Challenges and Opportunities on Nonlinear State Estimation of Chemical and Biochemical Processes

Alexander, Ronald; Campani, Gilson; Dinh, San; Lima, Fernando V.

doi:10.3390/pr8111462

Cited by 26 publications

(7 citation statements)

References 129 publications

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“…State and parameter estimation methods can be classified into recursive methods and optimization-based methods, namely Kalman filter (KF) and MHE, respectively (Alexander et al, 2020). Most of the estimators follow the assumption that online measurements are available for every time instance and desired state variable.…”

Section: Multi-rate Measurements and Ill-conditioning Of The Estimati...mentioning

confidence: 99%

Model predictive control and moving horizon estimation for adaptive optimal bolus feeding in high-throughput cultivation of \textit{E. coli}

Kim¹,

Krausch²,

Aizpuru³

et al. 2022

Preprint

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We discuss the application of a nonlinear model predictive control (MPC) and a moving horizon estimation (MHE) to achieve an optimal operation of E. coli fed-batch cultivations with intermittent bolus feeding. 24 parallel experiments were considered in a high-throughput microbioreactor platform at 10 mL scale. The robotic island in question can run up to 48 fed-batch processes in parallel with an automated liquid handling and online and atline analytics. The implementation of the model-based monitoring and control framework reveals that there are mainly three challenges which need to be addressed; First, the inputs are given in an instantaneous pulsed form by bolus injections, second, online and atline measurement frequencies are severely imbalanced, and third, optimization for the distinctive multiple reactors can

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Section: Multi-rate Measurements and Ill-conditioning Of The Estimati...mentioning

confidence: 99%

Model predictive control and moving horizon estimation for adaptive optimal bolus feeding in high-throughput cultivation of \textit{E. coli}

Kim¹,

Krausch²,

Aizpuru³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Due to some natural properties (e.g., variability and nonlinearity) [1], biochemical systems have difficulty in gaining a predetermined behavior, which hinders the further application of synthetic biology [2] in various fields. In order to obtain a stable and robust biochemical system, it is essential to build control systems in the form of biomolecular circuits [3], [4].…”

Section: Introductionmentioning

confidence: 99%

Cascade PID Control Systems Based on DNA Strand Displacement With Application in Polarization of Tumor-Associated Macrophages

Xue

Xiao

et al. 2023

IEEE Access

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Disturbances are widespread in biochemical systems. Nowadays, prevalent single-loop control strategies only take external disturbances into account. However, internal perturbations that threaten the stability of biochemical systems are invariably ignored. In this paper, a DNA strand displacement (DSD)based cascade PID control system is designed. In addition to traditionally realizing the tracking of reference input and the attenuation of primary disturbance, the presented control approach also innovatively completes the rejection of secondary disturbance. Specifically, the dynamics of the reference input signal are first governed by a first-order low-pass filter integrated with cascade PID control systems, which efficiently avoids the excessive response of the cascaded primary and secondary controllers to the reference signal. Then, cascade PID controllers and second-order time-delay plants are constructed by utilizing the chemical reaction network (CRN) and the DSD. In terms of secondary perturbation suppression, the obtained control scheme significantly outperforms the single-loop PID control scheme with a smaller overshoot and faster settling time. Finally, the DSD-based cascade PID control method is applied to regulate gene expressions of interferon regulatory factor 4 (IRF4) and interferon regulatory factor 5 (IRF5) that affect the polarization of tumorassociated macrophages (TAMs). Compared with the single-loop PID control strategy, the control strategy exhibits a better inhibitory effect on IRF5 gene overexpression (internal disturbance) and TAMs endogenous gene expression (external disturbance).INDEX TERMS Cascade PID control systems, chemical reaction networks, DNA strand displacement, secondary disturbance, regulation of tumor-associated macrophage polarization

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“…Based on a comparative study on the estimation performance of different nonlinear observers for an evaporative crystallization process, it was confirmed that UKF could provide good state estimation for implementing satisfactory closed-loop control performance . To accommodate for the operational constraints involved with nonlinear process dynamics, e.g., the supersaturation level and cooling rate during crystallization, a moving horizon estimator (MHE) was studied in refs , , which is an optimization-based estimator that minimizes the sum of squared errors between past measurements and state predictions over an N -length sliding window, weighted by the covariance matrices associated with the state and measurement uncertainties. , Mangold et al designed an MHE based on a population balance model (PBM) of barium sulfate precipitation to estimate the evolution of particle size distribution, thus improving batch control of product quality. Moreover, MHE was efficiently used for estimating batch-to-batch parametric drift, so as to conduct run-to-run process optimization .…”

Section: Introductionmentioning

confidence: 99%

Seeded Cooling Crystallization Process Optimization of β Form l-Glutamic Acid Based on Variable Moving Horizon State Estimation

Liu

Cui

Wang

et al. 2022

Ind. Eng. Chem. Res.

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In this paper, a cooling temperature optimization method is proposed for the seeded crystallization process of β form L-glutamic acid (LGA), based on moving horizon estimation (MHE) on the moment information of crystal growth kinetics. By transforming the population balance equations (PBEs) of the process kinetic model into differential algebraic equations using the quadrature method of moments (QMOM), a modified design of MHE with variable horizon is developed to estimate the zeroth-to the third-order moments that reflect the fundamental characteristics of the seeded cooling crystallization process. Based on these estimated moments, an optimization program is established to find the optimal operation profile of cooling temperature, by imposing the related constraints on these low-order moments and cooling rate for computation. An illustrative example of β form LGA crystallization yielding needle-shape crystals with one-dimensional size of length is used to demonstrate the advantage of the proposed MHE algorithm over the classical state estimation methods of extended Kalman filter (EKF) and MHE. Moreover, the optimized result of target crystal size distribution (CSD) by the proposed method is significantly improved compared to those of the conventional linear or programming cooling strategies along with another temperature optimization method in the literature. Experimental verification shows that the optimized temperature profile results in evidently improved product size distribution together with apparently reduced batch time.

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Challenges and Opportunities on Nonlinear State Estimation of Chemical and Biochemical Processes

Cited by 26 publications

References 129 publications

Model predictive control and moving horizon estimation for adaptive optimal bolus feeding in high-throughput cultivation of \textit{E. coli}

Model predictive control and moving horizon estimation for adaptive optimal bolus feeding in high-throughput cultivation of \textit{E. coli}

Cascade PID Control Systems Based on DNA Strand Displacement With Application in Polarization of Tumor-Associated Macrophages

Seeded Cooling Crystallization Process Optimization of β Form l-Glutamic Acid Based on Variable Moving Horizon State Estimation

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