Symbolic regression of uncertainty-resilient inferential sensors for fault diagnostics
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- @Article{HALE:2020:IFAC-PapersOnLine,
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author = "William T. Hale and George M. Bollas",
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title = "Symbolic regression of uncertainty-resilient
inferential sensors for fault diagnostics",
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journal = "IFAC-PapersOnLine",
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volume = "53",
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number = "2",
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pages = "11446--11451",
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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.2020.12.582",
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URL = "https://www.sciencedirect.com/science/article/pii/S2405896320308831",
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keywords = "genetic algorithms, genetic programming, fault
detection, diagnosis, experiment design, AI methods for
FDI",
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abstract = "An algorithm is presented for the design of
inferential sensors for fault diagnostics in thermal
management systems. The algorithm uses input and output
sensed system information to improve the detection and
isolation of a fault by generating inferential sensors
that augment the measured information to: (i) reduce
the evidence of uncertainty in the inferred variables,
and thus decrease false alarm and nondetection rates;
and (ii) provide distinguishable responses to faults,
and thus reduce reduce the rate of misdiagnoses. The
novelty of the algorithm is its use of genetic
programming to evolve explainable inferential sensors
that maximize information criteria specific to fault
diagnostics. The chosen criteria: (i) least squares
regression; and (ii) Ds -optimality (calculated from
the Fisher Information Matrix), leverage symbolic
mathematics and automatic differentiation to obtain
parametric sensitivities of the measured outputs and
inferential sensors. The algorithm is included in a
standard work for fault diagnostics, where its
effectiveness is assessed through k-NN classification
and illustrated in an application to an aircraft
cross-flow plate-fin heat exchanger",
- }
Genetic Programming entries for
William T Hale
George M Bollas
Citations