| Pitch-catch active sensing methods in structural health monitoring for aircraft structures JB Ihn, FK Chang Structural Health Monitoring 7 (1), 5-19, 2008 | 790 | 2008 |
| Detection and monitoring of hidden fatigue crack growth using a built-in piezoelectric sensor/actuator network: I. Diagnostics JB Ihn, FK Chang Smart materials and structures 13 (3), 609, 2004 | 589 | 2004 |
| Detection and monitoring of hidden fatigue crack growth using a built-in piezoelectric sensor/actuator network: II. Validation using riveted joints and repair patches JB Ihn, FK Chang Smart materials and structures 13 (3), 621, 2004 | 308 | 2004 |
| Machine health management in smart factory: A review GY Lee, M Kim, YJ Quan, MS Kim, TJY Kim, HS Yoon, S Min, DH Kim, ... Journal of Mechanical Science and Technology 32, 987-1009, 2018 | 125 | 2018 |
| Built-in diagnostics for monitoring crack growth in aircraft structures JB Ihn, FK Chang, H Speckmann Key engineering materials 204, 299-308, 2001 | 97 | 2001 |
| Lamb wave mode decomposition using concentric ring and circular piezoelectric transducers CM Yeum, H Sohn, JB Ihn Wave motion 48 (4), 358-370, 2011 | 89 | 2011 |
| Method and apparatus for modeling responses of a material to various inputs JB Ihn US Patent 7,991,587, 2011 | 84 | 2011 |
| Instantaneous delamination detection in a composite plate using a dual piezoelectric transducer network CM Yeum, H Sohn, JB Ihn, HJ Lim Composite Structures 94 (12), 3490-3499, 2012 | 82 | 2012 |
| Three dimensional evaluation of aluminum plates with wall-thinning by full-field pulse-echo laser ultrasound SC Hong, AD Abetew, JR Lee, JB Ihn Optics and Lasers in Engineering 99, 58-65, 2017 | 58 | 2017 |
| Reference‐free delamination detection using Lamb waves CM Yeum, H Sohn, HJ Lim, JB Ihn Structural Control and Health Monitoring 21 (5), 675-684, 2014 | 57 | 2014 |
| A potential link from damage diagnostics to health prognostics of composites through built-in sensors FK Chang, JFC Markmiller, JB Ihn, KY Cheng | 53 | 2007 |
| Bondline embedded current sensor CE Anway, AM Robb, JB Ihn US Patent 9,267,906, 2016 | 47 | 2016 |
| Mobilized sensor network for structural health monitoring JS Jang, JB Ihn US Patent 8,930,042, 2015 | 46 | 2015 |
| Direct printing of strain sensors via nanoparticle printer for the applications to composite structural health monitoring GY Lee, MS Kim, HS Yoon, J Yang, JB Ihn, SH Ahn Procedia CIRP 66, 238-242, 2017 | 45 | 2017 |
| Kirigami auxetic structure for high efficiency power harvesting in self-powered and wireless structural health monitoring systems S Farhangdoust, G Georgeson, JB Ihn, FK Chang Smart Materials and Structures 30 (1), 015037, 2020 | 40 | 2020 |
| Design principles and inspection techniques for long life endurance of aircraft structures C Boller, JB Ihn, WJ Staszewski, H Speckmann Proc. 3rd Internat. Workshop on Struct. Health Monitoring, 275-283, 2001 | 35 | 2001 |
| Multicrack growth monitoring at riveted lap joints using piezoelectric patches JB Ihn, FK Chang Smart Nondestructive Evaluation for Health Monitoring of Structural and …, 2002 | 32 | 2002 |
| Method of coupling digitizing sensors to a structure SS Kessler, JB Ihn, CT Dunn, JL Duce, MG Borgen US Patent 8,745,864, 2014 | 30 | 2014 |
| Ultrasonic non-destructive evaluation for structure health monitoring: built-in diagnostics for hot-spot monitoring in metallic and composite structures JB Ihn, FK Chang, T Kundu Ultrasonic Nondestructive Evaluation Engineering and Biological Material …, 2004 | 29 | 2004 |
| Highly sensitive solvent-free silver nanoparticle strain sensors with tunable sensitivity created using an aerodynamically focused nanoparticle printer GY Lee, MS Kim, SH Min, HS Kim, HJ Kim, R Keller, JB Ihn, SH Ahn ACS applied materials & interfaces 11 (29), 26421-26432, 2019 | 26 | 2019 |
