Western Taiwan is suffering severe subsidence caused by groundwater withdrawal. The conventional geodetic sensors, including leveling and GPS, have been used to monitor land subsidence. Those sensors can only deliver point-wise displacements and the monitoring capacity of displacement is limited by point density. In this study, we applied temporarily coherent point SAR interferometry (TCPInSAR) to derive long-term deformation rates over Changhua, Yunlin, and Chiayi. The proposed method can estimate deformation parameters without the effect of unresolved phase ambiguity resolut. The study uses 19 ALOS PALSAR images along track 446 from 2006 to 2011 to derive line of sight (LOS) deformation in Changhua. The pixel density over Changhua is 361 pixel/km2, compared to 0.2 point/km2 of the leveling benchmarks. The study also utilized 15 ALOS PALSAR images at 447 track from 2007 to 2011 derive LOS deformation in Yunlin and Chiayi. The pixel density over Yunlin and Chiayi are 196 and 250 pixel/km2, compared to 0.3 and 0.2 point/km2 of the leveling benchmarks respectively. We use GPS data to reduce the effect of the horizontal displacement on the LOS deformation to generate vertical displacement. The vertical displacements from TCPInSAR matches the leveling result to 0.9, 0.6, and 0.8 cm/year (RMSE) in Changhua, Yunlin, and Chiayi. This research suggests that TCPInSAR with ALOS PALSAR data can effectively monitor land deformation in a large area like western Taiwan.