무선 센서네트워크에서 오류 데이터 검출 및 데이터 통합 기법

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dc.contributor.advisorDongWook Lee-
dc.contributor.authorLee, Dong-Wook-
dc.date.accessioned2019-10-21T07:17:13Z-
dc.date.available2019-10-21T07:17:13Z-
dc.date.issued2011-02-
dc.identifier.other11339-
dc.identifier.urihttps://dspace.ajou.ac.kr/handle/2018.oak/17802-
dc.description학위논문(박사)--아주대학교 정보통신전문대학원 :정보통신공학과,2011. 2-
dc.description.tableofcontents1. INTRODUCTION 1 1.1. HIGH RELIABLE IN-NETWORK DATA VERIFICATION IN WIRELESS SENSOR NETWORKS 6 1.2. ANALYSIS OF OPTIMIZED AGGREGATION TIMING IN WIRELESS SENSOR NETWORKS 10 1.3. ANALYSIS OF REAL TIME AGGREGATION EFFECTS IN WSN 11 2. HIGH RELIABLE IN-NEWORK DATA VERIFICATION IN WIRELESS SENSOR NETWORKS 13 2.1. RELATED WORKS 13 2.2. DATA VERIFICATION 18 2.2.1. FAULTY SENSOR READINGS 18 2.2.2. FAULTY SENSOR READINGS ELIMINATION 21 2.2.2.1. ADAPTIVE SENSOR FAULT CHECKING 22 2.2.2.2. DATA GATHERING IN AN EVENT GROUP 25 2.2.2.3. MEASUREMENT ERROR ELIMINATION 27 2.2.2.4. SENSOR READING REFINEMENT 29 2.3. PERFORMANCE EVALUATION 31 3. ANALYSIS OF OPTIMIZED AGGREGATION TMING IN WIRELESS SENSOR NETWORKS 40 3.1. RELATED WORKS 40 3.2. AGGREGATION TIMING 42 3.2.1. Basic Approach 42 3.2.2. Stochastic Approach 44 3.2.2.1. Exponential Distribution 46 3.2.2.2. Other Distribution 47 3.3. PERFORMANCE ANALYSIS 48 4. ANALYSIS OF REAL TIME AGGREGATION EFFECTS IN WSN 52 4.1. RELATED WORKS 52 4.2. REAL-TIME AGGREGATION SCHEME AND EFFECTS 53 4.2.1. DELAY AND ENERGY MODEL 54 4.2.2. ANALYSIS OF REAL-TIME AGGREGATION IN SINGLE-HOP 58 5. CONCLUSION 67 5.1. HIGH RELIABLE IN-NETWORK DATA VERIFICATION IN WIRELESS SENSOR NETWORKS 67 5.2. ANALYSIS OF OPTIMIZED AGGREGATION TIMING IN WIRELESS SENSOR NETWORKS 68 5.3. ANALYSIS OF REAL TIME AGGREGATION EFFECTS IN WSN 68 BIBLIOGRAPHY 70-
dc.language.isoeng-
dc.publisherThe Graduate School, Ajou University-
dc.rights아주대학교 논문은 저작권에 의해 보호받습니다.-
dc.title무선 센서네트워크에서 오류 데이터 검출 및 데이터 통합 기법-
dc.title.alternativeFaulty Data Verification and Data Aggregation Scheme in Wireless Sensor Networks-
dc.typeThesis-
dc.contributor.affiliation아주대학교 정보통신전문대학원-
dc.contributor.department정보통신전문대학원 정보통신공학과-
dc.date.awarded2011. 2-
dc.description.degreeMaster-
dc.identifier.localId569196-
dc.identifier.urlhttp://dcoll.ajou.ac.kr:9080/dcollection/jsp/common/DcLoOrgPer.jsp?sItemId=000000011339-
dc.subject.keyword무선-
dc.subject.keyword센서네트워크-
dc.subject.keyword오류 데이터-
dc.subject.keyword검출-
dc.subject.keyword데이터 통합 기법-
dc.description.alternativeAbstractA wireless sensor network (WSN) is a self-organizing data gathering network, which consists of small sensor nodes that have several capabilities ? sensing, computing and wireless communication. Small sensor nodes (also called smart sensor nodes) sense various events such as variations in temperature, illumination, sound. Sensor nodes can be deployed in an ad-hoc fashion, and operate via wireless communication. Because of these self-configuration abilities, WSN is attractive in many fields like the military, environmental research, industry and home. However, to make sensor network technologies practical in the real-world, there remain several research issues which need to be resolved, such as minimizing sensor reading errors for reliability, efficient energy consumption for prolonging the network lifetime, and real-time data delivery for availability and utility. At the aspect of sensor reading error, we can identify two types of problems with unreliable sensor readings: the user system and the sensor network itself. At the aspect of an application service, sensor reading errors cause service faults to users. For example, if temperature sensors report inaccurate data to a system which controls an air conditioner and a heater, the system may perform an inappropriate task, such as turning on the air conditioner in the winter. Also, at the aspect of a sensor network, sensor reading errors result in high traffic and processing overheads, which causes inefficient energy consumption and communication latency. At the aspect of efficient energy consumption, un-rechargeable characteristics of sensor node, the place sensor node deployed and a great number of sensor nodes cause limited network lifetime of sensor network. There are two different kinds of problems in energy consumption. One is inefficient energy consumption, and the other is unbalanced energy consumption. Inefficient energy consumption is caused by unnecessary energy consumption like idle listening, overhearing and so on. It lowers overall network energy states and reduced network lifetime. Unbalanced energy consumption is caused by WSNs characteristics like inequality of event sensing and centralized data transmissions. It makes WSN lost its sensing spaces (hole problem) and paralyzes the network functions in spite of available resources that is enough to keep on network functions. From the node-level point of view, idle listening, overhearing, collision and control packet overhead are main reasons of inefficient energy consumption. And from the network-level point of view, unnecessary duplication of same data packet and always using optimal routing path are main reasons of energy inefficiency. In the case of unbalanced energy consumption, inequality of event sensing, disregard of remained energy and different distance from the sink node are main reasons. At the respect of real-time data delivery, even though WSN has data reliability and enough lifetime, it is useless if it can?t deliver the data to end user in time. Delivery delay of sensing data such as flood, fire, earthquake is disaster To make sensor network technologies practical in the real-world, these kinds of problems must be solved by providing reliability, energy efficiency and real-time delivery. For these, we studied data verification and data aggregation. Unreliable data in WSN called faulty sensor reading. We classify faulty sensor readings into sensor faults and measurement errors, then propose a novel in-network data verification algorithm which includes adaptive fault checking, measurement error elimination and data refinement. The proposed algorithm eliminates faulty readings as well as refines normal sensor readings, to increase reliability And, by data aggregation, we achieved energy efficiency and real-time delivery. Data aggregation is good choice in WSN because it enhances energy efficiency and minimizes communication delay by reducing data volume and redundancy.-
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Special Graduate Schools > Graduate School of Information and Communication Technology > Department of Information and Communication > 3. Theses(Master)
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