The global variation and distribution of water vapor play an important role in weather system and climate change. In this study, we used the total precipitable water (TPW) retrieved from FORMOSAT-3/COSMIC GPS Radio Occultation (RO) to exhibit global or regional water vapor distribution. By comparing GPS RO data with other different data sources, we can identify the correlation of GPS RO data with others and thus explore the same climate signals as revealed by their coincidence. We first focus on the comparison of global distribution between GPS RO TPW and all the other related data, including precipitation, OLR, SST and vertical velocity. We found that GPS RO data correlated well with all the other different variable data sets in tropical regions, regardless of opposite phases of the climate signals exhibited by El Nino (warm event) and La Nina (cold event) from 2007-2011. Similar global distributions were found when comparing GPS RO TPW with water vapor over ocean retrieved from SSM/I and AMSR-E. But, the unrealistic water vapor of GPS RO data in lower troposphere results in underestimate in most regions, especially during latitude range from 10oS to 30oN, as compared to estimates by the other two satellites. Besides, for a strong climate event, GPS RO data appear to address a clearer picture in agreement with the other two data sets. In summary, GPS RO data provide reliable water vapor estimation and climate signals. We also extended comparisons of the GPS RO TW with ground-based GPS TPW and found a very high correlation coefficient (>0.9) globally with latitudinal dependence. These comparisons highlight the value of the GPS RO water vapor retrieval over land and ocean.