SGP/EBBR - EBBR E9 Anemometer Frozen, Wind Speed Incorrect

The anemometer cups were frozen stalled.

The following values were therefore incorrect:

5 minute:  wind_s, res_ws
15 minute: wind_s
30 minute: wind_s, res_ws

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR - EBBR E9 Net Radiation Incorrect

The net radiometer top dome was broken and water had entered.  Net 
radiation values are therefore incorrect during the period.

The affected data are:

5 minute:  q
15 minute: mv_q
30 minute: q, h, e

• net radiation(q)

• Net radiation(mv_q)

• net radiation(q)
• h(h)
• latent heat flux(e)

SGP/EBBR/E9 - E9 EBBR Wind Direction Incorrect

The wind direction vane was frozen in one direction by icing during the indicated period.

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

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

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

SGP/EBBR/E9 - E9 EBBR Wind Speed Incorrect

The wind speed sensor cups were frozen in place by icing.

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - E9 EBBR Soil Heat Flow 1 Incorrect

Soil Heat flow sensor #1 produced measurements that were large negative during the 
indicated period.  This was the result of sensor failure.

• Soil heat flow 1(mv_hft1)

• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• h(h)
• 5 cm soil heat flow, site 1(shf1)
• soil heat flow, site 1(g1)
• average surface soil heat flow(ave_shf)
• latent heat flux(e)

SGP/EBBR/E9 - E9 EBBR Soil Heat Capacities Incorrect

Soil Heat Capacities were out-of-range during this period, as reported by
the datalogger. The cause of this is unknown.

Actual values used in the computations of fluxes were okay, as the fluxes were not 
affected.

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

SGP EBBR E9 - E9 EBBR Data Incorect During 6 Month Checks

The data was incorrect during the 6 month checks.

• 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)
• 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)
• 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)
• 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)
• 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)
• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 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)

• vector wind speed(res_ws)
• 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)
• Soil temperature 2(rr_ts2)
• 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)
• 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)
• net radiation(q)
• 5 cm soil heat flow corrected for soil moisture content, site 3(c_shf3)
• 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)
• 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 E9 - E9 EBBR AEM Hung, Data Incorrect

A worn AEM belt caused the AEM to hang frequently.
Gradient measurements, sensible heat flux, latent heat flux,
and Bowen ratio are incorrect during the indicated periods.

The AEM hung on 2/9/01 because of icing from an ice storm.

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP EBBR E9 - E9 EBBR AEM Hung, Data Incorrect

The AEM belt was worn and the AEM hung frequently.
Gradients, sensible heat flux, latent heat flux,
and Bowen ratio were incorrect during the indicated period.

The AEM was replaced during the recalibration changeout
on 5/11/01.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP EBBR E9 - E9 EBBR Wind Speed Frozen Stopped

An ice storm froze the wind speed sensor to a stop.

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP EBBR E9 - E9 EBBR Wind Direction Frozen In One Direction

An ice storm froze the wind direction sensor in one postion.
Th indicated measurements are incorrect.

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

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

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

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

Soil moisture probe #5 in the recalibrated unit installed
on 5/11/01 has not been working all of the time.  At times
the measurement has been very large and incorrect.  The
indicated measurements are incorrect at those times.  The
data must be inspected to determine the times that 
have incorrect data.  The sensible and latent heat fluxes can
be recalculated by using soil sets 1, 2, 3, and 4 only in a 
recalculation of the energy budget.

• Soil temperature 5(rr_ts5)

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

• Soil temperature 5(rr_ts5)

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

SGP EBBR E9 - E9 EBBR Gradients Incorrect During Sensor Replacement

During the replacement of the right air temperature
probe, all gradient measurements were incorrect.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP EBBR E9 - E9 EBBR Right Air Temperature Incorrect

The right air temperature probe measurements were
incorrect during these periods.

• Right air temperature(tair_r)

• latent heat flux(e)
• h(h)
• top air temperature(tair_top)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)
• bottom air temperature(tair_bot)

• top air temperature(tair_top)
• bottom air temperature(tair_bot)

• Right air temperature(tair_r)

• bottom air temperature(tair_bot)
• latent heat flux(e)
• top air temperature(tair_top)
• h(h)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)

SGP/EBBR/E9 - 6 Month Checks

The indicated measurements were incorrect during the 6 month checks.

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

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

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

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

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

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/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/E9 - Humidity Probe Measurements Incorrect

The temperature and humidity measurements from both T/RH probes were incorrect during 
changeout of the right probe.

• Bottom humidity(hum_bot)
• latent heat flux(e)
• Temperature of the top humidity chamber(thum_top)
• bottom vapor pressure(vp_bot)
• Top humidity(hum_top)
• h(h)
• Temperature of bottom humidity sensor chamber(thum_bot)
• top vapor pressure(vp_top)

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

• bottom vapor pressure(vp_bot)
• latent heat flux(e)
• Temperature of the top humidity chamber(thum_top)
• h(h)
• Bottom humidity(hum_bot)
• Top humidity(hum_top)
• top vapor pressure(vp_top)
• Temperature of bottom humidity sensor chamber(thum_bot)

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 - 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 - 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.

(NOTE: The actual begin date of some of these data streams
 is as early as 7/4/93.  This DQR applies to all 30m EBBR
 data.)

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

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

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

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

• 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 1(cs1)
• Soil heat capacity 3(cs3)
• Soil heat capacity 2(cs2)

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

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

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

SGP/EBBR/E9 - Data Incorrect during 6 month checks

Some of the measurements are incorrect during the 6 month checks.

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

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

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

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

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

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

Soil Temperature #5 was intermittently incorrect.
The cause is unknown. The indicated measurements 
that are calculated using soil temperature are 
also incorrect.

• 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/E9 - REPROCESS: Soil Heat Flow #4 Incorrect

Soil Heat Flow #4 was incorrect during these periods as a 
consequence of the repair of Soil Temperature #5.  
See below for a work-around.

• latent heat flux(e)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• 5 cm soil heat flow, site 4(shf4)
• average surface soil heat flow(ave_shf)
• h(h)
• soil heat flow, site 4(g4)

• soil heat flow, site 4(g4)
• h(h)
• 5 cm soil heat flow corrected for soil moisture content, site 4(c_shf4)
• average surface soil heat flow(ave_shf)
• 5 cm soil heat flow, site 4(shf4)
• latent heat flux(e)

SGP/EBBR/E9 - Net Rad data bad during dome replacement

The net radiation measurement was incorrect during replacement
of the top dome. Measurements calculated using net radiation are also incorrect.

• Net radiation(mv_q)

• latent heat flux(e)
• h(h)
• net radiation(q)

• net radiation(q)

• Net radiation(mv_q)

• net radiation(q)
• h(h)
• latent heat flux(e)

SGP/EBBR/E9 - AEM Malfunction

When the AEM (Automatic Exchange Mechanism) is hung 
inbetween a home position, the gradients of temperature and 
relative humidity, and thus sensible and latent heat fluxes, 
are incorrect.

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

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

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

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

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

SGP/EBBR/E9  - AEM Hung Inbetween Home Positions

The AEM was hung inbetween home positions, causing many measurements to be incorrect.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9  - 6 Month Checks

Many measurements were incorrect while the AEM was positioned with both aspirators at the 
same height for comparison checks.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9  - Soil Heat Flow #1 Incorrect

Soil Heat Flow #1 was incorrect.

• Soil heat flow 1(mv_hft1)

• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• soil heat flow, site 1(g1)
• latent heat flux(e)
• h(h)
• 5 cm soil heat flow, site 1(shf1)
• average surface soil heat flow(ave_shf)

• Soil heat flow 1(mv_hft1)

• 5 cm soil heat flow corrected for soil moisture content, site 1(c_shf1)
• soil heat flow, site 1(g1)
• average surface soil heat flow(ave_shf)
• latent heat flux(e)
• h(h)
• 5 cm soil heat flow, site 1(shf1)

SGP/EBBR/E9 -   Battery Voltage Low

Many of the measurements are incorrect much of the time during this period,
when the battery voltage was 10.9 volts or less.

• 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)
• 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)
• soil heat flow, site 3(g3)
• 0-5 cm change in soil heat storage with time, site 5(ces5)
• 5 cm soil heat flow corrected for soil moisture content, site 2(c_shf2)
• 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)

• 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)
• 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/E9 - AEM Hung in home 30 position.

The AEM was hung in the home 30 position.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9  - Water in Net Radiometer; Surface Fluxes are Incorrect

The net radiometer top dome was punctured by migrating birds.  This alone does not cause 
incorrect net radiation measurements.  However, when it subsequently rains, water collects 
in the bottom dome, causing the net radiation measurements to be too large during the 
day and too small at night.

• Net radiation(mv_q)

• latent heat flux(e)
• h(h)
• net radiation(q)

• net radiation(q)

• Net radiation(mv_q)

• net radiation(q)
• h(h)
• latent heat flux(e)

SGP/EBBR/E9  - Measurements All Zero

Data values were all zero after restarting the CR10 datalogger.

• 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)

• 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/E9 - 6 Month Checks

Many measurements were incorrect while the AEM was positioned with both aspirators at the 
same height for comparison checks.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

SGP/EBBR/E9  - Net Radiometer Iced Over During Storm

The net radiometer was covered with ice from a storm.  Net radiation values are incorrect, 
and are sometimes even negative during the daytime.  Sensible and latent heat fluxes are 
therefore incorrect.

• Net radiation(mv_q)

• net radiation(q)

• latent heat flux(e)
• h(h)
• net radiation(q)

SGP/EBBR/E9 - Wind Speed Sensor Frozen By Ice Storm

The wind speed sensor was frozen stopped by ice from a storm.  The wind speed 
and residual wind speed measurements are incorrect.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9  - Wind Speed Frozen Stopped By Ice

An ice storm froze the wind speed sensor to a stopped condition. The bearings
in the sensor appear to be worn, contributing to the problem.

The wind speed and residual wind speed measurements are incorrect.

This sensor failure does not affect the sensible and latent heat fluxes.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9  - Wind Direction Frozen Stopped By Ice

The wind direction sensor was frozen stopped by ice from a storm.  
The wind direction, sigma_wd, and residual wind speed measurements 
are incorrect.

• wind direction (relative to true north)(wind_d)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 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/EBBR/E9 - net radiometer top dome broken, water in bottom dome

The Net radiometer top dome was broken.  Site Ops did not indicate that there
was water in the bottom dome, but the data suggests it.  Net radiation values during the 
period are incorrect.

• net radiation(q)

• latent heat flux(e)
• h(h)
• net radiation(q)

SGP/EBBR/E9 - 6 Month Checks

Many measurements were incorrect while the AEM was positioned with both aspirators at the 
same height for comparison checks.

• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Left air temperature(tair_l)

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

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

SGP/EBBR/E9 - Wind Speed Threshhold Low

When the wind speed is very low, the anemometer cups stop turning.  Wind
speeds above the threshhold may be underestimated.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9  - Wind Speed Frozen Stopped By Ice Storm

An ice storm froze the wind speed sensor to a stopped condition.

The wind speed and residual wind speed measurements are incorrect.

This sensor failure does not affect the sensible and latent heat fluxes.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9  - Wind Direction Frozen Stopped By Ice Storm

The wind direction sensor was frozen stopped by ice from a storm.  
The wind direction, sigma_wd, and residual wind speed measurements 
are incorrect.

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

• wind direction (relative to true north)(wind_d)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 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/EBBR/E9  - Wind Direction Frozen Stopped By Ice

The wind direction sensor was frozen stopped by ice from a storm.  
The wind direction, sigma_wd, and residual wind speed measurements 
are incorrect.

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

• wind direction (relative to true north)(wind_d)
• standard deviation of wind direction (sigma theta)(sigma_wd)
• 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/EBBR/E9  - Wind Speed Frozen Stopped By Ice

An ice storm froze the wind speed sensor to a stopped condition.

The wind speed and residual wind speed measurements are incorrect.

This sensor failure does not affect the sensible and latent heat fluxes.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9 - Soil moisture too high

The 15 and 30 minute data for sm3 indicated that there was a problem with the sensor that 
kept the soil moisture artificially high.  This corrected itself on 6/11, but it is not 
clear why. 

A new sensor was installed on 6/17 and it has behaved well since then.

• Soil moisture 3(r_sm3)

• volumetric soil moisture, site 3(sm3)

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/E9 - Net Radiation Incorrect: Sensible and Latent Heat Fluxes Incorrect

Water had entered the top of the net radiometer during the rain on 10/31 early morning.  
The net radiation, and thus sensible and latent heat fluxes were incorreect during the 
stated period.

• Net radiation(mv_q)

• net radiation(q)

• latent heat flux(e)
• h(h)
• net radiation(q)

SGP/EBBR/E9 - Average Soil Heat Flux Incorrect

A typo in the version 9 EBBR program caused average soil heat flow to be zero, resulting 
in both sensible and latent heat fluxes being approximately 20 watts per meter squared too 
large during the middle of the day.

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

SGP/EBBR/E9 - metadata corrections

On 20050420, a series of metadata corrections and additions were completed.  These 
metadata changes apply to all EBBR.E9 data collected by ARM back to the installation of the 
instrument in December 1992. Please see the current metadata for correct information.  These 
changes do not affect data values or quality.	

The changes are summarized below:
1) Update of "sensor location" information
2) Addition of installation dates for the systems
3) Correction of soil moisture units (from "by volume" to "gravimetric")

• base time(base_time)

• base time(base_time)

• base time(base_time)

SGP/EBBR/E9 - Net Radiation, Sensible and Latent Heat Fluxes Incorrect

The top dome of the net radiometer was broken, resulting in net radiations that were too 
small, and thus sensible and latent heat fluxes that were too small.

• Net radiation(mv_q)

• net radiation(q)

• latent heat flux(e)
• h(h)
• net radiation(q)

SGP/EBBR/E9 - Wind Speed Incorrect

The wind speed measurement was incorrect after the cup anemometer lost a cup.

• scalar wind speed(wind_s)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

SGP/EBBR/E9 - Net Radiation Incorrect

There was water in the net radiometer.  

The net radiation data was incorrect.

• Net radiation(mv_q)

• net radiation(q)

• latent heat flux(e)
• h(h)
• net radiation(q)

SGP/EBBR/E9 - Temperature Portion of T/RH Probe

The Temperature portion of the right T/RH probe indicated too high a 
temperature for nearly 11 months.  I twice placed work requests to have the 
probe replaced, but no spares were available.  Spares recently became 
available and I placed a new work request to have the probe changed.  The 
replacement occurred on 18 June 1997; this fixed the problem.  The main 
results of the high temperatures were probe top and bottom temperatures
(used only for the calculation of vapor pressure) and vapor pressures that 
were too large.  Furthermore, this caused latent heat flux to be reported 
to be too large, and therefore sensible heat flux was reported to be too 
small.  Recalculation of the fluxes using thermocouple temperatures to 
calculate vapor pressure would be quite time consuming and would have to
assume that the thermocouple temperature and probe temperature were nearly 
the same.

The EBBR procedures have been changed to include comparison of the 
thermocouple and probe temperatures to make it easier for the site 
operators to detect this condition.

The data affected (and thus incorrect) includes:

15 minute: rr_thum_r 
30 minute: thum_top, thum_bot, vp_top, vp_bot, e, h, bowen.

• Battery(bat)
• Dummy altitude for Zeb(alt)
• Soil heat flow 3(mv_hft3)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Soil heat flow 4(mv_hft4)
• Soil heat flow 5(mv_hft5)
• lon(lon)
• Soil heat flow 1(mv_hft1)
• Soil heat flow 2(mv_hft2)
• base time(base_time)
• lat(lat)

• bottom vapor pressure(vp_bot)
• latent heat flux(e)
• Temperature of the top humidity chamber(thum_top)
• h(h)
• top vapor pressure(vp_top)
• Temperature of bottom humidity sensor chamber(thum_bot)
• ratio of sensible/latent heat fluxes (Bowen ratio)(bowen)

SGP/EBBR/E9 - EBBR Biannual Checks

During EBBR 6 month checks the Automatic Exchange Mechanism is disabled 
(reflected by home signals near zero) so that the two aspirator units
can be placed at the same height.  The measurements during these periods 
do not produce correct outputs of bowen ratio (bowen), sensible heat flux (h), 
or latent heat flux (e), nor do the air temperature and relative humidity 
measurements indicate correct gradients.  Checks performed before or after the 
AEM is disabled also lead to some incorrect data.  Incorrect 5, 15 minute and 
half hour data occurs for periods indicated.

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9 - Wind Direction Sensor Malfunction

During numerous intermittent times during the period listed, the wind direction
sensor at E9, Ashton, KS malfunctioned, putting out a value of 135.  The
sensor was replaced on 30 September 1997, at 1550 GMT.  All wind direction data
with values of 135 during the period listed should be considered incorrect.
The affected data are:

 5 minute: res_ws, wind_d, sigma_d

15 minute: mv_wind_d

30 minute: res_ws, wind_d, sigma_d

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

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

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

SGP/EBBR/E9 - EBBR Frozen Wind Speed

Wind speed cups were frozen during the indicated time periods. All 5,
15, and 30 minute data values indicated  are incorrect for the periods
listed.

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - EBBR AEMs Not Exchanging (Iced Or Fuse Blown)

The EBBR AEM stopped exchanging because of icing at during this time
period.

The calculations of Bowen ratio, latent heat flux, and sensible heat
flux are incorrect for the time period indicated.  The other
measurements listed  are also incorrect for those times:

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9 - EBBR Net Radiometer Domes Pierced, Water Inside - Data Affected

The upper dome of the EBBR net radiometers was punctured.
After the puncture, water collected in the top and/or bottom dome.  The
water was removed and the dome was replaced during PM visits. 

 In some cases, the puncture and water resulted in incorrect data. 
Comparison with net radiation values from surrounding EBBR sites and the
SIRS is neccesary to determine if the EBBR net radiation data 
are correct or incorrect.

It is often difficult to tell from the data when the punctures occurred,
but they would have existed for no more than 2 weeks, since the domes
are checked during each two-weekly PM visit.

Incorrect net radiation data results in the latent heat flux and
sensible heat flux also being incorrect.

• net radiation(q)

• Net radiation(mv_q)

• net radiation(q)
• h(h)
• latent heat flux(e)

SGP/EBBR/E9 - Wind Speed Sensor Frozen

The wind speed sensor was frozen stalled during this period. 

Data values that were affected are:

 5 minute: wind_s, res_ws
15 minute: wind_s
30 minute: wind_s, res_ws

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• null(Raw data stream - documentation not supported)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - 3-Month Check

During EBBR 3 month checks the Automatic Exchange Mechanism is disabled
(reflected by home signals near zero) so that the two aspirator units can be
placed at the same height.  The measurements during these periods 
do not produce correct outputs of bowen ratio (bowen), sensible heat flux
(h), or latent heat flux (e), nor do the air temperature and relative 
humidity measurements indicate correct gradients.  Checks performed before 
or after the AEM is disabled also lead to some incorrect data.  Incorrect 5,
15 minute and half hour data occurs for the period above.

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9 - Six Month Checks

During EBBR 6 month checks (formally called 3 month checks) the Automatic 
Exchange Mechanism is disabled (reflected by home signals near zero) so that
the two aspirator units can be placed at the same height.  The measurements
during these periods do not produce correct outputs of bowen ratio (bowen), 
sensible heat flux (h), or latent heat flux (e), nor do the air temperature
and relative humidity measurements indicate correct gradients.  Checks 
performed just before or after the AEM is disabled also lead to some 
incorrect data.  Incorrect 5, 15 minute and half hour data occurs for the 
period above.

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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

SGP/EBBR/E9 - Wind Direction Data Incorrect

The wind direction sensor stopped working correctly, resulting in the
following values being affected:

5 minute:  res_ws, wind_d, sigma_wd
15 minute: mv_wind_d
30 minute: res_ws, wind_d, sigma_wd

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

• null(Raw data stream - documentation not supported)

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

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

SGP/EBBR/E9 - EBBR E9 Net Radiometer Dome Broken, Flux Data Incorrect

Incorrect Net Radiation values resulted in incorrect sensible and 
latent heat fluxes. Affected values are:

5 minute:   q
15 minute:  mv_q
30 minute:  q, e, h

• net radiation(q)

• null(Raw data stream - documentation not supported)

• Net radiation(mv_q)

• net radiation(q)
• h(h)
• latent heat flux(e)

SGP/EBBR/E9 - Wind Speed Data Incorrect

The wind speed sensor was iced stopped by freezing rain, 
resulting in the following values being incorrect:

5 minute:  wind_s, res_ws
15 minute: wind_s
30 minute: wind_s, res_ws,

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• null(Raw data stream - documentation not supported)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - Wind Speed Data Incorrect

The wind speed sensor was iced stopped by freezing rain, 
resulting in the following values being incorrect:

5 minute:  wind_s, res_ws
15 minute: wind_s
30 minute: wind_s, res_ws,

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• null(Raw data stream - documentation not supported)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - Wind Speed Incorrect

The wind speed sensor lost two of the three cups.  Flux data is not 
affected.  The data values affected are:

5 minute: wind_s, res_ws
15 minute: wind_s
30 minute: wind_s, res_ws

• scalar wind speed(wind_s)
• vector wind speed(res_ws)

• null(Raw data stream - documentation not supported)

• scalar wind speed(wind_s)

• vector wind speed(res_ws)
• scalar wind speed(wind_s)

SGP/EBBR/E9 - Right Aspirator Not Working

The result of the right aspirator not working was a reduction in measured
temperature gradient and thus a reduction in estimated sensible heat flux
and an increase in latent heat flux.  The fluxes could be in error by as
much as 10%.  Reported right air and humidity probe temperatures, top and 
bottom air and humidity probe temperatures, right relative humidity, and 
top and bottom vapor pressure are affected.

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

• Left air temperature(tair_l)
• Temperature of right humidity sensor chamber(rr_thum_r)
• Right relative humidity(mv_hum_r)
• Temperature of left humidity sensor chamber(rr_thum_l)
• Right air temperature(tair_r)
• Left relative humidity(mv_hum_l)

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