An Artificial-Intelligence-Based Method to Automatically Create Interpretable Models from Data Targeting Embedded Control Applications
Created by W.Langdon from
gp-bibliography.bib Revision:1.8051
- @Article{BUCHNER:2020:IFAC-PapersOnLine,
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author = "Jens S. Buchner and Sebastian Boblest and
Patrick Engel and Andrej Junginger and Holger Ulmer",
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title = "An Artificial-Intelligence-Based Method to
Automatically Create Interpretable Models from Data
Targeting Embedded Control Applications",
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journal = "IFAC-PapersOnLine",
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volume = "53",
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number = "2",
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pages = "13789--13796",
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year = "2020",
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note = "21st IFAC World Congress",
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ISSN = "2405-8963",
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DOI = "doi:10.1016/j.ifacol.2020.12.887",
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URL = "https://www.sciencedirect.com/science/article/pii/S240589632031226X",
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keywords = "genetic algorithms, genetic programming, Nonlinear,
optimal automotive control, Automotive system
identification, modeling, Modeling, supervision,
control, diagnosis of automotive systems",
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abstract = "The development of new automotive drivetrain layouts
requires modeling of the involved components to allow
for ideal control strategies. The creation of these
models is both costly and challenging, specifically
because interpretability, accuracy, and computational
effort need to be balanced. In this study, a method is
put forward which supports experts in the modeling
process and in making an educated choice to balance
these constraints. The method is based on the
artificial intelligence technique of genetic
programming. By solving a symbolic regression problem,
it automatically identifies equation-based models from
data. To address possible system complexities,
data-based expressions like curves and maps can
additionally be employed for the model identification.
The performance of the method is demonstrated based on
two examples: 1. Identification of a pure equation
based model, demonstrating the benefit of
interpretability. 2. Creation of a hybrid-model,
combining a base equation with data-based expressions.
Possible applications of the method are model creation,
system identification, structural optimization, and
model reduction. The existing implementation in ETAS
ASCMO-MOCA also offers a high efficiency increase by
combining and automating the two procedural steps of
embedded function engineering and calibration",
- }
Genetic Programming entries for
Jens S Buchner
Sebastian Boblest
Patrick Engel
Andrej Junginger
Holger Ulmer
Citations