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Abstract

In this paper, a reduced multiple-model predictive controller based on gap metric and stability margin is presented to control heating, ventilating, and air conditioning (HVAC) systems. To tackle the strong nonlinearity and large number of degrees of freedom in HVAC system, two approaches, called Reduced Order Model Bank-Multiple Model (ROMB-MM) and Multiple Model-Reduced Order Model (MM-ROM), are introduced. In the first approach, the order reduction is performed prior to multiple models selection and in the second one multiple models selection is implemented before the model order reduction. Furthermore, soft switching is employed to enhance the closed-loop performance as well as to gain optimal energy consumption. In order to evaluate the proposed approaches, a sliding mode controller is also simulated to compare the results in terms of energy and cost savings, transient and steady-state responses, and robustness against external disturbances and model uncertainties.

Practical application: HVAC control systems are in charge of control indoor air temperature with energy optimization so that the thermal comfort is maintained. But how to model HVAC systems in each weather conditions is a significant challenge. A simpler and more accurate model will provide more efficient control of indoor air temperature. This paper suggests model order reduction and multiple model to select the simple linear model(s) in extreme weather conditions. The effectiveness of the proposed method can be implemented on nonlinear HVAC system.

Keywords

degree of freedom gap metric heating,ventilating,and air conditioning maximum stability margin model order reduction multiple model

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References

Tahersima

Stoustrup

Rasmussen

, et al. Thermal analysis of an HVAC system with TRV controlled hydronic radiator. In: 2010 IEEE International Conference on Automation Science and Engineering, Toronto, ON, Canada, 21-24 August 2010. IEEE, pp. 756–761.

Jin

Tan

Ding

, et al. Cooling coil unit dynamic control of in HVAC system. In: 2011 6th IEEE Conference on Industrial Electronics and Applications, Beijing, China, 21-23 June 2011. IEEE, pp. 942–947.

Jette

Zaheer-uddin

Fazio

. PI-control of dual duct systems: manual tuning and control loop interaction. Energ Convers Manag 1998; 39(14): 1471–1482.

Cai

. Practical receding-horizon optimization control of the air handling unit in HVAC systems. Ind Eng Chem Res 2005; 44(8): 2848–2855.

Wenping

, et al. A multiple model approach for predictive control of indoor thermal environment with high resolution. J Build Perform Simul 2018; 11(2): 164–178.

Wang

Bahri

Lee

, et al. A multiple model, state feedback strategy for robust control of nonlinear processes. Comput Chem Eng 2007; 31(5–6): 410–418.

Johansen

. Integrated multimodel control of nonlinear systems based on gap metric and stability margin. Ind Eng Chem Res 2014; 53(24): 10206–10215.

Galán

Romagnoli

Palazoǧlu

, et al. Gap metric concept and implications for multilinear model-based controller design. Ind Eng Chem Res 2003; 42(10): 2189–2197.

Salah

AAH

Garna

Ragot

, et al. Transition and control of nonlinear systems by combining the loop shaping design procedure and the gap metric theory. Trans Inst Meas Control 2016; 38(8): 1004–1020.

10.

Aghniaey

Lawrence

Mohammadpour

, et al. Optimizing thermal comfort considerations with electrical demand response program implementation. Build Serv Eng Res Technol 2018; 39(2): 219–231.

11.

Wang

Huang

. Robust MPC for temperature control of air-conditioning systems concerning on constraints and multi-type uncertainties. Build Serv Eng Res Technol 2010; 31(1): 39–55.

12.

Długosz

. Aggregation of state variables in an RC model. Build Serv Eng Res Technol 2018; 39(1): 66–80r.

13.

Antoulas

Sorensen

Gugercin

. A survey of model reduction methods for large-scale systems. Contemp Math 2001; 280: 193–219.

14.

Lymperopoulos

Loannou

. Distributed adaptive control of multi-zone HVAC systems. In: 27th Mediterranean Conference on Control and Automation (MED), Akko, Israel, 1-4 Jul 2019, pp. 553–558.

15.

Elnour

Meskin

. Multi-zone HVAC control system design using feedback linearization. In: 5th International Conference on Control, Instrumentation, and Automation (ICCIA), Shiraz, Iran, 21-23 November 2017. IEEE, pp. 249–254.

16.

Kianfar

Saif

Izadi-Zamanabadi

. Adaptive super twisting sliding mode control of a HVAC system. In: IEEE International Conference on Systems, Man, and Cybernetics (SMC), San Diego, CA, USA, 5-8 October 2014. IEEE, pp. 3520–3525.

17.

Ganchev

Teneva

Kutryanski

, et al. Decoupling fuzzy-neural temperature and humidity control in HVAC systems. IFAC-PapersOnline 2019; 52(25): 299–304.

18.

Nagpal

Staino

Basu

. Robust model predictive control of HVAC systems with uncertainty in building parameters using linear matrix inequalities. Adv Build Energ Res 2020; 14(3): 338–354.

19.

Kelman

Borrelli

. Analysis of local optima in predictive control for energy efficient buildings. J Build Perform Simul 2013; 6(3): 236–255.

20.

Tashtoush

Molhim

Al-Rousan

. Dynamic model of an HVAC system for control analysis. Energy 2005; 30(10): 1729–1745.

21.

El-Sakkary

. The gap metric: robustness of stabilization of feedback systems. IEEE Transact Automat Control 1985; 30(3): 240–247.

22.

Douma

Van den Hof

. Relations between uncertainty structures in identification for robust control. Automatica 2005; 41(3): 439–457.

23.

Georgiou

Smith

. Optimal robustness in the gap metric. IEEE Transact Automat Control 1990; 35(6): 673–686.

24.

Zhou

Doyle

. Essentials of Robust Control. Upper Saddle River, NJ: Prentice-Hall, 1998, Vol. 104.

25.

Wang

Mian

Wang

, et al. Robust multimode flight control design for an unmanned helicopter based on multiloop structure. Int J Control Autom Syst 2009; 7(5): 723–730.

26.

Ahmadi

Haeri

. A new structured multimodel control of nonlinear systems by integrating stability margin and performance. J Dyn Syst Meas 2017; 139(9): 091014.

27.

Ahmadi

Rikhtehgar

Haeri

. A multi-model control of nonlinear systems: a cascade decoupled design procedure based on stability and performance. Trans Inst Meas Control 2020; 42(7): 1271–1280.

28.

Gugercin

Sorensen

Antoulas

. A modified low-rank Smith method for large scale Lyapunov equations. Numer Algorithms 2003; 32(1): 27–55.

29.

Gugercin

Antoulas

. Model reduction of large-scale systems by least squares. Linear Algebra Appl 2006; 415(2–3): 290–321.

30.

Shridhar

Cooper

. A tuning strategy for unconstrained SISO model predictive control. Ind Eng Chem Res 1997; 36(3): 729–746.

31.

Long

Liu

Xie

, et al. A hierarchical distributed MPC for HVAC systems. In: American Control Conference (ACC), Boston, MA, USA, 6-8 July 2016. IEEE, pp. 2385–2390.

32.

Shah

Huang

Chen

, et al. Robust sliding mode control of air handling unit for energy efficiency enhancement. Energies 2017; 10(11): 1815.

Reduced multiple model predictive control of an heating,ventilating,and air conditioning system using gap metric and stability margin

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