scholarly journals Wireless Body Area Network Control Policies for Energy-Efficient Health Monitoring

Sensors ◽  
2021 ◽  
Vol 21 (12) ◽  
pp. 4245
Author(s):  
Yair Bar David ◽  
Tal Geller ◽  
Ilai Bistritz ◽  
Irad Ben-Gal ◽  
Nicholas Bambos ◽  
...  
Keyword(s):  
Health Monitoring ◽  
Optimal Policy ◽  
Belief State ◽  
Health State ◽  
Body Area ◽  
Markov Decision Problem ◽  
Trade Off ◽  
Look Ahead ◽  
One Step ◽  
Greedy Policy

Wireless body area networks (WBANs) have strong potential in the field of health monitoring. However, the energy consumption required for accurate monitoring determines the time between battery charges of the wearable sensors, which is a key performance factor (and can be critical in the case of implantable devices). In this paper, we study the inherent trade-off between the power consumption of the sensors and the probability of misclassifying a patient’s health state. We formulate this trade-off as a dynamic problem, in which at each step, we can choose to activate a subset of sensors that provide noisy measurements of the patient’s health state. We assume that the (unknown) health state follows a Markov chain, so our problem is formulated as a partially observable Markov decision problem (POMDP). We show that all the past measurements can be summarized as a belief state on the true health state of the patient, which allows tackling the POMDP problem as an MDP on the belief state. Then, we empirically study the performance of a greedy one-step look-ahead policy compared to the optimal policy obtained by solving the dynamic program. For that purpose, we use an open-source Continuous Glucose Monitoring (CGM) dataset of 232 patients over six months and extract the transition matrix and sensor accuracies from the data. We find that the greedy policy saves ≈50% of the energy costs while reducing the misclassification costs by less than 2% compared to the most accurate policy possible that always activates all sensors. Our sensitivity analysis reveals that the greedy policy remains nearly optimal across different cost parameters and a varying number of sensors. The results also have practical importance, because while the optimal policy is too complicated, a greedy one-step look-ahead policy can be easily implemented in WBAN systems.

scholarly journals Wireless Body Area Network Control Policies for Energy-Efficient Health Monitoring

2021 ◽  
Author(s):  
Yair Bar David ◽  
Tal Geller ◽  
Ilai Bistritz ◽  
Irad Ben-Gal ◽  
Nicholas Bambos ◽  
...  
Keyword(s):  
Health Monitoring ◽  
Optimal Policy ◽  
Belief State ◽  
Health State ◽  
Body Area ◽  
Markov Decision Problem ◽  
Trade Off ◽  
Look Ahead ◽  
One Step ◽  
Greedy Policy

Abstract: Wireless body area networks (WBANs) have strong potential in the field of health monitoring. However, the energy consumption required for accurate monitoring limits the time between battery charges of the wearable sensors, which is a key performance factor (and can be critical in the case of implantable devices). In this paper, we study the inherent trade-off between the power consumption of the sensors and the probability of misclassifying a patient’s health state. We formulate this trade-off as a dynamic problem, in which at each step we can choose to activate a subset of sensors that provide noisy measurements of the patient’s health state. We assume that the (unknown) health state follows a Markov chain, so our problem is formulated as a partially observable Markov decision problem (POMDP). We show that all the past measurements can be summarized as a belief state on the true health state of the patient, which allows tackling the POMDP problem as an MDP on the belief state. We then empirically study the performance of a greedy one-step look-ahead policy compared to the optimal policy obtained by solving the dynamic program. For that purpose, we use an open-source Continuous Glucose Monitoring (CGM) data set of 232 patients over six months and extract the transition matrix and sensor accuracies from the data. We find that the greedy policy saves ~50% of the energy costs while reducing the misclassification costs by less than 2% compared to the most accurate policy possible that always activates all sensors. Our sensitivity analysis reveals that the greedy policy remains nearly optimal across different cost parameters and a varying number of sensors. The results also have practical importance, because while the optimal policy is too complicated, a greedy one-step look-ahead policy can be easily implemented in WBAN systems.

scholarly journals Adaptive Semi-Active Suspension and Cruise Control through LPV Technique

2020 ◽  
Vol 11 (1) ◽  
pp. 290
Author(s):  
Hakan Basargan ◽  
András Mihály ◽  
Péter Gáspár ◽  
Olivier Sename
Keyword(s):  
Control Systems ◽  
Active Suspension ◽  
Cruise Control ◽  
Linear Parameter Varying ◽  
Trade Off ◽  
Look Ahead ◽  
Vehicle Velocity ◽  
Suspension Control ◽  
Road Data ◽  
Terrain Characteristics

Several studies exist on topics of semi-active suspension and vehicle cruise control systems in the literature, while many of them just consider actual road distortions and terrain characteristics, these systems are not adaptive and their subsystems designed separately. This study introduces a new method where the integration of look-ahead road data in the control of the adaptive semi-active suspension, where it is possible to the trade-off between comfort and stability orientation. This trade-off is designed by the decision layer, where the controller is modified based on prehistorical passive suspension simulations, vehicle velocity and road data, while the behavior of the controller can be modified by the use of a dedicated scheduling variable. The adaptive semi-active suspension control is designed by using Linear Parameter Varying (LPV) framework. In addition to this, it proposes designing the vehicle velocity for the cruise controller by considering energy efficiency and comfort together. TruckSim environment is used to validate the operation of the proposed integrated cruise and semi-active suspension control system.

Time trade-off and attitudes toward euthanasia: implications of using ‘death’ as an anchor in health state valuation

2012 ◽  
Vol 22 (4) ◽  
pp. 705-714 ◽  
Author(s):  
Liv A. Augestad ◽  
Kim Rand-Hendriksen ◽  
Knut Stavem ◽  
Ivar Sønbø Kristiansen
Keyword(s):  
Health State Valuation ◽  
Health State ◽  
Trade Off

scholarly journals On sensor optimisation for structural health monitoring robust to environmental variations

2021 ◽  
Vol 6 (5) ◽  
pp. 1107-1116
Author(s):  
Tingna Wang ◽  
David J. Wagg ◽  
Keith Worden ◽  
Robert J. Barthorpe
Keyword(s):  
Structural Health Monitoring ◽  
Health Monitoring ◽  
Health State ◽  
Damage Classification ◽  
Health States ◽  
Structural Health ◽  
Classification Technique ◽  
Statistical Pattern ◽  
Environmental Variations ◽  
Using Data

Abstract. Structural health monitoring (SHM) is often approached from a statistical pattern recognition or machine learning perspective with the aim of inferring the health state of a structure using data derived from a network of sensors placed upon it. In this paper, two SHM sensor placement optimisation (SPO) strategies that offer robustness to environmental effects are developed and evaluated. The two strategies both involve constructing an objective function (OF) based upon an established damage classification technique and an optimisation of sensor locations using a genetic algorithm (GA). The key difference between the two strategies explored here is in whether any sources of benign variation are deemed to be observable or not. The relative performances of both strategies are demonstrated using experimental data gathered from a glider wing tested in an environmental chamber, with the structure tested in different health states across a series of controlled temperatures.

scholarly journals IOT Based Health Monitoring System

2021 ◽  
Vol 9 (8) ◽  
pp. 1176-1178
Author(s):  
Sowmya G
Keyword(s):  
Monitoring System ◽  
Health Monitoring ◽  
Social Insurance ◽  
Vital Signs ◽  
Smart Phone ◽  
Smart Devices ◽  
The Internet ◽  
Health State ◽  
Health Monitoring System ◽  
Vital Parameters

Abstract: The increased use of smart phones and smart devices in the health zone has brought on extraordinary effect on the world’s critical care. The Internet of things is progressively permitting to coordinate sensors fit for associating with the Internet and give data on the health condition of patients. These technologies create an amazing change in medicinal services during pandemics. Likewise, many users are beneficiaries of the M-Health (Mobile Health) applications and E-Health (social insurance upheld by ICT) to enhance, help and assist continuously to specialists who help. The main aim of this ‘IOT Health Monitoring System’ is to build up a system fit for observing vital body signs such as body temperature, heart rate, pulse oximetry etc. The System is additionally equipped measuring Room Temperature and Humidity and Atmosphere CO level. To accomplish this, the system involves many sensors to display vital signs that can be interfaced to the doctor’s smart phone as well as caretakers’ smartphone. This prototype will upload the readings from the sensor to a server remotely and the information gathered will be accessible for analysis progressively. It has the capacity of reading and transmitting vital parameters measured to the cloud server and then to any Smartphone configured with Blynk App. These readings can be utilized to recognize the health state of the patient and necessary actions can be taken if the vital parameters are not in prescribed limits for a longer period. Keywords: IOT Health Monitoring System, Vital parameters, Blynk App

A Wireless Body Area Sensor Based IOT Scheme for Healthcare Applications

2021 ◽  
Author(s):  
Anna Palagan C ◽  
Sanjai Gupta ◽  
Anand J Dhas ◽  
Shrikant Taware ◽  
Ravi Chakravarthi R ◽  
...  
Keyword(s):  
Health Care ◽  
Heart Rate ◽  
Psychological Health ◽  
Wireless Sensors ◽  
Base Station ◽  
Health State ◽  
Body Area ◽  
Healthcare Applications ◽  
Speed Up ◽  
Physical And Psychological Health

Abstract Between the collections of applications allowed by the IoT, smart and linked health care may be mainly vital one. Networked sensors, either damaged on body or entrenched in atmospheres, alter the assembly of wealthy info symptomatic of our physical and psychological health. For example, heart patient parameter such as BP, heart rate and activities of fetal to regulate their health state. In this paper, a coordinator node has devoted on patient’s body to gather all the signals from the wireless sensors and directs them to base station. The involved sensors on patient’s body form a WBAN and they are talented to sense the heart rate, BP and so on. This scheme can notice the irregular conditions, problem an alarm to the patient and direct a message to the clinician, ambulance and family. The focal benefit of this scheme in assessment to earlier systems is to decrease the energy consumption to extend the network period, speed up and encompass the statement coverage to upsurge the choice for enhance patient superiority of lifetime. Here, we focus the chances and tasks for WSN in understanding this idea of longer term of health care.

Internet of Things Based Stable Increased-throughput Multi-hop Protocol for Link Efficiency (IoT-SIMPLE) for health monitoring in Wireless Body Area Networks

2021 ◽  
Vol 11 ◽  
Author(s):  
Arun Kumar Rana ◽  
Sharad Sharma
Keyword(s):  
Internet Of Things ◽  
Health Monitoring ◽  
Wireless Body Area Network ◽  
Body Area Networks ◽  
Wireless Body Area Networks ◽  
Body Area Network ◽  
Area Network ◽  
Body Area ◽  
Link Efficiency ◽  
Parent Node

Aims: Health monitoring in Wireless Body Area Networks. Background: A medical wireless body area network activated by IoT is mainly concerned with transmitting the quality details to the doctor within a fair period. The explosion of wearable gadgets and recent developments in miniature sensors illustrate the technological viability of any universal tracking program. IoT incorporates a range of tools fitted with sensing, recognition, communication, etc. Objective: To improve the medical facility. Method: The Wireless Body Area Network (WBAN) Internet of Things (IoT) for healthcare applications is an operational scenario for IoT systems that has attracted interest from large fields of study in the last few years. Internet of Things Based Stable Increased-throughput Multi-hop Protocol for Link Efficiency (IoT-SIMPLE), the IoT ties both topics to the healthcare network effortlessly. IoT enables the sensing, retrieval, and connectivity of all facilities or functional criteria and biomedicine. It puts the surgeons, the patients together And nurses can roam without any restrictions through smart devices, and each entity. Now work is underway to improve the healthcare sector by rising prices and increasing patient care quality. The route determines the route between the nodes and the sink. In this paper, we propose a protocol in WBAN that transmits body sensing data from various sensors, installed on the human body, to sink nodes using a multihop routing technique. Our key goal is to increase WBAN’s total network existence by raising cumulative energy usage. The residual energy parameter governs the usage of energy by the sensor nodes while the distance parameter ensures that the packet is effectively transmitted into the sink Result: Simulation results demonstrate that our proposed protocol very energy efficient and maximizes network stability for longer periods. Conclusion: Throughout this paper, we suggest a method for route data to WBANs. The suggested system uses the expense feature to choose the correct path to fall. The costs of the nodes and their spread from the drain are dependent on residual electricity. Nodes with a lower cost function value are selected as the parent node. Other nodes are parent node children and send their data to parent node. Our simulation tests demonstrate that the suggested routing scheme increases the network reliability period and the packet sent to the sink and in future more numbers of sensors can be used to extend this work to measure throughput, network lifetime, and end-to-end delay.

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