tsam is a python package which uses different machine learning algorithms for the aggregation of time series. The data aggregation can be performed in two freely combinable dimensions: By representing the time series by a user-defined number of typical periods or by decreasing the temporal resolution. tsam was originally designed for reducing the computational load for large-scale energy system optimization models by aggregating their input data, but is applicable for all types of time series, e.g., weather data, load data, both simultaneously or other arbitrary groups of time series.
The documentation of the tsam code can be found here.
- flexible handling of multidimensional time-series via the pandas module
- different aggregation methods implemented (averaging, k-means, exact k-medoids, hierarchical, k-maxoids, k-medoids with contiguity), which are based on scikit-learn, or self-programmed with pyomo
- hypertuning of aggregation parameters to find the optimal combination of the number of segments inside a period and the number of typical periods
- novel representation methods, keeping statistical attributes, such as the distribution
- flexible integration of extreme periods as own cluster centers
- weighting for the case of multidimensional time-series to represent their relevance
To avoid dependency conflicts, it is recommended that you install Tsam in its own environment. You can use either uv or conda/mamba ) to manage environments and installations. Before proceeding, you must install either UV or Conda/Mamba, or both.
Quick Install with uv
uv venv tsam_env
uv pip install tsamOr from conda-forge:
conda create -n tsam_env -c conda-forge tsamconda and mamba can be used interchangeably
git clone https://github.com/FZJ-IEK3-VSA/tsam.git
cd tsamuv venv
source .venv/bin/activate # On Windows: .venv\Scripts\activate
uv pip install -e ".[develop]"conda env create -n tsam_env --file=environment.yml
conda activate tsam_env
pip install -e . --no-depspre-commit installSee CONTRIBUTING.md for detailed development guidelines.
HiGHS is installed by default. For better performance on large problems, commercial solvers (Gurobi, CPLEX) are recommended if you have a license
A small example how tsam can be used is described as follows:
import pandas as pd
import tsamRead in the time series data set with pandas
raw = pd.read_csv('testdata.csv', index_col=0, parse_dates=True)Run the aggregation - specify the number of typical periods and configure clustering/segmentation options:
from tsam import aggregate, ClusterConfig, SegmentConfig
result = tsam.aggregate(
raw,
n_clusters=8,
period_duration='24h', # or 24, '1d'
cluster=ClusterConfig(
method='hierarchical',
representation='distribution_minmax',
),
segments=SegmentConfig(n_segments=8),
)Access the results:
# Get the typical periods DataFrame
cluster_representatives = result.cluster_representatives
# Check accuracy metrics
print(f"RMSE: {result.accuracy.rmse.mean():.4f}")
# Reconstruct the original time series from typical periods
reconstructed = result.reconstructed
# Save results
cluster_representatives.to_csv('cluster_representatives.csv')For backward compatibility, the class-based API of TSAM Version 2 is still available.
import tsam.timeseriesaggregation as tsam_legacy
aggregation = tsam_legacy.TimeSeriesAggregation(
raw,
noTypicalPeriods=8,
hoursPerPeriod=24,
segmentation=True,
noSegments=8,
representationMethod="distributionAndMinMaxRepresentation",
clusterMethod='hierarchical'
)
cluster_representatives = aggregation.createTypicalPeriods()Detailed examples can be found at:/docs/source/examples_notebooks/
A quickstart example shows the capabilities of tsam as a Jupyter notebook.
A second example shows in more detail how to access the relevant aggregation results required for parameterizing e.g. an optimization.
The example time series are based on a department publication and the test reference years of the DWD.
MIT License
Copyright (C) 2017-2025 Leander Kotzur (FZJ IEK-3), Maximilian Hoffmann (FZJ IEK-3), Peter Markewitz (FZJ IEK-3), Martin Robinius (FZJ IEK-3), Detlef Stolten (FZJ IEK-3)
You should have received a copy of the MIT License along with this program. If not, see https://opensource.org/licenses/MIT
The core developer team sits in the Institute of Energy and Climate Research - Techno-Economic Energy Systems Analysis (IEK-3) belonging to the Forschungszentrum Jülich.
If you want to use tsam in a published work, please kindly cite our latest journal articles:
- Hoffmann et al. (2022):
The Pareto-Optimal Temporal Aggregation of Energy System Models
If you are further interested in the impact of time series aggregation on the cost-optimal results on different energy system use cases, you can find a publication which validates the methods and describes their cababilites via the following link. A second publication introduces a method how to model state variables (e.g. the state of charge of energy storage components) between the aggregated typical periods which can be found here. Finally yet importantly the potential of time series aggregation to simplify mixed integer linear problems is investigated here.
The publications about time series aggregation for energy system optimization models published alongside the development of tsam are listed below:
- Hoffmann et al. (2021):
The Pareto-Optimal Temporal Aggregation of Energy System Models
(open access manuscript to be found here) - Hoffmann et al. (2021):
Typical periods or typical time steps? A multi-model analysis to determine the optimal temporal aggregation for energy system models - Hoffmann et al. (2020):
A Review on Time Series Aggregation Methods for Energy System Models - Kannengießer et al. (2019):
Reducing Computational Load for Mixed Integer Linear Programming: An Example for a District and an Island Energy System - Kotzur et al. (2018):
Time series aggregation for energy system design: Modeling seasonal storage
(open access manuscript to be found here) - Kotzur et al. (2018):
Impact of different time series aggregation methods on optimal energy system design
(open access manuscript to be found here)
This work is supported by the Helmholtz Association under the Joint Initiative "Energy System 2050 A Contribution of the Research Field Energy" and the program "Energy System Design" and within the BMWi/BMWk funded project METIS.
