Dead-Time Compensation for the First-Order Dead-Time Processes: Towards a Broader Overview

Huba, Mikuláš; Bisták, Pavol; Vrančić, Damir; Žáková, Katarı́na

doi:10.3390/math9131519

Cited by 9 publications

(7 citation statements)

References 65 publications

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“…C s d dt T s = q − q g − q r C g d dt T g = q g C r d dt T r = q r − q a (3) Considering Equations ( 1) and ( 2), the differential equations that describe the mathematical model of the electric oven are as follows: C r (4) where q is the thermal power, R is the coefficient of thermal resistivity, T is the temperature, the subscript g is the product to be heated (aluminum), the subscript s is the oven, the subscript r is the insulation, the subscript a is the air of the environment,u is the supply of electric potential, k is the thermal conductivity, and C is the thermal capacitance. The values of the constants can be seen in Table 1.…”

Section: Mathematical Model Of An Electric Ovenmentioning

confidence: 99%

“…There are several kinds of controls: proportional integral derivative (PID) controls are studied in [1,2], model-based controls are discussed in [3,4], and disturbance rejection controls are designed in [5,6]. For these controls, there are two types of objective-tracking, which involves the following of a time-varying set point, and regulation, which involves the following of a constant set point.…”

Section: Introductionmentioning

confidence: 99%

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The Regulation of an Electric Oven and an Inverted Pendulum

et al. 2022

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In this research, a proportional integral derivative regulator, a first-order sliding-mode regulator, and a second-order sliding-mode regulator are compared, for the regulation of two different types of mathematical model. A first-order sliding-mode regulator is a method where a sign-mapping checks that the error decays to zero after a convergence time; it has the problem of chattering in the output. A second-order sliding-mode regulator is a smooth method to counteract the chattering effect where the integral of the sign-mapping is used. A second-order sliding-mode regulator is presented as a new class of algorithm where the trajectory is asymptotic and stable; it is shown to greatly improve the convergence time in comparison with other regulators considered. Simulation and experimental results are described in which an electric oven is considered as a stable linear mathematical model, and an inverted pendulum is considered as an asymmetrical unstable non-linear mathematical model.

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Section: Mathematical Model Of An Electric Ovenmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Regulation of an Electric Oven and an Inverted Pendulum

et al. 2022

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“…Therefore, it will be useful to start clarifying the increased tuning complexity by explaining particular tuning steps, preferably from the simplest tasks. To illustrate the use of the RM-DTC design and practical problems associated with its application, we will consider the thermal process control discussed already in [31], [60], [64]. The choice of this process is motivated by several aspects -from a physical point of view, it is a highly nonlinear and time-variable higher-order process posing a challenge for robust control -only due to the fact that the concept of a nominal dynamics is strongly questionable.…”

Section: Illustrative Example: Temperature Controlmentioning

confidence: 99%

“…Parameters of the plant model identified in the vicinity of the selected operating point and applied in works [31], [64] can be given as…”

Section: A Simplified Plant Modellingmentioning

confidence: 99%

“…SP represents the best known structure for the control of time-delayed systems by combining the advantage of an independent design of dynamic feedforward control and of disturbance reconstruction and compensation. However, the use of integrating process models in SP leads to unobservable and unconstrained output disturbances [30], [31]. Moreover, equivalent output disturbances may increase beyond all limits in the presence of constant input disturbances [32].…”

Section: Introductionmentioning

confidence: 99%

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Reference Model Control of the Time Delayed Double Integrator

2022

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This paper illustrates the reference model-based dead-time compensator (RM-DTC) recently developed for first-order time-delayed systems using a real-time example, and extends this novel approach for a time-delayed double integrator system. RM-DTC enables fully decoupled setpoint tracking and disturbance reconstruction and compensation. The overall structure of RM-DTC includes feedforward control using either a transfer function based implementation or the primary loop which produces a filtered inverse of the model transfer function. The setpoint feedforward is complemented by a disturbanceobserver-based input disturbance reconstruction that also uses the filtered inverse of the plant model. The reference models of setpoint and input disturbance feedforward control allow the introduction of a stabilising PD controller without compromising the nominally independent dynamics of setpoint tracking and disturbance rejection. The main advantage of retaining the full functionality of disturbance reconstruction in RM-DTC is that it enables monitoring and diagnostics of the controlled process, which is important in terms of full automation of running processes representing the fundamental goal of the Industry 4.0 campaign. This surpasses the approaches based on internal model control, which have been modified for unstable systems to achieve internal stability by eliminating the reconstructed disturbance signal from the control loop. The excellent properties of RM -DTCs are illustrated by simulation and real-time control of thermal process.

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