Open AccessMultiple-Input Subject-Specific Modeling of Plasma Glucose Concentration for Feedforward Control
Author(s) -
Kaylee Kotz,
Ali Çιnar,
Yong Mei,
Amy Roggendorf,
Elizabeth Littlejohn,
Laurie Quinn,
Derrick K. Rollins
Publication year - 2014
Publication title -
industrial and engineering chemistry research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.878
H-Index - 221
eISSN - 1520-5045
pISSN - 0888-5885
DOI - 10.1021/ie404119b
Subject(s) - overfitting , artificial pancreas , feed forward , computer science , insulin , control (management) , control theory (sociology) , artificial intelligence , control engineering , diabetes mellitus , engineering , biology , microbiology and biotechnology , endocrinology , type 1 diabetes , artificial neural network
The ability to accurately develop subject-specific, input causation models, for blood glucose concentration (BGC) for large input sets can have a significant impact on tightening control for insulin dependent diabetes. More specifically, for Type 1 diabetics (T1Ds), it can lead to an effective artificial pancreas (i.e., an automatic control system that delivers exogenous insulin) under extreme changes in critical disturbances. These disturbances include food consumption, activity variations, and physiological stress changes. Thus, this paper presents a free-living, outpatient, multiple-input, modeling method for BGC with strong causation attributes that is stable and guards against overfitting to provide an effective modeling approach for feedforward control (FFC). This approach is a Wiener block-oriented methodology, which has unique attributes for meeting critical requirements for effective, long-term, FFC.
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