The northwestern part of Taiwan belongs to the Western Foothills Belt and is a fold-thrust belt formed by arc-continent collision. A series of faults and folds are distributed in this region, including the Hsinchu Fault, Hsincheng Fault, Touhuanping Fault, and Chingtsaohu Anticline. Among these, the Hsinchu Fault and Hsincheng Fault are active faults with the potential for significant earthquake hazards. In recent years, although there have been applications of GPS and precise leveling to monitor surface deformation in the Hsinchu-Miaoli area, the focus has generally been on the continuous fold-thrust belt including the Hsincheng Fault and Hsinchu Fault, while the coastal areas and fault-covered segments of Hsinchu-Miaoli lack sufficient observation points. Additionally, while a few studies have utilized Synthetic Aperture Radar Interferometry (InSAR) to investigate the relationship between surface deformation and the tectonics of the Hsinchu-Miaoli region, these studies have rarely addressed the coastal areas and fault-covered segments. This study aims to use Persistent Scatterer Interferometry (PSInSAR) to analyze surface deformation and its spatial and temporal variations in conjunction with background structural exploration to understand the deformation mechanisms in the region. Compared to traditional geodetic measurements, Persistent Scatterer Interferometry (PSInSAR) can provide wide and dense high-precision surface deformation data. This method overcomes the limitations of inadequate or unevenly distributed observation points in the study area when using GPS or precise leveling. In this research, Sentinel-1 C-band radar images from both ascending and descending orbits between 2015 and 2019 were processed using ISCE and StaMPS software to obtain average displacement and time series along the satellite line of sight. The results were further separated into east-west and vertical average displacement components and combined with previous research profiles and seismic data for comprehensive discussion. The results indicate that there is no significant change in the velocity gradient across fault boundaries within the study area, suggesting that the main structural activity is not pronounced. In particular, at the western end of the southern limb of the Chingtsaohu Anticline and at the intersection of the Hsincheng Fault and Touhuanping Fault, higher velocity fields are observed compared to the surrounding areas. Both ascending and descending displacements show motion towards the satellite, indicating uplift deformation dominance in these locations. The highly deformed area at the western end of the southern limb of the Chingtsaohu Anticline coincides with the location of a blind fault. Based on the right-lateral and uplift displacements and subsurface morphology, it can be inferred that the subsurface features of this highly deformed area are positive flower structures formed by a right-lateral reverse fault. Similarly, the highly deformed area where the Hsincheng Fault is intercepted by the Touhuanping Fault coincides with the seismic reflection profile of the Touhuanping Fault, suggesting its reverse displacement nature. Based on this, it is inferred that the local uplift deformation in the highly deformed area is a result of the combined effects of vertical slip along the Touhuanping Fault, northwestward reverse slip along the Hsincheng Fault, and right-lateral movement along the down-dip side of the Touhuanping Fault. The stress convergence in this region leads to more significant strain accumulation in the subsurface layers, causing upward arching of the strata and tensional forces on both sides along the major axis, resulting in opposite displacements.