Design and implementation of a proportional-integral-plus (PIP) control system for temperature, humidity and carbon dioxide in a glasshouse.

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Design and implementation of a proportional-integral-plus (PIP) control system for temperature, humidity and carbon dioxide in a glasshouse. / Lees, M. J.; Taylor, J.; Chotai, A. et al.
In: Acta Horticulturae (ISHS), Vol. 406, 1996, p. 115-124.

Research output: Contribution to Journal/Magazine › Journal article

Bibtex

@article{c59e4b9f31644a2ab03dad39304c1c13,

title = "Design and implementation of a proportional-integral-plus (PIP) control system for temperature, humidity and carbon dioxide in a glasshouse.",

abstract = "Conventional glasshouse climate controllers are based upon continuous-time PI controllers manually tuned to achieve adequate, although rather poor, tracking of set point changes. In this paper we consider the alternative, model based, Proportional-Integral-Plus (PIP) control system design (Young et al, 1987) which, although only slightly more complex than a PI controller, achieves much tighter control of the climate variables, allowing optimal setpoints (Chalabi, 1992) to be realised. A linear control model is identified and estimated from experimental data collected in a Venlo glasshouse at Silsoe Research Institute (SRI). A Non Minimum State Space (NMSS) representation of this control model is then used to design a robust PIP controller which was implemented during the 1993/94 winter growing season with a tomato crop. Control results were excellent with very tight control to the desired setpoints in all three variables. Air temperature was controlled to within 0.5°C of the setpoint for 85% of the validation period, and was shown to be very robust to model uncertainty and extreme weather conditions. Relative humidity was controlled to within 2% RH for 90% of the validation period, and CO2 was controlled to within 15 ppm for 80% of the validation period.",

author = "Lees, {M. J.} and J. Taylor and A. Chotai and Young, {P. C.} and Chalabi, {Z. S.} and Wlodek Tych",

year = "1996",

language = "English",

volume = "406",

pages = "115--124",

journal = "Acta Horticulturae (ISHS)",

publisher = "International Society for Horticultural Science",

}

RIS

TY - JOUR

T1 - Design and implementation of a proportional-integral-plus (PIP) control system for temperature, humidity and carbon dioxide in a glasshouse.

AU - Lees, M. J.

AU - Taylor, J.

AU - Chotai, A.

AU - Young, P. C.

AU - Chalabi, Z. S.

AU - Tych, Wlodek

PY - 1996

Y1 - 1996

N2 - Conventional glasshouse climate controllers are based upon continuous-time PI controllers manually tuned to achieve adequate, although rather poor, tracking of set point changes. In this paper we consider the alternative, model based, Proportional-Integral-Plus (PIP) control system design (Young et al, 1987) which, although only slightly more complex than a PI controller, achieves much tighter control of the climate variables, allowing optimal setpoints (Chalabi, 1992) to be realised. A linear control model is identified and estimated from experimental data collected in a Venlo glasshouse at Silsoe Research Institute (SRI). A Non Minimum State Space (NMSS) representation of this control model is then used to design a robust PIP controller which was implemented during the 1993/94 winter growing season with a tomato crop. Control results were excellent with very tight control to the desired setpoints in all three variables. Air temperature was controlled to within 0.5°C of the setpoint for 85% of the validation period, and was shown to be very robust to model uncertainty and extreme weather conditions. Relative humidity was controlled to within 2% RH for 90% of the validation period, and CO2 was controlled to within 15 ppm for 80% of the validation period.

AB - Conventional glasshouse climate controllers are based upon continuous-time PI controllers manually tuned to achieve adequate, although rather poor, tracking of set point changes. In this paper we consider the alternative, model based, Proportional-Integral-Plus (PIP) control system design (Young et al, 1987) which, although only slightly more complex than a PI controller, achieves much tighter control of the climate variables, allowing optimal setpoints (Chalabi, 1992) to be realised. A linear control model is identified and estimated from experimental data collected in a Venlo glasshouse at Silsoe Research Institute (SRI). A Non Minimum State Space (NMSS) representation of this control model is then used to design a robust PIP controller which was implemented during the 1993/94 winter growing season with a tomato crop. Control results were excellent with very tight control to the desired setpoints in all three variables. Air temperature was controlled to within 0.5°C of the setpoint for 85% of the validation period, and was shown to be very robust to model uncertainty and extreme weather conditions. Relative humidity was controlled to within 2% RH for 90% of the validation period, and CO2 was controlled to within 15 ppm for 80% of the validation period.

M3 - Journal article

VL - 406

SP - 115

EP - 124

JO - Acta Horticulturae (ISHS)

JF - Acta Horticulturae (ISHS)

ER -

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