Ms. Runjie Wang is an associate researcher specializing in photogrammetry and remote sensing, with a focus on high-precision and high-dynamic micro-deformation monitoring of urban infrastructure. Serving concurrently as Deputy Director of the Research Institute of Science and Technology Development at Beijing University of Civil Engineering and Architecture and Secretary of the Undergraduate Party Branch of Remote Sensing Science, she also contributes internationally as Secretary of the International Science Council GeoUnions Standing Committee on Disaster Risk Reduction. Her research centers on non-contact, high-frequency, and ultra-high-precision monitoring using ground-based SAR, addressing long-standing challenges in atmospheric disturbance correction, noise separation, and micro-deformation signal reliability for existing bridges and high-rise buildings. Through innovative atmospheric parameter optimization techniques, progressive denoising strategies, and a high-dynamic structural damage detection model based on instantaneous frequency–total energy integration, she has advanced methods for precise decomposition of linear and nonlinear vibrations and significantly improved the credibility of structural health assessments. Ms. Wang has independently led multiple research projects, including a national natural science foundation youth program, open laboratory funding, institutional capacity-building grants, and industry collaborations, contributing to a cumulative funding portfolio of over half a million RMB. Her academic output includes 17 peer-reviewed publications in journals such as Measurement, ISPRS International Journal of Geo-Information, and Remote Sensing, with 12 SCI papers as first or corresponding author, as well as three granted invention patents and one monograph. Her scholarly influence is evidenced by 90 citations, 77 citing documents, 35 total publications, and an h-index of 6, reflecting the growing recognition of her contributions to urban infrastructure monitoring and remote sensing methodology. A recipient of a competitive young talent support honor, Ms. Wang continues to advance high-dynamic remote sensing technologies that enhance the safety, reliability, and cost-effectiveness of critical urban infrastructure monitoring.
Featured Publications
Subway line settlement monitoring and analysis based on PS-InSAR technology and wavelet packet decomposition
Phase noise model construction and denoising method for dynamic infrastructure measurement in 5G base station
Real-time bridge dynamic deflection monitoring using 5G-integrated sensing and communication