Abstract
All real systems experience input saturation. Since the first proportional controller
was implemented, systems have been susceptible to saturation. The introduction of
the proportional-integral (PI) controller complicates matters further, since it reduces
the steady state error to zero for zero-order setpoint tracking. This encompasses a
fair portion of the implemented control strategies in the world.
It is clear that saturation, by limiting the input state for the process, limits the possible
output region. This is true in an absolute as well as a relative sense, due to limited
rate of change of the physical actuator. Hence not only is the absolute output range
limited, but the nonlinear effects also limit the output value at the next instant.
In single variable digital systems the performance degradation can be crippling.
Performance and stability are easily lost in systems with either high gains or small
control ranges. In multivariable systems, the condition is aggravated by the
transference of the saturation effects across all interacting loops. lIot only is the loop
experiencing saturation affected, but also the loops with which it is interacting. This
results in a situation where these loops also lose their ability to track their setpoint.
Moreover, in high gain systems, stability is jeopardised.
This dissertation presents a general solution for the practical problem that given the
physical constraint of saturation, a multivariable system's control engineer would be
able to prioritise the process outputs, and be given a choice over which outputs are
maintained during periods of nonlinear operation.
A review of the work done in anti-windup bumpless transfer (AWBT), using Kothare
et a/.'s (1994) "Unified framework for analysis of anti-windup bump/ess transfer
techniques" as a reference, it will be shown how these techniques are employed to
ensure system stability and linear performance recovery. Anti-windup (AW)
Techniques that are designed specifically for multivariable systems will also be
reviewed. The performance of these techniques, while the requested operating pOints
are outside of the realisable operating region, will be of particular interest. AWBT
does not in general meet the objective of allowing the engineer to prioritise the
nonlinear mode's operation during these periods.
The novel concept of error redistribution (ER) is introduced to meet this objective.
Error redistribution is a multivariable technique which allows the redistribution of error
in the saturating loops to the non-saturating, or rather, the correcting loops, to
maintain the setpoint of prioritised outputs; thus exploiting all degrees of freedom to
reach the nonlinear mode objective. The formalisation of this concept, along with a
stability proof and design guidelines are presented. The guidelines include being able
to measure the suitability of using ER on a process. The nature of the technique
allows the designer a controlled use, applying it only to the loops where it will be
effective and with minimal disruption to the process.
Throughout this thesis, a simulated example of a multivariable thermal process
(MVTP) is used to illustrate the principles and results relevant to dealing with
saturation using AW and ER compensation. An application chapter includes the
results of applying ER to a laboratory version of the MVTP; a simulated distillation
column and a typical gold mine milling circuit. Comparisons are done for different
pairings of ER compensation and AW techniques, including the implementation of the
Hanus conditioning technique and artificial-nonlinearity (AN) described by Peng et al.
(1998).
The result of this thesis is that error redistribution has been proven to be a viable
technique for the optimisation of process outputs during nonlinear operation. The
general structure of the system can easily implemented on industrial control
platforms.
Carew, W (2021). Multivariable Control of a Nonlinear Process Output Prioritisation by Error Redistribution. Afribary. Retrieved from https://track.afribary.com/works/multivariable-control-of-a-nonlinear-process-output-prioritisation-by-error-redistribution
Carew, Warren "Multivariable Control of a Nonlinear Process Output Prioritisation by Error Redistribution" Afribary. Afribary, 15 May. 2021, https://track.afribary.com/works/multivariable-control-of-a-nonlinear-process-output-prioritisation-by-error-redistribution. Accessed 27 Nov. 2024.
Carew, Warren . "Multivariable Control of a Nonlinear Process Output Prioritisation by Error Redistribution". Afribary, Afribary, 15 May. 2021. Web. 27 Nov. 2024. < https://track.afribary.com/works/multivariable-control-of-a-nonlinear-process-output-prioritisation-by-error-redistribution >.
Carew, Warren . "Multivariable Control of a Nonlinear Process Output Prioritisation by Error Redistribution" Afribary (2021). Accessed November 27, 2024. https://track.afribary.com/works/multivariable-control-of-a-nonlinear-process-output-prioritisation-by-error-redistribution