 8:09 am#

     Hi guest…please clarify your question so that we may better assist you.

     Reply
4. 

   SobieddApril 18, 2023 at 9:09 pm#

   Hi James, I’m wondering, if we use the “create_dataset” function to create the windows for the training, after training the model and using it ti predict we will need to transform our new dataset and have the same shape to predict, therefore, we won’t predict for the last “N lookback” instances due to the function is only getting windows for “len(dataset)-lookback”. In conclusion, we won’t predict values for the whole dataset, if I use lookback=3, I won’t get predictions for the last 3 instances.

   Reply
   • 

     James CarmichaelApril 19, 2023 at 9:35 am#

     Hi Sobiedd…I am not certain I am following your question. Have you performed a prediction and have noted an issue with the suggested methodology used in the tutorial? Perhaps we can start with your results and determine if there is something missing from the implementation.

     Reply
5. 

   DaneshwariMay 16, 2023 at 4:13 pm#

   Hi Jason! Thanks for this blog, it’s really helpful. I intended to use the lstm network for prediction. The dataset I have is a social media dataset with multiple variables(image features, posts posting date, tags, location info etc.). This dataset has temporal features, so I can plot each post v/s the output, taking month-year(the time scale) on x-axis and o/p on y-axis.

   I have done the feature engineering and now I wanted to train a lstm model to predict the output. But since NN/lstm models need data to be normalized, I was wondering –
   1.) whether to normalize/scale the data,
   2.) should I normalize considering each feature for each samples? or should I normalize it feature-wise(normalize by tags_length feature/column)?

   I need your suggestion as early as possible since I’m aiming for a deadline. Any help is highly appreciated. I look forward to your suggestion. Thank You!

   Reply
6. 

   AngeloJune 20, 2023 at 6:03 am#

   Hi James,

   Perhaps I am wrong, but it seems that you are using teacher forcing during the test phase. It doesn’t seem like the model is autoregressive. I would like to see results where the LSTM uses its own predictions to generate new ones.

   Reply
   • 

     James CarmichaelJune 20, 2023 at 9:57 am#

     Hi Angelo…The following example may help add clarity:

     https://machinelearningmastery.com/how-to-develop-lstm-models-for-multi-step-time-series-forecasting-of-household-power-consumption/

     Reply
7. 

   SantobediJuly 17, 2023 at 11:44 pm#

   Hi James,

   If I have to predict several consecutive future time-series values, how can I do it? For example, if I have predictor variables and target till now (t=0), how can I predict the target at t+1, t+2, and t+3? In other words, if I have the predictor variables and target for every hour (as historical data), how can I predict the values of the target for the upcoming three hours? How can I prepare the dataset and update my model (e.g., LSTM)?

   Thank you.

   Reply
8. 

   TomSeptember 1, 2023 at 7:51 pm#

   Hi James,

   I’m just checking – in the snipper where you extract the last step, are we missing a colon after the “-1”?

   Something like

   x = x[:, -1:, :]

   Reply
   • 

     James CarmichaelSeptember 2, 2023 at 8:15 am#

     Hi Tom…Thank you for your feedback! We do not see an issue with the original code. What did you find when you executed it?

     Reply
9. 

   MykOctober 5, 2023 at 7:31 am#

   Given time series nature of the input, why did you set shuffle=true in DataLoader?

   Reply
   • 

     James CarmichaelOctober 5, 2023 at 9:51 am#

     Hi Myk…The following resource may be of interest:

     https://machinelearningmastery.com/training-a-pytorch-model-with-dataloader-and-dataset/#:~:text=The%20batch%20size%20is%20a,to%20read%20every%20batch%20once.

     Reply
10. 

    MykOctober 6, 2023 at 1:16 am#

    The samples may be shuffled because each sample is independent. That is, a given sample captures an entire input sequence; therefore, sequential information is retained even as samples are shuffled.

    Reply
11. 

    MykOctober 6, 2023 at 5:34 am#

    In your “complete code” above, lines 74-75 are redundant, as line 76 does the same thing:

    y_pred = model(X_train)
    y_pred = y_pred[:, -1, :]
    train_plot[lookback:train_size] = model(X_train)[:, -1, :]

    Reply
12. 

    MajkOctober 19, 2023 at 1:01 am#

    Both graphs seem to be shifted in both train and test plot. Why is that happening? And how to fix it?

    Reply
    • 

      James CarmichaelOctober 19, 2023 at 9:07 am#

      You are working on a time series forecasting problem and you plot your forecasted time series against the actual time series and it looks like the forecast is one step behind the actual.

      This is common.

      It means that your model is making a persistence forecast. This is a forecast where the input to the forecast (e.g. the observation at the previous time step) is predicted as the output.

      The persistence forecast is used as a baseline method for comparison on time series forecasting. You can learn more about the method here:

      How to Make Baseline Predictions for Time Series Forecasting with Python
      The persistence forecast is the best that we can do on challenging time series forecasting problems, such as those series that are a random walk, like short range movements of stock prices. You can learn more about this here:

      A Gentle Introduction to the Random Walk for Times Series Forecasting with Python
      If your sophisticated model, such as a neural network, is outputting a persistence forecast, it might mean:

      That the model requires further tuning.
      That the chosen model cannot address your specific dataset.
      It might also mean that your time series problem is not predictable.

      Reply
13. 

    SarangaNovember 11, 2023 at 4:44 pm#

    Hi there,
    All those tutorials refer to forecast training and testing, but can you do a one which actually forecast beyond the dataset as example next 3 .months forecast

    Reply
    • 

      James CarmichaelNovember 12, 2023 at 10:31 am#

      Hi Saranga…The following resource may be of interest to you:

      https://stackoverflow.com/questions/69906416/forecast-future-values-with-lstm-in-python

      Reply
14. 

    MuriloNovember 12, 2023 at 12:37 am#

    Does LSTM works for time series classification?

    Reply
15. 

    MichaelDecember 1, 2023 at 2:49 pm#

    Looking at your final graph above, it appears that the trained model is still only doing a persistence forecast as it is almost an exact shifted version of the dataset. Is that a reflection of an issue in this lookback approach implementation in general or is it a reflection of the lack of useful features in the dataset? How would you proceed from here to make it more accurate?

    Reply
    • 

      James CarmichaelDecember 2, 2023 at 11:35 am#

      Hi Michael…You are working on a time series forecasting problem and you plot your forecasted time series against the actual time series and it looks like the forecast is one step behind the actual.

      This is common.

      It means that your model is making a persistence forecast. This is a forecast where the input to the forecast (e.g. the observation at the previous time step) is predicted as the output.

      The persistence forecast is used as a baseline method for comparison on time series forecasting. You can learn more about the method here:

      How to Make Baseline Predictions for Time Series Forecasting with Python
      The persistence forecast is the best that we can do on challenging time series forecasting problems, such as those series that are a random walk, like short range movements of stock prices. You can learn more about this here:

      A Gentle Introduction to the Random Walk for Times Series Forecasting with Python
      If your sophisticated model, such as a neural network, is outputting a persistence forecast, it might mean:

      That the model requires further tuning.
      That the chosen model cannot address your specific dataset.
      It might also mean that your time series problem is not predictable.

      Reply
16. 

    MichaelDecember 2, 2023 at 1:47 pm#

    I played a bit with your code and I note that if I adjust the settings to eliminate the persistence shift on the trained set by increasing lookback or network size, I end up over fitting and getting even worse performance on the test set, so I get the impression this is a hard tradeoff in the case of this lookback lstm stackup. I read the other material, it is helpful, but doesn’t show me a way out of this tradeoff of either overfitting or persistence.

    Reply
17. 

    MuriloDecember 22, 2023 at 4:23 am#

    I have a few questions:

    1 – Is ‘hidden_size’ from Pytorch the same parameter as ‘units’ in Tensorflow/Keras?

    2 – If yes, what they actually represent in the first figure in this post? For example, if we have ‘hidden_size = X’, we have X LSTM cells? Or when we define ‘nn.LSTM(input_size=1, hidden_size=X, num_layers=1, batch_first=True)’ we have one cell no matter the value of X?

    3 – And how they are conected to the linear/dense layer? Each cell is conected to each node in the linear layer? Or just the last cell is conected to each node?

    Reply
18. 

    AlexanderFebruary 12, 2024 at 7:52 am#

    Is the next line correct ?
    target = dataset[i+1:i+lookback+1]

    Because we want as target the next direct output, it should be:
    target = dataset[i+lookback:i+lookback+1]

    Reply
    • 

      James CarmichaelFebruary 12, 2024 at 8:15 am#

      Hi Alexander…It should be correct. Did you execute the code? If so what did you find?

      Reply
19. 

    JApril 5, 2024 at 8:55 pm#

    Hi. I have a question to confirm my observation. Does the number of records on both training and test splits lessened based on the number of lookbacks? For instance in my case, there were 699 records for the original train split which became 698 after applying create_dataset() function. The same happened for my test wherein from 48, it became 47.

    The same length was also applied for train and test predictions. I also have another question with regards to displaying the plot. Since the number of train and test predictions are different from the number of records from the original train and test splits, how should I plot it with the x-axis as the datetime stamp?

    Reply
    • 

      James CarmichaelApril 7, 2024 at 7:18 am#

      Hi J…Based on your description, it sounds like you are observing a common behavior in time series data preparation when using a function likecreate_dataset() which typically is used to reformat a time series dataset into a format suitable for LSTM models, by creating lookback sequences. Let’s clarify and answer both parts of your question:

      ### Reduction in Records Due to Lookbacks

      The reduction in the number of records from your original dataset to what you have after applying thecreate_dataset() function is indeed expected due to the nature of lookback processing. Here’s how it works:

      – **Lookback Logic**: If you are using a lookback period (also known as lag, window size, or sequence length), the function needs to create sequences of that many past observations to predict the current value. For example, with a lookback of 1, each input sequence for your model will consist of one previous time step to predict the current time step.

      – **Effect on Data Size**: This means that the first few records in your dataset (exactly as many as your lookback period) won’t have enough previous data points to form a complete sequence. Thus, these records are typically dropped from the training or testing datasets. For a lookback of 1, you lose 1 data point at the start, which matches what you observed: 699 records becoming 698, and 48 becoming 47.

      ### Plotting Data with Mismatched Lengths

      Regarding plotting the training and test predictions alongside the original data with timestamps on the x-axis, considering the mismatch in lengths due to the lookback, you can handle this by adjusting the index of your predictions. Here’s how you can do it:

      1. **Offset Adjustments**: Since each prediction corresponds to an output where the input sequence ends, you should start plotting predictions from the index equivalent to the lookback period. For example, if your lookback is 1, your predictions should start from the second record in your original dataset.

      2. **Code Example**: Suppose your DataFrame with the original time series isdf, and it includes a datetime columndate. Here’s a basic plotting approach using Python and matplotlib:

      python
import matplotlib.pyplot as plt

      # Sample data
dates = df['date'] # Assuming 'date' is your datetime column
original_train = df['value'][:698] # Assuming 'value' is what you're predicting
original_test = df['value'][698:]

      # Assumingtrain_predictions andtest_predictions are your model outputs
train_predictions = [None] + list(train_predictions) # Offset for alignment
test_predictions = [None] * 699 + list(test_predictions) # Offset for alignment

      plt.figure(figsize=(15, 8))
plt.plot(dates, df['value'], label='Original Data')
plt.plot(dates, train_predictions, label='Train Predictions')
plt.plot(dates, test_predictions, label='Test Predictions')
plt.legend()
plt.title('Time Series Prediction')
plt.xlabel('Date')
plt.ylabel('Value')
plt.show()


      **Key Points in the Plotting Code:**

      – **Alignment by Index**: TheNone values are added to the predictions list to align the predictions correctly with the original data indices. Adjust the number ofNone values based on your exact lookback and how your splits are structured.
      – **Plotting All Together**: This script plots the original data along with the adjusted predictions on the same graph for visual comparison.

      This approach will help you visually compare how well your model’s predictions match up against the actual values, taking into account the datetime sequence. Adjust the plotting details as needed to fit your specific setup and visualization needs.

      Reply
20. 

    Half DomeMay 5, 2024 at 9:35 am#

    If we add a single line logging the time series in the first cell:

    timeseries = np.log(timeseries)

    We get an almost perfect fit against the test set.

    Reply
    • 

      James CarmichaelMay 6, 2024 at 7:11 am#

      Hi Half Dome…Thank you for your feedback and suggestion!

      Reply
21. 

    Jack chenSeptember 3, 2024 at 5:34 pm#

    Hello, I have a question, does the standard LSTM include teacher forcing? Do you consider teacher forcing in your code?

    Reply
    • 

      James CarmichaelSeptember 4, 2024 at 7:48 am#

      Hi Jack…The standard LSTM (Long Short-Term Memory) architecture does not inherently include teacher forcing. Teacher forcing is a training technique often used in sequence-to-sequence models, particularly in tasks like language translation, where the output of the model at a previous time step is fed as input for the next time step during training.

      ### **Understanding Teacher Forcing**:
      – **Teacher Forcing**: During training, instead of using the model’s predicted output from the previous time step as the input for the next step, the actual ground truth (the correct previous output) is used. This can help the model learn faster and improve stability during training, particularly in the early stages.

      ### **Implementing Teacher Forcing**:
      If you want to use teacher forcing with an LSTM in your code, you will need to implement it manually. Here’s a simple way to include teacher forcing in an LSTM-based model using PyTorch:

      python
import torch
import torch.nn as nn

      class LSTMModel(nn.Module):
def __init__(self, input_size, hidden_size, output_size, num_layers=1):
super(LSTMModel, self).__init__()
self.lstm = nn.LSTM(input_size, hidden_size, num_layers)
self.fc = nn.Linear(hidden_size, output_size)

      def forward(self, input_seq, target_seq=None, teacher_forcing_ratio=0.5):
# input_seq: shape (seq_len, batch_size, input_size)
# target_seq: shape (seq_len, batch_size, output_size)
outputs = []
hidden, cell = None, None

      # Loop through the sequence
for t in range(input_seq.size(0)):
if t == 0 or target_seq is None or torch.rand(1).item() > teacher_forcing_ratio:
input_t = input_seq[t].unsqueeze(0) # use the predicted value
else:
input_t = target_seq[t-1].unsqueeze(0) # use the actual target

      output, (hidden, cell) = self.lstm(input_t, (hidden, cell) if hidden is not None else None)
output = self.fc(output)
outputs.append(output)

      outputs = torch.cat(outputs, dim=0) # Concatenate outputs across the time dimension
return outputs

      # Example usage:
# lstm_model = LSTMModel(input_size, hidden_size, output_size)
# output = lstm_model(input_seq, target_seq, teacher_forcing_ratio=0.5)


      ### **Key Points**:
      – **Teacher Forcing Ratio**: You can control how often teacher forcing is applied with theteacher_forcing_ratio. A ratio of 1.0 means always using the true previous output, while 0.0 means never using it (only using the model’s predictions).
      – **Flexibility**: This approach gives you the flexibility to experiment with and without teacher forcing to see which works best for your specific task.

      Reply
22. 

    Prommin VSeptember 8, 2024 at 12:15 am#

    Thank you very much for providing this helpful tutorial. I have some questions regarding the plotting section.

    I understand that we are using the prediction for only the last value of each window. However, in the plotting section, why are the prediction values placed continuously, instead of placing them with lookback step interval.

    Reply
    • 

      James CarmichaelSeptember 8, 2024 at 7:30 am#

      Hi Prommin…In LSTM-based time series prediction, while you’re using a specific window size (or lookback) to make predictions, the continuous placement of predictions in the plot is likely due to how the model is evaluated and how the results are plotted.

      Here’s why this might happen:

      1. **Sliding Window Prediction**:
      When training and predicting using a sliding window, the LSTM model takes a sequence of past data points (the lookback window) and predicts the next value. After making this prediction, the window is shifted by one time step, and the next sequence is used to predict the subsequent value. This process continues, resulting in predictions being made at every time step, even though each prediction is based on a sliding window of previous steps.

      2. **Plotting Predictions Continuously**:
      During plotting, since the model makes predictions at each time step, these predicted values are typically plotted continuously, even though each prediction corresponds to the end of a window. This gives the appearance of a continuous line in the plot because you are essentially predicting one time step ahead for each sliding window.

      3. **Lookback Interval vs. Predictions**:
      If you were to only plot the predictions at intervals corresponding to the lookback window, you’d only have predictions every few steps (depending on your lookback size). However, this would make the prediction plot sparse, and you wouldn’t see a smooth curve of predictions. In many cases, continuous plotting gives a better visual representation of how well the model is performing across all time steps.

      ### Adjusting Plotting Based on Lookback:
      If you want to plot only the predictions made at specific intervals (e.g., only at the end of each lookback window), you could modify your plotting code to only show those points. This would involve keeping track of the indices where predictions are made and plotting only those.

      In summary, the continuous placement of predictions in the plot comes from the model making one-step-ahead predictions at each time step, which is why the predictions are plotted without gaps. If you want the predictions to be plotted at the lookback step interval, you’ll need to manually adjust the plotting logic.

      Reply
23. 

    LouisSeptember 15, 2024 at 11:42 pm#

    Hi James

    I just have a silly question in regards to the training device, how does one cast this onto a GPU rather than the CPU?

    Thank you

    Reply
    • 

      James CarmichaelSeptember 16, 2024 at 3:36 am#

      Hi Louis…Hello,

      That’s a great question, and it’s not silly at all! Running your PyTorch models on a GPU can significantly speed up training, especially for models like LSTMs that can be computationally intensive.

      To cast your model and data to the GPU in PyTorch, you’ll need to follow these steps:

      1. **Check if a GPU is available**:
      First, you need to check if CUDA (the computing platform for NVIDIA GPUs) is available on your system.

      python
import torch

      device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
print('Using device:', device)


      This code sets thedevice to'cuda' if a GPU is available; otherwise, it defaults to'cpu'.

      2. **Move your model to the GPU**:
      After defining your model, move it to the GPU using the.to() method.

      python
model = YourModelClass(*args)
model.to(device)


      3. **Move your data to the GPU**:
      When you load your data, you’ll need to move the tensors to the GPU as well. This is typically done within your training loop.

      python
for inputs, labels in data_loader:
inputs = inputs.to(device)
labels = labels.to(device)

      # Now proceed with your forward and backward passes
outputs = model(inputs)
loss = criterion(outputs, labels)
loss.backward()
optimizer.step()


      Ensure that every tensor involved in computation is moved to the GPU. This includes inputs, labels, and any other tensors you might be using.

      4. **Handle the hidden state (for RNNs like LSTM)**:
      If your LSTM model maintains a hidden state that you initialize manually, make sure to move it to the GPU as well.

      python
h0 = torch.zeros(num_layers, batch_size, hidden_size).to(device)
c0 = torch.zeros(num_layers, batch_size, hidden_size).to(device)


      5. **Adjust your data types if necessary**:
      Sometimes, you might need to ensure that your data types match between the model and inputs, especially when working with GPUs.

      6. **Example Putting It All Together**:

      python
import torch
import torch.nn as nn
import torch.optim as optim

      # Define your device
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
print('Using device:', device)

      # Define your model
class LSTMModel(nn.Module):
def __init__(self, input_size, hidden_size, num_layers, output_size):
super(LSTMModel, self).__init__()
self.hidden_size = hidden_size
self.num_layers = num_layers
self.lstm = nn.LSTM(input_size, hidden_size, num_layers, batch_first=True)
self.fc = nn.Linear(hidden_size, output_size)

      def forward(self, x):
h0 = torch.zeros(self.num_layers, x.size(0), self.hidden_size).to(device)
c0 = torch.zeros(self.num_layers, x.size(0), self.hidden_size).to(device)

      out, _ = self.lstm(x, (h0, c0))
out = self.fc(out[:, -1, :])
return out

      # Instantiate the model, define loss and optimizer
model = LSTMModel(input_size, hidden_size, num_layers, output_size).to(device)
criterion = nn.MSELoss()
optimizer = optim.Adam(model.parameters(), lr=learning_rate)

      # Training loop
for epoch in range(num_epochs):
for inputs, labels in data_loader:
inputs = inputs.to(device)
labels = labels.to(device)

      # Forward pass
outputs = model(inputs)
loss = criterion(outputs, labels)

      # Backward and optimize
optimizer.zero_grad()
loss.backward()
optimizer.step()

      print(f'Epoch [{epoch+1}/{num_epochs}], Loss: {loss.item():.4f}')


      7. **Verify that CUDA is being used**:
      You can verify that your tensors are on the GPU by checking their.device attribute.

      python
print(next(model.parameters()).device)


      This should output'cuda:0' if the model is on the GPU.

      8. **Common Pitfalls**:

      – **Forgetting to move data to the GPU**: Remember that both your model and your data need to be on the same device.
      – **Inconsistent devices**: Ensure that any new tensors created during training are also moved to the GPU.
      – **GPU Memory Limitations**: GPUs have limited memory. If you encounter out-of-memory errors, you may need to reduce your batch size.

      9. **Additional Tips**:

      – **DataLoader Optimization**: When usingDataLoader, you can setpin_memory=True to speed up data transfer to GPU.

      python
data_loader = DataLoader(dataset, batch_size=batch_size, shuffle=True, pin_memory=True)


      – **Using Multiple GPUs**: If you have multiple GPUs, you can leveragetorch.nn.DataParallel ortorch.nn.parallel.DistributedDataParallel for parallel training.

      python
if torch.cuda.device_count() > 1:
print(f"Using {torch.cuda.device_count()} GPUs")
model = nn.DataParallel(model)
model.to(device)


      10. **Check GPU Utilization**:

      – You can monitor your GPU usage with thenvidia-smi command in the terminal.

      bash
watch -n 1 nvidia-smi


      – This will help you ensure that your program is utilizing the GPU as expected.

      —

      By following these steps, you should be able to cast your model and training process onto a GPU. Running your training on a GPU can significantly reduce training time and handle larger models or datasets more efficiently.

      Feel free to ask if you have any more questions or need further clarification!

      Reply
      • 

        LouisSeptember 18, 2024 at 9:55 pm#

        Thank you very much!

        If I can ask one more question, albeit a code/logic heavy one:

        How would you go about implementing a validation step?

        Reply
24. 

    NicoleSeptember 22, 2024 at 1:01 am#

    Good day James

    I hope you are well.
    I have a rather dumb question, I have checked online and keep getting errors. Is there a way one can add a r^2 score?
    Thank you and have a lovely day

    Reply
    • 

      James CarmichaelSeptember 22, 2024 at 6:18 am#

      Hi Nicole…It’s not a dumb question at all! Adding the R² score to evaluate your LSTM model’s performance is actually quite useful.

      Here’s how you can compute the R² score in PyTorch:

      1. **Import the required module**:
      python
from sklearn.metrics import r2_score


      2. **Calculate the R² score**:
      After you’ve made predictions with your LSTM model, you can compare the predicted values with the true target values (both should be of the same shape). For example:

      python
# Assuming y_true is your true values and y_pred is your model's predicted values
y_true = y_true.detach().cpu().numpy() # Convert tensors to numpy arrays if they are in tensor form
y_pred = y_pred.detach().cpu().numpy()

      r2 = r2_score(y_true, y_pred)
print(f'R^2 Score: {r2}')


      Make sure that bothy_true andy_pred are either tensors or numpy arrays, and they need to be in the same shape before passing them tor2_score.

      ### Common Errors to Avoid:
      – **Shape mismatch**: Ensure the shapes ofy_true andy_pred are identical.
      – **Tensor to Numpy conversion**: If your data is in the form of PyTorch tensors, use.detach().cpu().numpy() to convert them to numpy arrays for compatibility withr2_score.

      Let me know if you run into any errors, and I’d be happy to help! Have a lovely day too!

      Reply
      • 

        NicoleSeptember 25, 2024 at 9:41 pm#

        Good day

        Thank you so much for the help. And sorry to bother again. I have little experience with modelling so am troubleshooting one thing at a time. So based on my understanding, the prediction is model(X_test) and then the real should be y_test. As they are split in the train_test_split and after in the create dataset, they should be the same size? I’m getting errors that they aren’t, how can I fix this?
        Thank you so so much again
        Have a lovely day

        Reply
25. 

    MicahJanuary 23, 2025 at 4:17 am#

    Hi, I was wondering what adjustments I should make if my dataset contains multiple features and I want the target value to be the last feature of the dataset.

    Reply
    • 

      James CarmichaelJanuary 23, 2025 at 10:00 am#

      Hi Micah…When working with an LSTM for time series prediction in PyTorch and your dataset contains multiple features where the target value is the last feature, you can adjust your dataset preparation and model design to account for the multi-feature input and ensure the correct feature is used as the target. Here’s a step-by-step guide:

      —

      ### 1. **Prepare the Dataset**
      You need to split your dataset into input features (X) and the target value (y), ensuring the last feature is used as the target.

      #### Example:
      Assume your dataset is a NumPy array or a pandas DataFrame with shape(n_samples, n_features):
      python
import numpy as np
import pandas as pd

      # Example dataset
data = np.random.rand(1000, 5) # 5 features
df = pd.DataFrame(data, columns=['feature1', 'feature2', 'feature3', 'feature4', 'target'])

      # Separate input features (X) and target (y)
X = df.iloc[:, :-1].values # All features except the last
y = df.iloc[:, -1].values # Last feature as the target


      —

      ### 2. **Create Sequences**
      Time series models require sequential data. Create sequences of input features (X) and corresponding targets (y) for each sequence.

      #### Example:
      python
def create_sequences(X, y, sequence_length):
sequences = []
targets = []
for i in range(len(X) - sequence_length):
seq = X[i:i+sequence_length]
target = y[i+sequence_length]
sequences.append(seq)
targets.append(target)
return np.array(sequences), np.array(targets)

      # Parameters
sequence_length = 10
X_seq, y_seq = create_sequences(X, y, sequence_length)

      # X_seq shape: (n_sequences, sequence_length, n_features)
# y_seq shape: (n_sequences,)


      —

      ### 3. **Convert to PyTorch Tensors**
      Convert the prepared sequences and targets into PyTorch tensors:
      python
import torch
from torch.utils.data import TensorDataset, DataLoader

      # Convert to tensors
X_tensor = torch.tensor(X_seq, dtype=torch.float32)
y_tensor = torch.tensor(y_seq, dtype=torch.float32)

      # Create DataLoader for batch processing
dataset = TensorDataset(X_tensor, y_tensor)
data_loader = DataLoader(dataset, batch_size=32, shuffle=True)


      —

      ### 4. **Modify the LSTM Model**
      Ensure your LSTM model is configured to handle multiple input features and outputs a single target value.

      #### Example LSTM Model:
      python
import torch.nn as nn

      class LSTMTimeSeries(nn.Module):
def __init__(self, input_dim, hidden_dim, num_layers, output_dim):
super(LSTMTimeSeries, self).__init__()
self.lstm = nn.LSTM(input_dim, hidden_dim, num_layers, batch_first=True)
self.fc = nn.Linear(hidden_dim, output_dim)

      def forward(self, x):
# x shape: (batch_size, sequence_length, input_dim)
lstm_out, _ = self.lstm(x) # lstm_out shape: (batch_size, sequence_length, hidden_dim)
out = self.fc(lstm_out[:, -1, :]) # Take the output from the last time step
return out

      # Model parameters
input_dim = X_seq.shape[2] # Number of features
hidden_dim = 64
num_layers = 2
output_dim = 1 # Single target value

      # Initialize model
model = LSTMTimeSeries(input_dim, hidden_dim, num_layers, output_dim)


      —

      ### 5. **Train the Model**
      Use a suitable loss function (e.g.,nn.MSELoss for regression) and an optimizer to train your model.

      #### Example Training Loop:
      python
# Loss and optimizer
criterion = nn.MSELoss()
optimizer = torch.optim.Adam(model.parameters(), lr=0.001)

      # Training loop
num_epochs = 20
for epoch in range(num_epochs):
for inputs, targets in data_loader:
# Forward pass
outputs = model(inputs)
loss = criterion(outputs.squeeze(), targets)

      # Backward pass and optimization
optimizer.zero_grad()
loss.backward()
optimizer.step()

      print(f"Epoch {epoch+1}/{num_epochs}, Loss: {loss.item():.4f}")


      —

      ### Key Adjustments for Multi-Feature Input:
      1. **Separate Target**: Ensure the target is separated from the input features during dataset preparation.
      2. **Sequence Creation**: Generate sequences of the input features while aligning them with the target values.
      3. **Model Input Dimension**: Theinput_dim of the LSTM model should match the number of input features.
      4. **Output Dimension**: The final output layer (nn.Linear) should produce a single value corresponding to the target.

      Reply
26. 

    MicahJanuary 28, 2025 at 3:55 pm#

    Thank you for your response. I was wondering if you would use the same method for plotting the data or a different method since we’re now dealing with different shapes.

    Reply
27. 

    ManelMarch 29, 2025 at 8:58 am#

    Hi, I think I’m a bit confused. When you apply your trained model to X_test :

    test_plot[train_size+lookback:len(timeseries)] = model(X_test)[:, -1, :]

    I feel like this is not correct from a machine learning standard, because X_test is basically a bunch of points from your test set of your timeseries. So… it’s basically data that you shouldn’t have access to at this point, right ?

    What I’m doing is : taking the last point from y_train, which is the last point from the train set of the timeseries, and then I iterate : I apply the model to this point and I get my first predicted point in the test set area. Then I apply the model again on this predicted point to get my next prediction. And so on. Of course, my prediction is quite off, but I feel like it makes sense not to use the data of the test set at all, right ?

    Then my thought is to try a larger look_back, so the model has more data to make a prediction.

    Please let me know if I’m wrong in my logic. Thanks ! 🙂

    Reply
    • 

      James CarmichaelMarch 30, 2025 at 4:15 am#

      Hi Manel…You’re asking a **really great question**, and your thinking is actually quite aligned with good machine learning practices, especially when it comes to **time series forecasting**.

      Let’s break it down to clarify:

      —

      ### 🔁 The Code You Mentioned:
      python
test_plot[train_size+lookback:len(timeseries)] = model(X_test)[:, -1, :]

      This line *does* indeed apply the trained model toX_test, which is a **sliding window of known sequences from the test set**. That means you’re using actual test data (even if just input sequences) to get the predictions. So yes — **this is not true forecasting**. This is more like **evaluating performance on held-out known data** (sometimes called teacher-forcing), not simulating real-world conditions where future data is unknown.

      —

      ### ✅ Your Approach (Autoregressive Forecasting):
      What you’re doing — where you:
      1. Take the lastlook_back window from training data,
      2. Predict the next time step,
      3. Append that prediction to your input window,
      4. Slide the window forward using your own predicted point as the new input,

      This is **exactly how you’d use the model in production**: predicting *strictly* from past observed (or previously predicted) values. This is called **recursive** or **autoregressive forecasting**.

      You’re spot-on that this better simulates how forecasting is done in practice — where you don’t get to “peek” at actual future values.

      —

      ### 📏 Why the Difference in Results?
      The model is trained on clean sequences where the inputs are true past values. When you start feeding in **predicted values** instead of real ones, **error compounds** — a problem known as **exposure bias** or **error accumulation**. This is why your predictions “drift” or look worse than when evaluated withX_test.

      —

      ### 🧠 How to Improve Recursive Forecasting:
      1. **Train with Noise / Scheduled Sampling**: During training, sometimes replace ground truth inputs with predicted ones. This teaches the model to deal with its own errors.
      2. **Use Sequence-to-Sequence LSTM**: Predict multiple time steps at once (many-to-many), rather than one at a time.
      3. **Try a Transformer or Temporal Convolutional Network**: These may handle longer dependencies better than standard LSTMs.
      4. **Increase Lookback Window**: Like you suggested — giving the model more context can help it make more stable predictions.

      —

      ### 🧪 When IsX_test Usage OK?
      It’s okay to useX_test when:
      – You’re **evaluating** the model’s performance (e.g., RMSE over the test set).
      – You want to see how well the model generalizes on **known sequences** from a holdout set.
      But you should **not** use it during a true forecasting simulation.

      —

      ### ✅ Summary:
      – You’re right — usingX_test in forecasting is not realistic.
      – Your autoregressive method is correct for real forecasting.
      – It’s harder (and more honest), but better simulates reality.
      – Largerlook_back may help; also consider improvements like sequence prediction or noise-aware training.

      —

      Reply

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