Combining Embeddings and Fuzzy Time Series for High-Dimensional Time
Series Forecasting in Internet of Energy Applications
- URL: http://arxiv.org/abs/2112.02140v1
- Date: Fri, 3 Dec 2021 19:50:09 GMT
- Title: Combining Embeddings and Fuzzy Time Series for High-Dimensional Time
Series Forecasting in Internet of Energy Applications
- Authors: Hugo Vinicius Bitencourt, Luiz Augusto Facury de Souza, Matheus
Cascalho dos Santos, Petr\^onio C\^andido de Lima e Silva, Frederico Gadelha
Guimar\~aes
- Abstract summary: Fuzzy Time Series (FTS) models stand out as data-driven non-parametric models of easy implementation and high accuracy.
We present a new methodology for handling high-dimensional time series, by projecting the original high-dimensional data into a low dimensional embedding space.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: The prediction of residential power usage is essential in assisting a smart
grid to manage and preserve energy to ensure efficient use. An accurate energy
forecasting at the customer level will reflect directly into efficiency
improvements across the power grid system, however forecasting building energy
use is a complex task due to many influencing factors, such as meteorological
and occupancy patterns. In addiction, high-dimensional time series increasingly
arise in the Internet of Energy (IoE), given the emergence of multi-sensor
environments and the two way communication between energy consumers and the
smart grid. Therefore, methods that are capable of computing high-dimensional
time series are of great value in smart building and IoE applications. Fuzzy
Time Series (FTS) models stand out as data-driven non-parametric models of easy
implementation and high accuracy. Unfortunately, the existing FTS models can be
unfeasible if all features were used to train the model. We present a new
methodology for handling high-dimensional time series, by projecting the
original high-dimensional data into a low dimensional embedding space and using
multivariate FTS approach in this low dimensional representation. Combining
these techniques enables a better representation of the complex content of
multivariate time series and more accurate forecasts.
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