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--- |
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license: apache-2.0 |
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pipeline_tag: time-series-forecasting |
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tags: |
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- time series |
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- forecasting |
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- pretrained models |
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- foundation models |
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- time series foundation models |
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- time-series |
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--- |
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# TinyTimeMixer (TTM) 1M Model Card |
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<p align="center" width="100%"> |
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<img src="ttm_image.webp" width="600"> |
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</p> |
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TinyTimeMixers (TTMs) are compact pre-trained models for Multivariate Time-Series Forecasting, open-sourced by IBM Research. |
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**With less than 1 Million parameters, TTM introduces the notion of the first-ever “tiny” pre-trained models for Time-Series Forecasting.** |
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TTM is accepted in NeurIPS 2024. |
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TTM outperforms several popular benchmarks demanding billions of parameters in zero-shot and few-shot forecasting. TTMs are lightweight |
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forecasters, pre-trained on publicly available time series data with various augmentations. TTM provides state-of-the-art zero-shot forecasts and can easily be |
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fine-tuned for multi-variate forecasts with just 5% of the training data to be competitive. Refer to our [paper](https://arxiv.org/pdf/2401.03955.pdf) for more details. |
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**The current open-source version supports point forecasting use-cases specifically ranging from minutely to hourly resolutions |
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(Ex. 10 min, 15 min, 1 hour.).** |
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**Note that zeroshot, fine-tuning and inference tasks using TTM can easily be executed in 1 GPU machine or in laptops too!!** |
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## Model Releases (along with the branch name where the models are stored): |
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- **512-96:** Given the last 512 time-points (i.e. context length), this model can forecast up to next 96 time-points (i.e. forecast length) |
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in future. This model is targeted towards a forecasting setting of context length 512 and forecast length 96 and |
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recommended for hourly and minutely resolutions (Ex. 10 min, 15 min, 1 hour, etc). This model refers to the TTM-Q variant used in the paper. (branch name: main) [[Benchmark Scripts]](https://github.com/IBM/tsfm/blob/main/notebooks/hfdemo/tinytimemixer/ttm_benchmarking_512_96.ipynb) |
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- **1024-96:** Given the last 1024 time-points (i.e. context length), this model can forecast up to next 96 time-points (i.e. forecast length) |
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in future. This model is targeted towards a long forecasting setting of context length 1024 and forecast length 96 and |
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recommended for hourly and minutely resolutions (Ex. 10 min, 15 min, 1 hour, etc). (branch name: 1024-96-v1) [[Benchmark Scripts]](https://github.com/IBM/tsfm/blob/main/notebooks/hfdemo/tinytimemixer/ttm_benchmarking_1024_96.ipynb) |
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- **New Releases (trained on larger pretraining datasets, released on October 2024)**: |
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- **512-96-r2**: Given the last 512 time-points (i.e. context length), this model can forecast up to next 96 time-points (i.e. forecast length) |
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in future. This model is pre-trained with a larger pretraining dataset for improved accuracy. Recommended for hourly and minutely |
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resolutions (Ex. 10 min, 15 min, 1 hour, etc). This model refers to the TTM-B variant used in the paper (branch name: 512-96-r2) [[Benchmark Scripts]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/hfdemo/tinytimemixer/ttm_v2_benchmarking_512_96.ipynb) |
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## Model Capabilities with example scripts |
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The below model scripts can be used for any of the above TTM models. Please update the HF model URL and branch name in the `from_pretrained` call appropriately to pick the model of your choice. |
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- Getting Started [[colab]](https://colab.research.google.com/github/IBM/tsfm/blob/main/notebooks/tutorial/ttm_tutorial.ipynb) |
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- Zeroshot Multivariate Forecasting [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/hfdemo/ttm_getting_started.ipynb) |
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- Finetuned Multivariate Forecasting: |
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- Channel-Independent Finetuning [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/hfdemo/ttm_getting_started.ipynb) [M4-Hourly finetuning](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/hfdemo/tinytimemixer/ttm_m4_hourly.ipynb) |
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- Channel-Mix Finetuning [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/tutorial/ttm_channel_mix_finetuning.ipynb) |
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- **New Releases (extended features released on October 2024)** |
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- Finetuning and Forecasting with Exogenous/Control Variables [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/tutorial/ttm_with_exog_tutorial.ipynb) |
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- Finetuning and Forecasting with static categorical features [Example: To be added soon] |
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- Rolling Forecasts - Extend forecast lengths beyond 96 via rolling capability [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/hfdemo/ttm_rolling_prediction_getting_started.ipynb) |
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- Helper scripts for optimal Learning Rate suggestions for Finetuning [[Example]](https://github.com/ibm-granite/granite-tsfm/blob/ttm_v2_release/notebooks/tutorial/ttm_with_exog_tutorial.ipynb) |
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## Benchmarks |
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TTM outperforms popular benchmarks such as TimesFM, Moirai, Chronos, Lag-Llama, Moment, GPT4TS, TimeLLM, LLMTime in zero/fewshot forecasting while reducing computational requirements significantly. |
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Moreover, TTMs are lightweight and can be executed even on CPU-only machines, enhancing usability and fostering wider |
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adoption in resource-constrained environments. For more details, refer to our [paper](https://arxiv.org/pdf/2401.03955.pdf) TTM-Q referred in the paper maps to the `512-96` model |
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uploaded in the main branch, and TTM-B referred in the paper maps to the `512-96-r2` model. Please note that the Granite TTM models are pre-trained exclusively on datasets |
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with clear commercial-use licenses that are approved by our legal team. As a result, the pre-training dataset used in this release differs slightly from the one used in the research |
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paper, which may lead to minor variations in model performance as compared to the published results. Please refer to our paper for more details. |
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## Recommended Use |
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1. Users have to externally standard scale their data independently for every channel before feeding it to the model (Refer to [TSP](https://github.com/IBM/tsfm/blob/main/tsfm_public/toolkit/time_series_preprocessor.py), our data processing utility for data scaling.) |
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2. The current open-source version supports only minutely and hourly resolutions(Ex. 10 min, 15 min, 1 hour.). Other lower resolutions (say weekly, or monthly) are currently not supported in this version, as the model needs a minimum context length of 512 or 1024. |
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3. Enabling any upsampling or prepending zeros to virtually increase the context length for shorter-length datasets is not recommended and will |
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impact the model performance. |
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## Model Description |
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TTM falls under the category of “focused pre-trained models”, wherein each pre-trained TTM is tailored for a particular forecasting |
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setting (governed by the context length and forecast length). Instead of building one massive model supporting all forecasting settings, |
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we opt for the approach of constructing smaller pre-trained models, each focusing on a specific forecasting setting, thereby |
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yielding more accurate results. Furthermore, this approach ensures that our models remain extremely small and exceptionally fast, |
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facilitating easy deployment without demanding a ton of resources. |
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Hence, in this model card, we plan to release several pre-trained |
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TTMs that can cater to many common forecasting settings in practice. Additionally, we have released our source code along with |
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our pretraining scripts that users can utilize to pretrain models on their own. Pretraining TTMs is very easy and fast, taking |
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only 3-6 hours using 6 A100 GPUs, as opposed to several days or weeks in traditional approaches. |
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Each pre-trained model will be released in a different branch name in this model card. Kindly access the required model using our |
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getting started [notebook](https://github.com/IBM/tsfm/blob/main/notebooks/hfdemo/ttm_getting_started.ipynb) mentioning the branch name. |
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## Model Details |
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For more details on TTM architecture and benchmarks, refer to our [paper](https://arxiv.org/pdf/2401.03955.pdf). |
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TTM-1 currently supports 2 modes: |
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- **Zeroshot forecasting**: Directly apply the pre-trained model on your target data to get an initial forecast (with no training). |
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- **Finetuned forecasting**: Finetune the pre-trained model with a subset of your target data to further improve the forecast. |
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**Since, TTM models are extremely small and fast, it is practically very easy to finetune the model with your available target data in few minutes |
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to get more accurate forecasts.** |
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The current release supports multivariate forecasting via both channel independence and channel-mixing approaches. |
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Decoder Channel-Mixing can be enabled during fine-tuning for capturing strong channel-correlation patterns across |
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time-series variates, a critical capability lacking in existing counterparts. |
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In addition, TTM also supports exogenous infusion and categorical data infusion. |
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### Model Sources |
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- **Repository:** https://github.com/ibm-granite/granite-tsfm/tree/main/tsfm_public/models/tinytimemixer |
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- **Paper:** https://arxiv.org/pdf/2401.03955.pdf |
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### Blogs and articles on TTM: |
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- Refer to our [wiki](https://github.com/ibm-granite/granite-tsfm/wiki) |
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## Uses |
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``` |
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# Load Model from HF Model Hub mentioning the branch name in revision field |
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model = TinyTimeMixerForPrediction.from_pretrained( |
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"https://huggingface.co/ibm/TTM", revision="main" |
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) |
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# Do zeroshot |
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zeroshot_trainer = Trainer( |
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model=model, |
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args=zeroshot_forecast_args, |
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) |
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) |
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zeroshot_output = zeroshot_trainer.evaluate(dset_test) |
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# Freeze backbone and enable few-shot or finetuning: |
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# freeze backbone |
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for param in model.backbone.parameters(): |
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param.requires_grad = False |
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finetune_forecast_trainer = Trainer( |
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model=model, |
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args=finetune_forecast_args, |
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train_dataset=dset_train, |
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eval_dataset=dset_val, |
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callbacks=[early_stopping_callback, tracking_callback], |
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optimizers=(optimizer, scheduler), |
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) |
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finetune_forecast_trainer.train() |
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fewshot_output = finetune_forecast_trainer.evaluate(dset_test) |
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``` |
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## Training Data |
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The TTM models were trained on a collection of datasets from the Monash Time Series Forecasting repository. The datasets used include: |
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- Australian Electricity Demand: https://zenodo.org/records/4659727 |
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- Australian Weather: https://zenodo.org/records/4654822 |
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- Bitcoin dataset: https://zenodo.org/records/5122101 |
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- KDD Cup 2018 dataset: https://zenodo.org/records/4656756 |
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- London Smart Meters: https://zenodo.org/records/4656091 |
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- Saugeen River Flow: https://zenodo.org/records/4656058 |
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- Solar Power: https://zenodo.org/records/4656027 |
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- Sunspots: https://zenodo.org/records/4654722 |
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- Solar: https://zenodo.org/records/4656144 |
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- US Births: https://zenodo.org/records/4656049 |
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- Wind Farms Production data: https://zenodo.org/records/4654858 |
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- Wind Power: https://zenodo.org/records/4656032 |
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- [to be updated] |
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## Citation [optional] |
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Kindly cite the following paper, if you intend to use our model or its associated architectures/approaches in your |
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work |
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**BibTeX:** |
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``` |
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@inproceedings{ekambaram2024tinytimemixersttms, |
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title={Tiny Time Mixers (TTMs): Fast Pre-trained Models for Enhanced Zero/Few-Shot Forecasting of Multivariate Time Series}, |
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author={Vijay Ekambaram and Arindam Jati and Pankaj Dayama and Sumanta Mukherjee and Nam H. Nguyen and Wesley M. Gifford and Chandra Reddy and Jayant Kalagnanam}, |
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booktitle={Advances in Neural Information Processing Systems (NeurIPS 2024)}, |
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year={2024}, |
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} |
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``` |
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## Model Card Authors |
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Vijay Ekambaram, Arindam Jati, Pankaj Dayama, Wesley M. Gifford, Sumanta Mukherjee, Chandra Reddy and Jayant Kalagnanam |
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## IBM Public Repository Disclosure: |
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All content in this repository including code has been provided by IBM under the associated |
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open source software license and IBM is under no obligation to provide enhancements, |
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updates, or support. IBM developers produced this code as an |
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open source project (not as an IBM product), and IBM makes no assertions as to |
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the level of quality nor security, and will not be maintaining this code going forward. |