On the Use of Shape-Constrained Splines for Biokinetic Process Modeling

Alma Mašić; Sriniketh Srinivasan; Julien Billeter; Dominique Bonvin; Kris Villez

doi:10.1016/j.ifacol.2016.07.357

On the Use of Shape-Constrained Splines for Biokinetic Process Modeling

Alma Mašić, Sriniketh Srinivasan, Julien Billeter, Dominique Bonvin, Kris Villez

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Identification of mathematical models is an important task for the design and the optimization of biokinetic processes. Monod or Tessier growth-rate models are often chosen by default, although these models are not able to represent the dynamics of all bacterial growth processes. This imperfect representation then affects the quality of the model prediction. This paper introduces an alternative approach, which is based on constraints such as monotonicity and concavity and the use of shape-constrained spline functions, to describe the substrate affinity with high parametric flexibility. This way, the difficult task of searching through potentially incomplete rate-model libraries can be circumvented. A simulated case study is used to illustrate the superiority of the proposed method to represent non-ideal growth conditions, where neither Monod nor Tessier kinetics offer a good approximation.

Original language	English
Pages (from-to)	1145-1150
Number of pages	6
Journal	IFAC-PapersOnLine
Volume	49
Issue number	7
DOIs	https://doi.org/10.1016/j.ifacol.2016.07.357
State	Published - 2016
Externally published	Yes

Funding

★★ This study is financed by Eawag Discretionary Funds (PSP: This study is financed by Eawag Discretionary Funds (PSP: 5221.00492.009.03). 5221.00492.009.03).

Keywords

Monod equation
mathematical models
microbial growth-rate kinetics
shape-constrained spline function
wastewater treatment

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10.1016/j.ifacol.2016.07.357

Cite this

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abstract = "Identification of mathematical models is an important task for the design and the optimization of biokinetic processes. Monod or Tessier growth-rate models are often chosen by default, although these models are not able to represent the dynamics of all bacterial growth processes. This imperfect representation then affects the quality of the model prediction. This paper introduces an alternative approach, which is based on constraints such as monotonicity and concavity and the use of shape-constrained spline functions, to describe the substrate affinity with high parametric flexibility. This way, the difficult task of searching through potentially incomplete rate-model libraries can be circumvented. A simulated case study is used to illustrate the superiority of the proposed method to represent non-ideal growth conditions, where neither Monod nor Tessier kinetics offer a good approximation.",

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AU - Srinivasan, Sriniketh

AU - Billeter, Julien

AU - Bonvin, Dominique

AU - Villez, Kris

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AB - Identification of mathematical models is an important task for the design and the optimization of biokinetic processes. Monod or Tessier growth-rate models are often chosen by default, although these models are not able to represent the dynamics of all bacterial growth processes. This imperfect representation then affects the quality of the model prediction. This paper introduces an alternative approach, which is based on constraints such as monotonicity and concavity and the use of shape-constrained spline functions, to describe the substrate affinity with high parametric flexibility. This way, the difficult task of searching through potentially incomplete rate-model libraries can be circumvented. A simulated case study is used to illustrate the superiority of the proposed method to represent non-ideal growth conditions, where neither Monod nor Tessier kinetics offer a good approximation.

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On the Use of Shape-Constrained Splines for Biokinetic Process Modeling

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