Fuzzy PID Control for Respiratory Systems

Ibrahim M. Mehedi; Heidir S.M. Shah; Ubaid M. Al-Saggaf; Rachid Mansouri; Maamar Bettayeb

doi:10.1155/2021/7118711

Fuzzy PID Control for Respiratory Systems

Ibrahim M. Mehedi^*, Heidir S.M. Shah, Ubaid M. Al-Saggaf, Rachid Mansouri, Maamar Bettayeb

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

This paper presents the implementation of a fuzzy proportional integral derivative (FPID) control design to track the airway pressure during the mechanical ventilation process. A respiratory system is modeled as a combination of a blower-hose-patient system and a single compartmental lung system with nonlinear lung compliance. For comparison purposes, the classical PID controller is also designed and simulated on the same system. According to the proposed control strategy, the ventilator will provide airway flow that maintains the peak pressure below critical levels when there are unknown parameters of the patient's hose leak and patient breathing effort. Results show that FPID is a better controller in the sense of quicker response, lower overshoot, and smaller tracking error. This provides valuable insight for the application of the proposed controller.

Original language	English
Article number	7118711
Journal	Journal of Healthcare Engineering
Volume	2021
DOIs	https://doi.org/10.1155/2021/7118711
Publication status	Published - 2021
Externally published	Yes

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title = "Fuzzy PID Control for Respiratory Systems",

abstract = "This paper presents the implementation of a fuzzy proportional integral derivative (FPID) control design to track the airway pressure during the mechanical ventilation process. A respiratory system is modeled as a combination of a blower-hose-patient system and a single compartmental lung system with nonlinear lung compliance. For comparison purposes, the classical PID controller is also designed and simulated on the same system. According to the proposed control strategy, the ventilator will provide airway flow that maintains the peak pressure below critical levels when there are unknown parameters of the patient's hose leak and patient breathing effort. Results show that FPID is a better controller in the sense of quicker response, lower overshoot, and smaller tracking error. This provides valuable insight for the application of the proposed controller.",

author = "Mehedi, {Ibrahim M.} and Shah, {Heidir S.M.} and Al-Saggaf, {Ubaid M.} and Rachid Mansouri and Maamar Bettayeb",

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AU - Mehedi, Ibrahim M.

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AU - Al-Saggaf, Ubaid M.

AU - Mansouri, Rachid

AU - Bettayeb, Maamar

PY - 2021

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AB - This paper presents the implementation of a fuzzy proportional integral derivative (FPID) control design to track the airway pressure during the mechanical ventilation process. A respiratory system is modeled as a combination of a blower-hose-patient system and a single compartmental lung system with nonlinear lung compliance. For comparison purposes, the classical PID controller is also designed and simulated on the same system. According to the proposed control strategy, the ventilator will provide airway flow that maintains the peak pressure below critical levels when there are unknown parameters of the patient's hose leak and patient breathing effort. Results show that FPID is a better controller in the sense of quicker response, lower overshoot, and smaller tracking error. This provides valuable insight for the application of the proposed controller.

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JO - Journal of Healthcare Engineering

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Fuzzy PID Control for Respiratory Systems

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