Lynch, Jerome P. - Department of Civil and Environmental Engineering, University of Michigan

• 4th International Conference on Earthquake Engineering Taipei, Taiwan
• 1 Lynch, Law Source: Computing in Civil and Building Engineering: Proceedings of the Eight International Conference,
• Source: Proceedings of the US-Korea Workshop on Smart Structural Systems, Pusan, Korea, August 23-Laboratory and Field Validation of a Wireless Sensing Unit Design for
• STRUCTURAL CONTROL AND HEALTH MONITORING Struct. Control Health Monit. 2008; 15:471504
• In-situ Wireless Monitoring of Fiber Reinforced Cementitious Composite Bridge Piers
• POST-SEISMIC DAMAGE ASSESSMENT OF STEEL STRUCTURES INSTRUMENTED WITH SELF-INTERROGATING WIRELESS SENSORS
• 1 INTRODUCTION In the past two decades, many control algorithms and devices have been proposed for civil en-
• The National Science Foundation's Summer Institute in Japan Program Active Structural Control Research at Kajima Corporation
• Smart Structures and Systems, Vol. 3, No. 3 (2007) 321-340 321 Decentralized civil structural control using real-time
• DETECTION OF STRUCTURAL CRACKS USING PIEZOELECTRIC ACTIVE Jerome P. Lynch1
• World Conference on Structural Control and Monitoring 4WCSCM-242 A MULTIRATE RECURSIVE ARX ALGORITHM FOR ENERGY EFFICIENT WIRELESS
• Implementation of a Decentralized Control Algorithm Embedded within a Wireless Active Sensor
• 1 INTRODUCTION Traditionally, structural monitoring systems employ coax-
• Reliable information management in a low-cost wireless structural monitoring and control network
• Parallel data processing architectures for identification of structural modal properties using dense wireless sensor networks
• *wyang98@stanford.edu; phone 1 650 723-6213; fax 1 650 725-9755; http://eil.stanford.edu/WiMMS/ Design of a Low-Power Wireless Structural Monitoring System for
• EARTHQUAKE ENGINEERING AND STRUCTURAL DYNAMICS Earthquake Engng Struct. Dyn. 2002; 31:18551877 (DOI: 10.1002/eqe.193)
• World Conference on Structural Control and Monitoring 4WCSCM-252 Wang, Swartz, Lynch, Law, Lu and Loh 1
• IOP PUBLISHING NANOTECHNOLOGY Nanotechnology 18 (2007) 315501 (9pp) doi:10.1088/0957-4484/18/31/315501
• *jerlynch@umich.edu; phone 1-734-615-5290; fax 1-734-764-4292; http://www-personal.engin.umich.edu/~jerlynch/ Linear Classification of System Poles for Structural Damage Detection
• Issues in Wireless Structural Damage Monitoring Technologies
• Real-Time Damage Prognosis of High-Performance Fiber Reinforced Cementitious Composite Structures
• Yang Wang, and Kincho H. Law, Dept. of Civil and Environmental Engineering, Stanford University, Stanford, CA 94305. Jerome P. Lynch, Dept. of Civil and Environmental
• Application of a wireless sensing and control system to control a torsion-coupling building with MR-dampers
• Validation of a large-scale wireless structural monitoring system on the Geumdang Bridge
• * jerlynch@umich.edu; phone 1 734-615-5290; http://www-personal.engin.umich.edu/~jerlynch/ Rapid-to-Deploy Wireless Monitoring Systems for Static and Dynamic
• Source: Proceedings of the 9th International Conference on Applications of Statistics and Probability in Civil Engineering, San Francisco, CA, USA, July 6-9, 2003.
• Passive Wireless Strain and pH Sensing Using Carbon Nanotube-Gold Nanocomposite Thin Films
• 4th International Conference on Earthquake Engineering Taipei, Taiwan
• A Summary Review of Wireless Sensors and Sensor Networks for Structural Health Monitoring
• Source: SPIE 11th Annual International Symposium on Smart Structures and Materials, San Diego, CA, USA, March 14-18, 2004
• Data Driven Model Updating using Wireless Sensor Networks Andrew T. Zimmerman1
• Parallelized Simulated Annealing for Model Updating in Ad-Hoc Wireless Sensing Networks
• Critical Design Parameters and Operating Conditions of Wireless Sensor Units for Structural Health Monitoring
• 1 INTRODUCTION Structural monitoring and control have undergone
• Source: Proceedings of the MCEER Mitigation of Earthquake Disaster by Advanced Technologies (MEDAT-2) Workshop, Las Vegas, NV, USA, November 30-31, 2000.
• Partial Decentralized Wireless Control Through Distributed Computing for Seismically Excited Civil Structures: Theory and Validation
• Proceedings of ICAST2006: 17th International Conference on Adaptive Structures and Technologies
• WIRELESS SENSING FOR STRUCTURAL HEALTH MONITORING OF CIVIL STRUCTURES
• Inductively Coupled Multifunctional Carbon Nanotube-Based Nanocomposite Sensors
• Abstract --Civil structures are often exposed to strong winds and seismic loads resulting in large structural
• Source: The 5th US National Congress on Computational Mechanics, University of Colorado at Boulder, CO, USA, August 4-6, 1999. THE DEVELOPMENT AND APPLICATION OF A DAMAGE DETECTION TOOLBOX
• Source: Proceedings of the US-Korea Workshop on Smart Structural Systems, Pusan, Korea, August 23-Energy Market-Based Control of Linear Civil Structures
• Ambient Vibration Study of the Gi-Lu Cable-Stay Bridge: Application of Wireless Sensing Units
• Structural health monitoring (SHM) entails the use of structural response data to identify the existence, location, and severity of structural damage. However, damage
• Reliability and Data Quality of a Wireless Sensing Unit Developed for Structural Health Monitoring
• World Conference on Structural Control and Monitoring 4WCSCM-243 NANOENGINEERED INDUCTIVELY COUPLED CARBON NANOTUBE WIRELESS
• Automated identification of modal properties in a steel bridge instrumented with a dense wireless sensor network
• 1 INTRODUCTION Recently, multifunctional materials for structural health monitoring (SHM) have gained signifi-
• Source: Proceedings of International Conference on Advances and New Challenges in Earthquake Engineering Research (ICANCEER02), Hong Kong, China, August 19-20, 2002.
• Source: Proceedings of the 4th International Workshop on Structural Health Monitoring, Stanford,
• Mechanical-electrical characterization of carbon-nanotube thin films for structural monitoring applications
• INSTITUTE OF PHYSICS PUBLISHING SMART MATERIALS AND STRUCTURES Smart Mater. Struct. 13 (2004) 800810 PII: S0964-1726(04)80048-X
• 1 INTRODUCTION Civil structures require a substantial investment of
• STRUCTURAL CONTROL AND HEALTH MONITORING Struct. Control Health Monit. 2008; 15:518539
• Wireless Structural Monitoring of the Geumdang Bridge using Resolution Enhancing Signal Conditioning
• EARTHQUAKE ENGINEERING AND STRUCTURAL DYNAMICS Earthquake Engng Struct. Dyn. 2009; 38:377401
• Electrical impedance tomography of carbon nanotube composite Tsung-Chin Hou, Kenneth J. Loh, Jerome P. Lynch1
• Feasibility of real-time distributed structural control upon a wireless sensor network
• Structural Engineering and Mechanics, Vol. 15, No. 3 (2003) 285-297 285 Embedment of structural monitoring algorithms
• *jplynch@stanford.edu; phone 1-650-723-6213; fax 1-650-725-9755; The John A. Blume Earthquake Engineering Center, Stanford University; Stanford, CA 94305;
• IEEE SENSORS JOURNAL, VOL. 9, NO. 11, NOVEMBER 2009 1503 A Parallel Simulated Annealing Architecture for
• Electrical Impedance Tomographic Methods for Sensing Strain Fields and Crack Damage in Cementitious Structures
• J Nondestruct Eval (2009) 28: 925 DOI 10.1007/s10921-009-0043-y
• Smart Structures and Systems, Vol. 4, No. 5 (2008) 531-548 531 Inductively coupled nanocomposite wireless strain
• Automated Modal Parameter Estimation by Parallel Processing within Wireless Monitoring Systems
• Engineering Structures 30 (2008) 18201830 www.elsevier.com/locate/engstruct
• http://jim.sagepub.com Journal of Intelligent Material Systems and
• EARTHQUAKE ENGINEERING AND STRUCTURAL DYNAMICS Earthquake Engng Struct. Dyn. 2007; 36:13031328
• IOP PUBLISHING SMART MATERIALS AND STRUCTURES Smart Mater. Struct. 16 (2007) 429438 doi:10.1088/0964-1726/16/2/022
• A wireless structural health monitoring system with multithreaded sensing devices: design and validation
• An overview of wireless structural health monitoring for civil structures
• STRUCTURAL CONTROL AND HEALTH MONITORING Struct. Control Health Monit. 2005; 12:405423
• EARTHQUAKE ENGINEERING AND STRUCTURAL DYNAMICS Earthquake Engng Struct. Dyn. 2005; 34:555573
• Structural Engineering and Mechanics, Vol. 17, No. 3-4 (2004) 000-000 1 Design and performance validation of a wireless sensing
• Structural Engineering and Mechanics, Vol. 17, No. 3-4 (2004) 000-000 1 Decentralized energy market-based structural control
• WIRELESS AND ELECTROMECHANICAL APPROACHES FOR STRAIN SENSING AND CRACK DETECTION IN
• 1 INTRODUCTION The United States and Korea are both highly developed nations with extensive transportation
• Distributed Model Updating in Smart Wireless Monitoring Systems Andrew Zimmerman, University of Michigan, Ann Arbor, MI, atzimmer@umich.edu
• The Use of Wireless Sensors in Geotechnical Field Applications David A. Saftner1
• Damage Characterization of the Z24 Bridge by Transfer Function Pole Migration R. Andrew Swartz1
• Instrumentation for the NEESR Sand Aging Field Experiment David A. Saftner1
• Wireless Monitoring Techniques for Structural Health Kenneth J Loh and Andrew T Zimmerman
• Abstract--The performance aspects of a wireless "active" sensor, including the reliability of the wireless communication
• Wireless Sensing and Control , Kenneth J. Lohb
• 1 INTRODUCTION Deteriorating civil infrastructures (i.e. buildings,
• Performance evaluation of decentralized wireless sensing and control in civil structures
• Redundant Kalman Estimation for a Distributed Wireless Structural Control System R. Andrew Swartz1
• Electrical Impedance Analysis of Carbon Nanotube-Polyelectrolyte Thin Film Strain Sensors Jerome P. Lynch1,2
• 4th International Conference on Earthquake Engineering Taipei, Taiwan
• US-Taiwan Workshop on Smart Structural Technology for Seismic Hazard Mitigation Taipei, Taiwan
• World Conference on Structural Control and Monitoring 4WCSCM-261 Loh, Lu, Wang, Swartz, Lynch, and Lin 1
• Wireless Sensing, Actuation and Control --with Applications to Civil Structures
• * jerlynch@umich.edu; phone 1 734-615-5290; http://www-personal.engin.umich.edu/~jerlynch/ Wireless Feedback Structural Control with Embedded Computing
• Source: Proceedings of the 5th International Workshop on Structural Health Monitoring, Stanford,
• Yang Wang, and Kincho H. Law, Dept. of Civil and Environmental Engineering, Stanford University, Stanford, CA 94305.
• Damage Characterization of the IASC-ASCE Structural Health Monitoring Benchmark Structure by Transfer Function Pole Migration
• MONITORING STRAIN IN ENGINEERED CEMENTITIOUS COMPOSITES USING WIRELESS SENSORS
• *jerlynch@umich.edu; phone 1 734 615 5290; http://www-personal.engin.umich.edu/~jerlynch Local-based damage detection of cyclically loaded bridge piers using
• *jerlynch@umich.edu; phone 1 734 615 5290; http://www-personal.engin.umich.edu/~jerlynch Conductivity-based strain monitoring and damage characterization of
• Wireless Structural Sensors using Reliable Communication Protocols for Data Acquisition and Interrogation
• World Conference on Earthquake Engineering Vancouver, B.C., Canada
• Source: Proceedings of the 4th International Workshop on Structural Control and Monitoring, New
• Source: Proceedings of the 22nd International Modal Analysis Conference (IMAC XXII), Dearborn, MI, USA, January 26-29, 2004.
• 1 INTRODUCTION 1.1 General
• ABSTRACT: Recent years has witnessed a growing interest in wireless structural monitoring as a low-cost alternative to tethered monitoring systems. Past work has considered wireless sensors as passive elements in
• Design of Wireless Sensor Units with Embedded Statistical Time-Series Damage Detection Algorithms for Structural Health Monitoring
• Source: Proceedings of Advances in Structural Engineering and Mechanics (ASEM'02), Pusan, Korea, August 21-23, 2002.
• Source: Proceedings of International Conference on Advances and New Challenges in Earthquake Engineering Research (ICANCEER02), Hong Kong, China, August 19-20, 2002.
• *jplynch@stanford.edu; phone 1-650-723-6213; fax 1-650-725-9755; The John A. Blume Earthquake Engineering Center, Stanford University; Stanford, CA 94305;
• Source: Proceedings of the 20th International Modal Analysis Conference (IMAC XX), Los Angeles, CA, USA, February 4-7, 2002.
• Source: Proceedings of the 20th International Modal Analysis Conference (IMAC XX), Los Angeles, CA, USA, February 4-7, 2002.
• Investigation of Data Quality in a Wireless Sensing Unit Composed of Off-the-Shelf Components
• Source: Proceedings of the 19th International Modal Analysis Conference (IMAC XIX), Orlando, FL, USA, February 5-9, 2001.
• INTRODUCTION Currently, wind turbines can incur unforeseen damage up to five times a year.
• ylei@stanford.edu; phone (650) 725 0360; fax (650) 725 9755 Source: SPIE's 10
• Design of Piezoresistive MEMS-Based Accelerometer for Integration with Wireless Sensing Unit
• Source: Proceedings of the 5th International Workshop on Structural Health Monitoring, Stanford,
• 1 INTRODUCTION Wireless sensor networks tailored for structural
• Source: SPIE's 10 Annual International Symposium on Smart Structures and Materials, San Diego,
• Andrew T. Zimmerman, Ph.D. Student, Department of Civil & Environmental Engineering, University of Michigan, Ann Arbor, MI, USA, 48105.
• STRUCTURAL HEALTH MONITORING SYSTEM WITH THE LATEST INFORMATION TECHNOLOGIES
• Source: Proceedings of the International Workshop on Smart Materials and Structures Technology, Honolulu, Hawaii, USA, January 12-14, 2004.
• Strategic Network Utilization in a Wireless Structural Control System for Seismically Excited Structures
• INSTITUTE OF PHYSICS PUBLISHING SMART MATERIALS AND STRUCTURES Smart Mater. Struct. 15 (2006) 15611575 doi:10.1088/0964-1726/15/6/008
• US-Taiwan Workshop on Smart Structural Technology for Seismic Hazard Mitigation Taipei, Taiwan
• Steel Structures 8 (2008) 267-275 www.ijoss.org Smart Wireless Sensor Technology for Structural Health