10/31/12, Boise State University, Dept of Geosciences, Hydrologic Sciences, Jim McNamara Research Director, Pam Aishlin Data Management Data provided herein is for the Treeline weather station (TL) of Dry Creek Experimental Watershed, Boise, Idaho. DATA STREAM: 1. The TL measurement site was jointly installed by Boise State University and NW region Agricultural Resource, USDA, of Boise, Idaho, late 1998 with some instruments not operational until 2000. Instrumentation installed includes air temperature, relative humidity, wind direction and speed, solar and net radiation, shielded and unshielded precipitation by Belfort weighing bucket gages. Additional instrumentation added post 2007. Data collection and site maintenance is provided by Boise State University Hydrologic Sciences. 2. Data files collected via Campbell Scientific datalogger are retrieved via telemetry to initial server storage at Boise State University. Prior to July 2013, these were sent to the ARS office for initial processing wherein data was parsed into daily, hourly, quarter hourly and/or incremental time series. See ARS readme content below. This is level 0, raw data (CUAHSI HIS standards). Additional data formats are available upon request. Raw data files: event triggered data = TLwx_Table1.dat daily data values = TLwx_Table1440.dat 15 minute data = TLwx_Table15.dat hourly data = TLwx_Table60.dat Additional statistical data files added in 2018. (CUAHSI HIS standards, 0 = raw data, 1 = Quality controlled data that have passed quality assurance procedures such as routine estimation of timing and sensor calibration or visual inspection and removal of obvious errors, 2 = Derived products that require scientific and technical interpretation and may include multiple-sensor data. An example is basin average precipitation derived from rain gages using an interpolation procedure.) 3. Selected output files, including hourly and quarter hourly files, are quality checked and post processed for gapfilling, noise filtering and/or corrected according to established instrument calibrations. For weather data, the timeseries provided herein are shielded gage precipitation, air temperature, relative humidity, solar radiation and windspeed. See ARS readme content below for a full outline of additional data available by request. See our soil measurement data directory for soil data provided. 4. Data as collected and provided is, by protocol, in mountain standard time, year-round. SITE NOTES: The Treeline site is located at 1610 m within the Dry Creek Experimental Watershed (DCEW). Soil is sandy loam overlying weathered granodiorite. The primary vegetation includes sagebrush, forbs, grasses, and scattered trees (mainly Ponderosa Pine). Precipitation (annual average 570 mm) falls mostly during the cold season, with approximately half the annual precipitation falling as snow. Rain on snow events are common during the late fall and early spring seasons. A persistent snowpack remains from mid-December through March of most years. Winter air temperatures range from 5 to -10 C. Summer months are hot and dry (air temperature ranges from 20-28 C) with infrequent thunderstorm events. The site is drained by an ephemeral stream. Streamflow typically begins in early fall with the onset of fall rains, but remains low or episodic with the development of the snowpack. Late fall and early winter rain on snow events and/or complete melt on southerly aspects generate small hydrograph peaks. Snowpack on the north facing slope is usually maintained from the onset of snowfall. The annual hydrograph peak usually occurs in March or April depending on the duration of snowmelt. DATA/INSTRUMENT NOTES: Data logger - 1998-June 2013 Campbell Scientific cr10x. July 2013 to present, cr1000 datalogger. Air temperature - Operational at initial installation. RH-Air temperature meaurement is conducted with RH-T sensors, mfr Vaisala model HMP45AC, recalibrated annually, replaced Oct 31,2007. Each 100 ft of cable increases the apparent reading by by 0.56 C. Temperature accuracy varies with T, best accuracy +/-0.2 C occurs at 20 C, decreasing to +/-0.4 at -20 C and 60 C. REsolution is inferred as 0.1 C. Data provided is quality control level 1 (CUAHSI HIS standards as noted above). New RHT sensor 8/16/2016, cs215 SNE14232. Precipitation - Operational at initial installation. Precipitation is collected in Belfort cumulative weighing buckets for both shielded (Alter type shield) and unshielded gages, 2 meters above ground surface. Collection orifice is 8 in (20.3 cm). Catch capacity is 12 inches. Precision is 0.1% of full scale, while accuracy is 0.5% of full scale. Raw data is processed for noise removal and output as cumulative precipitation, for both shielded and unshielded rain gages. Primarily the shielded precipitation data is provided. Noise removal is provided by code initially written by Dr. Anurag Nayak, ARS, Boise, Idaho, 2008, with possible updated versions thereafter. Processed unshielded precipiation data is available upon request. Gap-filled data provided is quality control level 2 (CUAHSI HIS standards as noted above). Relative humidity - Operational at initial installation. RH-Air temperature meaurement is conducted with RH-T sensors, mfr Vaisala model HMP45AC, recalibrated/replaced annually. Values above 100% RH occurred and were set = 100. Each 100 ft of cable increases the apparent RH reading by 0.56% RH. Accuracy at 20 C is +/-2% RH up to 90% RH, +/-3% 90-100% RH. Resolution is inferred as 0.01. Data provided is quality control level 1 (CUAHSI HIS standards as noted above). New RHT sensor 8/16/2016, cs215 SNE14232. Snow depth - Operational at initial installation. Sensor employed at this site is a Judd snow depth sensor which employs air temperature measurement with corresponding corrections for distance to snow surface measured. Precision 3 mm, accuracy +/-1 cm or 0.4% distance to target. Temperature sensor accuracy is +/-0.5 C, precision 0.5 C. Vegetation is cleared from beneath this sloping hillslope surface prior to snowfall each winter. During non-snow periods, the sensor tracks vegetation height. Snow depth data presented has been processed for noise removal, wherein obvious erroneous output values, as well as non-snow values are replaced with -6999. These sensors are subject to erroneous measurement under windy conditions. This data is quality control level 1 (CUAHSI HIS standards as noted above). Alternately processed snowdepth data that involves smoothing is available upon request. Additional snowdepth sensors are emplaced along a transect across TL, parallel to a soil pit transect. Sensors are Nfacing high, mid (plus judd) and low to Sfacing low, mid, high. Solar - 1) MATRIX pyranometer: Initial installation included incoming solar radiation measurement via Matrix pyranometer, Mk 1-G Sol-A-Meter, silicon photovoltaic cell with spectral response 0.35 to 1.15 microns, peak sensitivity 0.85 microns, accuracy +/-5%. Data collection interval for this solar data has varied between 15 minute and hourly. In either case the data provided isthe average of solar radiation received during the measurement period, based on measurement scan rates which are commonly 1 to 10 minute. Sensor removed 7/1/2013. 2) NET radiometer: In 2007, a net radiometer was installed with data available since 1/31/2007 for which model NR-LITE (campbell sci) measures incoming-downward direct and diffuse solar radiation plus long wave irradiance, as well as outgoing-upward reflected solar radiation and long-wave. The data output forthis net radiometer is net (total) radiation. This instrument employs a thermopile with teflon coating and is less accurate than traditional pyranometers. It is also subject to wind-related error. Spectral response is 0.2 to 100 microns. Sensor removed 7/1/2013. 3) 4 COMPONENT radiometer: This sensor includes pyanometers, downward and upward facing, to measure short wave radiation, as well as pyrgeometers to measure far infrared radiation. Spectral response is 0.305 to 2.8 microns and 4.5 to 50 microns, accuracy +/-10% for daily totals. Data provided by these sensors is output in Watts per square meter with .1 resolution inferred. For more details on this sensor and data see readme TL_4_CompRad_Readme.txt . All solar data is provided at quality control level 1 (CUAHSI HIS standards as noted above), although some noise/error may remain in this data as provided herein. Wind - Over time, sensors vary. The program outputs wind speed, direction and related variables/calculations, including windrun. Note that prior to fall 2018, program limitations maxed windrun output at 7999 meters, in contrast to values as high as 19876 fall 2018 following program improvements. 1)METONE EARLY MODEL WIND VANE AND ANEMOMETER: Operational at initial installation. Wind direction sensors are MetOne model 013 anemometer for windspeed and 023 wind vane for wind direction. These instruments, assessed annually, have been calibrated/refurbished every two to three years. Wind direction accuracy is +/-5 degrees, 0.11 m/s (0.25 mph) or 1.5% for wind speed. Both sensors have a measurement threshold at 0.45 m/s (1 mph), more as bearings wear, max 100 mph wind speed. wind speed raw measurement units remain as mph, converted to meters/second. Several wind direction parameters are available in the ARS output. Data provided herein includes average hourly wind speed and mean resultant wind direction based on measurements conducted every 10 seconds over one hour with measurements taken every 10 seconds. See ARS readme below for additional wind variables available upon request. Wind data is quality control level 1 (CUAHSI HIS standards as noted above). Note: 2013 Lab and field assessments conclude that TL wind direction data has been erroneous > +/- 5 degrees over the past few to several years, as noted by annual field calibrations/assessments; a program and wiring change was emplaced to correct this problem, August 2013. . 2)METONE 034B purchased via Campbell Scientific was used temporarily late 2012-August 2013 at this site, which, when compared to data output by jointly installed Metone sensors described above, was found to provide comparable results. Program for wind output: WindVector(1, InstWndSpd, WndDir, FP2, 0, 900/scanrate, 0, 2) FieldNames("HzWindSpd:,WindSpdMeanVecMag:,WindDirResMean;,WindDirStDev:") 'output opt 2 = mean hz wind spd, resul mean wind spd, wind dir resultant mean and st dev of wind dir w/ csi algorithm. 'subinterval: 'originally 90 samples per subinterval, 4 subintervals per hour; new eqn is deisred subinterval in sec/ scan rate in sec '...therefore 900/10, = 90; 10 sec scan for 3600 sec/hr = 360 scans, /4 = 90; avg of 4 subinterval stdev, minimizes effect of meander under light wind Wind speed reported herein is that of the first field, mean (average) horizontal wind speed which is considered best for straightline Gaussian dispersion models. The existing MetOne wind vane and anemometer are replaced by a Metone 034B windset 1/24/14. 3) WindRun is incorrect from placement of cr1000 logger due to limit at 7999 meters. Corrected fall 2018 w/ program change from floatpoint2 to unsigned integer. Barometric pressure - PTB110 Barometric Pressure, Vaisala/Campbell Scientific. Total accuracy varies with temperature, with increased accuracy at higher temperatures, +/-1.5mb at 0 to 40 C, +/-2 mb below freezing, precision is inferred as 0.01 mb. Instantaneous values. Data provided is quality control level 1 (CUAHSI HIS standards as noted above). . . Soil moisture and Soil heat flux - See soil data directory regarding pit 3 and pit 4 at TL. Two heat Flux plates and 4 thermocouples were emplaced adjacent the weather station in 2007 (4/18) by Aurele Montagne, assumed to be installed similar to LDP site with an east and west pits, relative to weather tower, Thermocouples in each pit are installed at 2 and 6 cm. Heat flux plates are installed at 8 cm. Pits are 1 m due east, west of weather tower. Sensor numbering is assumed to be the same at TL as at LDP, TC1=west, 2cm, TC2, west 6 cm. TC3 east 2 cm, TC4 east 6 cm. Heatflux 1 west, 8 cm, Heatflux 2 east, 8 cm. ANNUAL ERRORS/GAPS/UPDATES: 1998- 1999- 2000- 2001- 2002- 2003- 2004- 2005- data gap to 1/21/05 1100, also 11/17 - 11/18/2005. 2006- data gap 12/1/06 1600 - 12/5/06 1700. 2007- data gaps 1/5/07 1500 - 2/1/07 1200, also 2/16 1200, 2/19 1600, 11/8 0900 - 11/9 1600, 11/16 0000 - 11/27 1400. On 10/31/2007 wind speed is assessed as erroneous for recent data, consequently anemometer was replaced, correction offset was applied to program on 10/31/2007. 2008- no gaps 2009- data gap 11/26/12 0000 - 12/1/09 1200. On 9/25/2009 a newly recalibrated anemometer was installed, as well as a refurbished wind vane. 2010- no gaps. 4 COMPONENT RADIOMETER installed fall 2010, some data gaps occur for this sensor following installation. Wind sensor performance verified on site 11/15/10, RH sensor replaced by newly calibrated sensor. 2011- Intermittent data gaps occur for soil and various weather sensors early 2011, also in July, late Oct-early Nov and late Dec 2011 due to work at site. RH sensor replaced by newly calibrated sensor 7/29/11, vaisala hmp45ac, wind sensor performance verified on site. Solar data is considered questionable 11/12-11/17/2011. 2012 1/19/12 rain on snow event. 2/9/12 clock reset on datalogger, minor time drift may have occurred. 6/24/12, 7/1/12 15 minute dataset incurred error. On 11/20/2012, wind sensors were removed for service, test results for wind direction received pass for gap noise, fail for torque for which the measurement results could have been response start threshold of 2mph instead of 1 mph. For wind speed, result was fail for torque but output frequency tested as well within spec. While sensors were being serviced in conjuction service needs at LW, a temporary new windspeed-direction sensor034B was in place at TL 11/20/12 - 7/29/2013. 2013 Data through June 2013 is provided via array data from a CR10x datalogger. From 7/1/2013, data is provided via a CR1000 datalogger. Data gaps occur for several sensors sporadically 7/1-7/9, 16/2013 due to logger memory-programming problems. Data gap occurs 9/14-9/16 due to power outage. Data lost 10/16/13-10/17/13 due to program changes. . 2013 WIND DATA: .8/10/14. 1/1/2013 through 7/29/2013; GAP 7/9 - 7/16/2013 for wind dir: . The 034B windset provides data with parallel emplacement with the refurbished MetonOne sensor. The two sensors were found to provide comparable results.To be noted, however, is a program and wiring change emplaced for the refurbished Metone wind vane. Lab and field assessments conclude that TL wind direction data has been erroneous > +/- 5 degrees over the past few to several years, as noted by annual field calibrations/assessments. For the month of july, wind data was provided by a windtest data table at 15 minute intervals, as well as by the 60 minute data interval table, both data sets were used, as available, to provide data presented herein, with most of the july data being provided by the 15 minute windtest data table. . 7/29/2013 08:00 - 12/31/2013: . The refurbished MetOne sensor provides valid data. . 2013 SOLAR: . 1/1 - 7/1 matrix pyranometer and net radiometer provide data at the main weather tower. These sensors were removed 7/1/2013 and replaced by the 4 component sensor relocated to the main weather tower, in conjunction with replacing the cr10x logger with a cr1000 logger 7/9/2013. . 7/1 - 7/9/2013 No solar data is available from the main weather site, however, data is available from pit logger site 4 comp radiometer. . 7/9 - 10/16/2013 4 comp radiometer moved to main weather station. Note that sensor orientation is horizontal as emplaced 7/9/2013 vs. parallel to slope, but changed soon thereafter to parallel to slope. Sensor orientation angle was parallel to slope at pit location. The 4 COMPONENT sensor NOT FULLY FUNCTIONAL from 7/9/2013 TILL 10/16/2013, largely due to error in temperature values. Therefore net radiation is not provided herein from 7/1/2013 until 10/17/2013. See the 4component radiation data sets for valid raw longwave data and corrected radiation sensor body tempterature data that may be used to calculate corrected longwave data. Also, shortwave incoming radiation 4comp sensor 7/9/2013 - 10/16/2013 is erroneous. On 10/16/2013 4 component instructions were changed for auto range; the error occurred wherein solar shorwave-in was limited in the upper range above 800 W/m2 using 5000 mv range, concurrently negative solar values are exaggerated. . 2014 Data gaps occur 1/23/2014 - 1/31/2014. 2/3/2014 program is changed to add additional variable for corrected incoming solar radiation wherein small negative values set to zero. The existing MetOne wind vane and anemometer are replaced by a Metone 034B windset 1/24/14. A gap in wind data occurs 1/31 - 2/3. Gap also on 3/10-3/11/14 late eve/early morning error in wind and snow depth sensors, values set to -6999. Minor gap in incoming solar radiation on 8/10, 9/13, 9/15, 10/19. Minor gap all data on 9/16 and 10/19. Snowdepth data for winter 2013-2014 is smoothed via matlab function plus minor manual smoothing, esp where sensor incurs outlier value errors as commonly occurs under windy conditions. 4 component solar 9/13/14 wiring and program change made. 2015 Minor data gap 3/18/15, 1400-1800. Precipitation data is processed by Matlab script version of the Precip Filter created by Dr. Anurag Nayak. Results at M:\boisefront\loggerdata\1_analysis_allcomparisons\PcpComparisons\MatlabProcessing Matlab script at M:\boisefront\loggerdata\matlab\Archive_Matlab_Code . Snowdepth also processed also using matlab script. Smoothing is largely successful in removing high outlier data noise. However, where outlier data points persist for several hours (Hrly data data points), such as may occur during a storm, smoothing may misrepresent actual snow accumulation and/or ablation during the event. Major noise remains during a storm on 1/12/2015 and late Jan through early Feb. Some manual noise removal was performed where clearly no snow fall occurred as indicated by additional data at this site and adjacent sites. Minor data noise, generally <2 cm, is reasonably smoothed. Diurnal noise occurs with effect that snowdepth appears to decrease mid day when temperatures warm. As a result of these data errors, minor snow accumulation events may be undermeasured. Data assessment indicates 2/5/2015 as the end of snowmelt, with a minor snow events possibly occurring 2/11 and 3/24/2015. This latter snow possible snowfall event is not included as it falls within the spring-fall period of vegetation growth/senescence beneath the sensor. Winter snow accumulation beginning point is assessed as 11/9/2015 1800. Data for 2/5/2015 1600 to 11/9/2015 1800 is set to zero snowdepth. 2016 Gaps (pcp specifically) occur Jan 24,25,30,31, Feb 2, June 29. Snow catch irregularity in mid March followed by bucket dump. evap occurs Jy, Aug, esp in unshielded bucket. Dumps occur Mar, Jy, Aug. Precipitation data is processed by Matlab script version of the Precip Filter created by Dr. Anurag Nayak. Results at M:\boisefront\loggerdata\1_analysis_allcomparisons\PcpComparisons\MatlabProcessing Matlab script at M:\boisefront\loggerdata\matlab\Archive_Matlab_Code Matlab pcp assessment: Undercatch apparent late March,late Dec, potentially signficant undercatch, snowfall. Matlab snowdepth assessment: major noise removed, smoothing is mostly effective, some noise remains. RH sensor- removed old sensor 11/13/16 after colocation testing with new sensor since 8/16/16. old sensor exhibits slightly lower T and RH; old rh sometimes over 100; 2017 Gap 7/7 1100 (work onsite). Precip filtered successfully. Snowdepth as well;some diurnal noise remains for which additional smoothing could be applied. TL 4 component incoming solar (and net radiation) suspect as slightly high compared w/ adjacent LW and SCR sites; if not due to local environmental conditions, this may be the result of the radiation sensor being mounted on and parallel to slope at this site, in contrast to perpendicular to horizontal and being mounted at a ridgetop/horizontal surface at adjacent weather station sites. In 2018, the sensor is realigned to be perpendicular to horizontal. 2018 Multiple program changes occur fall 2018 w/ minor data gaps. 10/29-11/1 Progam error - used sample winddir instead of usual avg for this brief period. 10/26/28/2018 data gap for 15 min data set only, solar. One of two soil flux sensors failed Feb 2018. 2019 no gaps. 2020 9/16 10:45 clock reset. Minor gap 12/18/20 1800. 2021 no gaps to 6/9/21. Gaps occur in spring snowdepth data wherein noise levels are too high to provide for correction (esp during storms). NOTE: CURRENT YEAR DATA IS PROVISIONAL. All data sets may be error corrected at year-end. Precipitation data and snow data undergo smoothing and additional data processing at year end in contrast to raw data that may be published realtime. ____________________________________________________________________________________ ARS The readme content below is produced by the NW Agricultural Research Office,USDA, relative to initial processing of weather station data for Treeline, aka Boise Front Upper site, and is presented herein as an outline of all available data for the Treeline weather station of Dry Creek Experimental Watershed. This BSU sponsored website provides data that has received additional processing for data publication, primarily hourly and/or quarter hourly data sets listed below. The original ARS output files are available on ARS ftp site, ftp://ftp.nwrc.ars.usda.gov/boisefront/. Contact PamAishlin@boisestate.edu for earlier ARS files. ARS contact is steven VanVactor. For questions on site maintenance, data collection and metadata contact PamAishlin@boisestate.edu. ARSreadme: The first letter of the file name indicates the sampling interval. File names that start with D contain daily records, H hourly records, I intermittent records and Q 15-minute records. The next three letters indicate which site. The remainder if the file name is the predominant type of data contained in the file. This list is alphabetical. The arrangement in the excel file is not. file name variable variable description ======== ======= ================================ DBFUMET date Date (SAS format) DBFUMET hum2a Relative Humidity @2m , Averaged (%) DBFUMET tmp2a Air Temperature @2m, Averaged (C) DBFUMET tmp2n Air Temperature @2m, Minimum (C) DBFUMET tmp2x Air Temperature @2m, Maximum (C) DBFUMET wnd2r Wind Run @2m (mile) DBFUMET ztmp2n Time of Minimum Air Temperature @2m (hhmm MST) DBFUMET ztmp2x Time of Maximum Air Temperature @2m (hhmm MST) DBFUMICRO date Date (SAS format) DBFUMICRO csp005p3 CS615 Period @5cm, Profile 3 (ms) DBFUMICRO csp005p4 CS615 Period @5cm, Profile 4 (ms) DBFUMICRO csp015p3 CS615 Period @15cm, Profile 3 (ms) DBFUMICRO csp015p4 CS615 Period @15cm, Profile 4 (ms) DBFUMICRO csp030p3 CS615 Period @30cm, Profile 3 (ms) DBFUMICRO csp030p4 CS615 Period @30cm, Profile 4 (ms) DBFUMICRO csp045p4 CS615 Period @45cm, Profile 4 (ms) DBFUMICRO csp060p3 CS615 Period @60cm, Profile 3 (ms) DBFUMICRO csp065p4 CS615 Period @65cm, Profile 4 (ms) DBFUMICRO csp100p3 CS615 Period @100cm, Profile 3 (ms) DBFUMICRO mst005p3a Water Content @5cm, Average, Profile 3 (% v) DBFUMICRO mst005p4a Water Content @5cm, Average, Profile 4 (% v) DBFUMICRO mst015p3a Water Content @15cm, Average, Profile 3 (% v) DBFUMICRO mst015p4a Water Content @15cm, Average, Profile 4 (% v) DBFUMICRO mst030p3a Water Content @30cm, Average, Profile 3 (% v) DBFUMICRO mst030p4a Water Content @30cm, Average, Profile 4 (% v) DBFUMICRO mst045p4a Water Content @45cm, Average, Profile 4 (% v) DBFUMICRO mst060p3a Water Content @60cm, Average, Profile 3 (% v) DBFUMICRO mst065p4a Water Content @65cm, Average, Profile 4 (% v) DBFUMICRO mst100p3a Water Content @100cm, Average, Profile 3 (% v) DBFUMICRO stm005p3a Soil Temperature @5cm, Average, Profile 3 (C) DBFUMICRO stm005p3n Soil Temperature @5cm, Profile 3, Minimum (C) DBFUMICRO stm005p3x Soil Temperature @5cm, Profile 3, Maximum (C) DBFUMICRO stm005p4a Soil Temperature @5cm, Average, Profile 4 (C) DBFUMICRO stm005p4n Soil Temperature @5cm, Profile 4, Minimum (C) DBFUMICRO stm005p4x Soil Temperature @5cm, Profile 4, Maximum (C) DBFUMICRO stm015p3a Soil Temperature @15cm, Average, Profile 3 (C) DBFUMICRO stm015p3n Soil Temperature @15cm, Profile 3, Minimum (C) DBFUMICRO stm015p3x Soil Temperature @15cm, Profile 3, Maximum (C) DBFUMICRO stm015p4a Soil Temperature @15cm, Average, Profile 4 (C) DBFUMICRO stm015p4n Soil Temperature @15cm, Profile 4, Minimum (C) DBFUMICRO stm015p4x Soil Temperature @15cm, Profile 4, Maximum (C) DBFUMICRO stm030p3a Soil Temperature @30cm, Average, Profile 3 (C) DBFUMICRO stm030p3n Soil Temperature @30cm, Profile 3, Minimum (C) DBFUMICRO stm030p3x Soil Temperature @30cm, Profile 3, Maximum (C) DBFUMICRO stm030p4a Soil Temperature @30cm, Average, Profile 4 (C) DBFUMICRO stm030p4n Soil Temperature @30cm, Profile 4, Minimum (C) DBFUMICRO stm030p4x Soil Temperature @30cm, Profile 4, Maximum (C) DBFUMICRO stm045p4a Soil Temperature @45cm, Average, Profile 4 (C) DBFUMICRO stm045p4n Soil Temperature @45cm, Profile 4, Minimum (C) DBFUMICRO stm045p4x Soil Temperature @45cm, Profile 4, Maximum (C) DBFUMICRO stm060p3a Soil Temperature @60cm, Average, Profile 3 (C) DBFUMICRO stm060p3n Soil Temperature @60cm, Profile 3, Minimum (C) DBFUMICRO stm060p3x Soil Temperature @60cm, Profile 3, Maximum (C) DBFUMICRO stm065p4a Soil Temperature @65cm, Average, Profile 4 (C) DBFUMICRO stm065p4n Soil Temperature @65cm, Profile 4, Minimum (C) DBFUMICRO stm065p4x Soil Temperature @65cm, Profile 4, Maximum (C) DBFUMICRO stm100p3a Soil Temperature @100cm, Average, Profile 3 (C) DBFUMICRO stm100p3n Soil Temperature @100cm, Profile 3, Minimum (C) DBFUMICRO stm100p3x Soil Temperature @100cm, Profile 3, Maximum (C) DBFUMICRO zstm005p3n Time of Minimum Soil Temperature @5cm, Profile 3 (hhmm MST) DBFUMICRO zstm005p3x Time of Maximum Soil Temperature @5cm, Profile 3 (hhmm MST) DBFUMICRO zstm005p4n Time of Minimum Soil Temperature @5cm, Profile 4 (hhmm MST) DBFUMICRO zstm005p4x Time of Maximum Soil Temperature @5cm, Profile 4 (hhmm MST) DBFUMICRO zstm015p3n Time of Minimum Soil Temperature @15cm, Profile 3 (hhmm MST) DBFUMICRO zstm015p3x Time of Maximum Soil Temperature @15cm, Profile 3 (hhmm MST) DBFUMICRO zstm015p4n Time of Minimum Soil Temperature @15cm, Profile 4 (hhmm MST) DBFUMICRO zstm015p4x Time of Maximum Soil Temperature @15cm, Profile 4 (hhmm MST) DBFUMICRO zstm030p3n Time of Minimum Soil Temperature @30cm, Profile 3 (hhmm MST) DBFUMICRO zstm030p3x Time of Maximum Soil Temperature @30cm, Profile 3 (hhmm MST) DBFUMICRO zstm030p4n Time of Minimum Soil Temperature @30cm, Profile 4 (hhmm MST) DBFUMICRO zstm030p4x Time of Maximum Soil Temperature @30cm, Profile 4 (hhmm MST) DBFUMICRO zstm045p4n Time of Minimum Soil Temperature @45cm, Profile 4 (hhmm MST) DBFUMICRO zstm045p4x Time of Maximum Soil Temperature @45cm, Profile 4 (hhmm MST) DBFUMICRO zstm060p3n Time of Minimum Soil Temperature @60cm, Profile 3 (hhmm MST) DBFUMICRO zstm060p3x Time of Maximum Soil Temperature @60cm, Profile 3 (hhmm MST) DBFUMICRO zstm065p4n Time of Minimum Soil Temperature @65cm, Profile 4 (hhmm MST) DBFUMICRO zstm065p4x Time of Maximum Soil Temperature @65cm, Profile 4 (hhmm MST) DBFUMICRO zstm100p3n Time of Minimum Soil Temperature @100cm, Profile 3 (hhmm MST) DBFUMICRO zstm100p3x Time of Maximum Soil Temperature @100cm, Profile 3 (hhmm MST) HBFUMET datetime Datetime (SAS format) HBFUMET hum2a Relative Humidity @2m , Averaged (%) HBFUMET snowdepth Depth of Snow Above Soil Surface, Judd Sensor (inch) HBFUMET tmp2a Air Temperature @2m, Averaged (C) HBFUMET tmp2aj Air Temperature @2m, Averaged, Judd Sensor (C) HBFUMET vltd Voltage of DAS Battery (V) HBFUMET vltp Voltage of Pump Battery (V) HBFUMET wnd2d Wind Direction @2m (Degree) HBFUMET wnd2dd Wind Direction @2m, Standard Deviation of Direction (Degree) HBFUMET wnd2dr Wind Direction @2m, Mean Resultant (Degree) HBFUMET wnd2dx Wind Direction @2m @Max. Speed (Degree) HBFUMET wnd2r Wind Run @2m (mile) HBFUMET wnd2sa Wind Speed @2m, Averaged (mph) HBFUMET wnd2sr Wind Speed @2m, Mean Resultant (mph) HBFUMET wnd2sx Wind Speed @2m, Maximum (mph) HBFUMET zwnd2sx Time of Maximum Wind Speed @2m (hhmm MST) HBFUMICRO datetime Datetime (SAS format) HBFUMICRO csp005p3 CS615 Period @5cm, Profile 3 (ms) HBFUMICRO csp005p4 CS615 Period @5cm, Profile 4 (ms) HBFUMICRO csp015p3 CS615 Period @15cm, Profile 3 (ms) HBFUMICRO csp015p4 CS615 Period @15cm, Profile 4 (ms) HBFUMICRO csp030p3 CS615 Period @30cm, Profile 3 (ms) HBFUMICRO csp030p4 CS615 Period @30cm, Profile 4 (ms) HBFUMICRO csp045p4 CS615 Period @45cm, Profile 4 (ms) HBFUMICRO csp060p3 CS615 Period @60cm, Profile 3 (ms) HBFUMICRO csp065p4 CS615 Period @65cm, Profile 4 (ms) HBFUMICRO csp100p3 CS615 Period @100cm, Profile 3 (ms) HBFUMICRO mst005p3 Water Content @5cm, Profile 3 (% v) HBFUMICRO mst005p4 Water Content @5cm, Profile 4 (% v) HBFUMICRO mst015p3 Water Content @15cm, Profile 3 (% v) HBFUMICRO mst015p4 Water Content @15cm, Profile 4 (% v) HBFUMICRO mst030p3 Water Content @30cm, Profile 3 (% v) HBFUMICRO mst030p4 Water Content @30cm, Profile 4 (% v) HBFUMICRO mst045p4 Water Content @45cm, Profile 4 (% v) HBFUMICRO mst060p3 Water Content @60cm, Profile 3 (% v) HBFUMICRO mst065p4 Water Content @65cm, Profile 4 (% v) HBFUMICRO mst100p3 Water Content @100cm, Profile 3 (% v) HBFUMICRO stm005p3 Soil Temperature @5cm, Profile 3 (C) HBFUMICRO stm005p3a Soil Temperature @5cm, Average, Profile 3 (C) HBFUMICRO stm005p4 Soil Temperature @5cm, Profile 4 (C) HBFUMICRO stm005p4a Soil Temperature @5cm, Average, Profile 4 (C) HBFUMICRO stm015p3 Soil Temperature @15cm, Profile 3 (C) HBFUMICRO stm015p3a Soil Temperature @15cm, Average, Profile 3 (C) HBFUMICRO stm015p4 Soil Temperature @15cm, Profile 4 (C) HBFUMICRO stm015p4a Soil Temperature @15cm, Average, Profile 4 (C) HBFUMICRO stm030p3 Soil Temperature @30cm, Profile 3 (C) HBFUMICRO stm030p3a Soil Temperature @30cm, Average, Profile 3 (C) HBFUMICRO stm030p4 Soil Temperature @30cm, Profile 4 (C) HBFUMICRO stm030p4a Soil Temperature @30cm, Average, Profile 4 (C) HBFUMICRO stm045p4 Soil Temperature @45cm, Profile 4 (C) HBFUMICRO stm045p4a Soil Temperature @45cm, Average, Profile 4 (C) HBFUMICRO stm060p3 Soil Temperature @60cm, Profile 3 (C) HBFUMICRO stm060p3a Soil Temperature @60cm, Average, Profile 3 (C) HBFUMICRO stm065p4 Soil Temperature @65cm, Profile 4 (C) HBFUMICRO stm065p4a Soil Temperature @65cm, Average, Profile 4 (C) HBFUMICRO stm100p3 Soil Temperature @100cm, Profile 3 (C) HBFUMICRO stm100p3a Soil Temperature @100cm, Average, Profile 3 (C) HBFUMICRO tmpr Reference Temperature, Multiplexer System, Averaged (C) IBFUPRECIP datetime Datetime (SAS format) IBFUPRECIP ppts Shielded Raingage Depth (inch) IBFUPRECIP pptu Unshielded Raingage Depth (inch) IBFUSTAGE datetime Datetime (SAS format) IBFUSTAGE arrayid Array ID from CR10 Datafile (###) IBFUSTAGE pump Pump Number Activated (1-4) IBFUSTAGE stg Stage @Time When Pump Activated (ft) IBFUSTAGE stgd Stage Difference Since Last Record (ft) IBFUSTAGE vltp Voltage of Pump Battery (V) QBFUMET datetime Datetime (SAS format) QBFUMET hum2i Relative Humidity @2m, Instantaneous (%) QBFUMET ppts Shielded Raingage Depth (mm) QBFUMET pptu Unshielded Raingage Depth (mm) QBFUMET solm Solar Radiation (Watts/m^2) QBFUMET stg3 Stage @Time When Pump Activated (ft) QBFUMET stg4 Stage @Time When Pump Activated (ft) QBFUMET tmp2i Air Temperature @2m, Instantaneous (C) QBFUMET wnd2d Wind Direction @2m (Degree) QBFUMET wnd2s Wind Speed @2m (mph)