Martin Rätz scite author profile

Time series forecasting is fundamental for various use cases in different domains such as energy systems and economics. Creating a forecasting model for a specific use case requires an iterative and complex design process. The typical design process includes five sections (1) data preprocessing, (2) feature engineering, (3) hyperparameter optimization, (4) forecasting method selection, and (5) forecast ensembling, which are commonly organized in a pipeline structure. One promising approach to handle the ever‐growing demand for time series forecasts is automating this design process. The article, thus, reviews existing literature on automated time series forecasting pipelines and analyzes how the design process of forecasting models is currently automated. Thereby, we consider both automated machine learning (AutoML) and automated statistical forecasting methods in a single forecasting pipeline. For this purpose, we first present and compare the identified automation methods for each pipeline section. Second, we analyze these automation methods regarding their interaction, combination, and coverage of the five pipeline sections. For both, we discuss the reviewed literature that contributes toward automating the design process, identify problems, give recommendations, and suggest future research. This review reveals that the majority of the reviewed literature only covers two or three of the five pipeline sections. We conclude that future research has to holistically consider the automation of the forecasting pipeline to enable the large‐scale application of time series forecasting. This article is categorized under: Technologies > Machine Learning Technologies > Prediction Algorithmic Development > Spatial and Temporal Data Mining

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Potential of Demand-controlled Ventilation in Different Space Types in a University Hospital Building : A Case Study

Kalliomäki¹,

Rätz²,

Müller³

et al. 2021

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Effect of reduced air change rates on indoor air quality and air conditioning energy consumption in retail buildings

Finkbeiner¹,

Müller²,

Rätz³

et al. 2021

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Identifying the Validity Domain of Machine Learning Models in Building Energy Systems

Rätz

Henkel

Stoffel

et al. 2023

Preprint

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Martin Rätz

Automated data-driven modeling of building energy systems via machine learning algorithms

Review of automated time series forecasting pipelines

Potential of Demand-controlled Ventilation in Different Space Types in a University Hospital Building : A Case Study

Effect of reduced air change rates on indoor air quality and air conditioning energy consumption in retail buildings

Identifying the Validity Domain of Machine Learning Models in Building Energy Systems

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