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Sigurd Skogestad Department of Chemical Engineering

Feedback: The simple and best solution. Applications to self-optimizing control and stabilization of new operating regimes. Sigurd Skogestad Department of Chemical Engineering Norwegian University of Science and Technology (NTNU) Trondheim. December 2004. Outline. About myself

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Sigurd Skogestad Department of Chemical Engineering

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  1. Feedback:The simple and best solution.Applications to self-optimizing control and stabilization of new operating regimes Sigurd Skogestad Department of Chemical Engineering Norwegian University of Science and Technology (NTNU) Trondheim December 2004

  2. Outline • About myself • I. Why feedback (and not feedforward) ? • II. Self-optimizing feedback control: What should we control? • III. Stabilizing feedback control: Anti-slug control • Conclusion

  3. Abstract • Feedback: The simple and best solutionMost chemical engineers are (indirectly) trained to be ``feedforward thinkers" and they immediately think of ``model inversion'' when it comes doing control. Thus, they prefer to rely on models instead of data, although simple feedback solutions in many cases are much simpler and certainly more robust.In the seminar two nice applications of feedback are considered: - Implementation of optimal operation by "self-optimizing control". The idea is to turn optimization into a setpoint control problem, and the trick is to find the right variable to control. Applications include process control, pizza baking, marathon running, biology and the central bank of a country. - Stabilization of desired operating regimes. Here feedback control can lead to completely new and simple solutions. One example would be stabilization of laminar flow at conditions where we normally have turbulent flow.In the seminar a nice application to anti-slug control in multiphase pipeline flow is discussed.   

  4. Trondheim, Norway

  5. Arctic circle North Sea Trondheim SWEDEN NORWAY Oslo DENMARK GERMANY UK

  6. NTNU, Trondheim

  7. Sigurd Skogestad • Born in 1955 • 1978: Siv.ing. Degree (MS) in Chemical Engineering from NTNU (NTH) • 1980-83: Process modeling group at the Norsk Hydro Research Center in Porsgrunn • 1983-87: Ph.D. student in Chemical Engineering at Caltech, Pasadena, USA. Thesis on “Robust distillation control”. Supervisor: Manfred Morari • 1987 - : Professor in Chemical Engineering at NTNU • Since 1994: Head of process systems engineering center in Trondheim (PROST) • Since 1999: Head of Department of Chemical Engineering • 1996: Book “Multivariable feedback control” (Wiley) • 2000,2003: Book “Prosessteknikk” (Norwegian) • Group of about 10 Ph.D. students in the process control area

  8. Research: Develop simple yet rigorous methods to solve problems of engineering significance. • Use of feedback as a tool to • reduce uncertainty (including robust control), • change the system dynamics (including stabilization; anti-slug control), • generally make the system more well-behaved (including self-optimizing control). • limitations on performance in linear systems (“controllability”), • control structure design and plantwide control, • interactions between process design and control, • distillation column design, control and dynamics. • Natural gas processes

  9. Outline • About myself • I. Why feedback (and not feedforward) ? • II. Self-optimizing feedback control: What should we control? • III. Stabilizing feedback control: Anti-slug control • Conclusion

  10. Model-based control =Feedforward (FF) control d Gd G u y ”Perfect” feedforward control: u = - G-1 Gd d Our case: G=k (=10 nominal), Gd = 10→ Use u = -d

  11. d Gd G u y (smaller process gain ) Feedforward with perfect model (k=10) Feedforward: sensitive to gain error

  12. d Gd ys e C G u y Measurement-based correction =Feedback (FB) control

  13. d Gd ys e C G u y Output y Input u Feedback generates inverse! Resulting output Feedback PI-control: Nominal case

  14. d Gd ys e C G u y Feedback PI control: insensitive to gain error

  15. Conclusion: Why feedback?(and not feedforward control) • Simple: High gain feedback! • Counteract unmeasured disturbances • Reduce effect of changes / uncertainty (robustness) • Change system dynamics (including stabilization) • Linearize the behavior • No explicit model required • MAIN PROBLEM • Potential instability (may occur suddenly) with time delay / RHP-zero

  16. DISTILLATION AND THE MYTH ABOUT SLOW CONTROL

  17. Outline • About myself • Why feedback (and not feedforward) ? • Distillation control • II. Self-optimizing feedback control: What should we control? • Stabilizing feedback control: Anti-slug control • Conclusion

  18. Optimal operation (economics) • Define scalar cost function J(u0,d) • u0: degrees of freedom • d: disturbances • Optimal operation for given d: minu0 J(u0,x,d) subject to: f(u0,x,d) = 0 g(u0,x,d) < 0

  19. ”Obvious” solution: Optimizing control =”Feedforward” Estimate d and compute new uopt(d) Probem: Complicated and sensitive to uncertainty

  20. Engineering systems • Most (all?) large-scale engineering systems are controlled using hierarchies of quite simple single-loop controllers • Commercial aircraft • Large-scale chemical plant (refinery) • 1000’s of loops • Simple components: on-off + P-control + PI-control + nonlinear fixes + some feedforward Same in biological systems

  21. RTO y1 = c ? (economics) MPC PID Process control hierarchy

  22. Hierarchical decomposition with separate layers What should we control?

  23. Implementation of optimal operation • Optimal solution is usually at constraints, that is, most of the degrees of freedom are used to satisfy “active constraints”, g(u0,d) = 0 • CONTROL ACTIVE CONSTRAINTS! • Implementation of active constraints is usually simple.

  24. Self-optimizing Control – Sprinter • Optimal operation of Sprinter (100 m), J=T • Active constraint control: • Maximum speed (”no thinking required”)

  25. Implementation of optimal operation • Optimal solution is usually at constraints, that is, most of the degrees of freedom are used to satisfy “active constraints”, g(u0,d) = 0 • CONTROL ACTIVE CONSTRAINTS! • Implementation of active constraints is usually simple. • WHAT MORE SHOULD WE CONTROL? • We here concentrate on the remaining unconstrained degrees of freedom u.

  26. Feedback implementation J Optimizer Issue: What should we control? c cs cm=c+n n Controller that adjusts u to keep cm = cs cs=copt u c d Plant uopt u

  27. Self-optimizing Control • Define loss: • Self-optimizing Control • Self-optimizing control is when acceptable loss can be achieved using constant set points (cs)for the controlled variables c (without re-optimizing when disturbances occur).

  28. Effect of implementation error Good Good BAD

  29. Self-optimizing Control – Marathon • Optimal operation of Marathon runner, J=T • Any self-optimizing variable c (to control at constant setpoint)?

  30. Self-optimizing Control – Marathon • Optimal operation of Marathon runner, J=T • Any self-optimizing variable c (to control at constant setpoint)? • c1 = distance to leader of race • c2 = speed • c3 = heart rate • c4 = level of lactate in muscles

  31. Further examples • Central bank. J = welfare. u = interest rate. c=inflation rate (2.5%) • Cake baking. J = nice taste, u = heat input. c = Temperature (200C) • Business, J = profit. c = ”Key performance indicator (KPI), e.g. • Response time to order • Energy consumption pr. kg or unit • Number of employees • Research spending Optimal values obtained by ”benchmarking” • Investment (portofolio management). J = profit. c = Fraction of investment in shares (50%) • Biological systems: • ”Self-optimizing” controlled variables c have been found by natural selection • Need to do ”reverse engineering” : • Find the controlled variables used in nature • From this possibly identify what overall objective J the biological system has been attempting to optimize

  32. Good candidate controlled variables c (for self-optimizing control) Requirements: • The optimal value of c should be insensitive to disturbances • c should be easy to measure and control • The value of c should be sensitive to changes in the degrees of freedom (Equivalently, J as a function of c should be flat) • For cases with more than one unconstrained degrees of freedom, the selected controlled variables should be independent. Singular value rule (Skogestad and Postlethwaite, 1996): Look for variables that maximize the minimum singular value of the appropriately scaled steady-state gain matrix G from u to c

  33. Outline • About myself • Why feedback (and not feedforward) ? • Self-optimizing feedback control: What should we control? • III. Stabilizing feedback control: Anti-slug control • Conclusion

  34. Application stabilizing feedback control:Anti-slug control Two-phase pipe flow (liquid and vapor) Slug (liquid) buildup

  35. Slug cycle (stable limit cycle) Experiments performed by the Multiphase Laboratory, NTNU

  36. Experimental mini-loop

  37. z p2 p1 Experimental mini-loopValve opening (z) = 100%

  38. z p2 p1 Experimental mini-loopValve opening (z) = 25%

  39. z p2 p1 Experimental mini-loopValve opening (z) = 15%

  40. z p2 p1 Experimental mini-loop:Bifurcation diagram No slug Valve opening z % Slugging

  41. Avoid slugging? • Design changes • Feedforward control? • Feedback control?

  42. z p2 p1 Design change Avoid slugging:1. Close valve (but increases pressure) No slugging when valve is closed Valve opening z %

  43. z p2 p1 Design change Avoid slugging:2. Other design changes to avoid slugging

  44. z p2 p1 Design change Minimize effect of slugging:3. Build large slug-catcher • Most common strategy in practice

  45. Avoid slugging: 4. Feedback control? Comparison with simple 3-state model: Simplified model (Storkaas, 2003) Valve opening z % Predicted smooth flow: Desirable but open-loop unstable

  46. ref PC PT Avoid slugging:4. ”Active” feedback control z p1 Simple PI-controller

  47. Anti slug control: Mini-loop experiments p1 [bar] z [%] Controller ON Controller OFF

  48. Anti slug control: Full-scale offshore experiments at Hod-Vallhall field (Havre,1999)

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