In our daily life, we spend a lot of time using the mobile devices, such as smart phones and tablet PCs. People receive the emitted light from the mobile displays. The light is mainly composed by the spectrum of the blue light. The energy of blue light is strong, so it can directly act on photoreceptors and cause vision impairment. However, blue light may also exhibit impacts on human physiology and behaviors, such as the circadian rhythms and sleep-wake activities. In our study, we investigated the effects of different spectra of light on the sleep architecture and sleep circadian rhythm. We used rats as the animal model. Rats were received different LED light exposures, including the blue light (450 nm ~ 490 nm), orange light (590 nm ~ 635 nm) and red light (620 nm ~ 650 nm) during the last 8 hours of the dark period or the light period in a 12:12h light:dark cycle. The intensity of each light spectrum was 500 lux ± 100 lux. Sleep-wake activities were recorded. Then, we investigated the sleep alterations after the light exposures. We further used melatonin ELISA kit to measure the concentrations of melatonin in rat serum in four time points (ZT0, ZT2, ZT4, ZT6) after blue light exposure. Our result indicated that non-rapid eye movement (NREM) sleep was increased when we gave the 8-h light exposure in dark period. Sleep fluctuation was shift about 2-h after light exposure. If we analyze the sleep percentage in the following two days, we could not see any significant change. There was almost no difference between blue, orange and red light groups. In this case, we have two hypotheses to explain. The first explanation is that NREM sleep was increased during the 8-h light exposure during the dark period, there might be a decrease of NREM sleep in the following light period by a compensatory effect. The other reason is that the light effect directly affected circadian process to change the sleep pattern. On the other hand, the 8-h light exposure given during the light period did not significantly change sleep-wake activities. However, the sleep architectures, including sleep bouts, sleep duration and transition, were changed when rats receive the light exposure either during the dark period or during the light period. NREM bouts were increased, duration was decreased and transition number was increased, indicating sleep was fragmented. The sleep architectures recorded in the following two days also exhibited the fragmentation of sleep activity. We further investigated the change of melatonin concentrations in serum after light exposure and found that the concentrations of melatonin were declined when rats were received the blue light exposure in ZT0, ZT2, ZT4, and ZT6. Our result suggests that the alterations in the sleep architectures and sleep circadian rhythm differed when rats exposed to different light spectra in different zeitgeber times. The NREM sleep architecture became fragmented after light exposure. In blue light group, the melatonin concentration was in low level after blue light exposure. Despite of blue light, other spectrums of light also have effects on circadian rhythms and sleep. In our daily life, it is important to consider the light effect from our environment.