Fire is one of the most important factors that reduce terrestrial carbon stocks. Recently, the global climate change results in higher temperature and long-term drought, which increase the intensity, burning area, and frequency of forest fire. In general, rising fire frequency would promote the grass encroachment. The invaded grasses sprout quickly in rainy season and become fuels at the next fire event. This grass-fire positive feedback cycle usually leads to repeated fire. Take the protection forest at Dadu tableland in Taichung for example. The original dominate vegetation there was Acacia confuse. The repeated fire caused tree mortality and induced the invasion of the pioneer grasses such as Panicum maximum. Passing through about 30 years repeated fire, the vegetation type of Dadu tableland includes: (1) unburned forest (Acacia confuse, AC) (2) grass invaded forest (IV) (3) standing dead with grass (SD) (4) grassland (GR). We studied how the high-frequency repeated fire influences net primary production (NPP), net ecosystem production (NEP), soil microbial biomass, and microbial community. The results suggested that NPP and NEP were higher at AC and IV, and both NPP and NEP decreased significantly due to fire. The SD and GR sites only remained 64% and 30% NPP of original forest respectively, and became carbon source (NEP were -3.16 and -4.76 Mg C ha-1 yr-1, respectively). These data indicated that repeated fire has a quiet negative impact on carbon cycle. Besides, fire also influenced soil microorganism obviously. Principal component analysis (PCA) separated the microbial communities by times of fire (GR; SD; AC and IV). Microbial biomass carbon of GR, the site being burned most of times, was significant lowest. In addition, GR was the only site that showed seasonal fluctuation in C3 and C4 plant contribution to microbe. Therefore, we considered that the high-frequency repeated fire certainly plays a key role in microorganisms.