10 KiB
+++ title = "Decentralized and decoupled control" author = ["Thomas Dehaeze"] draft = false +++
- Tags
- Multivariable Control, Decoupled Control
- Reference
- (Albertos and Antonio 2004)
- Author(s)
- Albertos, P., & Antonio, S.
- Year
- 2004
Introduction
Decentralized control is decomposed into two steps:
- decoupled the plant into several subsystems
- control the subsystems
The initial effort of decoupling the system results in subsequent easier design, implementation and tuning.
Decentralized control tries to control multivariable plants by a suitable decomposition into SISO control loops. If the process has strong coupling or conditioning problems, centralized control may be required. It however requires the availability of a precise model.
Two approaches can be used to control a coupled system with SISO techniques:
- decentralized control tries to divide the plant and design independent controllers for each subsystems.
Two alternative arise:
- neglect the coupling
- carry out a decoupling operation by "canceling" coupling by transforming the system into a diagonal or triangular structure bia a transformation matrix
- cascade control
Mutli-Loop Control, Pairing Selection
The strategy called multi-loop control consists of first proper input/output pairing, and then design of several SISO controllers. In this way, a complex control problem is divided into several simpler ones.
The multi-loop control may not work in strongly coupled systems. Therefore, a methodology the access the degree of interaction between the loops is needed.
Relative Gain Array
The Relative Gain Array (RGA) \(\Lambda(s)\) is defined as:
\begin{equation} \Lambda(s) = G(s) \times (G(s)^T)^{-1} \end{equation}
The RGA is scaling-independent and controller-independent. These coefficients can be interpreted as the ratio between the open-loop SISO static gain and the gain with "perfect" control on the rest of the loops.
For demanding control specifications, the values of \(\Lambda\) car be drawn as a function of frequency. In this case, at frequencies important for control stability robustness (around the peak of the sensitivity transfer function), if \(\Lambda(j\omega)\) approaches the identity matrix, stability problems are avoided in multi-loop control.
Decoupling
In cases when multi-loop control is not effective in reaching the desired specifications, a possible strategy for tackling the MIMO control could be to transform the transfer function matrix into a diagonal dominant one. This strategy is called decoupling.
Decoupled Control can be achieved in two ways:
- feedforward cancellation of the cross-coupling terms
- based on state measurements, via a feedback law
Feedforward Decoupling
A pre-compensator (Figure 1) can be added to transform the open-loop characteristics into a new one as chosen by the designer. This decoupler can be taken as the inverse of the plant provided it does not include RHP-zeros.
{{< figure src="/ox-hugo/albertos04_pre_compensator_decoupling.png" caption="Figure 1: Decoupler pre-compensator" >}}
Approximate decoupling: To design low-bandwidth loops, insertion of the inverse DC-gain before the loop ensures decoupling at least at steady-state. If further bandwidth extension is desired, an approximation of \(G^{-1}\) valid in low frequencies can be used.
Although at first glance, decoupling seems an appealing idea, there are some drawbacks:
- as decoupling is achieved via the coordination of sensors and actuators to achieve an "apparent" diagonal behavior, the failure of one the actuators may heavily affects all loops.
- a decoupling design (inverse-based controller) may not be desirable for all disturbance-rejection tasks.
- many MIMO non-minimum phase systems, when feedforward decoupled, increase the RHP-zero multiplicity so performance limitations due to its presence are exacerbated.
- decoupling may be very sensitive to modeling errors, specially for ill-conditionned plants
- feedback decoupling needs full state measurements
SVD Decoupling
A matrix \(M\) can be expressed, using the Singular Value Decomposition as:
\begin{equation} M = U \Sigma V^T \end{equation}
where \(U\) and \(V\) are orthogonal matrices and \(\Sigma\) is diagonal.
The SVD can be used to obtain decoupled equations between linear combinations of sensors and linear combinations of actuators. In this way, although losing part of its intuitive sense, a decoupled design can be carried out even for non-square plants.
If sensors are multiplied by \(U^T\) and control actions multiplied by \(V\), as in Figure 2, then the loop, in the transformed variables, is decoupled, so a diagonal controller \(K_D\) can be used. Usually, the sensor and actuator transformations are obtained using the DC gain, or a real approximation of \(G(j\omega)\), where \(\omega\) is around the desired closed-loop bandwidth.
{{< figure src="/ox-hugo/albertos04_svd_decoupling.png" caption="Figure 2: SVD decoupling: \(K_D\) is a diagonal controller designed for \(\Sigma\)" >}}
The transformed sensor-actuator pair corresponding to the maximum singular value is the direction with biggest "gain" on the plant, that is, the combination of variables being "easiest to control".
In ill-conditioned plants, the ratio between the biggest and lower singular value is large (for reference, greater than 20). They are very sensitive to input uncertainty as some "input directions" have much bigger gain than other ones.
SVD decoupling produces the most suitable combinations for independent "multi-loop" control in the transformed variables, so its performance may be better than RGA-based design (at the expense of losing physical interpretability). If some of the vectors in \(V\) (input directions) have a significant component on a particular input, and the corresponding output direction is also significantly pointing to a particular output, that combination is a good candidate for an independent multi-loop control.
Conclusions
In this chapter, the control of systems with multiple inputs and outputs is discussed using SISO-based tools, either directly or after some multivariable decoupling transformations.
Multi-loop strategies, if suitable, may present th advantages of fault tolerance, as well as simplicity. However, in some cases, tuning may be difficult and coupling may severely limit their performance.
Decoupling is based on mathematical transformations of the system models into diagonal form. Feedforward decoupling can be used in many cases. Feedback decoupling achieves its objective if state is measurable and system is minimum-phase. However, decoupling may be very sensitive to modelling errors and it is not the optimal strategy for disturbance rejection.
Cascade control is widely used in industry to improve the behaviour of basic SISO loops via the addition of extra sensors and actuators. However, ease of tuning requires that different time constants are involved in different subsystems. In general, addition of extra sensors and actuators in a SISO or MIMO loop, will improve achievable performance and/or tolerance to modelling errors. The level of improvement must be traded off against the cost of additional instrumentation.
Implementation and Other Issues
There are two main categories for the implementation of MIMO control:
- Decentralized, Decoupled, Cascade
- Centralized, optimization based
A fundamental reason to use cascade and decentralized control in most practical applications is because they require less modelling effort. Other advantages of cascade and decentralized control are:
- its behaviour can be easily understood
- standard equipment can be used (PID controllers, etc.)
- their decoupled behavior enables easier tuning with model-free strategies
- decentralized implementation tends to be more fault-tolerant, as individual loops will try to keep their set-points even in the case some other components have failed.
Anti-Windup Control
In practice, it is possible that an actuator saturate. In such case, the feedback path is broken, and this has several implications:
- unstable processes: the process output might go out of control
- multi-loop and centralized control: even with stable plants, opening a feedback path may cause the overall loop to become unstable
The wind-up problem can appear with integral action regulators: during significative step changes in the set point, the integral of the error keeps accumulation and when reaching the desired set-point the accumulated integral action produces a significant overshoot increment. In SISO PID regulators, anti-windup schemes are implemented by either stopping integration if the actuator is saturated or by implementing the following control law:
\begin{equation} u = K(r - y) - K T_D \frac{dy}{dt} + \int K T_i^{-1} (r - y) + T_t^{-1} (u_m - u) dt \label{eq:antiwindup_pid} \end{equation}
where \(u\) is the calculated control action and \(u_m\) is the actual control action applied to the plant. In non-saturated behaviour, \(u=u_m\) and the equation is the ordinary PID. In saturation, \(u_m\) is a constant and the resulting equations drive \(u\) down towards \(u_m\) dynamically, with time constant \(T_T\).
Bumpless Transfer
When switching on the regulator, significant transient behavior can be seen and the controller may saturate the actuators. The solution is similar to that of the wind-up phenomenon: the regulator should be always on, carrying out calculations by using \eqref{eq:antiwindup_pid}.
Bibliography
Albertos, P., and S. Antonio. 2004. “Decentralized and Decoupled Control.” In Multivariable Control Systems: An Engineering Approach, 125–62. Advanced Textbooks in Control and Signal Processing. Springer-Verlag. https://doi.org/10.1007/b97506.