Climate Data for Latitude -10.75 Longitude -76.25

Köppen climate classification: ET (Climate: polar; Temperature: polar tundra)
 

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Lago de Junín
Lago de Junín

Averages (English) Metric

TypeUnitsJanFebMarAprMayJunJulAugSepOctNovDecPeriod
Min Temp32.832.731.830.127.624.223.924.927.929.529.830.388 years
Mean Temp44.344.043.843.442.741.741.141.742.443.643.943.8109 years
Max Temp55.855.455.956.757.859.158.458.457.057.757.957.3109 years
FrostDays20.514.719.024.531.030.031.031.029.928.829.927.6109 years
Precipitationin4.34.85.22.71.30.30.60.81.72.93.13.9109 years
Potential Evapotranspirationin2.92.62.73.03.54.14.54.53.73.83.43.4109 years
Yearly Average Temperatures 2010 - 2009 (English) Latitude -10.75 Longitude -76.25
Monthly Mean Temperatures 1901 - 2009 (English) Latitude -10.75 Longitude -76.25
Yearly Total Frost Days 1901 - 2009 Latitude -10.75 Longitude -76.25
Yearly Total Precipitation 1901 - 2009 (English) Latitude -10.75 Longitude -76.25
Yearly Total Potential Evapotranspiration 1901 - 2009 (English) Latitude -10.75 Longitude -76.25

Climate data provided by CRU TS 3.1 - University of East Anglia Climate Research Unit (CRU). [Phil Jones, Ian Harris]. CRU Time Series (TS) high resolution gridded datasets, [Internet]. NCAS British Atmospheric Data Centre, 2008, Accessed: 28-July-2011
Charting software provided by pChart - a PHP class to build charts.
Köppen climate classification provided by Kottek, M., J. Grieser, C. Beck, B. Rudolf, and F. Rubel, 2006: World Map of Köppen-Geiger Climate Classification updated. Meteorol. Z., 15, 259-263
The calculation method for the potential evapotranspiration is the FAO grass reference equation (Ekstrom et al., 2007, which is based on Allen et al., 1994). It is a variant of the Penman Monteith method using TMP, TMN, TMX, VAP, CLD.