Global Historical Climatology Network Monthly - Version 2
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GHCN-Monthly Version 2 Ascii Text Files |
The Global Historical Climatology Network (GHCN-Monthly) database contains historical temperature, precipitation, and pressure data for thousands of land stations worldwide. The period of record varies from station to station, with several thousand extending back to 1950 and monthly updates for several hundred stations via CLIMAT reports. The data are available without charge through NCEI's anonymous FTP service. Effective May 2, 2011, the Global Historical Climatology Network-Monthly (GHCN-M) version 3 dataset of monthly mean temperature has replaced GHCN-M version 2 as the dataset for operational climate monitoring activities for temperature. The formal designation is ghcnm.x.y.z[optionally -betan].yyyymmdd.
Both historical and near-real-time GHCN data undergo rigorous quality assurance reviews. These reviews include preprocessing checks on source data, time series checks that identify spurious changes in the mean and variance, spatial comparisons that verify the accuracy of the climatological mean and the seasonal cycle, and neighbor checks that identify outliers from both a serial and a spatial perspective.
GHCN-Monthly is used operationally by NCEI to monitor long-term trends in temperature and precipitation. It has also been employed in several international climate assessments, including the Intergovernmental Panel on Climate Change 4th Assessment Report, the Arctic Climate Impact Assessment, and the "State of the Climate" report published annually by the Bulletin of the American Meteorological Society.
Data Description
One of the primary goals of GHCN-Monthly was to acquire additional data in order to enhance spatial and temporal coverage. There were three reasons for this goal: data for recent months allows one to assess current climatic conditions and place them in historical perspective, denser coverage facilitates the analysis of regional climate change, and certain areas (or certain times in certain areas) are under-sampled even from the perspective of a global analysis. Because numerous institutions operate weather stations and because no single repository archives all of the data for all stations, five acquisition strategies were employed to maximize the available pool of data: contacting data centers, exploiting personal contacts, tapping related projects, conducting literature searches, and distributing miscellaneous requests. As a result, GHCN-Monthly contains data from dozens of diverse sources.
Temperature Data Sources & Precipitation Data Sources Tables
GHCN-Monthly contains mean temperature data for 7,280 stations and maximum/minimum temperature data for 4,966 stations. All have at least 10 years of data. The archive also contains homogeneity-adjusted data for a subset of this network (5,206 mean temperature stations and 3,647 maximum/minimum temperature stations). The homogeneity-adjusted network is somewhat smaller because at least 20 years of data were required to compute reliable discontinuity adjustments. Adequate assessment of the homogeneity of some isolated stations was not possible. Precipitation data are available for 20,590 stations and sea level pressure data for 2,668 stations. In general, the best spatial coverage is evident in North America, Europe, Australia, and parts of Asia. Likewise, coverage in the Northern Hemisphere is better than the Southern Hemisphere.
Temperature Methods
The following journal articles describe the methods used in developing the GHCN-Monthly Temperature dataset:
- Peterson, T. C., and R. S. Vose, 1997: An overview of the Global Historical Climatology Network temperature database. Bulletin of the American Meteorological Society, 78, 2837-2849, doi:10.1175/1520-0477(1997)078%3C2837:AOOTGH%3E2.0.CO;2.
- Peterson, T.C., R. Vose, R. Schmoyer, and V. Razuvaev, 1998: Global Historical Climatology Network (GHCN) quality control of monthly temperature data. International Journal of Climatology, 18, 1169-1179, doi:10.1002/(SICI)1097-0088(199809)18:11<1169::AID-JOC309>3.0.CO;2-U
Precipitation Methods
- Duplicate Elimination
Scientists can frequently GHCN obtain a precipitation time series for a given station more than one source. For example, rainfall data for Beijing were available in three different source datasets. In brief, comparing each station with all the other stations in all source datasets identified duplicate stations. The description of similarity between stations uses several statistics, including the number of identical months of data, the length of the longest run of identical months, and the number of identical values that were zero. Use of these diagnostic statistics, in conjunction with station metadata subjectively determine whether station were duplicates. In most cases, the decision was relatively straightforward, although a few degenerate time series posed proved more challenging. - Quality Control
Staff employed a variety of tests to assess data quality. The first step involved comparing stations with a gridded climatology and plotting the stations for visual inspection. Both of these processes uncovered mislocated stations and the digitized formerly uncovered stations 6 months out of phase. Additionally, each time series was tested for significant discontinuities using the Cumulative Sum test (which looks for changes in the mean) and an analogous test that looks for changes in the variance or scale. Evaluation of each time series for runs of three or more months of the same nonzero value. Finally, scientists evaluated each individual precipitation total to determine if it was an outlier in space and/or time using a variety of nonparametric statistics.
Version 2 Bias Correction Software
The automated bias correction software (Peterson and Easterling, 1994; Easterling and Peterson, 1995) used to detect and adjust for documented and undocumented inhomogeneities in the GHCN-Monthly version 2 monthly temperature dataset.
Please refer to the README file in this directory for information on this software.
- Easterling, D. R., and T. C. Peterson, 1995: A new method for detecting undocumented discontinuities in climatological time series. International Journal of Climatology, 15, 369-377, doi:10.1002/joc.3370150403.
- Peterson, T. C., and D. R. Easterling, 1994: Creation of homogeneous composite climatological reference series. International Journal of Climatology, 14, 671-679, doi:10.1002/joc.3370140606.
Contact
For questions specific to GHCNM, please email NCDC.GHCNM@noaa.gov.
Citing and Metadata
Information is available on the how users can cite the dataset and view the Metadata.