The Experts below are selected from a list of 2544 Experts worldwide ranked by ideXlab platform
Nathan Van De Wouw - One of the best experts on this subject based on the ideXlab platform.
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Online hose calibration for Pressure control in mechanical ventilation
2019 American Control Conference (ACC), 2019Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are used to assist patients who are unable to breathe sufficiently on their own. The aim of this paper is to develop a control method that achieves exact tracking of a time-varying Target Pressure, invariant to patient-hose-leak parameters. This is achieved by an online hose calibration that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is analyzed and the performance improvement compared to state-of-practice feedforward and linear feedback control strategies is demonstrated by a simulation case study.
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Adaptive Control for Mechanical Ventilation for Improved Pressure Support
IEEE Transactions on Control Systems Technology, 1Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are medical devices used to assist patients to breathe. The aim of this article is to develop a control method that achieves exact tracking of a time-varying Target Pressure, for unknown patient-hose-leak parameters and in the presence of patient breathing effort. This is achieved by an online estimation of the hose characteristics that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is proven, and the performance improvement compared to the existing control strategies is demonstrated by simulation and experimental case studies.
Joey Reinders - One of the best experts on this subject based on the ideXlab platform.
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Online hose calibration for Pressure control in mechanical ventilation
2019 American Control Conference (ACC), 2019Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are used to assist patients who are unable to breathe sufficiently on their own. The aim of this paper is to develop a control method that achieves exact tracking of a time-varying Target Pressure, invariant to patient-hose-leak parameters. This is achieved by an online hose calibration that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is analyzed and the performance improvement compared to state-of-practice feedforward and linear feedback control strategies is demonstrated by a simulation case study.
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Adaptive Control for Mechanical Ventilation for Improved Pressure Support
IEEE Transactions on Control Systems Technology, 1Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are medical devices used to assist patients to breathe. The aim of this article is to develop a control method that achieves exact tracking of a time-varying Target Pressure, for unknown patient-hose-leak parameters and in the presence of patient breathing effort. This is achieved by an online estimation of the hose characteristics that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is proven, and the performance improvement compared to the existing control strategies is demonstrated by simulation and experimental case studies.
Bram Hunnekens - One of the best experts on this subject based on the ideXlab platform.
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Online hose calibration for Pressure control in mechanical ventilation
2019 American Control Conference (ACC), 2019Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are used to assist patients who are unable to breathe sufficiently on their own. The aim of this paper is to develop a control method that achieves exact tracking of a time-varying Target Pressure, invariant to patient-hose-leak parameters. This is achieved by an online hose calibration that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is analyzed and the performance improvement compared to state-of-practice feedforward and linear feedback control strategies is demonstrated by a simulation case study.
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Adaptive Control for Mechanical Ventilation for Improved Pressure Support
IEEE Transactions on Control Systems Technology, 1Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are medical devices used to assist patients to breathe. The aim of this article is to develop a control method that achieves exact tracking of a time-varying Target Pressure, for unknown patient-hose-leak parameters and in the presence of patient breathing effort. This is achieved by an online estimation of the hose characteristics that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is proven, and the performance improvement compared to the existing control strategies is demonstrated by simulation and experimental case studies.
Frank Heck - One of the best experts on this subject based on the ideXlab platform.
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Online hose calibration for Pressure control in mechanical ventilation
2019 American Control Conference (ACC), 2019Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are used to assist patients who are unable to breathe sufficiently on their own. The aim of this paper is to develop a control method that achieves exact tracking of a time-varying Target Pressure, invariant to patient-hose-leak parameters. This is achieved by an online hose calibration that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is analyzed and the performance improvement compared to state-of-practice feedforward and linear feedback control strategies is demonstrated by a simulation case study.
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Adaptive Control for Mechanical Ventilation for Improved Pressure Support
IEEE Transactions on Control Systems Technology, 1Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are medical devices used to assist patients to breathe. The aim of this article is to develop a control method that achieves exact tracking of a time-varying Target Pressure, for unknown patient-hose-leak parameters and in the presence of patient breathing effort. This is achieved by an online estimation of the hose characteristics that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is proven, and the performance improvement compared to the existing control strategies is demonstrated by simulation and experimental case studies.
Tom Oomen - One of the best experts on this subject based on the ideXlab platform.
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Online hose calibration for Pressure control in mechanical ventilation
2019 American Control Conference (ACC), 2019Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are used to assist patients who are unable to breathe sufficiently on their own. The aim of this paper is to develop a control method that achieves exact tracking of a time-varying Target Pressure, invariant to patient-hose-leak parameters. This is achieved by an online hose calibration that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is analyzed and the performance improvement compared to state-of-practice feedforward and linear feedback control strategies is demonstrated by a simulation case study.
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Adaptive Control for Mechanical Ventilation for Improved Pressure Support
IEEE Transactions on Control Systems Technology, 1Co-Authors: Joey Reinders, Bram Hunnekens, Frank Heck, Tom Oomen, Nathan Van De WouwAbstract:Respiratory modules are medical devices used to assist patients to breathe. The aim of this article is to develop a control method that achieves exact tracking of a time-varying Target Pressure, for unknown patient-hose-leak parameters and in the presence of patient breathing effort. This is achieved by an online estimation of the hose characteristics that enables compensation for the Pressure drop over the hose. Stability of the closed-loop system is proven, and the performance improvement compared to the existing control strategies is demonstrated by simulation and experimental case studies.
