Glycemic Control and Temperature Control in Buildings

• This thesis consists of two parts, applying concepts from automatic control to different application areas.The first part of this thesis concerns the development of an optimization-based algorithm, determining the size of insulin and glucose doses for patients suffering from Diabetes Mellitus and treated with multiple insulin injections. Diabetes Mellitus is a chronic disease characterized by elevated blood glucose levels. The therapy usually consists of insulin injections, where the amount of insulin to be administered is decided by the patient using empirically developed rules of thumb. An algorithm is proposed determining the dose intakes of insulin and glucose bringing the blood glucose concentration back to a healthy range. The algorithm uses optimization methods and patient-individual blood glucose predictions to determine thesedoses. The cost function used for the optimization problem reflects the risk associated with the blood glucose values. A virtual patient was used as an in-silico test-bed for the proposed algorithm. The results were compared to a bolus calculator. It was found that the proposed control algorithm could improve the time of the simulated patient’s blood glucose spends in a safe range compared to the bolus calculator.The second part of this thesis aims at applying inverted decoupling to the area of temperature control in buildings. With inverted decoupling, a multi-variable system can be controlled as several single input single output systems. Buildings are multi-variable systems with many interacting variables. In the second part of this thesis, inverted decoupling is applied to two examples to decrease couplings in the dynamics. Forthe first example, the aim was to use the decoupling method to decrease interactions of the temperature dynamics of adjacent rooms, in order to be able to regulate the temperature of each room without influence from another room. In the second example, the room temperature was to be regulated using the temperature of the air in a ventilation system. However, changing the air flow rate in the ventilation system influences the room temperature as well. The aim was to use inverted decoupling to decrease this coupling. In simulation studies, the proposed decoupled controller could reduce the effect of the couplings in both examples.

• This thesis is consists of two parts, applying concepts from automatic control to different application areas.The first part of this thesis concerns the development of an optimization-based algorithm, determining the size of insulin and glucose doses for patients suffering from Diabetes Mellitus and treated with multiple insulin injections. Diabetes Mellitus is a chronic disease characterized by elevated blood glucose levels. The therapy usually consists of insulin injections, where the amount of insulin to be administered is decided by the patient using empirically developed rules of thumb. An algorithm is proposed determining the dose intakes of insulin and glucose bringing the blood glucose concentration back to a healthy range. The algorithm uses optimization methods and patient-individual blood glucose predictions to determine thesedoses. The cost function used for the optimization problem reflects the risk associated with the blood glucose values. A virtual patient was used as an in-silico test-bed for the proposed algorithm. The results were compared to a bolus calculator. It was found that the proposed control algorithm could improve the time of the simulated patient’s blood glucose spends in a safe range compared to the bolus c0alculator.The second part of this thesis aims at applying inverted decoupling to the area of temperature control in buildings. With inverted decoupling, a multi-variable system can be controlled as several single input single output systems. Buildings are multi-variable systems with many interacting variables. In the second part of this thesis, inverted decoupling is applied to two examples to decrease couplings in the dynamics. Forthe first example, the aim was to use the decoupling method to decrease interactions of the temperature dynamics of adjacent rooms, in order to be able to regulate the temperature of each room without influence from another room. In the second example, the room temperature was to be regulated using the temperature of the air in a ventilation system. However, changing the air flow rate in the ventilation system influences the room temperature as well. The aim was to use inverted decoupling to decrease this coupling. In simulation studies, the proposed decoupled controller could reduce the effect of the couplings in both examples.

Ämnesord

TEKNIK OCH TEKNOLOGIER  -- Elektroteknik och elektronik -- Reglerteknik (hsv//swe)

ENGINEERING AND TECHNOLOGY  -- Electrical Engineering, Electronic Engineering, Information Engineering -- Control Engineering (hsv//eng)

MEDICIN OCH HÄLSOVETENSKAP  -- Medicinsk bioteknologi -- Annan medicinsk bioteknologi (hsv//swe)

MEDICAL AND HEALTH SCIENCES  -- Medical Biotechnology -- Other Medical Biotechnology (hsv//eng)

Nyckelord

Diabetes, Prediction, Optimization, Decision Support System, Inverted Decoupling, PID, Buildings, Ventilation System

Publikations- och innehållstyp

dok (ämneskategori)

vet (ämneskategori)