https://github.com/winedarksea/AutoTS

Automated Time Series Forecasting
https://github.com/winedarksea/AutoTS

automl autots deep-learning feature-engineering forecasting machine-learning preprocessing time-series

Last synced: about 2 months ago
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Automated Time Series Forecasting

• Host: GitHub
• URL: https://github.com/winedarksea/AutoTS
• Owner: winedarksea
• License: mit
• Created: 2019-11-26T14:13:16.000Z (almost 5 years ago)
• Default Branch: master
• Last Pushed: 2024-07-26T15:57:08.000Z (about 2 months ago)
• Last Synced: 2024-07-26T17:41:46.843Z (about 2 months ago)
• Topics: automl, autots, deep-learning, feature-engineering, forecasting, machine-learning, preprocessing, time-series
• Language: Python
• Homepage:
• Size: 40.4 MB
• Stars: 1,066
• Watchers: 23
• Forks: 98
• Open Issues: 22
• Metadata Files:
  • Readme: README.md
  • Contributing: CONTRIBUTING.md
  • License: LICENSE
  • Code of conduct: CODE_OF_CONDUCT.md

Awesome Lists containing this project

• awesome-time-series - AutoTS - accuracy forecasts at scale. (📦 Packages / Python)
• StarryDivineSky - winedarksea/AutoTS

README

        
# AutoTS



AutoTS is a time series package for Python designed for rapidly deploying high-accuracy forecasts at scale. 

In 2023, AutoTS won in the M6 forecasting competition, delivering the highest performance investment decisions across 12 months of stock market forecasting.

There are dozens of forecasting models usable in the `sklearn` style of `.fit()` and `.predict()`. 

These includes naive, statistical, machine learning, and deep learning models. 

Additionally, there are over 30 time series specific transforms usable in the `sklearn` style of `.fit()`, `.transform()` and `.inverse_transform()`. 

All of these function directly on Pandas Dataframes, without the need for conversion to proprietary objects. 

All models support forecasting multivariate (multiple time series) outputs and also support probabilistic (upper/lower bound) forecasts. 

Most models can readily scale to tens and even hundreds of thousands of input series. 

Many models also support passing in user-defined exogenous regressors. 

These models are all designed for integration in an AutoML feature search which automatically finds the best models, preprocessing, and ensembling for a given dataset through genetic algorithms. 

Horizontal and mosaic style ensembles are the flagship ensembling types, allowing each series to receive the most accurate possible models while still maintaining scalability.

A combination of metrics and cross-validation options, the ability to apply subsets and weighting, regressor generation tools, simulation forecasting mode, event risk forecasting, live datasets, template import and export, plotting, and a collection of data shaping parameters round out the available feature set. 

## Table of Contents

* [Installation](https://github.com/winedarksea/AutoTS#installation)

* [Basic Use](https://github.com/winedarksea/AutoTS#basic-use)

* [Tips for Speed and Large Data](https://github.com/winedarksea/AutoTS#tips-for-speed-and-large-data)

* Extended Tutorial [GitHub](https://github.com/winedarksea/AutoTS/blob/master/extended_tutorial.md) or [Docs](https://winedarksea.github.io/AutoTS/build/html/source/tutorial.html)

* [Production Example](https://github.com/winedarksea/AutoTS/blob/master/production_example.py)

## Installation

```

pip install autots

```

This includes dependencies for basic models, but [additonal packages](https://github.com/winedarksea/AutoTS/blob/master/extended_tutorial.md#installation-and-dependency-versioning) are required for some models and methods.

Be advised there are several other projects that have chosen similar names, so make sure you are on the right AutoTS code, papers, and documentation.

## Basic Use

Input data for AutoTS is expected to come in either a *long* or a *wide* format:

- The *wide* format is a `pandas.DataFrame` with a `pandas.DatetimeIndex` and each column a distinct series. 

- The *long* format has three columns: 

  - Date (ideally already in pandas-recognized `datetime` format)

  - Series ID. For a single time series, series_id can be `= None`.

  - Value

- For *long* data, the column name for each of these is passed to `.fit()` as `date_col`, `id_col`, and `value_col`. No parameters are needed for *wide* data.

Lower-level functions are only designed for `wide` style data.

```python

# also load: _hourly, _monthly, _weekly, _yearly, or _live_daily

from autots import AutoTS, load_daily

# sample datasets can be used in either of the long or wide import shapes

long = False

df = load_daily(long=long)

model = AutoTS(

    forecast_length=21,

    frequency='infer',

    prediction_interval=0.9,

    ensemble='auto',

    model_list="fast",  # "superfast", "default", "fast_parallel"

    transformer_list="fast",  # "superfast",

    drop_most_recent=1,

    max_generations=4,

    num_validations=2,

    validation_method="backwards"

)

model = model.fit(

    df,

    date_col='datetime' if long else None,

    value_col='value' if long else None,

    id_col='series_id' if long else None,

)

prediction = model.predict()

# plot a sample

prediction.plot(model.df_wide_numeric,

                series=model.df_wide_numeric.columns[0],

                start_date="2019-01-01")

# Print the details of the best model

print(model)

# point forecasts dataframe

forecasts_df = prediction.forecast

# upper and lower forecasts

forecasts_up, forecasts_low = prediction.upper_forecast, prediction.lower_forecast

# accuracy of all tried model results

model_results = model.results()

# and aggregated from cross validation

validation_results = model.results("validation")

```

The lower-level API, in particular the large section of time series transformers in the scikit-learn style, can also be utilized independently from the AutoML framework.

Check out [extended_tutorial.md](https://winedarksea.github.io/AutoTS/build/html/source/tutorial.html) for a more detailed guide to features.

Also take a look at the [production_example.py](https://github.com/winedarksea/AutoTS/blob/master/production_example.py)

## Tips for Speed and Large Data:

* Use appropriate model lists, especially the predefined lists:

	* `superfast` (simple naive models) and `fast` (more complex but still faster models, optimized for many series)

	* `fast_parallel` (a combination of `fast` and `parallel`) or `parallel`, given many CPU cores are available

		* `n_jobs` usually gets pretty close with `='auto'` but adjust as necessary for the environment

	* 'scalable' is the best list to avoid crashing when many series are present. There is also a transformer_list = 'scalable'

	* see a dict of predefined lists (some defined for internal use) with `from autots.models.model_list import model_lists`

* Use the `subset` parameter when there are many similar series, `subset=100` will often generalize well for tens of thousands of similar series.

	* if using `subset`, passing `weights` for series will weight subset selection towards higher priority series.

	* if limited by RAM, it can be distributed by running multiple instances of AutoTS on different batches of data, having first imported a template pretrained as a starting point for all.

* Set `model_interrupt=True` which passes over the current model when a `KeyboardInterrupt` ie `crtl+c` is pressed (although if the interrupt falls between generations it will stop the entire training).

* Use the `result_file` method of `.fit()` which will save progress after each generation - helpful to save progress if a long training is being done. Use `import_results` to recover.

* While Transformations are pretty fast, setting `transformer_max_depth` to a lower number (say, 2) will increase speed. Also utilize `transformer_list` == 'fast' or 'superfast'.

* Check out [this example](https://github.com/winedarksea/AutoTS/discussions/76) of using AutoTS with pandas UDF.

* Ensembles are obviously slower to predict because they run many models, 'distance' models 2x slower, and 'simple' models 3x-5x slower.

	* `ensemble='horizontal-max'` with `model_list='no_shared_fast'` can scale relatively well given many cpu cores because each model is only run on the series it is needed for.

* Reducing `num_validations` and `models_to_validate` will decrease runtime but may lead to poorer model selections.

* For datasets with many records, upsampling (for example, from daily to monthly frequency forecasts) can reduce training time if appropriate.

	* this can be done by adjusting `frequency` and `aggfunc` but is probably best done before passing data into AutoTS.

* It will be faster if NaN's are already filled. If a search for optimal NaN fill method is not required, then fill any NaN with a satisfactory method before passing to class.

* Set `runtime_weighting` in `metric_weighting` to a higher value. This will guide the search towards faster models, although it may come at the expense of accuracy. 

* Memory shortage is the most common cause of random process/kernel crashes. Try testing a data subset and using a different model list if issues occur. Please also report crashes if found to be linked to a specific set of model parameters (not AutoTS parameters but the underlying forecasting model params). Also crashes vary significantly by setup such as underlying linpack/blas so seeing crash differences between environments can be expected. 

## How to Contribute:

* Give feedback on where you find the documentation confusing

* Use AutoTS and...

	* Report errors and request features by adding Issues on GitHub

	* Posting the top model templates for your data (to help improve the starting templates)

	* Feel free to recommend different search grid parameters for your favorite models

* And, of course, contributing to the codebase directly on GitHub.

*Also known as Project CATS (Catlin's Automated Time Series) hence the logo.*