The characteristics of atmospheric boundary layer in valleys differs from the same issue over plane terrain. Not only mountain-valley wind but also the deformation of wind field play a role in the development of boundary layer circulation. Some literatures showed that, in addition to mountain-valley wind circulation which is caused by the thermal effect, the prevailing winds have little impact on the wind flow in the valley. Through in-situ observation and high-resolution spatial-time numerical simulation, this research presents the phenomenon of valley boundary layer and the characteristics of wind flow in Xitou valley, which locates in the middle Taiwan with near 1000-m altitude and is part of the Experimental Forest, College of Bio-Resources and Agriculture, National Taiwan University. The in-situ observation showed that, except for the thinner mixed layer, the vertical atmospheric profile in Xitou is similar to that in a general plane. Obvious mountain-valley wind can be observed from local agricultural weather station、40-m height flux tower and the balloon radiosondes. It was also found the mountain-valley wind can only blow under the height of mountain ridges (~2000m MSL), and the wind would approach to prevailing winds above the mountain ridges instead. The temperature and wind field observation of 40m-height flux tower indicate the top of canopy is the critical level near surface. In computational simulations, this study uses STREAM Computational Fluid Dynamics model provide by Cradle Corp. of Japan, to simulate the wind field passing over the real topography in Xitou. In model settings, one stable northerly wind and two real vertical profiles of wind flow from radiosondes’ measurement were set as the boundary condition of wind. The 40m-resolution topography was also imported in these simulations. The results indicated that the northerly V-shape Xitou valley has small wind speed all the time which is caused by the leeside of the mountains for synoptic winds (westerly or west-southerly wind) at Taiwan. In other words, the prevailing winds have little impact on the wind field of Xitou valley. We also found that the wind field was separated by the height of mountain ridges in observation and simulations similarly. Obviously, the height of boundary layer of Xitou valley is decided by the topographic factor. In addition, the numerical simulations with the high-resolution topography gave reasonable results on the characteristics of 3D wind flow in this small-scale valley.