SGP/SMOS/E21 - Reprocess: Errors in Global Metadata

The netcdf files for SMOS.E21 incorrectly list sensor heights at E21, Okmulgee
as being 10m for winds, 2m for temp, RH and vapor pressure, and 1m for barometric
pressure.  The Okmulgee site is a forested site and these sensors are mounted on
a tower above the canopy.  The actual sensor heights are 18m for winds, 17m for
temp, RH and vapor pressure, and 19m for barometric pressure which corresponds
to 3.7m, 2.7m, and 4.7m above the average canopy height respectively.

• barometric pressure(bar_pres)
• Mean Wind Speed(wspd)
• Standard Deviation of wind direction(sd_deg)
• Beam 0 Temperature(temp)
• Vapor Pressure (kiloPascals)(vap_pres)
• Wind Speed (vector averaged)(wspd_va)
• Relative humidity inside the instrument enclosure(rh)
• Unit Vector Wind Direction(wdir)

• Time of Minimum Wind Speed(time_min_wspd)
• Minimum of Wind speed(min_wspd)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Minimum Temperature(min_temp)
• Minimum Relative Humidity(min_rh)
• Time of Minimum Temperature(time_min_temp)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Minimum Vapor Pressure(min_vap_pres)
• Time of Maximum Temperature(time_max_temp)
• Maximum Temperature(max_temp)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Minimum Relative Humidity(time_min_rh)
• Minimum Barometric Pressure(min_bar_pres)
• Time of Maximum Relative Humidity(time_max_rh)
• Maximum Barometric Pressure(max_bar_pres)
• Maximum Vapor Pressure(max_vap_pres)
• maximum wind speed (gusts)(max_wspd)
• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Maximum Relative Humidity(max_rh)

• barometric pressure(bar_pres)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Relative humidity inside the instrument enclosure(rh)
• Mean Wind Speed(wspd)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of wind direction(sd_deg)
• Wind Speed (vector averaged)(wspd_va)
• Vapor Pressure (kiloPascals)(vap_pres)
• Beam 0 Temperature(temp)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Standard Deviation of Wind Speed(sd_wspd)
• Standard Deviation of Air Temperature(sd_temp)

• Relative humidity inside the instrument enclosure(rh)
• barometric pressure(bar_pres)
• Wind Speed (vector averaged)(wspd_va)
• Mean Wind Speed(wspd)
• Beam 0 Temperature(temp)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of wind direction(sd_deg)
• Vapor Pressure (kiloPascals)(vap_pres)

• Beam 0 Temperature(temp)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Standard Deviation of Wind Speed(sd_wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Unit Vector Wind Direction(wdir)
• Mean Wind Speed(wspd)
• Wind Speed (vector averaged)(wspd_va)

SGP/EBBR/E4 - AEM Hung

• Left air temperature(tair_l)
• Right air temperature(tair_r)

• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• Bottom humidity(hum_bot)
• bottom air temperature(tair_bot)
• latent heat flux(e)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Temperature of the top humidity chamber(thum_top)
• top vapor pressure(vp_top)
• h(h)
• top air temperature(tair_top)

• Left air temperature(tair_l)
• Right air temperature(tair_r)

• Temperature of bottom humidity sensor chamber(thum_bot)
• top vapor pressure(vp_top)
• bottom air temperature(tair_bot)
• Temperature of the top humidity chamber(thum_top)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• h(h)
• top air temperature(tair_top)
• Bottom humidity(hum_bot)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• latent heat flux(e)

• top air temperature(tair_top)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• bottom air temperature(tair_bot)
• Temperature of the top humidity chamber(thum_top)
• Bottom humidity(hum_bot)
• top vapor pressure(vp_top)
• Temperature of bottom humidity sensor chamber(thum_bot)

SGP/EBBR/E4 - Data Incorrect or Zero

After the barometer was changed out, the measurements were zero or otherwise incorrect.

• Reference temperature(rr_tref)
• Atmospheric pressure(mv_pres)
• Soil moisture 3(rr_sm3)
• Left air temperature(tair_l)
• Soil temperature 4(rr_ts4)
• Soil moisture 4(r_sm4)
• Soil temperature 3(rr_ts3)
• Left relative humidity(mv_hum_l)
• Soil moisture 5(r_sm5)
• Soil temperature 2(rr_ts2)
• Right relative humidity(mv_hum_r)
• Time offset of tweaks from base_time(time_offset)
• lat(lat)
• Soil moisture 2(r_sm2)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Signature(signature)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 3(r_sm3)
• Right air temperature(tair_r)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Battery(bat)
• base time(base_time)
• Dummy altitude for Zeb(alt)
• Soil heat flow 5(mv_hft5)
• Soil temperature 1(rr_ts1)
• lon(lon)
• Soil moisture 1(rr_sm1)
• scalar wind speed(wind_s)
• Soil heat flow 4(mv_hft4)
• Net radiation(mv_q)
• Soil heat flow 3(mv_hft3)
• Soil moisture 2(rr_sm2)
• Soil temperature 5(rr_ts5)
• Soil heat flow 1(mv_hft1)
• Home signal(mv_home)
• Soil heat flow 2(mv_hft2)
• Soil moisture 5(rr_sm5)
• Soil moisture 1(r_sm1)
• Soil moisture 4(rr_sm4)

• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• Bottom humidity(hum_bot)
• Soil heat capacity 5(cs5)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• Retrieved pressure profile(pres)
• net radiation(q)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• volumetric soil moisture, site 1(sm1)
• volumetric soil moisture, site 4(sm4)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• volumetric soil moisture, site 3(sm3)
• volumetric soil moisture, site 2(sm2)
• Temperature of bottom humidity sensor chamber(thum_bot)
• 0-5 cm integrated soil temperature, site 4(ts4)
• volumetric soil moisture, site 5(sm5)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• soil heat flow, site 5(g5)
• 0-5 cm integrated soil temperature, site 5(ts5)
• scalar wind speed(wind_s)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• bottom air temperature(tair_bot)
• soil heat flow, site 4(g4)
• Top humidity(hum_top)
• Reference Thermistor Temperature(tref)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• h(h)
• top air temperature(tair_top)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)
• latent heat flux(e)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Soil heat capacity 4(cs4)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• bottom vapor pressure(vp_bot)
• vector wind speed(res_ws)
• 0-5 cm integrated soil temperature, site 2(ts1)
• Soil heat capacity 1(cs1)
• soil heat flow, site 1(g1)
• lat(lat)
• 0-5 cm integrated soil temperature, site 2(ts2)
• wind direction (relative to true north)(wind_d)
• Temperature of the top humidity chamber(thum_top)
• Dummy altitude for Zeb(alt)
• 5 cm soil heat flow, site 2(shf2)
• Time offset of tweaks from base_time(time_offset)
• top vapor pressure(vp_top)
• average surface soil heat flow(ave_shf)
• base time(base_time)
• 0-5 cm integrated soil temperature, site 3(ts3)
• 5 cm soil heat flow, site 1(shf1)
• lon(lon)
• 5 cm soil heat flow, site 5(shf5)
• 5 cm soil heat flow, site 3(shf3)
• 5 cm soil heat flow, site 4(shf4)
• soil heat flow, site 3(g3)
• soil heat flow, site 2(g2)

• null(Raw data stream - documentation not supported)

• lat(lat)
• h(h)
• vector wind speed(res_ws)
• Soil heat capacity 4(cs4)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Temperature of the top humidity chamber(thum_top)
• top air temperature(tair_top)
• soil heat flow, site 1(g1)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• soil heat flow, site 2(g2)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• scalar wind speed(wind_s)
• Soil heat capacity 2(cs2)
• net radiation(q)
• Soil heat capacity 1(cs1)
• volumetric soil moisture, site 1(sm1)
• 0-5 cm integrated soil temperature, site 2(ts1)
• volumetric soil moisture, site 2(sm2)
• 0-5 cm integrated soil temperature, site 5(ts5)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• Reference Thermistor Temperature(tref)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• top vapor pressure(vp_top)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• Retrieved pressure profile(pres)
• volumetric soil moisture, site 3(sm3)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• volumetric soil moisture, site 4(sm4)
• Soil heat capacity 3(cs3)
• Time offset of tweaks from base_time(time_offset)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• Bottom humidity(hum_bot)
• soil heat flow, site 4(g4)
• Top humidity(hum_top)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 0-5 cm integrated soil temperature, site 2(ts2)
• soil heat flow, site 3(g3)
• average surface soil heat flow(ave_shf)
• 5 cm soil heat flow, site 1(shf1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• 5 cm soil heat flow, site 4(shf4)
• volumetric soil moisture, site 5(sm5)
• latent heat flux(e)
• 5 cm soil heat flow, site 2(shf2)
• wind direction (relative to true north)(wind_d)
• Temperature of bottom humidity sensor chamber(thum_bot)
• bottom air temperature(tair_bot)
• 0-5 cm integrated soil temperature, site 3(ts3)
• Soil heat capacity 5(cs5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• 5 cm soil heat flow, site 3(shf3)
• bottom vapor pressure(vp_bot)
• 0-5 cm integrated soil temperature, site 4(ts4)
• soil heat flow, site 5(g5)
• lon(lon)
• 5 cm soil heat flow, site 5(shf5)
• Dummy altitude for Zeb(alt)
• base time(base_time)

• lon(lon)
• Home signal(mv_home)
• Wind direction (relative to true north)(mv_wind_d)
• Right air temperature(tair_r)
• Left air temperature(tair_l)
• lat(lat)
• base time(base_time)
• Soil temperature 2(rr_ts2)
• Signature(signature)
• Reference temperature(rr_tref)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Soil temperature 3(rr_ts3)
• Soil temperature 1(rr_ts1)
• Soil moisture 4(r_sm4)
• Soil temperature 4(rr_ts4)
• Soil moisture 3(r_sm3)
• Soil heat flow 1(mv_hft1)
• Soil heat flow 5(mv_hft5)
• Left relative humidity(mv_hum_l)
• Battery(bat)
• Soil moisture 5(r_sm5)
• Soil heat flow 4(mv_hft4)
• Soil heat flow 3(mv_hft3)
• Soil heat flow 2(mv_hft2)
• Time offset of tweaks from base_time(time_offset)
• scalar wind speed(wind_s)
• Right relative humidity(mv_hum_r)
• Soil temperature 5(rr_ts5)
• Net radiation(mv_q)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil moisture 1(r_sm1)
• Soil moisture 2(r_sm2)
• Atmospheric pressure(mv_pres)
• Dummy altitude for Zeb(alt)

• scalar wind speed(wind_s)
• top air temperature(tair_top)
• top vapor pressure(vp_top)
• lon(lon)
• bottom air temperature(tair_bot)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• wind direction (relative to true north)(wind_d)
• base time(base_time)
• Dummy altitude for Zeb(alt)
• Reference Thermistor Temperature(tref)
• Retrieved pressure profile(pres)
• net radiation(q)
• Time offset of tweaks from base_time(time_offset)
• Temperature of the top humidity chamber(thum_top)
• vector wind speed(res_ws)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Home signal(home)
• lat(lat)
• Bottom humidity(hum_bot)
• Temperature of bottom humidity sensor chamber(thum_bot)

SGP/EBBR/E7 - AEM Hung

The indicated measurements were incorrect because the automatic exchange mechanism hung in 
one position.

• top air temperature(tair_top)
• bottom vapor pressure(vp_bot)
• Temperature of the top humidity chamber(thum_top)
• Temperature of bottom humidity sensor chamber(thum_bot)
• top vapor pressure(vp_top)
• Top humidity(hum_top)
• bottom air temperature(tair_bot)
• Bottom humidity(hum_bot)

• Left air temperature(tair_l)
• Right air temperature(tair_r)

• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• top air temperature(tair_top)
• Top humidity(hum_top)
• top vapor pressure(vp_top)
• bottom air temperature(tair_bot)
• Temperature of bottom humidity sensor chamber(thum_bot)
• bottom vapor pressure(vp_bot)
• latent heat flux(e)
• h(h)
• Bottom humidity(hum_bot)
• Temperature of the top humidity chamber(thum_top)

• Right air temperature(tair_r)
• Left air temperature(tair_l)

• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• top air temperature(tair_top)
• bottom air temperature(tair_bot)
• Bottom humidity(hum_bot)
• Temperature of bottom humidity sensor chamber(thum_bot)
• h(h)
• top vapor pressure(vp_top)
• latent heat flux(e)
• Temperature of the top humidity chamber(thum_top)

SGP/EBBR/E12 - Measurements Incorrect

All measurements were incorrect or offscale for an unknown reason.

• Left relative humidity(mv_hum_l)
• Soil moisture 2(r_sm2)
• Soil temperature 5(rr_ts5)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Reference temperature(rr_tref)
• scalar wind speed(wind_s)
• Soil temperature 4(rr_ts4)
• Right air temperature(tair_r)
• Soil heat flow 5(mv_hft5)
• Soil heat flow 4(mv_hft4)
• Soil moisture 1(r_sm1)
• Soil moisture 4(r_sm4)
• Home signal(mv_home)
• Soil heat flow 2(mv_hft2)
• Soil moisture 5(r_sm5)
• Battery(bat)
• Soil heat flow 3(mv_hft3)
• Left air temperature(tair_l)
• Soil temperature 1(rr_ts1)
• Soil temperature 3(rr_ts3)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 3(r_sm3)
• Atmospheric pressure(mv_pres)
• Soil heat flow 1(mv_hft1)
• Right relative humidity(mv_hum_r)
• Soil temperature 2(rr_ts2)
• Net radiation(mv_q)

• null(Raw data stream - documentation not supported)

• 5 cm soil heat flow, site 1(shf1)
• net radiation(q)
• Soil heat capacity 4(cs4)
• 5 cm soil heat flow, site 3(shf3)
• Soil heat capacity 1(cs1)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• Soil heat capacity 2(cs2)
• top vapor pressure(vp_top)
• Temperature of the top humidity chamber(thum_top)
• latent heat flux(e)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• wind direction (relative to true north)(wind_d)
• bottom vapor pressure(vp_bot)
• Temperature of bottom humidity sensor chamber(thum_bot)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• average surface soil heat flow(ave_shf)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 5 cm soil heat flow, site 2(shf2)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• Soil heat capacity 3(cs3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• Soil heat capacity 5(cs5)
• volumetric soil moisture, site 3(sm3)
• volumetric soil moisture, site 4(sm4)
• 5 cm soil heat flow, site 4(shf4)
• 0-5 cm integrated soil temperature, site 4(ts4)
• soil heat flow, site 2(g2)
• 5 cm soil heat flow, site 5(shf5)
• volumetric soil moisture, site 1(sm1)
• Reference Thermistor Temperature(tref)
• bottom air temperature(tair_bot)
• h(h)
• soil heat flow, site 4(g4)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• top air temperature(tair_top)
• volumetric soil moisture, site 2(sm2)
• scalar wind speed(wind_s)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• soil heat flow, site 1(g1)
• 0-5 cm integrated soil temperature, site 5(ts5)
• Retrieved pressure profile(pres)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• soil heat flow, site 5(g5)
• vector wind speed(res_ws)
• soil heat flow, site 3(g3)
• 0-5 cm integrated soil temperature, site 3(ts3)
• volumetric soil moisture, site 5(sm5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• 0-5 cm integrated soil temperature, site 2(ts2)

• bottom air temperature(tair_bot)
• top vapor pressure(vp_top)
• Home signal(home)
• Reference Thermistor Temperature(tref)
• vector wind speed(res_ws)
• top air temperature(tair_top)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• wind direction (relative to true north)(wind_d)
• Top humidity(hum_top)
• Retrieved pressure profile(pres)
• net radiation(q)
• Bottom humidity(hum_bot)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Temperature of the top humidity chamber(thum_top)
• bottom vapor pressure(vp_bot)
• scalar wind speed(wind_s)

• 0-5 cm integrated soil temperature, site 5(ts5)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• Temperature of bottom humidity sensor chamber(thum_bot)
• bottom vapor pressure(vp_bot)
• 0-5 cm integrated soil temperature, site 3(ts3)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• soil heat flow, site 1(g1)
• soil heat flow, site 3(g3)
• Soil heat capacity 2(cs2)
• volumetric soil moisture, site 3(sm3)
• Soil heat capacity 5(cs5)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)
• Reference Thermistor Temperature(tref)
• soil heat flow, site 4(g4)
• 0-5 cm integrated soil temperature, site 4(ts4)
• Retrieved pressure profile(pres)
• bottom air temperature(tair_bot)
• Soil heat capacity 3(cs3)
• wind direction (relative to true north)(wind_d)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• Temperature of the top humidity chamber(thum_top)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• volumetric soil moisture, site 1(sm1)
• soil heat flow, site 5(g5)
• vector wind speed(res_ws)
• top vapor pressure(vp_top)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• 5 cm soil heat flow, site 2(shf2)
• top air temperature(tair_top)
• Top humidity(hum_top)
• volumetric soil moisture, site 4(sm4)
• volumetric soil moisture, site 2(sm2)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• latent heat flux(e)
• Bottom humidity(hum_bot)
• 5 cm soil heat flow, site 4(shf4)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 5 cm soil heat flow, site 3(shf3)
• volumetric soil moisture, site 5(sm5)
• net radiation(q)
• 5 cm soil heat flow, site 1(shf1)
• 5 cm soil heat flow, site 5(shf5)
• scalar wind speed(wind_s)
• soil heat flow, site 2(g2)
• average surface soil heat flow(ave_shf)
• h(h)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 0-5 cm change in soil heat storage with time, site 2(ces1)

• Home signal(mv_home)
• Soil moisture 5(r_sm5)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Soil heat flow 3(mv_hft3)
• Soil moisture 3(r_sm3)
• Soil heat flow 2(mv_hft2)
• Net radiation(mv_q)
• Left air temperature(tair_l)
• Soil heat flow 4(mv_hft4)
• Soil temperature 1(rr_ts1)
• Soil moisture 5(rr_sm5)
• Soil temperature 2(rr_ts2)
• Battery(bat)
• Soil temperature 3(rr_ts3)
• Soil moisture 2(rr_sm2)
• Left relative humidity(mv_hum_l)
• Right relative humidity(mv_hum_r)
• Soil moisture 4(r_sm4)
• Right air temperature(tair_r)
• Soil heat flow 5(mv_hft5)
• Soil moisture 1(r_sm1)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 1(rr_sm1)
• Soil moisture 2(r_sm2)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil temperature 5(rr_ts5)
• Soil heat flow 1(mv_hft1)
• Soil moisture 3(rr_sm3)
• Soil moisture 4(rr_sm4)
• Soil temperature 4(rr_ts4)
• scalar wind speed(wind_s)
• Atmospheric pressure(mv_pres)
• Reference temperature(rr_tref)

SGP/EBBR/E12 - Resistance Measurements Incorrect

All sensors that depend on resistance measurements are incorrect.
Average soil heat flow, sensible heat flux, and latent heat flux are incorrect as a 
result.

This condition normally occurs when the reference temperature sensor is disconnected or 
bad.

• Left air temperature(tair_l)
• Right air temperature(tair_r)

• volumetric soil moisture, site 3(sm3)
• volumetric soil moisture, site 4(sm4)
• soil heat flow, site 2(g2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• volumetric soil moisture, site 1(sm1)
• Reference Thermistor Temperature(tref)
• bottom air temperature(tair_bot)
• Soil heat capacity 4(cs4)
• h(h)
• soil heat flow, site 4(g4)
• Soil heat capacity 1(cs1)
• Soil heat capacity 2(cs2)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• top vapor pressure(vp_top)
• Temperature of the top humidity chamber(thum_top)
• latent heat flux(e)
• top air temperature(tair_top)
• volumetric soil moisture, site 2(sm2)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• soil heat flow, site 1(g1)
• bottom vapor pressure(vp_bot)
• 0-5 cm integrated soil temperature, site 5(ts5)
• Temperature of bottom humidity sensor chamber(thum_bot)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• average surface soil heat flow(ave_shf)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• soil heat flow, site 5(g5)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• Soil heat capacity 3(cs3)
• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm integrated soil temperature, site 3(ts3)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• volumetric soil moisture, site 5(sm5)
• Soil heat capacity 5(cs5)
• 0-5 cm integrated soil temperature, site 2(ts2)

• bottom air temperature(tair_bot)
• top vapor pressure(vp_top)
• Temperature of bottom humidity sensor chamber(thum_bot)
• top air temperature(tair_top)
• Temperature of the top humidity chamber(thum_top)
• bottom vapor pressure(vp_bot)

• 0-5 cm integrated soil temperature, site 5(ts5)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• Temperature of bottom humidity sensor chamber(thum_bot)
• bottom vapor pressure(vp_bot)
• 0-5 cm integrated soil temperature, site 3(ts3)
• top air temperature(tair_top)
• volumetric soil moisture, site 4(sm4)
• soil heat flow, site 1(g1)
• soil heat flow, site 3(g3)
• volumetric soil moisture, site 2(sm2)
• Soil heat capacity 2(cs2)
• volumetric soil moisture, site 3(sm3)
• latent heat flux(e)
• 0-5 cm integrated soil temperature, site 2(ts1)
• Soil heat capacity 5(cs5)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)
• Reference Thermistor Temperature(tref)
• volumetric soil moisture, site 5(sm5)
• soil heat flow, site 4(g4)
• 0-5 cm integrated soil temperature, site 4(ts4)
• bottom air temperature(tair_bot)
• Soil heat capacity 3(cs3)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• soil heat flow, site 2(g2)
• Temperature of the top humidity chamber(thum_top)
• average surface soil heat flow(ave_shf)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• volumetric soil moisture, site 1(sm1)
• h(h)
• soil heat flow, site 5(g5)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• top vapor pressure(vp_top)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)

• Right air temperature(tair_r)
• Left air temperature(tair_l)

SGP/EBBR/E13 - Wind Direction Incorrect

The wind direction and sigma_wd was near zero for the indicated times.

• standard deviation of wind direction (sigma theta)(sigma_wd)
• wind direction (relative to true north)(wind_d)
• vector wind speed(res_ws)

• standard deviation of wind direction (sigma theta)(sigma_wd)
• wind direction (relative to true north)(wind_d)
• vector wind speed(res_ws)

• wind direction (relative to true north)(wind_d)
• vector wind speed(res_ws)
• standard deviation of wind direction (sigma theta)(sigma_wd)

SGP/EBBR/E9 - Reprocess: Soil Temperature #5 Incorrect

Soil temperature # 5 was incorrect most of the time, leading to incorrect surface heat 
flow, latent heat flux and sensible heat flux.  The heat fluxes can be recalculated by using 
soil sets 1-4 as follows:

ave_shf = (g1 + g2 + g3 + g4)/4
e = -(q + ave_shf)/(1 + bowen)
h = -(q + e + ave_shf)

• latent heat flux(e)
• soil heat flow, site 5(g5)
• average surface soil heat flow(ave_shf)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• h(h)
• 0-5 cm integrated soil temperature, site 5(ts5)

• 0-5 cm integrated soil temperature, site 5(ts5)
• h(h)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• soil heat flow, site 5(g5)
• average surface soil heat flow(ave_shf)
• latent heat flux(e)

SGP/EBBR/E19 - Reprocess: Soil Temperature #3 Incorrect

Soil Temperature 3 was incorrect for the period indicated, causing average soil flow, 
latent heat flux, and sensible heat flux to be incorrect also.

Average soil heat flow, sensible heat flux, and latent heat flux can be recalculated using 
the remaining good sets of soil sensors as follows:

ave_shf = (g1 + g2 + g4 + g5)/4

e = -(q + ave_shf)/(1 + bowen)

h = -(q + e + ave_shf)

• latent heat flux(e)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm integrated soil temperature, site 3(ts3)
• average surface soil heat flow(ave_shf)
• soil heat flow, site 3(g3)
• h(h)

• soil heat flow, site 3(g3)
• average surface soil heat flow(ave_shf)
• h(h)
• latent heat flux(e)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm integrated soil temperature, site 3(ts3)

SGP/EBBR/E9 - Measurements All Zeros

The measurements were all zeros at the indicated times.  This occurs after a CR10 program 
restart, which sometimes happens after some servicing of the EBBR is performed.

• Soil moisture 2(r_sm2)
• Soil moisture 3(r_sm3)
• Soil moisture 1(r_sm1)
• Soil temperature 4(rr_ts4)
• Right relative humidity(mv_hum_r)
• Soil heat flow 1(mv_hft1)
• Soil temperature 5(rr_ts5)
• Right air temperature(tair_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Soil temperature 1(rr_ts1)
• Soil temperature 3(rr_ts3)
• Soil temperature 2(rr_ts2)
• Soil heat flow 3(mv_hft3)
• Soil heat flow 4(mv_hft4)
• Atmospheric pressure(mv_pres)
• Home signal(mv_home)
• Soil moisture 4(r_sm4)
• Net radiation(mv_q)
• Wind direction (relative to true north)(mv_wind_d)
• Reference temperature(rr_tref)
• Left relative humidity(mv_hum_l)
• Battery(bat)
• Soil heat flow 5(mv_hft5)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil heat flow 2(mv_hft2)
• scalar wind speed(wind_s)
• Left air temperature(tair_l)
• Soil moisture 5(r_sm5)

• bottom vapor pressure(vp_bot)
• h(h)
• top vapor pressure(vp_top)
• bottom air temperature(tair_bot)
• Bottom humidity(hum_bot)
• volumetric soil moisture, site 2(sm2)
• Soil heat capacity 3(cs3)
• 5 cm soil heat flow, site 2(shf2)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• volumetric soil moisture, site 3(sm3)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• vector wind speed(res_ws)
• Soil heat capacity 5(cs5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• Soil heat capacity 4(cs4)
• scalar wind speed(wind_s)
• volumetric soil moisture, site 1(sm1)
• Temperature of the top humidity chamber(thum_top)
• Soil heat capacity 1(cs1)
• wind direction (relative to true north)(wind_d)
• soil heat flow, site 1(g1)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• volumetric soil moisture, site 4(sm4)
• 5 cm soil heat flow, site 5(shf5)
• soil heat flow, site 4(g4)
• Retrieved pressure profile(pres)
• 0-5 cm integrated soil temperature, site 3(ts3)
• soil heat flow, site 2(g2)
• 5 cm soil heat flow, site 1(shf1)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• volumetric soil moisture, site 5(sm5)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• net radiation(q)
• 5 cm soil heat flow, site 3(shf3)
• Top humidity(hum_top)
• 0-5 cm integrated soil temperature, site 5(ts5)
• Soil heat capacity 2(cs2)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• Reference Thermistor Temperature(tref)
• 5 cm soil heat flow, site 4(shf4)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• top air temperature(tair_top)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• latent heat flux(e)
• soil heat flow, site 5(g5)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• Temperature of bottom humidity sensor chamber(thum_bot)
• average surface soil heat flow(ave_shf)

• null(Raw data stream - documentation not supported)

• vector wind speed(res_ws)
• Home signal(home)
• Top humidity(hum_top)
• Temperature of bottom humidity sensor chamber(thum_bot)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• bottom air temperature(tair_bot)
• wind direction (relative to true north)(wind_d)
• top vapor pressure(vp_top)
• top air temperature(tair_top)
• bottom vapor pressure(vp_bot)
• Retrieved pressure profile(pres)
• Reference Thermistor Temperature(tref)
• Bottom humidity(hum_bot)
• scalar wind speed(wind_s)
• net radiation(q)
• Temperature of the top humidity chamber(thum_top)

• Left air temperature(tair_l)
• Soil moisture 3(r_sm3)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil moisture 1(rr_sm1)
• Soil moisture 2(r_sm2)
• Soil moisture 4(rr_sm4)
• Soil moisture 2(rr_sm2)
• Soil moisture 3(rr_sm3)
• Soil moisture 5(rr_sm5)
• Reference temperature(rr_tref)
• Soil temperature 5(rr_ts5)
• Soil moisture 4(r_sm4)
• Wind direction (relative to true north)(mv_wind_d)
• Left relative humidity(mv_hum_l)
• Soil temperature 4(rr_ts4)
• Soil heat flow 4(mv_hft4)
• Soil moisture 5(r_sm5)
• Battery(bat)
• Soil temperature 2(rr_ts2)
• Home signal(mv_home)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Soil temperature 3(rr_ts3)
• Right relative humidity(mv_hum_r)
• Soil temperature 1(rr_ts1)
• Soil heat flow 1(mv_hft1)
• scalar wind speed(wind_s)
• Soil heat flow 5(mv_hft5)
• Atmospheric pressure(mv_pres)
• Soil heat flow 3(mv_hft3)
• Net radiation(mv_q)
• Soil moisture 1(r_sm1)
• Soil heat flow 2(mv_hft2)

• soil heat flow, site 4(g4)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• soil heat flow, site 1(g1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• Temperature of bottom humidity sensor chamber(thum_bot)
• h(h)
• 5 cm soil heat flow, site 1(shf1)
• soil heat flow, site 5(g5)
• 0-5 cm integrated soil temperature, site 2(ts1)
• soil heat flow, site 2(g2)
• latent heat flux(e)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 0-5 cm integrated soil temperature, site 5(ts5)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• wind direction (relative to true north)(wind_d)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• Soil heat capacity 3(cs3)
• 5 cm soil heat flow, site 4(shf4)
• 0-5 cm integrated soil temperature, site 3(ts3)
• Soil heat capacity 2(cs2)
• top vapor pressure(vp_top)
• Soil heat capacity 1(cs1)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• soil heat flow, site 3(g3)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• net radiation(q)
• Reference Thermistor Temperature(tref)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Soil heat capacity 4(cs4)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• volumetric soil moisture, site 3(sm3)
• average surface soil heat flow(ave_shf)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• volumetric soil moisture, site 4(sm4)
• 5 cm soil heat flow, site 5(shf5)
• Bottom humidity(hum_bot)
• 0-5 cm integrated soil temperature, site 2(ts2)
• Soil heat capacity 5(cs5)
• scalar wind speed(wind_s)
• 5 cm soil heat flow, site 2(shf2)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 5 cm soil heat flow, site 3(shf3)
• bottom air temperature(tair_bot)
• 0-5 cm integrated soil temperature, site 4(ts4)
• bottom vapor pressure(vp_bot)
• Retrieved pressure profile(pres)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• volumetric soil moisture, site 5(sm5)
• vector wind speed(res_ws)
• top air temperature(tair_top)
• Temperature of the top humidity chamber(thum_top)
• Top humidity(hum_top)
• volumetric soil moisture, site 1(sm1)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• volumetric soil moisture, site 2(sm2)

SGP/EBBR/E19 - All Measurements Zero

Measurements are often zero the first period after a CR10 restart.

• null(Raw data stream - documentation not supported)

• Right air temperature(tair_r)
• Reference temperature(rr_tref)
• Soil temperature 5(rr_ts5)
• scalar wind speed(wind_s)
• Soil temperature 4(rr_ts4)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 1(r_sm1)
• Home signal(mv_home)
• Soil moisture 3(r_sm3)
• Soil moisture 2(r_sm2)
• Soil heat flow 1(mv_hft1)
• Soil heat flow 2(mv_hft2)
• Left air temperature(tair_l)
• Left relative humidity(mv_hum_l)
• Battery(bat)
• Soil heat flow 4(mv_hft4)
• Right relative humidity(mv_hum_r)
• Soil heat flow 5(mv_hft5)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil heat flow 3(mv_hft3)
• Soil moisture 4(r_sm4)
• Soil temperature 1(rr_ts1)
• Soil temperature 2(rr_ts2)
• Soil moisture 5(r_sm5)
• Soil temperature 3(rr_ts3)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Atmospheric pressure(mv_pres)
• Net radiation(mv_q)

• Right relative humidity(mv_hum_r)
• Soil heat flow 1(mv_hft1)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil temperature 1(rr_ts1)
• Soil heat flow 3(mv_hft3)
• Atmospheric pressure(mv_pres)
• Soil temperature 2(rr_ts2)
• Soil heat flow 2(mv_hft2)
• Left air temperature(tair_l)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Soil moisture 5(r_sm5)
• Soil temperature 4(rr_ts4)
• Net radiation(mv_q)
• scalar wind speed(wind_s)
• Reference temperature(rr_tref)
• Soil moisture 2(r_sm2)
• Soil temperature 5(rr_ts5)
• Battery(bat)
• Left relative humidity(mv_hum_l)
• Soil temperature 3(rr_ts3)
• Home signal(mv_home)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 4(r_sm4)
• Right air temperature(tair_r)
• Soil moisture 3(r_sm3)
• Soil heat flow 4(mv_hft4)
• Soil heat flow 5(mv_hft5)
• Soil moisture 1(r_sm1)

• bottom vapor pressure(vp_bot)
• Temperature of the top humidity chamber(thum_top)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• vector wind speed(res_ws)
• wind direction (relative to true north)(wind_d)
• bottom air temperature(tair_bot)
• Reference Thermistor Temperature(tref)
• top air temperature(tair_top)
• scalar wind speed(wind_s)
• Retrieved pressure profile(pres)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Home signal(home)
• top vapor pressure(vp_top)
• net radiation(q)

• 0-5 cm integrated soil temperature, site 3(ts3)
• vector wind speed(res_ws)
• 5 cm soil heat flow, site 1(shf1)
• soil heat flow, site 2(g2)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• soil heat flow, site 1(g1)
• 5 cm soil heat flow, site 4(shf4)
• net radiation(q)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• Reference Thermistor Temperature(tref)
• volumetric soil moisture, site 3(sm3)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• 5 cm soil heat flow, site 5(shf5)
• average surface soil heat flow(ave_shf)
• top vapor pressure(vp_top)
• volumetric soil moisture, site 4(sm4)
• Soil heat capacity 3(cs3)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• Soil heat capacity 5(cs5)
• Retrieved pressure profile(pres)
• Temperature of the top humidity chamber(thum_top)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 5 cm soil heat flow, site 2(shf2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• Soil heat capacity 2(cs2)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 0-5 cm integrated soil temperature, site 2(ts2)
• soil heat flow, site 4(g4)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• volumetric soil moisture, site 2(sm2)
• Soil heat capacity 1(cs1)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 0-5 cm integrated soil temperature, site 5(ts5)
• latent heat flux(e)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• Soil heat capacity 4(cs4)
• h(h)
• bottom vapor pressure(vp_bot)
• wind direction (relative to true north)(wind_d)
• soil heat flow, site 3(g3)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Top humidity(hum_top)
• volumetric soil moisture, site 5(sm5)
• Bottom humidity(hum_bot)
• soil heat flow, site 5(g5)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 5 cm soil heat flow, site 3(shf3)
• scalar wind speed(wind_s)
• top air temperature(tair_top)
• bottom air temperature(tair_bot)
• volumetric soil moisture, site 1(sm1)
• 0-5 cm change in soil heat storage with time, site 5(ces5)

• 0-5 cm integrated soil temperature, site 5(ts5)
• 0-5 cm integrated soil temperature, site 3(ts3)
• Reference Thermistor Temperature(tref)
• 5 cm soil heat flow, site 2(shf2)
• volumetric soil moisture, site 1(sm1)
• volumetric soil moisture, site 2(sm2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• Soil heat capacity 5(cs5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• volumetric soil moisture, site 4(sm4)
• Soil heat capacity 3(cs3)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• h(h)
• Temperature of the top humidity chamber(thum_top)
• scalar wind speed(wind_s)
• top air temperature(tair_top)
• Soil heat capacity 4(cs4)
• Bottom humidity(hum_bot)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• soil heat flow, site 4(g4)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 0-5 cm integrated soil temperature, site 2(ts1)
• top vapor pressure(vp_top)
• vector wind speed(res_ws)
• average surface soil heat flow(ave_shf)
• volumetric soil moisture, site 5(sm5)
• latent heat flux(e)
• wind direction (relative to true north)(wind_d)
• soil heat flow, site 2(g2)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Soil heat capacity 1(cs1)
• volumetric soil moisture, site 3(sm3)
• soil heat flow, site 5(g5)
• soil heat flow, site 1(g1)
• soil heat flow, site 3(g3)
• bottom vapor pressure(vp_bot)
• 5 cm soil heat flow, site 1(shf1)
• Soil heat capacity 2(cs2)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 5 cm soil heat flow, site 5(shf5)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• Top humidity(hum_top)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• bottom air temperature(tair_bot)
• net radiation(q)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• 5 cm soil heat flow, site 3(shf3)
• 5 cm soil heat flow, site 4(shf4)
• Retrieved pressure profile(pres)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)

SGP/EBBR/E19 - Pressure Incorrect

The pressure measurement was incorrect.  This is used to determine the Bowen ratio, 
thereby affecting the sensible and latent heat fluxes also.

• Retrieved pressure profile(pres)

• latent heat flux(e)
• h(h)
• Retrieved pressure profile(pres)

• Retrieved pressure profile(pres)
• h(h)
• latent heat flux(e)

SGP/EBBR/E19 - Low Battery Voltage

A battery voltage of less than 10.5 causes many of the sensors to produce incorrect 
measurements.
The 15 minute data contains the battery voltage and should be used to determine whether 
the measurements are usable, based on battery voltage.

• null(Raw data stream - documentation not supported)

• Right air temperature(tair_r)
• Reference temperature(rr_tref)
• Soil temperature 5(rr_ts5)
• scalar wind speed(wind_s)
• Soil temperature 4(rr_ts4)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 1(r_sm1)
• Home signal(mv_home)
• Soil moisture 3(r_sm3)
• Soil moisture 2(r_sm2)
• Soil heat flow 1(mv_hft1)
• Soil heat flow 2(mv_hft2)
• Left air temperature(tair_l)
• Left relative humidity(mv_hum_l)
• Soil heat flow 4(mv_hft4)
• Right relative humidity(mv_hum_r)
• Soil heat flow 5(mv_hft5)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil heat flow 3(mv_hft3)
• Soil moisture 4(r_sm4)
• Soil temperature 1(rr_ts1)
• Soil temperature 2(rr_ts2)
• Soil moisture 5(r_sm5)
• Soil temperature 3(rr_ts3)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Atmospheric pressure(mv_pres)
• Net radiation(mv_q)

• Right relative humidity(mv_hum_r)
• Soil heat flow 1(mv_hft1)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil temperature 1(rr_ts1)
• Soil heat flow 3(mv_hft3)
• Atmospheric pressure(mv_pres)
• Soil temperature 2(rr_ts2)
• Soil heat flow 2(mv_hft2)
• Left air temperature(tair_l)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Soil moisture 5(r_sm5)
• Soil temperature 4(rr_ts4)
• Net radiation(mv_q)
• scalar wind speed(wind_s)
• Reference temperature(rr_tref)
• Soil moisture 2(r_sm2)
• Soil temperature 5(rr_ts5)
• Left relative humidity(mv_hum_l)
• Soil temperature 3(rr_ts3)
• Home signal(mv_home)
• Wind direction (relative to true north)(mv_wind_d)
• Soil moisture 4(r_sm4)
• Right air temperature(tair_r)
• Soil moisture 3(r_sm3)
• Soil heat flow 4(mv_hft4)
• Soil heat flow 5(mv_hft5)
• Soil moisture 1(r_sm1)

• bottom vapor pressure(vp_bot)
• Temperature of the top humidity chamber(thum_top)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• vector wind speed(res_ws)
• wind direction (relative to true north)(wind_d)
• bottom air temperature(tair_bot)
• Reference Thermistor Temperature(tref)
• top air temperature(tair_top)
• scalar wind speed(wind_s)
• Retrieved pressure profile(pres)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Home signal(home)
• top vapor pressure(vp_top)
• net radiation(q)

• 0-5 cm integrated soil temperature, site 3(ts3)
• vector wind speed(res_ws)
• 5 cm soil heat flow, site 1(shf1)
• soil heat flow, site 2(g2)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• soil heat flow, site 1(g1)
• 5 cm soil heat flow, site 4(shf4)
• net radiation(q)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• Reference Thermistor Temperature(tref)
• volumetric soil moisture, site 3(sm3)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• 5 cm soil heat flow, site 5(shf5)
• average surface soil heat flow(ave_shf)
• top vapor pressure(vp_top)
• volumetric soil moisture, site 4(sm4)
• Soil heat capacity 3(cs3)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• Soil heat capacity 5(cs5)
• Retrieved pressure profile(pres)
• Temperature of the top humidity chamber(thum_top)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 5 cm soil heat flow, site 2(shf2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• Soil heat capacity 2(cs2)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• soil heat flow, site 4(g4)
• 0-5 cm integrated soil temperature, site 2(ts1)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• volumetric soil moisture, site 2(sm2)
• Soil heat capacity 1(cs1)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• 0-5 cm integrated soil temperature, site 5(ts5)
• latent heat flux(e)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• Soil heat capacity 4(cs4)
• h(h)
• bottom vapor pressure(vp_bot)
• wind direction (relative to true north)(wind_d)
• soil heat flow, site 3(g3)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Top humidity(hum_top)
• volumetric soil moisture, site 5(sm5)
• Bottom humidity(hum_bot)
• soil heat flow, site 5(g5)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 5 cm soil heat flow, site 3(shf3)
• scalar wind speed(wind_s)
• top air temperature(tair_top)
• bottom air temperature(tair_bot)
• volumetric soil moisture, site 1(sm1)
• 0-5 cm change in soil heat storage with time, site 5(ces5)

• 0-5 cm integrated soil temperature, site 5(ts5)
• 0-5 cm integrated soil temperature, site 3(ts3)
• Reference Thermistor Temperature(tref)
• 5 cm soil heat flow, site 2(shf2)
• volumetric soil moisture, site 1(sm1)
• volumetric soil moisture, site 2(sm2)
• 0-5 cm integrated soil temperature, site 4(ts4)
• Exchange mechanism position indicator (15 to 30 min)(home_30)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• Soil heat capacity 5(cs5)
• Exchange mechanism position indicator (0 to 15 min)(home_15)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• volumetric soil moisture, site 4(sm4)
• Soil heat capacity 3(cs3)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• h(h)
• Temperature of the top humidity chamber(thum_top)
• scalar wind speed(wind_s)
• top air temperature(tair_top)
• Soil heat capacity 4(cs4)
• Bottom humidity(hum_bot)
• soil heat flow, site 4(g4)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 0-5 cm integrated soil temperature, site 2(ts1)
• top vapor pressure(vp_top)
• vector wind speed(res_ws)
• average surface soil heat flow(ave_shf)
• volumetric soil moisture, site 5(sm5)
• latent heat flux(e)
• wind direction (relative to true north)(wind_d)
• soil heat flow, site 2(g2)
• Temperature of bottom humidity sensor chamber(thum_bot)
• Soil heat capacity 1(cs1)
• volumetric soil moisture, site 3(sm3)
• soil heat flow, site 5(g5)
• soil heat flow, site 1(g1)
• soil heat flow, site 3(g3)
• bottom vapor pressure(vp_bot)
• 5 cm soil heat flow, site 1(shf1)
• Soil heat capacity 2(cs2)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 5 cm soil heat flow, site 5(shf5)
• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• Top humidity(hum_top)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• bottom air temperature(tair_bot)
• net radiation(q)
• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• 5 cm soil heat flow, site 3(shf3)
• 5 cm soil heat flow, site 4(shf4)
• Retrieved pressure profile(pres)
• 0-5 cm integrated soil temperature, site 2(ts2)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)

SGP/EBBR/E26 - Multiplexer 2 Failure From High Temperature

Multiplexer 2 is failing during times of control box temperatures above 29 degrees C.  The 
failure begins in the last channel and progresses to lower channels as the temperature 
increases.  It has not yet been determined whether the failure is in the relays or a solid 
state component of the multiplexer.  This condition is probably due to the aging of the 
device and the millions of cycles that this 10 year old device has made.  More failures 
of this sort may occur in the future.  A cure is being sought aside from replacement of 
the multiplexers to prevent the problem.

The indicated measurements need to be inspected to determine which ones are usable.

• top air temperature(tair_top)
• top vapor pressure(vp_top)
• bottom air temperature(tair_bot)
• bottom vapor pressure(vp_bot)

• Right air temperature(tair_r)
• Left air temperature(tair_l)

• Left air temperature(tair_l)
• Right air temperature(tair_r)

• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• top air temperature(tair_top)
• h(h)
• latent heat flux(e)
• top vapor pressure(vp_top)
• bottom vapor pressure(vp_bot)
• soil heat flow, site 5(g5)
• bottom air temperature(tair_bot)
• average surface soil heat flow(ave_shf)
• 5 cm soil heat flow, site 5(shf5)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• soil heat flow, site 3(g3)
• 5 cm soil heat flow, site 4(shf4)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• 5 cm soil heat flow, site 3(shf3)
• soil heat flow, site 4(g4)

• 5 cm soil heat flow corrected for soil moisture content, site 5(c_shf5)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• top vapor pressure(vp_top)
• 5 cm soil heat flow, site 4(shf4)
• top air temperature(tair_top)
• soil heat flow, site 4(g4)
• 5 cm soil heat flow, site 3(shf3)
• average surface soil heat flow(ave_shf)
• soil heat flow, site 3(g3)
• 5 cm soil heat flow, site 5(shf5)
• bottom vapor pressure(vp_bot)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• soil heat flow, site 5(g5)
• h(h)
• bottom air temperature(tair_bot)
• latent heat flux(e)

SGP/EBBR/E9 - Right Humidity Suspect

The Right Humidity measurement was normally incorrect, although it is often difficult to 
determine it by looking at the measurement.  The measurements float around, sometimes 
being too large and sometimes being too small, through most of the day, particularly for the 
hour before sunset through the hour after sunrise.  Great care and comparison with 
surrounding EBBR sites would be needed to be able to use any of the latent and sensible heat 
flux measurements from E9 for this period. 

Another DQPR has been issued to fix this problem, which has eluded repair efforts so far.

• Bottom humidity(hum_bot)
• latent heat flux(e)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• h(h)
• top vapor pressure(vp_top)

• top vapor pressure(vp_top)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• bottom vapor pressure(vp_bot)

• bottom vapor pressure(vp_bot)
• latent heat flux(e)
• h(h)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• top vapor pressure(vp_top)

SGP/EBBR/E12 - Reprocess: Soil Temperature #3 Incorrect

Soil Temperature #3 was flaky primarily during nighttime hours and sometimes during early 
daylight hours.  Average soil heat flow, sensible heat flux, and latent heat flux are 
also affected; these can be recalculated using the remaining good sets of soil sensors as 
follows:

The heat fluxes can be recalculated by using soil sets 1, 2, 4, and 5 as follows:
     ave_shf = (g1 + g2 + g4 + g5)/4
     e = -(q + ave_shf)/(1 + bowen)
     h = -(q + e + ave_shf)

• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm integrated soil temperature, site 3(ts3)
• latent heat flux(e)
• h(h)
• average surface soil heat flow(ave_shf)

• soil heat flow, site 3(g3)
• 0-5 cm integrated soil temperature, site 3(ts3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• latent heat flux(e)
• average surface soil heat flow(ave_shf)
• h(h)

SGP/EBBR/E12 - Wind Direction Incorrect

The wind direction measurement was zero, in the 50s, or always less than 180 degrees.

A DQPR has been issued to resolve the problem.

• vector wind speed(res_ws)
• wind direction (relative to true north)(wind_d)
• standard deviation of wind direction (sigma theta)(sigma_wd)

• standard deviation of wind direction (sigma theta)(sigma_wd)
• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• vector wind speed(res_ws)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• wind direction (relative to true north)(wind_d)

SGP/SMOS/E6 - RH Values Incorrect

RH and values calculated from RH suspect due to malfunction of sensor during saturated 
conditions.  RH readings exceeded 104% and at times reached 111%.  During non-saturated 
periods RH readings appear to be ~20% higher than neighboring sites.

• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Minimum Relative Humidity(min_rh)
• Maximum Vapor Pressure(max_vap_pres)
• Time of Minimum Relative Humidity(time_min_rh)
• Maximum Relative Humidity(max_rh)
• Minimum Vapor Pressure(min_vap_pres)
• Time of Maximum Relative Humidity(time_max_rh)
• Time of Minimum Vapor Pressure(time_min_vap_pres)

• Vapor Pressure (kiloPascals)(vap_pres)
• Relative humidity inside the instrument enclosure(rh)

• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)

• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)

• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)

SGP/SMOS/E6 - 30 minute Data Values Suspect

30 minute data values supect due to tower being lowered from 18:25 - 18:42 GMT for T/RH 
probe replacement.

• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Unit Vector Wind Direction(wdir)
• barometric pressure(bar_pres)
• Beam 0 Temperature(temp)
• Snow Depth(snow)
• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Wind Speed(sd_wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Snow Depth Sensor(snow_sen)
• Mean Wind Speed(wspd)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Relative Humidity(sd_rh)
• Hourly precipitation(precip)
• Standard Deviation of wind direction(sd_deg)

• Unit Vector Wind Direction(wdir)
• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)
• Hourly precipitation(precip)
• Standard Deviation of Relative Humidity(sd_rh)
• Wind Speed (vector averaged)(wspd_va)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Mean Wind Speed(wspd)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Beam 0 Temperature(temp)
• Snow Depth(snow)
• Standard Deviation of Wind Speed(sd_wspd)

SGP/SMOS/E7 - 30 minute Data Values Suspect

30 minute data values suspect due to tower being lowered from 14:22 - 14:38 GMT for T/RH 
probe replacement.

• Snow Depth Sensor(snow_sen)
• Hourly precipitation(precip)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Relative Humidity(sd_rh)
• Beam 0 Temperature(temp)
• Standard Deviation of Air Temperature(sd_temp)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Wind Speed(sd_wspd)
• Vapor Pressure (kiloPascals)(vap_pres)
• Snow Depth(snow)
• Mean Wind Speed(wspd)
• barometric pressure(bar_pres)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of wind direction(sd_deg)
• Relative humidity inside the instrument enclosure(rh)

• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Snow Depth Sensor(snow_sen)
• Vapor Pressure (kiloPascals)(vap_pres)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Hourly precipitation(precip)
• Unit Vector Wind Direction(wdir)
• barometric pressure(bar_pres)
• Beam 0 Temperature(temp)
• Standard Deviation of wind direction(sd_deg)
• Standard Deviation of Wind Speed(sd_wspd)
• Wind Speed (vector averaged)(wspd_va)
• Mean Wind Speed(wspd)
• Snow Depth(snow)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Relative Humidity(sd_rh)

SGP/SMOS/E24 - RH Values Incorrect

RH values approximately 10 - 20% low compared to neighboring sites.

• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Vapor Pressure (kiloPascals)(vap_pres)
• Relative humidity inside the instrument enclosure(rh)

• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)

• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Relative humidity inside the instrument enclosure(rh)

• Maximum Vapor Pressure(max_vap_pres)
• Time of Maximum Relative Humidity(time_max_rh)
• Maximum Relative Humidity(max_rh)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Minimum Vapor Pressure(min_vap_pres)
• Minimum Relative Humidity(min_rh)
• Time of Minimum Relative Humidity(time_min_rh)

• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)

SGP/SMOS/E24 - 30 minute Data Values Suspect

30 minute data values suspect due to tower being lowered from 16:42 - 17:05 GMT for T/RH 
probe replacement.

• Hourly precipitation(precip)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Wind Speed(sd_wspd)
• barometric pressure(bar_pres)
• Beam 0 Temperature(temp)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Mean Wind Speed(wspd)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of Relative Humidity(sd_rh)
• Snow Depth(snow)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of wind direction(sd_deg)

• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Wind Speed(sd_wspd)
• barometric pressure(bar_pres)
• Wind Speed (vector averaged)(wspd_va)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of Relative Humidity(sd_rh)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Snow Depth(snow)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of wind direction(sd_deg)
• Hourly precipitation(precip)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Mean Wind Speed(wspd)
• Unit Vector Wind Direction(wdir)
• Relative humidity inside the instrument enclosure(rh)
• Beam 0 Temperature(temp)

SGP/SMOS/E24 - Precip Data Suspect

Precipitation data suspect due to rain gauge being clogged with bird droppings.

• Hourly precipitation(precip)

• Hourly precipitation(precip)

• Hourly precipitation(precip)

• Hourly precipitation(precip)

SGP/SMOS/E15 - 30 minute Data Values Suspect

30 minute data values suspect due to tower being lowered from 17:12 - 17:21 GMT for wind 
monitor replacement.

• Standard Deviation of Relative Humidity(sd_rh)
• Mean Wind Speed(wspd)
• barometric pressure(bar_pres)
• Standard Deviation of Air Temperature(sd_temp)
• Snow Depth Sensor(snow_sen)
• Beam 0 Temperature(temp)
• Vapor Pressure (kiloPascals)(vap_pres)
• Hourly precipitation(precip)
• Snow Depth(snow)
• Standard Deviation of wind direction(sd_deg)
• Standard Deviation of Wind Speed(sd_wspd)
• Relative humidity inside the instrument enclosure(rh)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Wind Speed (vector averaged)(wspd_va)

• Standard Deviation of Air Temperature(sd_temp)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of wind direction(sd_deg)
• Unit Vector Wind Direction(wdir)
• barometric pressure(bar_pres)
• Mean Wind Speed(wspd)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Beam 0 Temperature(temp)
• Snow Depth(snow)
• Standard Deviation of Relative Humidity(sd_rh)
• Hourly precipitation(precip)
• Standard Deviation of Wind Speed(sd_wspd)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)

SGP/SMOS/E11 - 30 minute Data Values Suspect

30 minute data values suspect due to all data values being off-scale from 18:57 - 19:07 
GMT during barometer re-test.

• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Relative humidity inside the instrument enclosure(rh)
• Beam 0 Temperature(temp)
• Standard Deviation of wind direction(sd_deg)
• Snow Depth(snow)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Wind Speed(sd_wspd)
• barometric pressure(bar_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Hourly precipitation(precip)
• Snow Depth Sensor(snow_sen)
• Vapor Pressure (kiloPascals)(vap_pres)
• Mean Wind Speed(wspd)
• Standard Deviation of Air Temperature(sd_temp)

• Unit Vector Wind Direction(wdir)
• Hourly precipitation(precip)
• Relative humidity inside the instrument enclosure(rh)
• Snow Depth(snow)
• Mean Wind Speed(wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Wind Speed(sd_wspd)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of wind direction(sd_deg)
• Vapor Pressure (kiloPascals)(vap_pres)
• Beam 0 Temperature(temp)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• barometric pressure(bar_pres)

SGP/SMOS/E11 - 30 minute Data Values Incorrect

30 minute data values incorrect due to all data values being off-scale from 15:58 - 16:20 
GMT.  All T/RH/water vapor measurements incorrect from 16:38 - 16:43 during T/RH probe 
replacement.

• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Relative humidity inside the instrument enclosure(rh)
• Beam 0 Temperature(temp)
• Standard Deviation of wind direction(sd_deg)
• Snow Depth(snow)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Wind Speed(sd_wspd)
• barometric pressure(bar_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Hourly precipitation(precip)
• Snow Depth Sensor(snow_sen)
• Vapor Pressure (kiloPascals)(vap_pres)
• Mean Wind Speed(wspd)
• Standard Deviation of Air Temperature(sd_temp)

• Unit Vector Wind Direction(wdir)
• Hourly precipitation(precip)
• Relative humidity inside the instrument enclosure(rh)
• Snow Depth(snow)
• Mean Wind Speed(wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Relative Humidity(sd_rh)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Wind Speed(sd_wspd)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of wind direction(sd_deg)
• Vapor Pressure (kiloPascals)(vap_pres)
• Beam 0 Temperature(temp)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• barometric pressure(bar_pres)

SGP/SMOS/E7 - Barometric Pressure Incorrect

The 30 minute barometric pressure reading is artificially low due to two 0.00 values being 
used (20:02 & 20:03 GMT) in the averaging period.

• barometric pressure(bar_pres)
• Standard Deviation of Barometric Pressure(sd_bar_pres)

• barometric pressure(bar_pres)
• Standard Deviation of Barometric Pressure(sd_bar_pres)

SGP/EBBR - Incorrect Units for Soil Heat Capacity (cs1, cs2, cs3, cs4, cs5) in 30EBBR 
Header

The units for Soil Heat Capacity (cs1, cs2, cs3, cs4, cs5) in the 
EBBR 30 minute netcdf header have been incorrect from the beginning 
of processing the data into netcdf files.  The correct units are 
MJ/m^3/C.

This does not affect the data quality.

• Soil heat capacity 4(cs4)
• Soil heat capacity 5(cs5)
• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)
• Soil heat capacity 1(cs1)

• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)
• Soil heat capacity 5(cs5)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)

• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)
• Soil heat capacity 5(cs5)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)

• Soil heat capacity 1(cs1)
• Soil heat capacity 4(cs4)
• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)
• Soil heat capacity 5(cs5)

• Soil heat capacity 1(cs1)
• Soil heat capacity 4(cs4)
• Soil heat capacity 5(cs5)
• Soil heat capacity 2(cs2)
• Soil heat capacity 3(cs3)

• Soil heat capacity 4(cs4)
• Soil heat capacity 2(cs2)
• Soil heat capacity 1(cs1)
• Soil heat capacity 3(cs3)
• Soil heat capacity 5(cs5)

• Soil heat capacity 1(cs1)
• Soil heat capacity 4(cs4)
• Soil heat capacity 5(cs5)
• Soil heat capacity 2(cs2)
• Soil heat capacity 3(cs3)

• Soil heat capacity 2(cs2)
• Soil heat capacity 5(cs5)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)
• Soil heat capacity 3(cs3)

• Soil heat capacity 1(cs1)
• Soil heat capacity 5(cs5)
• Soil heat capacity 2(cs2)
• Soil heat capacity 3(cs3)
• Soil heat capacity 4(cs4)

• Soil heat capacity 2(cs2)
• Soil heat capacity 3(cs3)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)
• Soil heat capacity 5(cs5)

• Soil heat capacity 5(cs5)
• Soil heat capacity 3(cs3)
• Soil heat capacity 4(cs4)
• Soil heat capacity 1(cs1)
• Soil heat capacity 2(cs2)

• Soil heat capacity 3(cs3)
• Soil heat capacity 1(cs1)
• Soil heat capacity 4(cs4)
• Soil heat capacity 5(cs5)
• Soil heat capacity 2(cs2)

• Soil heat capacity 5(cs5)
• Soil heat capacity 3(cs3)
• Soil heat capacity 4(cs4)
• Soil heat capacity 2(cs2)
• Soil heat capacity 1(cs1)

SGP/EBBR/E15 - REPROCESS: Soil Moisture #1 Offset

The wrong offset (9.5264) was used in the calibration coefficients for
Soil Moisture Probe #1. The correct offset is 0.95264.

Sensible and Latent Heat Flux measurements are not significantly affected.

• volumetric soil moisture, site 1(sm1)

• volumetric soil moisture, site 1(sm1)

SGP/EBBR/E15 - Wind Direction 10 Degrees Low

The wind direction at E15 EBBR was 10 degrees low for the period (since
installation of the EBBR unit on 10/11/01). The wind direction sensor was apparently 
aligned to magnetic north instead of true north at installation.

• Wind direction (relative to true north)(mv_wind_d)

• wind direction (relative to true north)(wind_d)

• wind direction (relative to true north)(wind_d)

• wind direction (relative to true north)(wind_d)

• Wind direction (relative to true north)(mv_wind_d)

SGP/EBBR/E19 - Metadata errors

The latitude, longitude and altitude of the El Reno (E19) site were
incorrectly entered into the ARM database.  The correct location
of the EBBR.E19 instrument is:
    Lat: 35.557N
    Lon: 98.017W
    Alt:    421m

• lat(lat)
• Dummy altitude for Zeb(alt)
• lon(lon)

• Dummy altitude for Zeb(alt)
• lat(lat)
• lon(lon)

• Dummy altitude for Zeb(alt)
• lon(lon)
• lat(lat)

SGP/EBBR/E15 - Soil Moisture Coefficients Incorrect

The soil Moisture coefficients used for E15 were incorrect from the time of
installation of the system in program version 8.  On 9 July 02 parameter 4  (an offset 
value) of program step 136 was changed from 9.5264 to the correct value 0.95264 (this error 
had been made by the vendor). The error masked the real problem (wrong soil type) and 
after 9 July 02 resulted in very low soil moisture measurements.  The coefficients used were 
for coarse sand.  On 28 Sep 04 I visited the E15 site and found the soil type a fine 
sandy clay or fine sandy loam.  I changed the coefficients  at 1509 GMT to those for a very 
fine sandy loam; this produced reasonable soil moistures for the soil type.

The old coefficients in parameters 4 through 9 for step 136 of the program were: 0.95264, 
-6.7859, 36.224, -58.619, 25.073, 4.2278

The new coefficients are: 10.241, -27.943, 49.523, -12.648, -52.643, 38.054

• volumetric soil moisture, site 3(sm3)
• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 3(ces3)
• 0-5 cm change in soil heat storage with time, site 4(ces4)
• volumetric soil moisture, site 2(sm2)
• soil heat flow, site 2(g2)
• latent heat flux(e)
• volumetric soil moisture, site 1(sm1)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• soil heat flow, site 1(g1)
• 0-5 cm change in soil heat storage with time, site 2(ces1)
• soil heat flow, site 5(g5)
• average surface soil heat flow(ave_shf)
• volumetric soil moisture, site 4(sm4)
• 0-5 cm change in soil heat storage with time, site 2(ces2)
• h(h)
• soil heat flow, site 4(g4)
• volumetric soil moisture, site 5(sm5)

SGP/SMOS/E4 - Reprocess: Wind direction offset

When the SGP.E4 SMOS tower was installed it was not aligned
properly resulting in a 7 degree offset.  On 3/9/05, the
datalogger program was modifed to correct for this offset.

• Unit Vector Wind Direction(wdir)

• Unit Vector Wind Direction(wdir)

SGP/SMOS/E3 - Reprocess: Wind direction offset

When the SGP.E3 SMOS tower was installed it was not aligned
properly resulting in a 7 degree offset.  On 3/9/05, the 
datalogger program was modified to correct for this offset.

• Unit Vector Wind Direction(wdir)

• Unit Vector Wind Direction(wdir)

SGP/SMOS/E6 - Reprocess: Wind direction offset

When the SGP.E6 SMOS tower was installed it was not aligned
properly resulting in a 7 degree offset.  On 3/10/05, the
datalogger program was modified to correct for this offset.

• Unit Vector Wind Direction(wdir)

• Unit Vector Wind Direction(wdir)

SGP/SMOS/E7 - Reprocess: Wind direction offset

When the SGP.E7 SMOS tower was installed it was not aligned
properly resulting in a 6 degree offset.  On 3/08/05, the
datalogger program was modified to correct for this offset.

• Unit Vector Wind Direction(wdir)

• Unit Vector Wind Direction(wdir)

SGP/EBBR/E13 - Improved EBBR CR10 Program

Effective 20050331.2100, the EBBR.E13 CR10 program was revised to improve the quality of 
the primary measurements as follows:

1) An RMS procedure is used to determine max and min limits of acceptable soil heat flow.  
This is applied to the individual soil sets.  Measurements outside the limits are 
rejected and the measurements within the limits are used to calculate the average soil heat flow.

2) Max and min limits are used to determine incorrect values of net radiation, sensible 
heat flux (h), latent heat flux (e), and automatic exchange mechanism (AEM) signal.  If AEM 
signal is outside the limits, h and e are set to 999s.  If net radiation is outside the 
limits, h and e are set to 999s. If h or e are outside the limits, h and e are set to 999s.

Virtually no incorrect soil measurement will affect the primary measurements of h and e.

By setting h and e to 999s, it can be easily seen that the primary variables are 
incorrect; no other interpretation is possible.

Prior to 20050331, the improved CR10 program was NOT in effect.  DQRs have been submitted 
for known instances of incorrect soil measurements which affected the quality of the 
primary measurements of h and e.

Note: the DQR begin date is the begin date of the sgp30ebbrE13.b1 data stream.  The 
earlier version of the CR10 program was also used on previous EBBR datastream names (e.g. 
sgp30ebbrE13.a1).

• average surface soil heat flow(ave_shf)
• latent heat flux(e)
• h(h)

SGP/EBBR/E15 - Improved EBBR CR10 Program

Effective 20050329.1900, the EBBR.E15 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050329, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE15.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE15.a1).

• latent heat flux(e)
• average surface soil heat flow(ave_shf)
• h(h)

SGP/EBBR/E18 - Improved EBBR CR10 Program

Effective 20050330.0000, the EBBR.E18 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050330, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE18.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE18.a1).

• latent heat flux(e)
• h(h)
• average surface soil heat flow(ave_shf)

SGP/EBBR/E19 - Improved EBBR CR10 Program

Effective 20050331.1600, the EBBR.E19 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050331, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE19.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE19.a1).

• average surface soil heat flow(ave_shf)
• h(h)
• latent heat flux(e)

SGP/EBBR/E20 - Improved EBBR CR10 Program

Effective 20050330.1900, the EBBR.E20 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050330, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE20.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE20.a1).

• average surface soil heat flow(ave_shf)
• latent heat flux(e)
• h(h)

SGP/EBBR/E22 - Improved EBBR CR10 Program

Effective 20050330.1930, the EBBR.E20 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050330, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE20.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE20.a1).

• h(h)
• average surface soil heat flow(ave_shf)
• latent heat flux(e)

SGP/EBBR/E26 - Improved EBBR CR10 Program

Effective 20050331.1700, the EBBR.E26 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050331, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE26.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE26.a1).
~

• latent heat flux(e)
• h(h)
• average surface soil heat flow(ave_shf)

SGP/EBBR/E2 - Improved EBBR CR10 Program

Effective 20050324.1700, the EBBR.E2 CR10 program was revised to improve the quality of 
the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h and e are set to 
999s.  If net radiation is outside the limits, h and e are set to 999s. If h or e are 
outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary variables are 
incorrect; no other interpretation is possible.
   
Prior to 20050324, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE2.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE2.a1).

• average surface soil heat flow(ave_shf)
• h(h)
• latent heat flux(e)

SGP/EBBR/E4 - Improved EBBR CR10 Program

Effective 20050323.1800, the EBBR.E4 CR10 program was revised to improve the quality of 
the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h and e are set to 
999s.  If net radiation is outside the limits, h and e are set to 999s. If h or e are 
outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary variables are 
incorrect; no other interpretation is possible.
   
Prior to 20050323, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE4.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE4.a1).

• h(h)
• average surface soil heat flow(ave_shf)
• latent heat flux(e)

SGP/EBBR/E7 - Improved EBBR CR10 Program

Effective 20050322.1900, the EBBR.E7 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050322, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE7.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE7.a1).

• average surface soil heat flow(ave_shf)
• h(h)
• latent heat flux(e)

SGP/EBBR/E8 - Improved EBBR CR10 Program

Effective 20050322.1730, the EBBR.E8 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050322, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE8.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE8.a1).

• average surface soil heat flow(ave_shf)
• latent heat flux(e)
• h(h)

SGP/EBBR/E9 - Improved EBBR CR10 Program

Effective 20050322.1600, the EBBR.E9 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050322, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE9.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE9.a1).

• latent heat flux(e)
• average surface soil heat flow(ave_shf)
• h(h)

SGP/EBBR/E12 - Improved EBBR CR10 Program

Effective 20050329.1830, the EBBR.E12 CR10 program was revised to improve 
the quality of the primary measurements as follows:
   
1) An RMS procedure is used to determine max and min limits of acceptable
soil heat flow.  This is applied to the individual soil sets.  Measurements
outside the limits are rejected and the measurements within the limits are
used to calculate the average soil heat flow.
   
2) Max and min limits are used to determine incorrect values of net
radiation, sensible heat flux (h), latent heat flux (e), and automatic
exchange mechanism (AEM) signal.  If AEM signal is outside the limits, h 
and e are set to 999s.  If net radiation is outside the limits, h and e are 
set to 999s. If h or e are outside the limits, h and e are set to 999s.
   
Virtually no incorrect soil measurement will affect the primary 
measurements of h and e.
   
By setting h and e to 999s, it can be easily seen that the primary 
variables are incorrect; no other interpretation is possible.
   
Prior to 20050329, the improved CR10 program was NOT in effect.  DQRs have
been submitted for known instances of incorrect soil measurements which
affected the quality of the primary measurements of h and e.
   
Note: the DQR begin date is the begin date of the sgp30ebbrE12.b1 data
stream.  The earlier version of the CR10 program was also used on previous
EBBR datastream names (e.g. sgp30ebbrE12.a1).

• latent heat flux(e)
• average surface soil heat flow(ave_shf)
• h(h)

SGP/SMOS/E1 - Missing data

Data are missing and unrecoverable.

• Beam 0 Temperature(temp)
• Time offset of tweaks from base_time(time_offset)
• Relative humidity inside the instrument enclosure(rh)
• Dummy altitude for Zeb(alt)
• base time(base_time)
• Unit Vector Wind Direction(wdir)
• Mean Wind Speed(wspd)
• Hourly precipitation(precip)
• Vapor Pressure (kiloPascals)(vap_pres)
• lon(lon)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Wind Speed (vector averaged)(wspd_va)
• lat(lat)

• Batter Voltage(vbat)
• Dummy altitude for Zeb(alt)
• Standard Deviation of Wind Speed(sd_wspd)
• lon(lon)
• Relative humidity inside the instrument enclosure(rh)
• Time offset of tweaks from base_time(time_offset)
• Snow Depth Sensor(snow_sen)
• Hourly precipitation(precip)
• base time(base_time)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Air Temperature(sd_temp)
• Snow Depth(snow)
• barometric pressure(bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• Mean Wind Speed(wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• lat(lat)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Relative Humidity(sd_rh)
• Beam 0 Temperature(temp)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Standard Deviation of wind direction(sd_deg)

• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Minimum Relative Humidity(min_rh)
• Time of Maximum Temperature(time_max_temp)
• Time of Maximum Snow Depth(time_max_snow)
• lon(lon)
• Time offset of tweaks from base_time(time_offset)
• Minimum Vapor Pressure(min_vap_pres)
• Minimum Snow Depth(min_snow_depth)
• Time of Minimum Snow Depth(time_min_snow)
• Dummy altitude for Zeb(alt)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Minimum Relative Humidity(time_min_rh)
• maximum wind speed (gusts)(max_wspd)
• base time(base_time)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Time of Maximum Relative Humidity(time_max_rh)
• Time of Minimum Temperature(time_min_temp)
• Minimum Barometric Pressure(min_bar_pres)
• lat(lat)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Maximum Snow Depth(max_snow)
• Maximum Barometric Pressure(max_bar_pres)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• Maximum Relative Humidity(max_rh)
• Minimum Temperature(min_temp)
• Minimum of Wind speed(min_wspd)
• Maximum Vapor Pressure(max_vap_pres)
• Maximum Temperature(max_temp)
• Time of Minimum Wind Speed(time_min_wspd)

SGP/SMOS/E3 - Missing data

Data are missing and unrecoverable

• Wind Speed (vector averaged)(wspd_va)
• lat(lat)
• lon(lon)
• barometric pressure(bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• base time(base_time)
• Standard Deviation of wind direction(sd_deg)
• Hourly precipitation(precip)
• Relative humidity inside the instrument enclosure(rh)
• Dummy altitude for Zeb(alt)
• Time offset of tweaks from base_time(time_offset)
• Beam 0 Temperature(temp)
• Unit Vector Wind Direction(wdir)
• Mean Wind Speed(wspd)

• Minimum Vapor Pressure(min_vap_pres)
• Time of Minimum Relative Humidity(time_min_rh)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Minimum Wind Speed(time_min_wspd)
• lon(lon)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• base time(base_time)
• Minimum Snow Depth(min_snow_depth)
• Minimum Relative Humidity(min_rh)
• Time offset of tweaks from base_time(time_offset)
• Time of Minimum Snow Depth(time_min_snow)
• maximum wind speed (gusts)(max_wspd)
• lat(lat)
• Time of Maximum Snow Depth(time_max_snow)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Maximum Snow Depth(max_snow)
• Time of Maximum Relative Humidity(time_max_rh)
• Minimum Barometric Pressure(min_bar_pres)
• Maximum Barometric Pressure(max_bar_pres)
• Minimum Temperature(min_temp)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• Time of Maximum Temperature(time_max_temp)
• Maximum Temperature(max_temp)
• Time of Minimum Temperature(time_min_temp)
• Dummy altitude for Zeb(alt)
• Maximum Relative Humidity(max_rh)
• Minimum of Wind speed(min_wspd)
• Maximum Vapor Pressure(max_vap_pres)
• Time of Maximum Barometric Pressure(time_max_bar_pres)

• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Unit Vector Wind Direction(wdir)
• Wind Speed (vector averaged)(wspd_va)
• Batter Voltage(vbat)
• Snow Depth Sensor(snow_sen)
• lat(lat)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Mean Wind Speed(wspd)
• base time(base_time)
• Standard Deviation of Relative Humidity(sd_rh)
• Standard Deviation of Air Temperature(sd_temp)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Hourly precipitation(precip)
• Snow Depth(snow)
• Standard Deviation of Wind Speed(sd_wspd)
• Beam 0 Temperature(temp)
• Dummy altitude for Zeb(alt)
• Relative humidity inside the instrument enclosure(rh)
• lon(lon)
• Time offset of tweaks from base_time(time_offset)

SGP/SMOS/E8 - Missing Data

Data are missing and unrecoverable.

• base time(base_time)
• Wind Speed (vector averaged)(wspd_va)
• Dummy altitude for Zeb(alt)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• lon(lon)
• Time offset of tweaks from base_time(time_offset)
• lat(lat)
• Snow Depth(snow)
• Standard Deviation of wind direction(sd_deg)
• Beam 0 Temperature(temp)
• Hourly precipitation(precip)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Wind Speed(sd_wspd)
• Mean Wind Speed(wspd)
• Snow Depth Sensor(snow_sen)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Relative Humidity(sd_rh)
• Batter Voltage(vbat)
• Unit Vector Wind Direction(wdir)
• barometric pressure(bar_pres)

• Mean Wind Speed(wspd)
• lon(lon)
• Relative humidity inside the instrument enclosure(rh)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of wind direction(sd_deg)
• Unit Vector Wind Direction(wdir)
• Hourly precipitation(precip)
• barometric pressure(bar_pres)
• Time offset of tweaks from base_time(time_offset)
• Dummy altitude for Zeb(alt)
• Wind Speed (vector averaged)(wspd_va)
• lat(lat)
• Beam 0 Temperature(temp)
• base time(base_time)

• lat(lat)
• Minimum Temperature(min_temp)
• Minimum Vapor Pressure(min_vap_pres)
• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Maximum Relative Humidity(max_rh)
• Minimum Barometric Pressure(min_bar_pres)
• Dummy altitude for Zeb(alt)
• Minimum Snow Depth(min_snow_depth)
• Time of Maximum Relative Humidity(time_max_rh)
• Time of Minimum Relative Humidity(time_min_rh)
• Time offset of tweaks from base_time(time_offset)
• Minimum of Wind speed(min_wspd)
• Time of Minimum Snow Depth(time_min_snow)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Time of Minimum Temperature(time_min_temp)
• Maximum Barometric Pressure(max_bar_pres)
• Time of Minimum Wind Speed(time_min_wspd)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Maximum Temperature(time_max_temp)
• lon(lon)
• Time of Maximum Snow Depth(time_max_snow)
• Maximum Vapor Pressure(max_vap_pres)
• base time(base_time)
• maximum wind speed (gusts)(max_wspd)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Maximum Temperature(max_temp)
• Maximum Snow Depth(max_snow)
• Minimum Relative Humidity(min_rh)
• Time of Minimum Barometric Pressure(time_min_bar_pres)

SGP/SMOS/E11 - Missing Data

Data are missing and unrecoverable

• Wind Speed (vector averaged)(wspd_va)
• Time offset of tweaks from base_time(time_offset)
• Hourly precipitation(precip)
• Relative humidity inside the instrument enclosure(rh)
• Dummy altitude for Zeb(alt)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• lon(lon)
• Unit Vector Wind Direction(wdir)
• Beam 0 Temperature(temp)
• base time(base_time)
• Mean Wind Speed(wspd)
• lat(lat)

• Time offset of tweaks from base_time(time_offset)
• Minimum Relative Humidity(min_rh)
• Maximum Snow Depth(max_snow)
• base time(base_time)
• Time of Minimum Relative Humidity(time_min_rh)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Minimum Temperature(min_temp)
• Minimum Barometric Pressure(min_bar_pres)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Time of Minimum Wind Speed(time_min_wspd)
• Minimum Vapor Pressure(min_vap_pres)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• Maximum Barometric Pressure(max_bar_pres)
• Maximum Relative Humidity(max_rh)
• Dummy altitude for Zeb(alt)
• Time of Minimum Snow Depth(time_min_snow)
• Maximum Temperature(max_temp)
• Minimum Snow Depth(min_snow_depth)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Maximum Temperature(time_max_temp)
• lon(lon)
• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Time of Minimum Temperature(time_min_temp)
• maximum wind speed (gusts)(max_wspd)
• Minimum of Wind speed(min_wspd)
• Time of Maximum Relative Humidity(time_max_rh)
• Time of Maximum Snow Depth(time_max_snow)
• Maximum Vapor Pressure(max_vap_pres)
• lat(lat)

• Unit Vector Wind Direction(wdir)
• base time(base_time)
• Batter Voltage(vbat)
• Hourly precipitation(precip)
• Relative humidity inside the instrument enclosure(rh)
• Snow Depth(snow)
• Time offset of tweaks from base_time(time_offset)
• Standard Deviation of Relative Humidity(sd_rh)
• Snow Depth Sensor(snow_sen)
• barometric pressure(bar_pres)
• Dummy altitude for Zeb(alt)
• Mean Wind Speed(wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of Wind Speed(sd_wspd)
• lon(lon)
• Standard Deviation of wind direction(sd_deg)
• Beam 0 Temperature(temp)
• Vapor Pressure (kiloPascals)(vap_pres)
• lat(lat)
• Wind Speed (vector averaged)(wspd_va)
• Standard Deviation of Barometric Pressure(sd_bar_pres)

SGP/SMOS/E15 - Missing Data

Data are missing and unrecoverable

• Mean Wind Speed(wspd)
• Dummy altitude for Zeb(alt)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Time offset of tweaks from base_time(time_offset)
• Hourly precipitation(precip)
• lat(lat)
• lon(lon)
• base time(base_time)
• Beam 0 Temperature(temp)
• Unit Vector Wind Direction(wdir)
• Vapor Pressure (kiloPascals)(vap_pres)
• Wind Speed (vector averaged)(wspd_va)

• Time of Minimum Wind Speed(time_min_wspd)
• maximum wind speed (gusts)(max_wspd)
• Time of Maximum Wind Speed(time_max_wspd)
• Maximum Barometric Pressure(max_bar_pres)
• Time of Maximum Snow Depth(time_max_snow)
• Maximum Relative Humidity(max_rh)
• Minimum Barometric Pressure(min_bar_pres)
• Maximum Snow Depth(max_snow)
• Minimum Snow Depth(min_snow_depth)
• base time(base_time)
• Minimum Temperature(min_temp)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• Time offset of tweaks from base_time(time_offset)
• Time of Maximum Relative Humidity(time_max_rh)
• Minimum Vapor Pressure(min_vap_pres)
• Time of Minimum Snow Depth(time_min_snow)
• Minimum of Wind speed(min_wspd)
• Minimum Relative Humidity(min_rh)
• Maximum Temperature(max_temp)
• Time of Minimum Temperature(time_min_temp)
• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Time of Maximum Temperature(time_max_temp)
• Dummy altitude for Zeb(alt)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• lat(lat)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• lon(lon)
• Maximum Vapor Pressure(max_vap_pres)
• Time of Minimum Relative Humidity(time_min_rh)

• lon(lon)
• Batter Voltage(vbat)
• Dummy altitude for Zeb(alt)
• Unit Vector Wind Direction(wdir)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• Beam 0 Temperature(temp)
• Hourly precipitation(precip)
• base time(base_time)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Vapor Pressure (kiloPascals)(vap_pres)
• Standard Deviation of Air Temperature(sd_temp)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of wind direction(sd_deg)
• barometric pressure(bar_pres)
• Mean Wind Speed(wspd)
• Wind Speed (vector averaged)(wspd_va)
• lat(lat)
• Snow Depth(snow)
• Standard Deviation of Relative Humidity(sd_rh)
• Time offset of tweaks from base_time(time_offset)
• Standard Deviation of Wind Speed(sd_wspd)

SGP/SMOS/E24 - Missing Data

Data are missing and unrecoverable

• Time offset of tweaks from base_time(time_offset)
• Vapor Pressure (kiloPascals)(vap_pres)
• Beam 0 Temperature(temp)
• barometric pressure(bar_pres)
• Unit Vector Wind Direction(wdir)
• Dummy altitude for Zeb(alt)
• Wind Speed (vector averaged)(wspd_va)
• Relative humidity inside the instrument enclosure(rh)
• Hourly precipitation(precip)
• lon(lon)
• Standard Deviation of wind direction(sd_deg)
• lat(lat)
• Mean Wind Speed(wspd)
• base time(base_time)

• Vapor Pressure (kiloPascals)(vap_pres)
• Snow Depth Sensor(snow_sen)
• Standard Deviation of Relative Humidity(sd_rh)
• Time offset of tweaks from base_time(time_offset)
• Dummy altitude for Zeb(alt)
• Batter Voltage(vbat)
• Standard Deviation of Barometric Pressure(sd_bar_pres)
• Hourly precipitation(precip)
• Mean Wind Speed(wspd)
• Standard Deviation of Vapor Pressure(sd_vap_pres)
• base time(base_time)
• Relative humidity inside the instrument enclosure(rh)
• Standard Deviation of Wind Speed(sd_wspd)
• barometric pressure(bar_pres)
• Wind Speed (vector averaged)(wspd_va)
• Snow Depth(snow)
• lat(lat)
• Standard Deviation of Air Temperature(sd_temp)
• Standard Deviation of wind direction(sd_deg)
• Unit Vector Wind Direction(wdir)
• lon(lon)
• Beam 0 Temperature(temp)

• Time of Maximum Temperature(time_max_temp)
• Time of Minimum Wind Speed(time_min_wspd)
• Minimum Vapor Pressure(min_vap_pres)
• Minimum Barometric Pressure(min_bar_pres)
• maximum wind speed (gusts)(max_wspd)
• Time of Maximum Relative Humidity(time_max_rh)
• Time of Minimum Vapor Pressure(time_min_vap_pres)
• lat(lat)
• Time of Maximum Vapor Pressure(time_max_vap_pres)
• Minimum Temperature(min_temp)
• base time(base_time)
• Minimum Relative Humidity(min_rh)
• Maximum Snow Depth(max_snow)
• Time offset of tweaks from base_time(time_offset)
• Maximum Vapor Pressure(max_vap_pres)
• Maximum Barometric Pressure(max_bar_pres)
• Time of Minimum Barometric Pressure(time_min_bar_pres)
• Time of Minimum Snow Depth(time_min_snow)
• Time of Minimum Temperature(time_min_temp)
• Time of Maximum Snow Depth(time_max_snow)
• Maximum Temperature(max_temp)
• Maximum Relative Humidity(max_rh)
• Minimum of Wind speed(min_wspd)
• Dummy altitude for Zeb(alt)
• lon(lon)
• Time of Maximum Barometric Pressure(time_max_bar_pres)
• Time of Maximum Wind Speed(time_max_wspd)
• Time of Minimum Relative Humidity(time_min_rh)
• Minimum Snow Depth(min_snow_depth)