A Reliable Transmission Protocol for ZigBee-Based Wireless Patient Monitoring IEEE JOURNALS Volume: 16, Issue:1 Shyr-Kuen Chen, Tsair Kao, Chia-Tai Chan,

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A Reliable Transmission Protocol for ZigBee-Based Wireless Patient Monitoring IEEE JOURNALS Volume: 16, Issue:1 Shyr-Kuen Chen, Tsair Kao, Chia-Tai Chan, Chih-Ning Huang, Chih-Yen Chiang, Chin-Yu Lai, Tse-Hua Tung, and Pi-Chung Wang Presenter: Yu-Ming Chen Adviser: Hung-Chi Yang

Outline Introduction Introduction Related Work Related Work Reliable Transmission Protocol Reliable Transmission Protocol Fall Monitoring system Fall Monitoring system Simulation and implementation Results Simulation and implementation Results Conclusion Conclusion

INTRODUCTION The global elderly population is fast growing and will outnumber the population of children in near future. The global elderly population is fast growing and will outnumber the population of children in near future. The changes brought about by the aging society include an increasing demand for caretaking; thus, patient monitoring systems are gaining their importance in reducing the need for human resources. The changes brought about by the aging society include an increasing demand for caretaking; thus, patient monitoring systems are gaining their importance in reducing the need for human resources.

INTRODUCTION In this paper, we present a reliable transmission protocol based on anycast routing for wireless patient monitoring. In this paper, we present a reliable transmission protocol based on anycast routing for wireless patient monitoring.

INTRODUCTION In this paper, we present a reliable protocol of packet forwarding that transmits emergency messages with vital signs on a multihop ZigBee network. In this paper, we present a reliable protocol of packet forwarding that transmits emergency messages with vital signs on a multihop ZigBee network.

INTRODUCTION We deploy multiple data sinks in a ZigBee network. We deploy multiple data sinks in a ZigBee network. Our protocol uses anycast to find the nearest available data sink. Our protocol uses anycast to find the nearest available data sink. When the path to the original data sink fails, our protocol automatically selects another data sink as destination. When the path to the original data sink fails, our protocol automatically selects another data sink as destination.

INTRODUCTION As compared with multicast/broadcast approaches, our protocol significantly reduces the traffic overhead while maintaining the reliability at the same level.

INTRODUCTION We implement a ZigBee device for fall monitoring, which integrates fall detection indoor positioning, and ECG monitoring. We implement a ZigBee device for fall monitoring, which integrates fall detection indoor positioning, and ECG monitoring. When the triaxial accelerometer of our device detects a fall, the current position of the patient is generated and transmitted to a data sink through a ZigBee network. When the triaxial accelerometer of our device detects a fall, the current position of the patient is generated and transmitted to a data sink through a ZigBee network.

INTRODUCTION In order to clarify the situation of the fallen patient, 4-s ECG signals are transmitted along with the emergency message. In order to clarify the situation of the fallen patient, 4-s ECG signals are transmitted along with the emergency message.

RELATED WORK A Communication Modes A Communication Modes Data transmission can be categorized into four modes, namely unicast, multicast, broadcast, and anycast. Data transmission can be categorized into four modes, namely unicast, multicast, broadcast, and anycast.

RELATED WORK B. Wireless Patient Monitoring System This framework uses four routing schemes(multicast, reliable multicast, broadcast, and reliable broadcast) This framework uses four routing schemes(multicast, reliable multicast, broadcast, and reliable broadcast)

RELATED WORK B. Wireless Patient Monitoring System Using IEEE standard for ECG, the maximum payload size only allow up to 118 samples per frame bringing the accumulation delay to 236ms. Using IEEE standard for ECG, the maximum payload size only allow up to 118 samples per frame bringing the accumulation delay to 236ms.

RELATED WORK B. Wireless Patient Monitoring System The minimum data sampling rate of 1 sample per frame result in an accumulated delay of 2 ms. The minimum data sampling rate of 1 sample per frame result in an accumulated delay of 2 ms.

RELATED WORK B. Wireless Patient Monitoring System B. Wireless Patient Monitoring System Previous schemes tend to use broadcast or multicast schemes to achieve message delivery in a multihop wireless network. Previous schemes tend to use broadcast or multicast schemes to achieve message delivery in a multihop wireless network.

RELATED WORK RELATED WORK B. Wireless Patient Monitoring System B. Wireless Patient Monitoring System Although the number of transmission hops and traffic overhead can be reduced by using excess transmission power, the collision domain is also enlarged to severely degrade the transmission efficiency of MAC layer. Although the number of transmission hops and traffic overhead can be reduced by using excess transmission power, the collision domain is also enlarged to severely degrade the transmission efficiency of MAC layer.

RELATED WORK B. Wireless Patient Monitoring System B. Wireless Patient Monitoring System We combine anycast with a reliable transmission mechanism to improve the efficiency of message transmission in this paper. We combine anycast with a reliable transmission mechanism to improve the efficiency of message transmission in this paper. Since our scheme does not rely on in creasing transmission power, the power efficiency of our scheme can be improved as well. Since our scheme does not rely on in creasing transmission power, the power efficiency of our scheme can be improved as well.

RELIABLE TRANSMISSION PROTOCOL Sensor Node Sensor Node Router Node Router Node Data receiver Data receiver

RELIABLE TRANSMISSION PROTOCOL A. Sensor Node A. Sensor Node

RELIABLE TRANSMISSION PROTOCOL B. Router Node B. Router Node

RELIABLE TRANSMISSION PROTOCOL C. Data Receiver C. Data Receiver

FALL MONITORING SYSTEM SVM: Sum Vector Magnitude of acceleration SVM: Sum Vector Magnitude of acceleration

SIMULATION AND IMPLEMENTATION RESULTS A. Simulation Results A. Simulation Results

SIMULATION AND IMPLEMENTATION RESULTS B. Implementation Results B. Implementation Results

CONCLUSION This paper presents a reliable anycast routing protocol for ZigBee-based wireless patient monitoring. This paper presents a reliable anycast routing protocol for ZigBee-based wireless patient monitoring. A broken path can be recovered in a short latency. A broken path can be recovered in a short latency. We demonstrate that our scheme can improve the feasibility of wireless patient monitoring systems. We demonstrate that our scheme can improve the feasibility of wireless patient monitoring systems.