On Adaptive Optimal Input Design
The problem of optimal input design (OID) for a fed-batch bioreactor case study is solved recursively. Here an adaptive receding horizon optimal control problem, involving the so-called E-criterion, is solved on-line, using the current estimate of the parameter vector at each sample instant {tk, k = 0, , N - h}, where N marks the end of the experiment and h is the control horizon for which the input design problem is solved. The optimal feed rate F(tk) thus obtained is applied and the observation y(tk+1) that becomes available is subsequently used in a recursive prediction error algorithm to find an improved estimate of the actual parameter estimate (tk). The case study involves an identification experiment with a Rapid Oxygen Demand TOXicity device (RODTOX) for estimation of the biokinetic parameters max and KS in a Monod type of growth model. It is assumed that the dissolved oxygen probe is the only instrument available, which is an important limitation. Satisfactory results are presented and compared to a naïve input design in which the system is driven by an independent binary random sequence. This comparison shows that the OID approach yields improved confidence intervals on the parameter estimates. © 2006 American Institute of Chemical Engineers AIChE J, 2006
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dig-wur-nl-wurpubs-3260422024-06-25 Stigter, J.D. Vries, D. Keesman, K.J. Article in monograph or in proceedings On Adaptive Optimal Input Design 2003 The problem of optimal input design (OID) for a fed-batch bioreactor case study is solved recursively. Here an adaptive receding horizon optimal control problem, involving the so-called E-criterion, is solved on-line, using the current estimate of the parameter vector at each sample instant {tk, k = 0, , N - h}, where N marks the end of the experiment and h is the control horizon for which the input design problem is solved. The optimal feed rate F(tk) thus obtained is applied and the observation y(tk+1) that becomes available is subsequently used in a recursive prediction error algorithm to find an improved estimate of the actual parameter estimate (tk). The case study involves an identification experiment with a Rapid Oxygen Demand TOXicity device (RODTOX) for estimation of the biokinetic parameters max and KS in a Monod type of growth model. It is assumed that the dissolved oxygen probe is the only instrument available, which is an important limitation. Satisfactory results are presented and compared to a naïve input design in which the system is driven by an independent binary random sequence. This comparison shows that the OID approach yields improved confidence intervals on the parameter estimates. © 2006 American Institute of Chemical Engineers AIChE J, 2006 en application/pdf https://research.wur.nl/en/publications/on-adaptive-optimal-input-design https://edepot.wur.nl/36109 Life Science Wageningen University & Research |
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The problem of optimal input design (OID) for a fed-batch bioreactor case study is solved recursively. Here an adaptive receding horizon optimal control problem, involving the so-called E-criterion, is solved on-line, using the current estimate of the parameter vector at each sample instant {tk, k = 0, , N - h}, where N marks the end of the experiment and h is the control horizon for which the input design problem is solved. The optimal feed rate F(tk) thus obtained is applied and the observation y(tk+1) that becomes available is subsequently used in a recursive prediction error algorithm to find an improved estimate of the actual parameter estimate (tk). The case study involves an identification experiment with a Rapid Oxygen Demand TOXicity device (RODTOX) for estimation of the biokinetic parameters max and KS in a Monod type of growth model. It is assumed that the dissolved oxygen probe is the only instrument available, which is an important limitation. Satisfactory results are presented and compared to a naïve input design in which the system is driven by an independent binary random sequence. This comparison shows that the OID approach yields improved confidence intervals on the parameter estimates. © 2006 American Institute of Chemical Engineers AIChE J, 2006 |
| format |
Article in monograph or in proceedings |
| topic_facet |
Life Science |
| author |
Stigter, J.D. Vries, D. Keesman, K.J. |
| author_facet |
Stigter, J.D. Vries, D. Keesman, K.J. |
| author_sort |
Stigter, J.D. |
| title |
On Adaptive Optimal Input Design |
| title_short |
On Adaptive Optimal Input Design |
| title_full |
On Adaptive Optimal Input Design |
| title_fullStr |
On Adaptive Optimal Input Design |
| title_full_unstemmed |
On Adaptive Optimal Input Design |
| title_sort |
on adaptive optimal input design |
| url |
https://research.wur.nl/en/publications/on-adaptive-optimal-input-design |
| work_keys_str_mv |
AT stigterjd onadaptiveoptimalinputdesign AT vriesd onadaptiveoptimalinputdesign AT keesmankj onadaptiveoptimalinputdesign |
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1813209339695988736 |