Dale E. Seborg scite author profile

A design method for PID controllers based on the direct synthesis approach and specification of the desired closed-loop transfer function for disturbances is proposed. Analytical expressions for PID controllers are derived for several common types of process models, including firstorder and second-order plus time delay models and an integrator plus time delay model. Although the controllers are designed for disturbance rejection, the set-point responses are usually satisfactory and can be tuned independently via a set-point weighting factor. Nine simulation examples demonstrate that the proposed design method results in very good control for a wide variety of processes including those with integrating and/or nonminimum phase characteristics. The simulations show that the proposed design method provides better disturbance rejection than the standard direct synthesis and internal model control methods when the controllers are tuned to have the same degree of robustness.

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Control-Relevant Models for Glucose Control Using A Priori Patient Characteristics

Heusden

Dassau

Zisser

et al. 2012

IEEE Trans. Biomed. Eng.

140

144

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One of the difficulties in the development of a reliable artificial pancreas for people with type 1 diabetes mellitus (T1DM) is the lack of accurate models of an individual's response to insulin. Most control algorithms proposed to control the glucose level in subjects with T1DM are model-based. Avoiding postprandial hypoglycemia ( 60 mg/dl) while minimizing prandial hyperglycemia ( > 180 mg/dl) has shown to be difficult in a closed-loop setting due to the patient-model mismatch. In this paper, control-relevant models are developed for T1DM, as opposed to models that minimize a prediction error. The parameters of these models are chosen conservatively to minimize the likelihood of hypoglycemia events. To limit the conservatism due to large intersubject variability, the models are personalized using a priori patient characteristics. The models are implemented in a zone model predictive control algorithm. The robustness of these controllers is evaluated in silico, where hypoglycemia is completely avoided even after large meal disturbances. The proposed control approach is simple and the controller can be set up by a physician without the need for control expertise.

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Nonlinear Adaptive Control of a pH Neutralization Process

1992

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Nonlinear internal model control strategy for neural network models

Nahas

Henson

Seborg

1992

Computers & Chemical Engineering

259

118

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Dale E. Seborg

Teaching process control in the 21/sup st/ century: what has changed?

PI/PID Controller Design Based on Direct Synthesis and Disturbance Rejection

Control-Relevant Models for Glucose Control Using A Priori Patient Characteristics

Nonlinear Adaptive Control of a pH Neutralization Process

Nonlinear internal model control strategy for neural network models

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