Name |
value |
Principal investigator |
William Massman |
Site name |
GLEES, Wyoming, USA |
Site description |
ENF Evergreen needleleaf forest |
Latitude |
41.3644 |
Longitude |
-106.2394 |
Elevation |
3190 |
crdate |
29AUG2013 |
GLEES, Wyoming, USA |
input files and their date ranges |
Obs |
OrigFile |
mindate |
maxdate |
nrec |
1 |
GLEES_AmeriFlux_2004to2011_v2.3.csv |
10/01/2004 |
12/31/2011 |
127104 |
2 |
GLEES_AmeriFlux_2012_v2.3.csv |
01/01/2012 |
12/31/2012 |
17568 |
GLEES, Wyoming, USA |
variable names and original descriptions |
VarSource=GLEES_AmeriFlux_2004to2011_v2.3.csv-2012,GLEES_AmeriFlux_v2.2a.html |
Obs |
col |
Variable |
Origdesc |
1 |
6 |
TA_fill |
TA = Air Temperature (C) |
2 |
7 |
TA_f |
TA_flag |
3 |
8 |
Tdew_fill |
Tdew = Dew Point Temperature (C) |
4 |
9 |
Tdew_f |
Tdew_flag |
5 |
10 |
RH_fill |
RH = Relative Humidity (%) |
6 |
11 |
RH_f |
RH_flag |
7 |
12 |
VP_fill |
VP = Vapor Pressure (kPa) |
8 |
13 |
VP_f |
VP_flag |
9 |
14 |
SVP_fill |
VPsat = Saturation Vapor Pressure (kPa) |
10 |
15 |
SVP_f |
VPsat_flag |
11 |
16 |
VPD_fill |
VPD = Vapor Pressure Deficit (kPa) |
12 |
17 |
VPD_f |
VPD_flag |
13 |
18 |
H2O_fill |
H2O = Vapor Concentration (mmol mol-1) |
14 |
19 |
H2O_f |
H2O_flag |
15 |
20 |
H2Oden_fill |
DENSH2O = Water Vapor Density (g m-3) |
16 |
21 |
H2Oden_f |
DENSH2O_flag |
17 |
22 |
WS_fill |
WS = Wind Speed (m s-1) |
18 |
23 |
WS_f |
WS_flag |
19 |
24 |
WD_fill |
WD = Wind Direction (deg) |
20 |
25 |
WD_f |
WD_flag |
21 |
26 |
PRESS_fill |
PA = Barometric Pressure (kPa) |
22 |
27 |
PRESS_f |
PA_flag |
23 |
28 |
DryAirDen_fill |
DENSDryAir = Dry Air Density (kg m-3) |
24 |
29 |
DryAirDen_f |
DENSDryAir_flag |
25 |
30 |
WetAirDen_fill |
DENSAir = Air Density (kg m-3) |
26 |
31 |
WetAirDen_f |
DENSAir_flag |
27 |
32 |
CO2_fill |
CO2 = CO2 Concentration (umol mo-1) |
28 |
33 |
CO2_f |
CO2_flag |
29 |
34 |
CO2den_fill |
DENSCO2 = CO2 Density (mg m-3) |
30 |
35 |
CO2den_f |
DENSCO2_flag |
31 |
36 |
Rn_fill |
RNET = Net Radiation (W m-2) |
32 |
37 |
Rn_f |
RNET_flag |
33 |
38 |
Rn__2_fill |
RNET_4way = 4way Net Radiation (W m-2) 4-way Net Radiation is the sum of incoming and outgoing shortwave and longwave radiation |
34 |
39 |
Rn__2_f |
RNET_4way_flag |
35 |
40 |
PAR_fill |
PAR_in = Incoming Photosynthetically Active Radiation (umol m-2 s-1) |
36 |
41 |
PAR_f |
PAR_in_flag |
37 |
42 |
PARout_fill |
PAR_out = Outgoing Photosynthetically Active Radiation(umol m-2 s-1) |
38 |
43 |
PARout_f |
PAR_out_flag |
39 |
44 |
Rg_fill |
Rshort_in = Incoming Shortwave Radiation (W m-2) |
40 |
45 |
Rg_f |
Rshort_in_flag |
41 |
46 |
RgOut_fill |
Rshort_out = Outgoing Shortwave Radiation (W m-2) |
42 |
47 |
RgOut_f |
Rshort_out_flag |
43 |
48 |
Rgl_fill |
Rlong_in = Incoming Longwave Radiation (W m-2) |
44 |
49 |
Rgl_f |
Rlong_in_flag |
45 |
50 |
RglOut_fill |
Rlong_out = Outgoing Longwave Radiation (W m-2) |
46 |
51 |
RglOut_f |
Rlong_out_flag |
47 |
52 |
PREC_fill |
PRECIP = Precipitation (mm) |
48 |
53 |
PREC_f |
PRECIP_flag |
49 |
54 |
UST_fill |
UST = Friction Velocity (m s-1) |
50 |
55 |
UST_f |
UST_flag |
51 |
56 |
TAUxz_fill |
TAU = Momentum Flux (kg m-1 s-2) |
52 |
57 |
TAUxz_f |
TAU_flag |
53 |
58 |
H_fill |
H = Sensible Heat Flux (W m-2) |
54 |
59 |
H_f |
H_flag 1 = filled with sensible heat flux calculated without water vapor flux, 2 = filled with modeled data |
55 |
60 |
FC_fill |
FC = CO2 Flux (umol m-2 s-1) |
56 |
61 |
FC_f |
FC_flag |
57 |
62 |
SFC_fill |
SFC = CO2 canopy storage (umol m-2 s-1) |
58 |
63 |
SFC_f |
SFC_flag n = filled with CO2 canopy storage calculated with n sample tubes missing (n = 1-7), 8 = filled with modeled data |
59 |
64 |
NEE_fill |
NEE = Net ecosystem exchange of CO2 (umol m-2 s-1) |
60 |
65 |
NEE_f |
NEE_flag |
61 |
66 |
FH2O_fill |
FH2O = Water Vapor Flux (mmol m-2 s-1) |
62 |
67 |
FH2O_f |
FH2O_flag |
63 |
68 |
LE_fill |
LE = Latent Heat Flux (W m-2) |
64 |
69 |
LE_f |
LE_flag |
65 |
70 |
ZL_fill |
ZL = Atmospheric Stability Parameter (unitless) |
66 |
71 |
ZL_f |
ZL_flag |
67 |
72 |
WS__2_fill |
WS2_sonic = Sonic Anemometer Wind Speed (m s-1) |
68 |
73 |
WS__2_f |
WS2_sonic_flag |
69 |
74 |
WD__2_fill |
WD2_sonic = Sonic Anemometer Wind Direction (m s-1) |
70 |
75 |
WD__2_f |
WD2_sonic_flag |
71 |
76 |
TAU_fill |
UWcvar = Kinematic Momentum Parallel to Wind Direction (m2 s-2) |
72 |
77 |
TAU_f |
UWcvar_flag |
73 |
78 |
VWcvar_fill |
VWcvar = Kinematic Momentum Perpendicular to Wind Direction (m2 s-2) |
74 |
79 |
VWcvar_f |
VWcvar_flag |
75 |
80 |
TS_fill |
TS_5cm = Soil temperature at 5 cm depth (C) |
76 |
81 |
TS_f |
TS_5cm_flag 1=filled with soil temperature calculated with only 1 sample,2=filled with modeled data,3=filled with soil temperature from GLEES Met Tower |
77 |
82 |
FG_fill |
G_M1_Rep1_Surface = Soil heat flux at site Meadow 1, replicate 1, surface (W m-2) |
78 |
83 |
FG_f |
G_M1_Rep1_Surface_flag |
79 |
84 |
FG__2_fill |
G_M1_Rep2_Surface = Soil heat flux at site Meadow 1, replicate 2, surface (W m-2) |
80 |
85 |
FG__2_f |
G_M2_Rep1_Surface_flag |
81 |
86 |
TS_fill_3 |
TS_M1_Rep1_3cm = Soil temperature at site Meadow 1, replicate 1, 3 cm depth (C) |
82 |
87 |
TS_3_f |
TS_M1_Rep1_3cm_flag |
83 |
88 |
TS_fill_9 |
TS_M1_Rep1_9cm = Soil temperature at site Meadow 1, replicate 1, 9 cm depth (C) |
84 |
89 |
TS_9_f |
TS_M1_Rep1_9cm_flag |
85 |
90 |
TS__2_fill_3 |
TS_M1_Rep2_3cm = Soil temperature at site Meadow 1, replicate 2, 3 cm depth (C) |
86 |
91 |
TS__2_3_f |
TS_M1_Rep2_3cm_flag |
87 |
92 |
TS__2_fill_9 |
TS_M1_Rep2_9cm = Soil temperature at site Meadow 1, replicate 2, 9 cm depth (C) |
88 |
93 |
TS__2_9_f |
TS_M1_Rep2_9cm_flag |
89 |
94 |
FG_fill_9 |
G_M1_Rep1_9cm = Soil heat flux at site Meadow 1, replicate 1, 9 cm depth (W m-2) |
90 |
95 |
FG_9_f |
G_M1_Rep1_9cm_flag |
91 |
96 |
FG__2_fill_9 |
G_M1_Rep2_9cm = Soil heat flux at site Meadow 1, replicate 2, 9 cm depth (W m-2) |
92 |
97 |
FG__2_9_f |
G_M2_Rep1_9cm_flag |
93 |
98 |
TS_fill_5 |
TS_M1_RepNRCS_5cm = Soil temperature at site Meadow 1, replicate NRCS, 5 cm depth (C) |
94 |
99 |
TS_5_f |
TS_M1_RepNRCS_5cm _flag |
95 |
100 |
TS_fill_10 |
TS_M1_RepNRCS_10cm = Soil temperature at site Meadow 1, replicate NRCS, 10 cm depth (C) |
96 |
101 |
TS_10_f |
TS_M1_RepNRCS_10cm _flag |
97 |
102 |
TS_fill_20 |
TS_M1_RepNRCS_20cm = Soil temperature at site Meadow 1, replicate NRCS, 20 cm depth (C) |
98 |
103 |
TS_20_f |
TS_M1_RepNRCS_20cm _flag |
99 |
104 |
TS_fill_50 |
TS_M1_RepNRCS_50cm = Soil temperature at site Meadow 1, replicate NRCS, 50 cm depth (C) |
100 |
105 |
TS_50_f |
TS_M1_RepNRCS_50cm _flag |
101 |
106 |
TS_fill_100 |
TS_M1_RepNRCS_100cm = Soil temperature at site Meadow 1, replicate NRCS, 100 cm depth (C) |
102 |
107 |
TS_100_f |
TS_M1_RepNRCS_100cm _flag |
103 |
108 |
TS__2_fill_5 |
TS_F2_RepNRCS_5cm = Soil temperature at site Fir 2, replicate NRCS, 5 cm depth (C) |
104 |
109 |
TS__2_5_f |
TS_F2_RepNRCS_5cm _flag |
105 |
110 |
TS__2_fill_10 |
TS_F2_RepNRCS_10cm = Soil temperature at site Fir 2, replicate NRCS, 10 cm depth (C) |
106 |
111 |
TS__2_10_f |
TS_F2_RepNRCS_10cm _flag |
107 |
112 |
TS__2_fill_20 |
TS_F2_RepNRCS_20cm = Soil temperature at site Fir 2, replicate NRCS, 20 cm depth (C) |
108 |
113 |
TS__2_20_f |
TS_F2_RepNRCS_20cm _flag |
109 |
114 |
TS__2_fill_50 |
TS_F2_RepNRCS_50cm = Soil temperature at site Fir 2, replicate NRCS, 50 cm depth (C) |
110 |
115 |
TS__2_50_f |
TS_F2_RepNRCS_50cm _flag |
111 |
116 |
TS__2_fill_100 |
TS_F2_RepNRCS_100cm = Soil temperature at site Fir 2, replicate NRCS, 100 cm depth (C) |
112 |
117 |
TS__2_100_f |
TS_F2_RepNRCS_100cm _flag |
113 |
118 |
SWC_fill_5 |
SWC_M1_RepNRCS_5cm = Soil water content at site Meadow 1, replicate NRCS, 5 cm depth (m3 m-3) |
114 |
119 |
SWC_5_f |
SWC_M1_RepNRCS_5cm _flag |
115 |
120 |
SWC_fill_10 |
SWC_M1_RepNRCS_10cm = Soil water content at site Meadow 1, replicate NRCS, 10 cm depth (m3 m-3) |
116 |
121 |
SWC_10_f |
SWC_M1_RepNRCS_10cm _flag |
117 |
122 |
SWC_fill_20 |
SWC_M1_RepNRCS_20cm = Soil water content at site Meadow 1, replicate NRCS, 20 cm depth (m3 m-3) |
118 |
123 |
SWC_20_f |
SWC_M1_RepNRCS_20cm _flag |
119 |
124 |
SWC_fill_50 |
SWC_M1_RepNRCS_50cm = Soil water content at site Meadow 1, replicate NRCS, 50 cm depth (m3 m-3) |
120 |
125 |
SWC_50_f |
SWC_M1_RepNRCS_50cm _flag |
121 |
126 |
SWC_fill_100 |
SWC_M1_RepNRCS_100cm = Soil water content at site Meadow 1, replicate NRCS, 100 cm depth (m3 m-3) |
122 |
127 |
SWC_100_f |
SWC_M1_RepNRCS_100cm _flag |
123 |
128 |
SWC__2_fill_5 |
SWC_F2_RepNRCS_5cm = Soil water content at site Fir 2, replicate NRCS, 5 cm depth (m3 m-3) |
124 |
129 |
SWC__2_5_f |
SWC_F2_RepNRCS_5cm _flag |
125 |
130 |
SWC__2_fill_10 |
SWC_F2_RepNRCS_10cm = Soil water content at site Fir 2, replicate NRCS, 10 cm depth (m3 m-3) |
126 |
131 |
SWC__2_10_f |
SWC_F2_RepNRCS_10cm _flag |
127 |
132 |
SWC__2_fill_20 |
SWC_F2_RepNRCS_20cm = Soil water content at site Fir 2, replicate NRCS, 20 cm depth (m3 m-3) |
128 |
133 |
SWC__2_20_f |
SWC_F2_RepNRCS_20cm _flag |
129 |
134 |
SWC__2_fill_50 |
SWC_F2_RepNRCS_50cm = Soil water content at site Fir 2, replicate NRCS, 50 cm depth (m3 m-3) |
130 |
135 |
SWC__2_50_f |
SWC_F2_RepNRCS_50cm _flag |
131 |
136 |
SWC__2_fill_100 |
SWC_F2_RepNRCS_100cm = Soil water content at site Fir 2, replicate NRCS, 100 cm depth (m3 m-3) |
132 |
137 |
SWC__2_100_f |
SWC_F2_RepNRCS_100cm _flag |
133 |
138 |
SNOWdepth_fill |
SnowDepth = Snow depth (m) |
134 |
139 |
SNOWdepth_f |
SnowDepth_flag |
GLEES, Wyoming, USA |
variable edits |
Obs |
Reset |
1 |
* GLEES reset fg__2_fill to -fg__2_fill, change of sign convention; |
2 |
* GLEES reset fg__2_fill_9 to -fg__2_fill_9, change of sign convention; |
3 |
* GLEES reset fg_fill to -fg_fill, change of sign convention; |
4 |
* GLEES reset fg_fill_9 to -fg_fill_9, change of sign convention; |
GLEES, Wyoming, USA |
number of records reset to missing or other values |
Obs |
variable |
nreset |
1 |
fg__2_fill |
76912 |
2 |
fg__2_fill_9 |
138801 |
3 |
fg_fill |
77329 |
4 |
fg_fill_9 |
137444 |
GLEES, Wyoming, USA |
variable or unit conversions |
Obs |
cline |
1 |
* GLEES convert dryairden_fill from kg/m3 to mol/m3; |
2 |
dryairden_fill = dryairden_fill / 28.97 *1000; |
3 |
* GLEES convert wetairden_fill from kg/m3 to mol/m3; |
4 |
wetairden_fill = wetairden_fill / 28.97 *1000; |
5 |
* GLEES convert h2oden_fill from g/m3 to mmol/m3; |
6 |
h2oden_fill = h2oden_fill / 18.0 * 1000; |
7 |
* GLEES convert co2den_fill from mg/m3 to mmol/m3; |
8 |
co2den_fill = co2den_fill / 44.0; |
9 |
* GLEES convert swc_fill_5 from fraction to percent; |
10 |
swc_fill_5 = swc_fill_5 * 100; |
11 |
* GLEES convert swc_fill_10 from fraction to percent; |
12 |
swc_fill_10 = swc_fill_10 * 100; |
13 |
* GLEES convert swc_fill_20 from fraction to percent; |
14 |
swc_fill_20 = swc_fill_20 * 100; |
15 |
* GLEES convert swc_fill_50 from fraction to percent; |
16 |
swc_fill_50 = swc_fill_50 * 100; |
17 |
* GLEES convert swc_fill_100 from fraction to percent; |
18 |
swc_fill_100 = swc_fill_100 * 100; |
19 |
* GLEES convert swc__2_fill_5 from fraction to percent; |
20 |
swc__2_fill_5 = swc__2_fill_5 * 100; |
21 |
* GLEES convert swc__2_fill_10 from fraction to percent; |
22 |
swc__2_fill_10 = swc__2_fill_10 * 100; |
23 |
* GLEES convert swc__2_fill_20 from fraction to percent; |
24 |
swc__2_fill_20 = swc__2_fill_20 * 100; |
25 |
* GLEES convert swc__2_fill_50 from fraction to percent; |
26 |
swc__2_fill_50 = swc__2_fill_50 * 100; |
27 |
* GLEES convert swc__2_fill_100 from fraction to percent; |
28 |
swc__2_fill_100 = swc__2_fill_100 * 100; |
GLEES, Wyoming, USA |
calculated or derived variables |
Obs |
cline |
1 |
* GLEES calculate ta from ta_fill and ta_f; |
2 |
ta = ifn(ta_f=0, ta_fill, .); |
3 |
* GLEES calculate tdew from tdew_fill and tdew_f; |
4 |
tdew = ifn(tdew_f=0, tdew_fill, .); |
5 |
* GLEES calculate rh from rh_fill and rh_f; |
6 |
rh = ifn(rh_f=0, rh_fill, .); |
7 |
* GLEES calculate vp from vp_fill and vp_f; |
8 |
vp = ifn(vp_f=0, vp_fill, .); |
9 |
* GLEES calculate svp from svp_fill and svp_f; |
10 |
svp = ifn(svp_f=0, svp_fill, .); |
11 |
* GLEES calculate vpd from vpd_fill and vpd_f; |
12 |
vpd = ifn(vpd_f=0, vpd_fill, .); |
13 |
* GLEES calculate h2o from h2o_fill and h2o_f; |
14 |
h2o = ifn(h2o_f=0, h2o_fill, .); |
15 |
* GLEES calculate h2oden from h2oden_fill and h2oden_f; |
16 |
h2oden = ifn(h2oden_f=0, h2oden_fill, .); |
17 |
* GLEES calculate ws from ws_fill and ws_f; |
18 |
ws = ifn(ws_f=0, ws_fill, .); |
19 |
* GLEES calculate wd from wd_fill and wd_f; |
20 |
wd = ifn(wd_f=0, wd_fill, .); |
21 |
* GLEES calculate press from press_fill and press_f; |
22 |
press = ifn(press_f=0, press_fill, .); |
23 |
* GLEES calculate dryairden from dryairden_fill and dryairden_f; |
24 |
dryairden = ifn(dryairden_f=0, dryairden_fill, .); |
25 |
* GLEES calculate wetairden from wetairden_fill and wetairden_f; |
26 |
wetairden = ifn(wetairden_f=0, wetairden_fill, .); |
27 |
* GLEES calculate co2 from co2_fill and co2_f; |
28 |
co2 = ifn(co2_f=0, co2_fill, .); |
29 |
* GLEES calculate co2den from co2den_fill and co2den_f; |
30 |
co2den = ifn(co2den_f=0, co2den_fill, .); |
31 |
* GLEES calculate rn from rn_fill and rn_f; |
32 |
rn = ifn(rn_f=0, rn_fill, .); |
33 |
* GLEES calculate rn__2 from rn__2_fill and rn__2_f; |
34 |
rn__2 = ifn(rn__2_f=0, rn__2_fill, .); |
35 |
* GLEES calculate par from par_fill and par_f; |
36 |
par = ifn(par_f=0, par_fill, .); |
37 |
* GLEES calculate parout from parout_fill and parout_f; |
38 |
parout = ifn(parout_f=0, parout_fill, .); |
39 |
* GLEES calculate rg from rg_fill and rg_f; |
40 |
rg = ifn(rg_f=0, rg_fill, .); |
41 |
* GLEES calculate rgout from rgout_fill and rgout_f; |
42 |
rgout = ifn(rgout_f=0, rgout_fill, .); |
43 |
* GLEES calculate rgl from rgl_fill and rgl_f; |
44 |
rgl = ifn(rgl_f=0, rgl_fill, .); |
45 |
* GLEES calculate rglout from rglout_fill and rglout_f; |
46 |
rglout = ifn(rglout_f=0, rglout_fill, .); |
47 |
* GLEES calculate prec from prec_fill and prec_f; |
48 |
prec = ifn(prec_f=0, prec_fill, .); |
49 |
* GLEES calculate ust from ust_fill and ust_f; |
50 |
ust = ifn(ust_f=0, ust_fill, .); |
51 |
* GLEES calculate tauxz from tauxz_fill and tauxz_f; |
52 |
tauxz = ifn(tauxz_f=0, tauxz_fill, .); |
53 |
* GLEES calculate h from h_fill and h_f; |
54 |
h = ifn(h_f=0, h_fill, .); |
55 |
* GLEES calculate fc from fc_fill and fc_f; |
56 |
fc = ifn(fc_f=0, fc_fill, .); |
57 |
* GLEES calculate sfc from sfc_fill and sfc_f; |
58 |
sfc = ifn(sfc_f=0, sfc_fill, .); |
59 |
* GLEES calculate nee from nee_fill and nee_f; |
60 |
nee = ifn(nee_f=0, nee_fill, .); |
61 |
* GLEES calculate fh2o from fh2o_fill and fh2o_f; |
62 |
fh2o = ifn(fh2o_f=0, fh2o_fill, .); |
63 |
* GLEES calculate le from le_fill and le_f; |
64 |
le = ifn(le_f=0, le_fill, .); |
65 |
* GLEES calculate zl from zl_fill and zl_f; |
66 |
zl = ifn(zl_f=0, zl_fill, .); |
67 |
* GLEES calculate ws__2 from ws__2_fill and ws__2_f; |
68 |
ws__2 = ifn(ws__2_f=0, ws__2_fill, .); |
69 |
* GLEES calculate wd__2 from wd__2_fill and wd__2_f; |
70 |
wd__2 = ifn(wd__2_f=0, wd__2_fill, .); |
71 |
* GLEES calculate tau from tau_fill and tau_f; |
72 |
tau = ifn(tau_f=0, tau_fill, .); |
73 |
* GLEES calculate vwcvar from vwcvar_fill and vwcvar__2_f; |
74 |
vwcvar = ifn(vwcvar_f=0, vwcvar_fill, .); |
75 |
* GLEES calculate ts from ts_fill and ts_f; |
76 |
ts = ifn(ts_f=0, ts_fill, .); |
77 |
* GLEES calculate fg from fg_fill and fg_f; |
78 |
fg = ifn(fg_f=0, fg_fill, .); |
79 |
* GLEES calculate fg__2 from fg__2_fill and fg__2_f; |
80 |
fg__2 = ifn(fg__2_f=0, fg__2_fill, .); |
81 |
* GLEES calculate ts_3 from ts_fill_3 and ts_3_f; |
82 |
ts_3 = ifn(ts_3_f=0, ts_fill_3, .); |
83 |
* GLEES calculate ts_9 from ts_fill_9 and ts_9_f; |
84 |
ts_9 = ifn(ts_9_f=0, ts_fill_9, .); |
85 |
* GLEES calculate ts__2_3 from ts__2_fill_3 and ts__2_3_f; |
86 |
ts__2_3 = ifn(ts__2_3_f=0, ts__2_fill_3, .); |
87 |
* GLEES calculate ts__2_9 from ts__2_fill_9 and ts__2_9_f; |
88 |
ts__2_9 = ifn(ts__2_9_f=0, ts__2_fill_9, .); |
89 |
* GLEES calculate fg_9 from fg_fill_9 and fg_9_f; |
90 |
fg_9 = ifn(fg_9_f=0, fg_fill_9, .); |
91 |
* GLEES calculate fg__2_9 from fg__2_fill_9 and fg__2_9_f; |
92 |
fg__2_9 = ifn(fg__2_9_f=0, fg__2_fill_9, .); |
93 |
* GLEES calculate ts_5 from ts_fill_5 and ts_5_f; |
94 |
ts_5 = ifn(ts_5_f=0, ts_fill_5, .); |
95 |
* GLEES calculate ts_10 from ts_fill_10 and ts_10_f; |
96 |
ts_10 = ifn(ts_10_f=0, ts_fill_10, .); |
97 |
* GLEES calculate ts_20 from ts_fill_20 and ts_20_f; |
98 |
ts_20 = ifn(ts_20_f=0, ts_fill_20, .); |
99 |
* GLEES calculate ts_50 from ts_fill_50 and ts_50_f; |
100 |
ts_50 = ifn(ts_50_f=0, ts_fill_50, .); |
101 |
* GLEES calculate ts_100 from ts_fill_100 and ts_100_f; |
102 |
ts_100 = ifn(ts_100_f=0, ts_fill_100, .); |
103 |
* GLEES calculate ts__2_5 from ts__2_fill and ts__2_5_f; |
104 |
ts__2_5 = ifn(ts__2_5_f=0, ts__2_fill_5, .); |
105 |
* GLEES calculate ts__2_10 from ts__2_fill_10 and ts__2_10_f; |
106 |
ts__2_10 = ifn(ts__2_10_f=0, ts__2_fill_10, .); |
107 |
* GLEES calculate ts__2_20 from ts__2_fill_20 and ts__2_20_f; |
108 |
ts__2_20 = ifn(ts__2_20_f=0, ts__2_fill_20, .); |
109 |
* GLEES calculate ts__2_50 from ts__2_fill_50 and ts__2_50_f; |
110 |
ts__2_50 = ifn(ts__2_50_f=0, ts__2_fill_50, .); |
111 |
* GLEES calculate ts__2_100 from ts__2_fill_100 and ts__2_100_f; |
112 |
ts__2_100 = ifn(ts__2_100_f=0, ts__2_fill_100, .); |
113 |
* GLEES calculate swc_5 from swc_fill_5 and swc_5_f; |
114 |
swc_5 = ifn(swc_5_f=0, swc_fill_5, .); |
115 |
* GLEES calculate swc_10 from swc_fill_10 and swc_10_f; |
116 |
swc_10 = ifn(swc_10_f=0, swc_fill_10, .); |
117 |
* GLEES calculate swc_20 from swc_fill_20 and swc_20_f; |
118 |
swc_20 = ifn(swc_20_f=0, swc_fill_20, .); |
119 |
* GLEES calculate swc_50 from swc_fill_50 and swc_50_f; |
120 |
swc_50 = ifn(swc_50_f=0, swc_fill_50, .); |
121 |
* GLEES calculate swc_100 from swc_fill_100 and swc_100_f; |
122 |
swc_100 = ifn(swc_100_f=0, swc_fill_100, .); |
123 |
* GLEES calculate swc__2_5 from swc__2_fill_5 and swc__2_5_f; |
124 |
swc__2_5 = ifn(swc__2_5_f=0, swc__2_fill_5, .); |
125 |
* GLEES calculate swc__2_10 from swc__2_fill_10 and swc__2_10_f; |
126 |
swc__2_10 = ifn(swc__2_10_f=0, swc__2_fill_10, .); |
127 |
* GLEES calculate swc__2_20 from swc__2_fill_20 and swc__2_20_f; |
128 |
swc__2_20 = ifn(swc__2_20_f=0, swc__2_fill_20, .); |
129 |
* GLEES calculate swc__2_50 from swc__2_fill_50 and swc__2_50_f; |
130 |
swc__2_50 = ifn(swc__2_50_f=0, swc__2_fill_50, .); |
131 |
* GLEES calculate swc__2_100 from swc__2_fill_100 and swc__2_100_f; |
132 |
swc__2_100 = ifn(swc__2_100_f=0, swc__2_fill_100, .); |
133 |
* GLEES calculate snowdepth from snowdepth_fill and snowdepth_f; |
134 |
snowdepth = ifn(snowdepth_f=0, snowdepth_fill, .); |
135 |
* GLEES calculate tsmean_10 as the mean of ts_10 and ts__2_10; |
136 |
if(ts_10 ne .) and (ts__2_10 ne .) then tsmean_10=(ts_10+ts__2_10)*0.5; else tsmean_10=.; |
137 |
* GLEES calculate tsmean_fill_10 as the mean of ts_fill_10 and ts__2_fill_10; |
138 |
if(ts_fill_10 ne .) and (ts__2_fill_10 ne .) then tsmean_fill_10=(ts_fill_10+ts__2_fill_10)*0.5; else tsmean_fill_10=.; |
139 |
* GLEES calculate swc as the mean of swc_5 and swc__2_5; |
140 |
if(swc_5 ne .) and (swc__2_5 ne .) then swc=(swc_5+swc__2_5)*0.5; else swc=.; |
141 |
* GLEES calculate swc_fill as the mean of swc_fill_5 and swc__2_fill_5; |
142 |
if(swc_fill_5 ne .) and (swc__2_fill_5 ne .) then swc_fill=(swc_fill_5+swc__2_fill_5)*0.5; else swc_fill=.; |
143 |
* GLEES calculate swcmean_10 as the mean of swc_10 and swc__2_10; |
144 |
if(swc_10 ne .) and (swc__2_10 ne .) then swcmean_10=(swc_10+swc__2_10)*0.5; else swcmean_10=.; |
145 |
* GLEES calculate swcmean_fill_10 as the mean of swc_fill_10 and swc__2_fill_10; |
146 |
if(swc_fill_10 ne .) and (swc__2_fill_10 ne .) then swcmean_fill_10=(swc_fill_10+swc__2_fill_10)*0.5; else swcmean_fill_10=.; |
147 |
* GLEES calculate preccum for year 2008 and later; |
148 |
if sasdate>= '01jan08'd then preccum = ifn(first.year, prec, sum(preccum, prec)); |
149 |
* GLEES calculate preccum_fill for year 2008 and later; |
150 |
if sasdate>= '01jan08'd then preccum_fill = ifn(first.year, prec_fill, sum(preccum_fill, prec_fill)); |
GLEES, Wyoming, USA |
variable statistics for L2 data |
Obs |
Variable |
MIN |
MEAN |
MAX |
N |
NMISS |
TOTAL |
1 |
CO2 |
364.85 |
387.022 |
415.15 |
140615 |
4057 |
144672 |
2 |
CO2_f |
0.00 |
0.028 |
1.00 |
144672 |
0 |
144672 |
3 |
CO2_fill |
364.85 |
386.987 |
415.15 |
144672 |
0 |
144672 |
4 |
CO2den |
10.53 |
11.702 |
13.89 |
140615 |
4057 |
144672 |
5 |
CO2den_f |
0.00 |
0.028 |
1.00 |
144672 |
0 |
144672 |
6 |
CO2den_fill |
10.53 |
11.701 |
13.89 |
144672 |
0 |
144672 |
7 |
DryAirDen |
27.97 |
30.218 |
34.34 |
144036 |
636 |
144672 |
8 |
DryAirDen_f |
0.00 |
0.004 |
1.00 |
144672 |
0 |
144672 |
9 |
DryAirDen_fill |
27.97 |
30.218 |
34.34 |
144672 |
0 |
144672 |
10 |
FC |
-38.18 |
-0.358 |
30.20 |
105959 |
38713 |
144672 |
11 |
FC_f |
0.00 |
0.000 |
0.00 |
105959 |
38713 |
144672 |
12 |
FC_fill |
-38.18 |
-0.358 |
30.20 |
105959 |
38713 |
144672 |
13 |
FG |
-157.84 |
1.221 |
303.03 |
77329 |
67343 |
144672 |
14 |
FG_9 |
-35.88 |
0.381 |
132.60 |
137062 |
7610 |
144672 |
15 |
FG_9_f |
0.00 |
0.003 |
1.00 |
137444 |
7228 |
144672 |
16 |
FG__2 |
-74.62 |
2.046 |
235.44 |
76912 |
67760 |
144672 |
17 |
FG__2_9 |
-26.87 |
0.486 |
105.80 |
138102 |
6570 |
144672 |
18 |
FG__2_9_f |
0.00 |
0.005 |
1.00 |
138801 |
5871 |
144672 |
19 |
FG__2_f |
0.00 |
0.000 |
0.00 |
76912 |
67760 |
144672 |
20 |
FG__2_fill |
-74.62 |
2.046 |
235.44 |
76912 |
67760 |
144672 |
21 |
FG__2_fill_9 |
-26.87 |
0.477 |
105.80 |
138801 |
5871 |
144672 |
22 |
FG_f |
0.00 |
0.000 |
0.00 |
77329 |
67343 |
144672 |
23 |
FG_fill |
-157.84 |
1.221 |
303.03 |
77329 |
67343 |
144672 |
24 |
FG_fill_9 |
-35.88 |
0.378 |
132.60 |
137444 |
7228 |
144672 |
25 |
FH2O |
-7.30 |
1.057 |
12.42 |
107561 |
37111 |
144672 |
26 |
FH2O_f |
0.00 |
0.257 |
1.00 |
144672 |
0 |
144672 |
27 |
FH2O_fill |
-7.30 |
1.027 |
12.42 |
144672 |
0 |
144672 |
28 |
H |
-696.42 |
42.551 |
700.06 |
107561 |
37111 |
144672 |
29 |
H2O |
0.09 |
5.433 |
19.60 |
144209 |
463 |
144672 |
30 |
H2O_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
31 |
H2O_fill |
0.09 |
5.437 |
19.60 |
144672 |
0 |
144672 |
32 |
H2Oden |
2.89 |
162.266 |
565.58 |
144209 |
463 |
144672 |
33 |
H2Oden_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
34 |
H2Oden_fill |
2.89 |
162.392 |
565.58 |
144672 |
0 |
144672 |
35 |
H_f |
0.00 |
0.380 |
2.00 |
144672 |
0 |
144672 |
36 |
H_fill |
-696.42 |
35.805 |
1022.21 |
144672 |
0 |
144672 |
37 |
LE |
-325.04 |
49.994 |
580.56 |
107561 |
37111 |
144672 |
38 |
LE_f |
0.00 |
0.257 |
1.00 |
144672 |
0 |
144672 |
39 |
LE_fill |
-325.04 |
48.672 |
580.56 |
144672 |
0 |
144672 |
40 |
NEE |
-38.08 |
-0.358 |
30.21 |
105854 |
38818 |
144672 |
41 |
NEE_f |
0.00 |
0.268 |
1.00 |
144672 |
0 |
144672 |
42 |
NEE_fill |
-38.08 |
-0.262 |
30.21 |
144672 |
0 |
144672 |
43 |
PAR |
0.00 |
401.368 |
2415.20 |
135014 |
9658 |
144672 |
44 |
PAR_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
45 |
PAR_fill |
0.00 |
393.799 |
2415.20 |
144672 |
0 |
144672 |
46 |
PARout |
0.00 |
29.331 |
495.17 |
135012 |
9660 |
144672 |
47 |
PARout_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
48 |
PARout_fill |
0.00 |
28.395 |
495.17 |
144672 |
0 |
144672 |
49 |
PREC |
0.00 |
0.119 |
25.20 |
71804 |
72868 |
144672 |
50 |
PREC_f |
0.00 |
0.447 |
1.00 |
129932 |
14740 |
144672 |
51 |
PREC_fill |
0.00 |
0.082 |
25.20 |
129932 |
14740 |
144672 |
52 |
PRECcum |
0.00 |
791.315 |
1664.72 |
87422 |
57250 |
144672 |
53 |
PRECcum_fill |
0.00 |
800.710 |
1664.72 |
87696 |
56976 |
144672 |
54 |
PRESS |
66.30 |
68.927 |
70.48 |
144105 |
567 |
144672 |
55 |
PRESS_f |
0.00 |
0.004 |
1.00 |
144672 |
0 |
144672 |
56 |
PRESS_fill |
66.30 |
68.929 |
70.48 |
144672 |
0 |
144672 |
57 |
RH |
1.31 |
57.818 |
96.78 |
144209 |
463 |
144672 |
58 |
RH_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
59 |
RH_fill |
1.31 |
57.854 |
96.78 |
144672 |
0 |
144672 |
60 |
Rg |
0.00 |
190.792 |
1196.20 |
135014 |
9658 |
144672 |
61 |
RgOut |
0.00 |
20.360 |
227.26 |
135012 |
9660 |
144672 |
62 |
RgOut_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
63 |
RgOut_fill |
0.00 |
20.339 |
227.26 |
144672 |
0 |
144672 |
64 |
Rg_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
65 |
Rg_fill |
0.00 |
187.508 |
1196.20 |
144672 |
0 |
144672 |
66 |
Rgl |
92.92 |
239.862 |
374.71 |
135012 |
9660 |
144672 |
67 |
RglOut |
172.41 |
315.739 |
455.33 |
135012 |
9660 |
144672 |
68 |
RglOut_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
69 |
RglOut_fill |
172.41 |
313.081 |
455.33 |
144672 |
0 |
144672 |
70 |
Rgl_f |
0.00 |
0.067 |
1.00 |
144672 |
0 |
144672 |
71 |
Rgl_fill |
92.92 |
237.896 |
374.71 |
144672 |
0 |
144672 |
72 |
Rn |
-126.78 |
103.840 |
982.40 |
144268 |
404 |
144672 |
73 |
Rn__2 |
-162.18 |
95.949 |
1014.38 |
121071 |
23601 |
144672 |
74 |
Rn__2_f |
0.00 |
0.163 |
1.00 |
144672 |
0 |
144672 |
75 |
Rn__2_fill |
-168.34 |
91.525 |
1014.38 |
144672 |
0 |
144672 |
76 |
Rn_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
77 |
Rn_fill |
-126.78 |
103.794 |
982.40 |
144672 |
0 |
144672 |
78 |
SFC |
-7.70 |
0.000 |
7.41 |
104793 |
39879 |
144672 |
79 |
SFC_f |
0.00 |
1.378 |
8.00 |
142294 |
2378 |
144672 |
80 |
SFC_fill |
-7.70 |
0.000 |
7.83 |
142294 |
2378 |
144672 |
81 |
SNOWdepth |
-0.06 |
0.796 |
3.76 |
131360 |
13312 |
144672 |
82 |
SNOWdepth_f |
0.00 |
0.092 |
1.00 |
144672 |
0 |
144672 |
83 |
SNOWdepth_fill |
-0.06 |
0.870 |
3.88 |
144672 |
0 |
144672 |
84 |
SVP |
0.03 |
0.746 |
2.86 |
144304 |
368 |
144672 |
85 |
SVP_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
86 |
SVP_fill |
0.03 |
0.746 |
2.86 |
144672 |
0 |
144672 |
87 |
SWC |
7.50 |
24.989 |
41.10 |
131257 |
13415 |
144672 |
88 |
SWC_10 |
18.80 |
35.003 |
40.57 |
138459 |
6213 |
144672 |
89 |
SWC_100 |
14.60 |
21.752 |
33.19 |
137972 |
6700 |
144672 |
90 |
SWC_100_f |
0.00 |
0.016 |
1.00 |
140206 |
4466 |
144672 |
91 |
SWC_10_f |
0.00 |
0.012 |
1.00 |
140203 |
4469 |
144672 |
92 |
SWC_20 |
23.73 |
34.368 |
40.73 |
138448 |
6224 |
144672 |
93 |
SWC_20_f |
0.00 |
0.013 |
1.00 |
140209 |
4463 |
144672 |
94 |
SWC_5 |
9.50 |
31.952 |
40.73 |
131984 |
12688 |
144672 |
95 |
SWC_50 |
22.90 |
28.823 |
37.25 |
138426 |
6246 |
144672 |
96 |
SWC_50_f |
0.00 |
0.013 |
1.00 |
140208 |
4464 |
144672 |
97 |
SWC_5_f |
0.00 |
0.059 |
1.00 |
140209 |
4463 |
144672 |
98 |
SWC__2_10 |
5.81 |
18.226 |
40.70 |
136090 |
8582 |
144672 |
99 |
SWC__2_100 |
19.90 |
26.709 |
40.00 |
137656 |
7016 |
144672 |
100 |
SWC__2_100_f |
0.00 |
0.013 |
1.00 |
139488 |
5184 |
144672 |
101 |
SWC__2_10_f |
0.00 |
0.020 |
1.00 |
138883 |
5789 |
144672 |
102 |
SWC__2_20 |
6.30 |
19.201 |
39.89 |
137730 |
6942 |
144672 |
103 |
SWC__2_20_f |
0.00 |
0.013 |
1.00 |
139490 |
5182 |
144672 |
104 |
SWC__2_5 |
4.90 |
18.091 |
41.60 |
137748 |
6924 |
144672 |
105 |
SWC__2_50 |
9.60 |
21.127 |
39.60 |
138253 |
6419 |
144672 |
106 |
SWC__2_50_f |
0.00 |
0.014 |
1.00 |
140206 |
4466 |
144672 |
107 |
SWC__2_5_f |
0.00 |
0.012 |
1.00 |
139490 |
5182 |
144672 |
108 |
SWC__2_fill_10 |
5.81 |
18.289 |
40.70 |
138883 |
5789 |
144672 |
109 |
SWC__2_fill_100 |
19.90 |
26.718 |
40.00 |
139488 |
5184 |
144672 |
110 |
SWC__2_fill_20 |
6.30 |
19.213 |
39.89 |
139490 |
5182 |
144672 |
111 |
SWC__2_fill_5 |
4.90 |
18.072 |
41.60 |
139490 |
5182 |
144672 |
112 |
SWC__2_fill_50 |
9.60 |
21.169 |
39.60 |
140206 |
4466 |
144672 |
113 |
SWC_fill |
7.50 |
24.882 |
41.10 |
139490 |
5182 |
144672 |
114 |
SWC_fill_10 |
18.80 |
35.017 |
40.57 |
140203 |
4469 |
144672 |
115 |
SWC_fill_100 |
14.60 |
21.761 |
33.19 |
140206 |
4466 |
144672 |
116 |
SWC_fill_20 |
23.73 |
34.385 |
40.73 |
140209 |
4463 |
144672 |
117 |
SWC_fill_5 |
9.50 |
31.699 |
40.73 |
140209 |
4463 |
144672 |
118 |
SWC_fill_50 |
22.90 |
28.829 |
37.25 |
140208 |
4464 |
144672 |
119 |
SWCmean_10 |
12.43 |
26.598 |
40.60 |
136073 |
8599 |
144672 |
120 |
SWCmean_fill_10 |
12.43 |
26.641 |
40.60 |
138876 |
5796 |
144672 |
121 |
TA |
-34.36 |
-0.089 |
23.21 |
144304 |
368 |
144672 |
122 |
TAU |
-10.59 |
-1.194 |
0.50 |
126781 |
17891 |
144672 |
123 |
TAU_f |
0.00 |
0.124 |
1.00 |
144672 |
0 |
144672 |
124 |
TAU_fill |
-10.59 |
-1.189 |
0.50 |
144672 |
0 |
144672 |
125 |
TAUxz |
0.00 |
1.091 |
9.50 |
107561 |
37111 |
144672 |
126 |
TAUxz_f |
0.00 |
0.257 |
1.00 |
144672 |
0 |
144672 |
127 |
TAUxz_fill |
0.00 |
1.063 |
9.50 |
144672 |
0 |
144672 |
128 |
TA_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
129 |
TA_fill |
-34.36 |
-0.081 |
23.21 |
144672 |
0 |
144672 |
130 |
TS |
-0.64 |
2.773 |
15.05 |
130294 |
14378 |
144672 |
131 |
TS_10 |
-0.04 |
3.600 |
16.49 |
138047 |
6625 |
144672 |
132 |
TS_100 |
-0.45 |
3.010 |
10.22 |
134742 |
9930 |
144672 |
133 |
TS_100_f |
0.00 |
0.003 |
1.00 |
135118 |
9554 |
144672 |
134 |
TS_10_f |
0.00 |
0.003 |
1.00 |
138416 |
6256 |
144672 |
135 |
TS_20 |
-0.30 |
3.317 |
14.42 |
138400 |
6272 |
144672 |
136 |
TS_20_f |
0.00 |
0.003 |
1.00 |
138761 |
5911 |
144672 |
137 |
TS_3 |
-0.84 |
3.307 |
23.88 |
114368 |
30304 |
144672 |
138 |
TS_3_f |
0.00 |
0.057 |
1.00 |
121245 |
23427 |
144672 |
139 |
TS_5 |
-0.49 |
3.514 |
21.71 |
134611 |
10061 |
144672 |
140 |
TS_50 |
-0.80 |
3.159 |
12.20 |
134718 |
9954 |
144672 |
141 |
TS_50_f |
0.00 |
0.003 |
1.00 |
135092 |
9580 |
144672 |
142 |
TS_5_f |
0.00 |
0.003 |
1.00 |
134972 |
9700 |
144672 |
143 |
TS_9 |
-0.49 |
3.247 |
18.46 |
129386 |
15286 |
144672 |
144 |
TS_9_f |
0.00 |
0.017 |
1.00 |
131589 |
13083 |
144672 |
145 |
TS__2_10 |
-1.11 |
2.196 |
8.61 |
102420 |
42252 |
144672 |
146 |
TS__2_100 |
0.01 |
1.956 |
6.00 |
136597 |
8075 |
144672 |
147 |
TS__2_100_f |
0.00 |
0.003 |
1.00 |
136960 |
7712 |
144672 |
148 |
TS__2_10_f |
0.00 |
0.004 |
1.00 |
102807 |
41865 |
144672 |
149 |
TS__2_20 |
-0.37 |
2.034 |
7.77 |
136651 |
8021 |
144672 |
150 |
TS__2_20_f |
0.00 |
0.003 |
1.00 |
137014 |
7658 |
144672 |
151 |
TS__2_3 |
-0.45 |
3.571 |
20.32 |
131409 |
13263 |
144672 |
152 |
TS__2_3_f |
0.00 |
0.053 |
1.00 |
138739 |
5933 |
144672 |
153 |
TS__2_5 |
-1.16 |
1.832 |
9.38 |
136661 |
8011 |
144672 |
154 |
TS__2_50 |
-0.45 |
1.636 |
6.32 |
138271 |
6401 |
144672 |
155 |
TS__2_50_f |
0.00 |
0.003 |
1.00 |
138635 |
6037 |
144672 |
156 |
TS__2_5_f |
0.00 |
0.003 |
1.00 |
137023 |
7649 |
144672 |
157 |
TS__2_9 |
-0.48 |
3.554 |
17.42 |
129776 |
14896 |
144672 |
158 |
TS__2_9_f |
0.00 |
0.009 |
1.00 |
130907 |
13765 |
144672 |
159 |
TS__2_fill_10 |
-1.11 |
2.189 |
8.61 |
102807 |
41865 |
144672 |
160 |
TS__2_fill_100 |
0.01 |
1.953 |
6.00 |
136960 |
7712 |
144672 |
161 |
TS__2_fill_20 |
-0.37 |
2.030 |
7.77 |
137014 |
7658 |
144672 |
162 |
TS__2_fill_3 |
-0.63 |
3.400 |
20.32 |
138739 |
5933 |
144672 |
163 |
TS__2_fill_5 |
-1.16 |
1.827 |
9.38 |
137023 |
7649 |
144672 |
164 |
TS__2_fill_50 |
-0.45 |
1.633 |
6.32 |
138635 |
6037 |
144672 |
165 |
TS__2_fill_9 |
-0.48 |
3.533 |
17.42 |
130907 |
13765 |
144672 |
166 |
TS_f |
0.00 |
0.324 |
4.00 |
144672 |
0 |
144672 |
167 |
TS_fill |
-0.71 |
2.568 |
16.80 |
144672 |
0 |
144672 |
168 |
TS_fill_10 |
-0.04 |
3.594 |
16.49 |
138416 |
6256 |
144672 |
169 |
TS_fill_100 |
-0.45 |
3.005 |
10.22 |
135118 |
9554 |
144672 |
170 |
TS_fill_20 |
-0.30 |
3.311 |
14.42 |
138761 |
5911 |
144672 |
171 |
TS_fill_3 |
-0.84 |
3.134 |
23.88 |
121245 |
23427 |
144672 |
172 |
TS_fill_5 |
-0.49 |
3.507 |
21.71 |
134972 |
9700 |
144672 |
173 |
TS_fill_50 |
-0.80 |
3.153 |
12.20 |
135092 |
9580 |
144672 |
174 |
TS_fill_9 |
-0.49 |
3.201 |
18.46 |
131589 |
13083 |
144672 |
175 |
TSmean_10 |
-0.45 |
3.222 |
12.33 |
102038 |
42634 |
144672 |
176 |
TSmean_fill_10 |
-0.45 |
3.214 |
12.33 |
102430 |
42242 |
144672 |
177 |
Tdew |
-49.74 |
-8.595 |
11.26 |
144209 |
463 |
144672 |
178 |
Tdew_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
179 |
Tdew_fill |
-49.74 |
-8.581 |
11.26 |
144672 |
0 |
144672 |
180 |
UST |
0.01 |
0.974 |
3.26 |
107561 |
37111 |
144672 |
181 |
UST_f |
0.00 |
0.257 |
1.00 |
144672 |
0 |
144672 |
182 |
UST_fill |
0.00 |
0.954 |
3.26 |
144672 |
0 |
144672 |
183 |
VP |
0.01 |
0.373 |
1.34 |
144209 |
463 |
144672 |
184 |
VPD |
0.01 |
0.373 |
2.41 |
144209 |
463 |
144672 |
185 |
VPD_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
186 |
VPD_fill |
0.01 |
0.372 |
2.41 |
144672 |
0 |
144672 |
187 |
VP_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
188 |
VP_fill |
0.01 |
0.373 |
1.34 |
144672 |
0 |
144672 |
189 |
VWcvar |
-1.81 |
0.069 |
2.38 |
126949 |
17723 |
144672 |
190 |
VWcvar_f |
0.00 |
0.123 |
1.00 |
144672 |
0 |
144672 |
191 |
VWcvar_fill |
-1.81 |
0.060 |
2.38 |
144672 |
0 |
144672 |
192 |
WD |
0.00 |
259.017 |
359.98 |
143484 |
1188 |
144672 |
193 |
WD__2 |
0.00 |
254.051 |
360.00 |
126949 |
17723 |
144672 |
194 |
WD__2_f |
0.00 |
0.000 |
0.00 |
126949 |
17723 |
144672 |
195 |
WD__2_fill |
0.00 |
254.051 |
360.00 |
126949 |
17723 |
144672 |
196 |
WD_f |
0.00 |
0.008 |
1.00 |
144672 |
0 |
144672 |
197 |
WD_fill |
0.00 |
258.384 |
359.99 |
144672 |
0 |
144672 |
198 |
WS |
0.00 |
5.259 |
17.55 |
144297 |
375 |
144672 |
199 |
WS__2 |
0.00 |
4.135 |
14.12 |
126949 |
17723 |
144672 |
200 |
WS__2_f |
0.00 |
0.000 |
0.00 |
126949 |
17723 |
144672 |
201 |
WS__2_fill |
0.00 |
4.135 |
14.12 |
126949 |
17723 |
144672 |
202 |
WS_f |
0.00 |
0.003 |
1.00 |
144672 |
0 |
144672 |
203 |
WS_fill |
0.00 |
5.256 |
17.55 |
144672 |
0 |
144672 |
204 |
WetAirDen |
28.15 |
30.319 |
34.35 |
144036 |
636 |
144672 |
205 |
WetAirDen_f |
0.00 |
0.004 |
1.00 |
144672 |
0 |
144672 |
206 |
WetAirDen_fill |
28.15 |
30.319 |
34.35 |
144672 |
0 |
144672 |
207 |
ZL |
-2349.60 |
0.839 |
14963.37 |
107561 |
37111 |
144672 |
208 |
ZL_f |
0.00 |
0.257 |
1.00 |
144672 |
0 |
144672 |
209 |
ZL_fill |
-325485.68 |
132.637 |
1320607.58 |
144583 |
89 |
144672 |
GLEES, Wyoming, USA |
AmeriFlux L2 variable names and descriptions |
Obs |
name |
label |
1 |
BIOME |
BIOME class |
2 |
CO2 |
CO2 concentration at 22.5m (umol/mol) |
3 |
CO2_f |
CO2 flag 0=measured,1=filled |
4 |
CO2_fill |
gap-filled CO2 concentration at 22.5m (umol/mol) |
5 |
CO2den |
CO2 density at 22.5m (mmol/m3) |
6 |
CO2den_f |
CO2den flag 0=measured,1=filled |
7 |
CO2den_fill |
gap-filled CO2 density at 22.5m (mmol/m3) |
8 |
Dataname |
Dataset name |
9 |
Day |
Day |
10 |
DirName |
Directory Name |
11 |
DryAirDen |
Dry air density (mol/m3) |
12 |
DryAirDen_f |
DryAirDen flag 0=measured,1=filled |
13 |
DryAirDen_fill |
gap-filled Dry air density (mol/m3) |
14 |
Ebalance |
Energy balance [[LE+H+FG]/Rn] |
15 |
Elevation |
Elevation (masl) |
16 |
FC |
CO2 flux at 22.5m (umol/m2/s) |
17 |
FC_f |
FC flag 0=measured,1=filled |
18 |
FC_fill |
gap-filled CO2 flux at 22.5m (umol/m2/s) |
19 |
FG |
Soil heat flux at 0cm (W/m2) |
20 |
FG_9 |
Soil heat flux at 9cm (W/m2) |
21 |
FG_9_f |
FG_9 flag at 9cm 0=measured,1=filled |
22 |
FG__2 |
2nd Soil heat flux at 0cm (W/m2) |
23 |
FG__2_9 |
2nd Soil heat flux at 9cm (W/m2) |
24 |
FG__2_9_f |
FG__2_9 flag at 9cm 0=measured,1=filled |
25 |
FG__2_f |
FG__2 flag at 0cm 0=measured,1=filled |
26 |
FG__2_fill |
2nd gap-filled Soil heat flux at 0cm (W/m2) |
27 |
FG__2_fill_9 |
2nd gap-filled Soil heat flux at 9cm (W/m2) |
28 |
FG_f |
FG flag at 0cm 0=measured,1=filled |
29 |
FG_fill |
gap-filled Soil heat flux at 0cm (W/m2) |
30 |
FG_fill_9 |
gap-filled Soil heat flux at 9cm (W/m2) |
31 |
FH2O |
Water vapor flux at 22.5m (mmol/m2/s) |
32 |
FH2O_f |
FH2O flag 0=measured,1=filled |
33 |
FH2O_fill |
gap-filled Water vapor flux at 22.5m (mmol/m2/s) |
34 |
FluxnetID |
Fluxnet name |
35 |
GMT |
Greenwich mean time |
36 |
GMT_date |
GMT date |
37 |
GMT_day |
GMT day |
38 |
GMT_hour |
GMT hour |
39 |
GMT_jd |
GMT Day of year |
40 |
GMT_min |
GMT minute |
41 |
GMT_month |
GMT month |
42 |
GMT_year |
GMT year |
43 |
H |
Sensible heat flux at 22.5m (W/m2) |
44 |
H2O |
Water vapor concentration at 23.7m (mmol/mol) |
45 |
H2O_f |
H2O flag 0=measured,1=filled |
46 |
H2O_fill |
gap-filled Water vapor concentration at 23.7m (mmol/mol) |
47 |
H2Oden |
Water vapor density at 23.7m (mmol/m3) |
48 |
H2Oden_f |
H2Oden flag 0=measured,1=filled |
49 |
H2Oden_fill |
gap-filled Water vapor density at 23.7m (mmol/m3) |
50 |
H_f |
H flag 1=filled with sensible heat flux calculated without water vapor flux,2=filled with modeled data |
51 |
H_fill |
gap-filled Sensible heat flux at 22.5m (W/m2) |
52 |
Hour |
Hour |
53 |
IGBP |
IGBP veg type |
54 |
JD |
Day of year |
55 |
LE |
Latent heat flux at 22.5m (W/m2) |
56 |
LE_f |
LE flag 0=measured,1=filled |
57 |
LE_fill |
gap-filled Latent heat flux at 22.5m (W/m2) |
58 |
Latitude |
Latitude (decimal degrees) |
59 |
Longitude |
Longitude (decimal degrees) |
60 |
MODIS |
MODIS Land Cover Type 5 |
61 |
Minute |
Minute |
62 |
Month |
Month |
63 |
NEE |
Net ecosystem exchange (umol/m2/s) |
64 |
NEE_f |
NEE flag 0=measured,1=filled |
65 |
NEE_fill |
gap-filled Net ecosystem exchange (umol/m2/s) |
66 |
OrigFile |
Originating filename |
67 |
PAR |
Incoming photosynthetically active radiation at 24.3m (umol/m2/s) |
68 |
PAR_f |
PAR flag 0=measured,1=filled |
69 |
PAR_fill |
gap-filled Incoming photosynthetically active radiation at 24.3m (umol/m2/s) |
70 |
PARout |
Outgoing photosynthetically active radiation at 24.3m (umol/m2/s) |
71 |
PARout_f |
PARout flag 0=measured,1=filled |
72 |
PARout_fill |
gap-filled Outgoing photosynthetically active radiation at 24.3m (umol/m2/s) |
73 |
PI |
Principal investigator |
74 |
PIemail |
PI email |
75 |
PREC |
Precipitation (mm) |
76 |
PREC_f |
PREC flag 0=measured,1=filled |
77 |
PREC_fill |
gap-filled Precipitation (mm) |
78 |
PRECcum |
Precipitation annual cumulative (mm) |
79 |
PRECcum_fill |
gap-filled Precipitation annual cumulative (mm) |
80 |
PRESS |
Barometric pressure at 23.2m (kPa) |
81 |
PRESS_f |
PRESS flag 0=measured,1=filled |
82 |
PRESS_fill |
gap-filled Barometric pressure at 23.2m (kPa) |
83 |
RH |
Relative humidity of air at 23.7m (%) |
84 |
RH_f |
RH flag 0=measured,1=filled |
85 |
RH_fill |
gap-filled Relative humidity of air at 23.7m (%) |
86 |
Rg |
Incoming global solar radiation at 24.3m (W/m2) |
87 |
RgOut |
Outgoing global solar radiation at 24.3m (W/m2) |
88 |
RgOut_f |
RgOut flag 0=measured,1=filled |
89 |
RgOut_fill |
gap-filled Outgoing global solar radiation at 24.3m (W/m2) |
90 |
Rg_f |
Rg flag 0=measured,1=filled |
91 |
Rg_fill |
gap-filled Incoming global solar radiation at 24.3m (W/m2) |
92 |
Rgl |
Incoming long wave radiation at 24.3m (W/m2) |
93 |
RglOut |
Outgoing long wave radiation at 24.3m (W/m2) |
94 |
RglOut_f |
RglOut flag 0=measured,1=filled |
95 |
RglOut_fill |
gap-filled Outgoing long wave radiation at 24.3m (W/m2) |
96 |
Rgl_f |
Rgl flag 0=measured,1=filled |
97 |
Rgl_fill |
gap-filled Incoming long wave radiation at 24.3m (W/m2) |
98 |
Rn |
Net radiation at 24.3m (W/m2) |
99 |
Rn__2 |
2nd Net radiation at 24.3m (W/m2) |
100 |
Rn__2_f |
Rn__2 flag 0=measured,1=filled |
101 |
Rn__2_fill |
2nd gap-filled Net radiation at 24.3m (W/m2) |
102 |
Rn_f |
Rn flag 0=measured,1=filled |
103 |
Rn_fill |
gap-filled Net radiation at 24.3m (W/m2) |
104 |
SASDTime |
DateTime |
105 |
SASDate |
Date |
106 |
SFC |
CO2 storage flux at 0-22.5m (umol/m2/s) |
107 |
SFC_f |
SFC flag n=filled with CO2 canopy storage calculated with n sample tubes missing (n=1-7),8=filled with modeled data |
108 |
SFC_fill |
gap-filled CO2 storage flux at 0-22.5m (umol/m2/s) |
109 |
SNOWdepth |
Snow depth (m) |
110 |
SNOWdepth_f |
SNOWdepth flag 0=measured,1=filled |
111 |
SNOWdepth_fill |
gap-filled Snow depth (m) |
112 |
SVP |
Saturated vapor pressure (kPa) |
113 |
SVP_f |
SVP flag 0=measured,1=filled |
114 |
SVP_fill |
gap-filled Saturated vapor pressure (kPa) |
115 |
SWC |
Mean soil moisture volumetric content at 5cm (%) |
116 |
SWC_10 |
Soil moisture volumetric content, Meadow site at 10cm (%) |
117 |
SWC_100 |
Soil moisture volumetric content, Meadow site at 100cm (%) |
118 |
SWC_100_f |
SWC_100 flag at 100cm 0=measured,1=filled |
119 |
SWC_10_f |
SWC_10 flag at 10cm 0=measured,1=filled |
120 |
SWC_20 |
Soil moisture volumetric content, Meadow site at 20cm (%) |
121 |
SWC_20_f |
SWC_20 flag at 20cm 0=measured,1=filled |
122 |
SWC_5 |
Soil moisture volumetric content, Meadow site at 5cm (%) |
123 |
SWC_50 |
Soil moisture volumetric content, Meadow site at 50cm (%) |
124 |
SWC_50_f |
SWC_50 flag at 50cm 0=measured,1=filled |
125 |
SWC_5_f |
SWC_5 flag at 5cm 0=measured,1=filled |
126 |
SWC__2_10 |
Soil moisture volumetric content, Fir site at 10cm (%) |
127 |
SWC__2_100 |
Soil moisture volumetric content, Fir site at 100cm (%) |
128 |
SWC__2_100_f |
SWC__2_100 flag at 100cm 0=measured,1=filled |
129 |
SWC__2_10_f |
SWC__2_10 flag at 10cm 0=measured,1=filled |
130 |
SWC__2_20 |
Soil moisture volumetric content, Fir site at 20cm (%) |
131 |
SWC__2_20_f |
SWC__2_20 flag at 20cm 0=measured,1=filled |
132 |
SWC__2_5 |
Soil moisture volumetric content, Fir site at 5cm (%) |
133 |
SWC__2_50 |
Soil moisture volumetric content, Fir site at 50cm (%) |
134 |
SWC__2_50_f |
SWC__2_50 flag at 50cm 0=measured,1=filled |
135 |
SWC__2_5_f |
SWC__2_5 flag at 5cm 0=measured,1=filled |
136 |
SWC__2_fill_10 |
gap-filled Soil moisture volumetric content, Fir site at 10cm (%) |
137 |
SWC__2_fill_100 |
gap-filled Soil moisture volumetric content, Fir site at 100cm (%) |
138 |
SWC__2_fill_20 |
gap-filled Soil moisture volumetric content, Fir site at 20cm (%) |
139 |
SWC__2_fill_5 |
gap-filled Soil moisture volumetric content, Fir site at 5cm (%) |
140 |
SWC__2_fill_50 |
gap-filled Soil moisture volumetric content, Fir site at 50cm (%) |
141 |
SWC_fill |
gap-filled Mean soil moisture volumetric content at 5cm (%) |
142 |
SWC_fill_10 |
gap-filled Soil moisture volumetric content, Meadow site at 10cm (%) |
143 |
SWC_fill_100 |
gap-filled Soil moisture volumetric content, Meadow site at 100cm (%) |
144 |
SWC_fill_20 |
gap-filled Soil moisture volumetric content, Meadow site at 20cm (%) |
145 |
SWC_fill_5 |
gap-filled Soil moisture volumetric content, Meadow site at 5cm (%) |
146 |
SWC_fill_50 |
gap-filled Soil moisture volumetric content, Meadow site at 50cm (%) |
147 |
SWCmean_10 |
Mean soil moisture volumetric content at 10cm (%) |
148 |
SWCmean_fill_10 |
gap-filled Mean soil moisture volumetric content at 10cm (%) |
149 |
Site |
Site |
150 |
SiteDesc |
Site description |
151 |
SiteName |
Site name |
152 |
TA |
Air temperature at 23.7m (deg C) |
153 |
TAU |
Momentum flux UW (m2/s2) |
154 |
TAU_f |
TAU flag 0=measured,1=filled |
155 |
TAU_fill |
gap-filled Momentum flux UW (m2/s2) |
156 |
TAUxz |
Reynolds stress [rho_air*[UW]] (kg/m/s2) |
157 |
TAUxz_f |
TAUxz flag 0=measured,1=filled |
158 |
TAUxz_fill |
gap-filled Reynolds stress [rho_air*[UW]] (kg/m/s2) |
159 |
TA_f |
TA flag 0=measured,1=filled |
160 |
TA_fill |
gap-filled Air temperature at 23.7m (deg C) |
161 |
TS |
Mean soil temperature at 5cm (deg C) |
162 |
TS_10 |
Soil temperature, Meadow site at 10cm (deg C) |
163 |
TS_100 |
Soil temperature, Meadow site at 100cm (deg C) |
164 |
TS_100_f |
TS_100 flag at 100cm 0=measured,1=filled |
165 |
TS_10_f |
TS_10 flag at 10cm 0=measured,1=filled |
166 |
TS_20 |
Soil temperature, Meadow site at 20cm (deg C) |
167 |
TS_20_f |
TS_20 flag at 20cm 0=measured,1=filled |
168 |
TS_3 |
Soil temperature, Meadow site at 3cm (deg C) |
169 |
TS_3_f |
TS_3 flag at 3cm 0=measured,1=filled |
170 |
TS_5 |
Soil temperature, Meadow site at 5cm (deg C) |
171 |
TS_50 |
Soil temperature, Meadow site at 50cm (deg C) |
172 |
TS_50_f |
TS_50 flag at 50cm 0=measured,1=filled |
173 |
TS_5_f |
TS_5 flag at 5cm 0=measured,1=filled |
174 |
TS_9 |
Soil temperature, Meadow site at 9cm (deg C) |
175 |
TS_9_f |
TS_9 flag at 9cm 0=measured,1=filled |
176 |
TS__2_10 |
Soil temperature, Fir site at 10cm (deg C) |
177 |
TS__2_100 |
Soil temperature, Fir site at 100cm (deg C) |
178 |
TS__2_100_f |
TS__2_100 flag at 100cm 0=measured,1=filled |
179 |
TS__2_10_f |
TS__2_10 flag at 10cm 0=measured,1=filled |
180 |
TS__2_20 |
Soil temperature, Fir site at 20cm (deg C) |
181 |
TS__2_20_f |
TS__2_20 flag at 20cm 0=measured,1=filled |
182 |
TS__2_3 |
2nd Soil temperature, Meadow site at 3cm (deg C) |
183 |
TS__2_3_f |
TS__2_3 flag at 3cm 0=measured,1=filled |
184 |
TS__2_5 |
Soil temperature, Fir site at 5cm (deg C) |
185 |
TS__2_50 |
Soil temperature, Fir site at 50cm (deg C) |
186 |
TS__2_50_f |
TS__2_50 flag at 50cm 0=measured,1=filled |
187 |
TS__2_5_f |
TS__2_5 flag at 5cm 0=measured,1=filled |
188 |
TS__2_9 |
2nd Soil temperature, Meadow site at 9cm (deg C) |
189 |
TS__2_9_f |
TS__2_9 flag at 9cm 0=measured,1=filled |
190 |
TS__2_fill_10 |
gap-filled Soil temperature, Fir site at 10cm (deg C) |
191 |
TS__2_fill_100 |
gap-filled Soil temperature, Fir site at 100cm (deg C) |
192 |
TS__2_fill_20 |
gap-filled Soil temperature, Fir site at 20cm (deg C) |
193 |
TS__2_fill_3 |
2nd gap-filled Soil temperature, Meadow site at 3cm (deg C) |
194 |
TS__2_fill_5 |
gap-filled Soil temperature, Fir site at 5cm (deg C) |
195 |
TS__2_fill_50 |
gap-filled Soil temperature, Fir site at 50cm (deg C) |
196 |
TS__2_fill_9 |
2nd gap-filled Soil temperature, Meadow site at 9cm (deg C) |
197 |
TS_f |
TS flag at 5cm 1=filled with soil temperature calculated with only 1 sample,2=filled with modeled data,3=filled with soil temperature from GLEES Met Tower |
198 |
TS_fill |
gap-filled Mean soil temperature at 5cm (deg C) |
199 |
TS_fill_10 |
gap-filled Soil temperature, Meadow site at 10cm (deg C) |
200 |
TS_fill_100 |
gap-filled Soil temperature, Meadow site at 100cm (deg C) |
201 |
TS_fill_20 |
gap-filled Soil temperature, Meadow site at 20cm (deg C) |
202 |
TS_fill_3 |
gap-filled Soil temperature, Meadow site at 3cm (deg C) |
203 |
TS_fill_5 |
gap-filled Soil temperature, Meadow site at 5cm (deg C) |
204 |
TS_fill_50 |
gap-filled Soil temperature, Meadow site at 50cm (deg C) |
205 |
TS_fill_9 |
gap-filled Soil temperature, Meadow site at 9cm (deg C) |
206 |
TSmean_10 |
Mean soil temperature at 10cm (deg C) |
207 |
TSmean_fill_10 |
gap-filled Mean soil temperature at 10cm (deg C) |
208 |
Tdew |
Dew point temperature (deg C) |
209 |
Tdew_f |
Tdew flag 0=measured,1=filled |
210 |
Tdew_fill |
gap-filled Dew point temperature (deg C) |
211 |
UST |
Friction velocity (m/s) |
212 |
UST_f |
UST flag 0=measured,1=filled |
213 |
UST_fill |
gap-filled Friction velocity at 22.5m (m/s) |
214 |
VP |
Atmospheric vapor pressure at 23.7m (kPa) |
215 |
VPD |
Vapor pressure deficit at 23.7m (kPa) |
216 |
VPD_f |
VPD flag 0=measured,1=filled |
217 |
VPD_fill |
gap-filled Vapor pressure deficit at 23.7m (kPa) |
218 |
VP_f |
VP flag 0=measured,1=filled |
219 |
VP_fill |
gap-filled Atmospheric vapor pressure at 23.7m (kPa) |
220 |
VWcvar |
V and W covariance(m2/s2) |
221 |
VWcvar_f |
VWcvar flag 0=measured,1=filled |
222 |
VWcvar_fill |
gap-filled V and W covariance (m2/s2) |
223 |
WD |
Wind direction at 25.7m (deg) |
224 |
WD__2 |
2nd Wind direction at 22.5m (deg) |
225 |
WD__2_f |
WD__2 flag 0=measured,1=filled |
226 |
WD__2_fill |
2nd gap-filled Wind direction at 22.5m (deg) |
227 |
WD_f |
WD flag 0=measured,1=filled |
228 |
WD_fill |
gap-filled Wind direction at 25.7m (deg) |
229 |
WS |
Wind speed at 25.7m (m/s) |
230 |
WS__2 |
2nd Wind speed at 22.5m (m/s) |
231 |
WS__2_f |
WS__2 flag 0=measured,1=filled |
232 |
WS__2_fill |
2nd gap-filled Wind speed at 22.5m (m/s) |
233 |
WS_f |
WS flag 0=measured,1=filled |
234 |
WS_fill |
gap-filled Wind speed at 25.7m (m/s) |
235 |
WetAirDen |
Wet air density (mol/m3) |
236 |
WetAirDen_f |
WetAirDen flag 0=measured,1=filled |
237 |
WetAirDen_fill |
gap-filled Wet air density (mol/m3) |
238 |
Year |
Year |
239 |
ZL |
Atmospheric stability parameter [[Z - d]/L] (unitless) |
240 |
ZL_f |
ZL flag 0=measured,1=filled |
241 |
ZL_fill |
gap-filled Atmospheric stability parameter [[Z - d]/L] at (unitless) |
GLEES, Wyoming, USA |
Ameriflux L2 variables mapped into standardized files |
with gaps |
Obs |
rec |
1 |
/* filename glees.sas */ |
2 |
/* Modis name usglacie */ |
3 |
CO2top = co2; |
4 |
CO2height = 22.5; |
5 |
CO2 = co2; * co2; |
6 |
FC = fc; * fc above the canopy; |
7 |
if fc ne . then GAP = 0 ; else gap = -1; |
8 |
FG = fg; |
9 |
H = h; * h; |
10 |
H2O = h2o; * h2o above the canopy; |
11 |
LE = le; * le; |
12 |
NEE = nee; |
13 |
PAR = par; * par; |
14 |
PARout = parout; * parout; |
15 |
PREC = prec; * prec; |
16 |
PRESS = press; * press; |
17 |
RH = rh; * above the canopy; |
18 |
Rg = rg; * rg; |
19 |
RgOut = rgout; * rgout; |
20 |
Rgl = rgl; * rgl; |
21 |
RglOut = rglout; * rglout; |
22 |
Rn = rn; * above the canopy; |
23 |
SFC = sfc; * sfc; |
24 |
SWC1 = swc; * mean swc at first level; |
25 |
SWC2 = swcmean_10; * mean swc at second level; |
26 |
SWCdepth1 = 5; |
27 |
SWCdepth2 = 10; |
28 |
TA = ta; * above the canopy; |
29 |
TS1 = ts; * mean ts at the first depth; |
30 |
TS2 = tsmean_10; * mean ts at the second depth; |
31 |
TSdepth1 = 5; |
32 |
TSdepth2 = 10; |
33 |
UST = ust; * ust; |
34 |
VPD = vpd; * vpd; |
35 |
WD = wd; * above the canopy; |
36 |
WS = ws; * above the canopy; |
37 |
ZL = zl; |
38 |
APAR = -6999.; * apar; |
39 |
APARpct = -6999.; * aparpct; |
40 |
GPP = -6999.; * gpp; |
41 |
PARdif = -6999.; * pardif diffuse par; |
42 |
Rgdif = -6999.; * rgdif diffuse radiation; |
43 |
RE = -6999.; * re; |
44 |
SH = -6999.; * sh; |
45 |
SLE = -6999.; * sle; |
GLEES, Wyoming, USA |
Ameriflux L2 variables mapped into standardized files |
gap filled |
Obs |
rec |
1 |
/* filename glees_gf.sas */ |
2 |
/* Modis name usglacie_gf */ |
3 |
CO2top = co2_fill; |
4 |
CO2height = 22.5; |
5 |
CO2 = co2_fill; * co2; |
6 |
FC = fc_fill; * fc above the canopy; |
7 |
if fc ne . then GAP = 0 ; else gap = -1; |
8 |
FG = fg_fill; |
9 |
H = h_fill; * h; |
10 |
H2O = h2o_fill; * h2o above the canopy; |
11 |
LE = le_fill; * le; |
12 |
NEE = nee_fill; |
13 |
PAR = par_fill; * par; |
14 |
PARout = parout_fill; * parout; |
15 |
PREC = prec_fill; * prec; |
16 |
PRESS = press_fill; * press; |
17 |
RH = rh_fill; * above the canopy; |
18 |
Rg = rg_fill; * rg; |
19 |
RgOut = rgout_fill; * rgout; |
20 |
Rgl = rgl_fill; * rgl; |
21 |
RglOut = rglout_fill; * rglout; |
22 |
Rn = rn_fill; * above the canopy; |
23 |
SFC = sfc_fill; * sfc; |
24 |
SWC1 = swc_fill; * mean swc at the first level; |
25 |
SWC2 = swcmean_fill_10; * mean swc at the second level; |
26 |
SWCdepth1 = 5; |
27 |
SWCdepth2 = 10; |
28 |
TA = ta_fill; * above the canopy; |
29 |
TS1 = ts_fill; * mean ts at the first depth; |
30 |
TS2 = tsmean_fill_10; * mean ts at the second depth; |
31 |
TSdepth1 = 5; |
32 |
TSdepth2 = 10; |
33 |
UST = ust_fill; * ust; |
34 |
VPD = vpd_fill; * vpd; |
35 |
WD = wd_fill; * above the canopy; |
36 |
WS = ws_fill; * above the canopy; |
37 |
ZL = zl_fill; |
38 |
APAR = -6999.; * apar; |
39 |
APARpct = -6999.; * aparpct; |
40 |
GPP = -6999.; * gpp; |
41 |
PARdif = -6999.; * pardif diffuse par; |
42 |
Rgdif = -6999.; * rgdif diffuse radiation; |
43 |
RE = -6999.; * re; |
44 |
SH = -6999.; * sh; |
45 |
SLE = -6999.; * sle; |