Four ferns with different light adaptation capabilities (ranking from high to low, Pyrrosia lingus, Asplenium antiquum, Diplazium donianum, Archangiopteris somai) were used to elucidate energy quenching and photoinhibition during light induction. Pot-grown materials received up to three levels of light intensity, i.e., 100%, 50% and 10% sunlight, according to their light adaptation capabilities. At least six months after light acclimation, plant were illuminated with 50, 100, 300, 500, 1000 and 2000 μmol m^(-2) s ^(-1) photosynthetic photon flux density (PPFD), respectively, for 30 min, and then dark-adapted for 30 min. Chlorophyll fluorescence were recorded just before and every 2-5 min during illumination and darkness. Results showed that the leaves measured under high-light intensity declined more in PSII efficiency and showed less reversion after dark adapted for 30 min (high photoinhibition). Even though four tested ferns had different capability of light adaptation, when compared to the same level of PPFD, the degree of photoinhibition was only divided into two groups. Among them, P. lingus utilized more sunlight with high photosynthetic capacity, while A. antiquum and D. donianum dissipated more excess light energy through energy-dependent quenching (qE). This showed that three species could maintain a low degree of photoinhibition, and this could possibly be attributed to their adaptation to direct sunlight and sunfleck. In contrast, A. somai,a heavy-shade adapted fern, showed low photosynthetic rate as well as qE, hence they had high level of excess energy and low ability of photoprotection, resulting in high degree of photoinhibition.