The Inframetrics 760 airborne thermal infrared data on the

The Inframetrics 760 airborne thermal infrared data
on the ReSeDA experiment
1-Data acquisition
The ReSeDA site is located close to Avignon (France), north of the Alpilles small
mountain chain (N 43 o 47 ’ latitude, E 4 o 45 ’ longitude, 10 m altitude above sea level,
region, with sunflower, wheat, corn,
Mediterranean climate). It is a 5 5 km agricultural
grassland and alfalfa fields about 200 200 m size (see Figure 1). Detailed descriptions
of the experiment are given in (Prévot et al., 1998; Olioso et al., 2002). During the
experiment that lasted from December 1996 to December 1997, three types of surface
brightness temperature data were acquired. Satellite data are available with respect to
satellite orbits and meteorological conditions, airborne measurements were carried out at
a 15 day frequency, and field data were collected both hourly and occasionally. We focus
here on the acquisition and preprocessing of the airborne data.
1-1-Airborne data
The thermal infrared data were acquired using a thermal video camera set on board a
PIPER PA28 ARROW4 plane. Flights were performed approximately one or two times per
month on clear sky days from January, 30th to September, 18th with a total of 22 days at
both 1500 m and 3000 m altitudes that yielded to nadir spatial resolutions of respectively
10 m and 20 m (the altitudes were controlled thanks to a Global Positioning System).
At the 3000 m altitude, four flight lines were parallel to the principal plane and one was
perpendicular whereas at the 1500 m altitude, three flight lines were oriented according
to the North-South direction and corresponded respectively to the East, the Center and
the West of the site (see Figure 2). The two flight altitudes were completed within 1 hour
centered around solar noon.
The data were acquired at a 25 Hz frequency using a thermal video camera along with
a magnetic recorder, and next digitized with a 1 Hz frequency at the laboratory using a
numerization software. The data storage were performed by considering the images flight
line by flight line. The sensor we used was a thermal infrared camera INFRAMETRICS 760
(Inframetrics, 1991) along with a large Field Of View (FOV) lens (80 o ). The camera
scanned the target thanks to two oscillating mirrors, projecting the beam on a HgCdTe
detector cooled at -200 o C by a Stirling system (see Figure 3). The radiometric resolution
was about 0.2 o C and 0.4 o C for brightness temperature ranges of respectively 20 o C and
50 o C. The measurements were performed over the [7.25 m- 13.25 m] spectral band as
shown in Figure 4. The incoming radiance flux was converted in brightness temperature
assuming an emissivity of 1.0 for the target.
1
Cla sses
0
1 km
W
Alfalfa
Corn
Fallow
Gras s
Pla
stiq ue tunnels
uses
Ho
Vario us
Orchards
Sunflo wer
Unkno wn
Vegeta
bl e
W
s he
at
N
S
E
Figure 1: Land use map of the ReSeDA
experimental site.
2
Figure 2: Scheme of the flight line configuration over the ReSeDA site at 3000 and
1500 m altitudes. 3000 m flight altitude: A0 A1, A2 A0, A0 A3, A4 A0,
B0 B1. 1500 m altitude: W, C, E
Figure 3: Technical description of the INFRAMETRICS 760.
3
10
8
7
−1
−1
Radiance (W.m .sr .µm )
9
−2
6
5
4
3
Radiance emitted by surface
Radiance incoming at sensor
Radiance detected by sensor
2
1
0
7
7.5
8
8.5
9
9.5 10 10.5 11 11.5 12 12.5 13 13.5
Wavelength (µm)
Figure 4: Shapes of surface spectral radiance, incoming spectral radiance
at sensor level and spectral radiance detected by
sensor corresponding to
"!$#&% . Observation conditions: atmospheric profile from radiosounding
launched at Nîmes on
September, 4 at 12H00
U.T.; flight altitude about
3000 m; nadir viewing and surface brightness
temperature of 20 o C .
In the next pages, Tables 1, 2, 3, 4, and 5 provide informations on the data acquisition (for
each sequence that corresponds to a flight line : the number of the flight line, the altitude,
the begin and end times, the flight line direction and the number of numerized images).
4
Date
Flight
line
Altitude
(m)
Starting
time
(U.T.)
Ending
time
(U.T.)
Flight
Direction
Number of
Numerized
Images
970130
970130
970130
970130
970130
970130
1
2
3
4
5
6
3000
3000
3000
3000
3000
3000
12h02mn22s
12h08mn32s
12h16mn26s
12h23mn20s
12h37mn51s
12h15mn42s *
12h04mn54s
12h10mn35s
12h19mn02s
12h25mn57s
12h42mn01s
12h18mn49s *
ns
sn
ns
sn
ew
ns
135
110
140
140
220
168
970227
970227
970227
970227
1
2
3
4
3000
3000
3000
3000
12h10mn56s
12h18mn11s
12h53mn57s
12h58mn49s
12h14mn06s
12h22mn07s
12h56mn28s
13h01mn19s
ns
sn
ew
ew
167
210
135
135
970307
970307
970307
970307
1
2
3
4
3000
3000
3000
1200
11h57mn54s
12h03mn06s
12h11mn58s
12h28mn32s
12h00mn25s
12h05mn37s
12h14mn30s
12h30mn51s
ns
sn
ew
ns
135
135
135
125
970312
970312
970312
970312
970312
970312
1
2
3
4
5
6
3000
3000
3000
3000
3000
3000
12h07mn37s
12h19mn46s
12h26mn34s
12h35mn14s
12h43mn55s
12h51mn32s
12h10mn40s
12h22mn57s
12h29mn33s
12h37mn15s
12h46mn10s
12h53mn35s
ns
sn
ns
we
ns
sn
163
170
160
110
120
110
970326
970326
970326
970326
970326
970326
970326
970326
1
2
3
4
5
6
7
8
3000
3000
3000
3000
3000
1500
1500
1500
11h56mn25s
12h01mn55s
12h08mn33s
12h15mn51s
12h23mn20s
12h38mn46s
12h48mn02s
12h58mn37s
11h57mn54s
12h04mn44s
12h10mn58s
12h17mn24s
12h25mn22s
12h40mn14s
12h49mn59s
13h00mn24s
ns
sn
ns
sn
ew
ns/e
ns/c
ns/w
85
151
130
84
110
80
105
95
Table 1: Listing of the TIR data acquired. The nomenclature of the fly direction is the
following. Altitude of 3000 m: ns=from North to South, sn=from South to North, ew=from
East to West, we=from West to East. Altitude of 1500 m: ns(sn)/e=from North to South
(South to North) at the East of the site, ns(sn)/c=from North to South (South to North) at
the center of the site, ns(sn)/w: from North to South (South to North) at the West of the
site. *: notice that this time period seems strange compared to the other flight lines (to be
checked).
5
Date
Flight
line
Altitude
(m)
Starting
time
(U.T.)
Ending
time
(U.T.)
Flight
Direction
Number of
Numerized
Images
970410
970410
970410
970410
970410
970410
970410
1
2
3
4
5
6
7
3000
3000
3000
3000
3000
1500
1500
10h40mn13s
10h46mn05s
10h52mn45s
10h59mn37s
11h25mn11s
11h38mn33s
11h47mn37s
10h42mn04s
10h48mn08s
10h54mn59s
11h01mn55s
11h26mn10s
11h39mn45s
11h49mn15s
ns
sn
ns
sn
ew
ns/e
ns/w
100
110
120
123
55
65
90
970416
970416
970416
970416
970416
970416
970416
970416
970416
970416
1
2
3
4
5
6
7
8
9
10
3000
3000
3000
3000
3000
1500
1500
1500
1500
1500
10h50mn21s
10h55mn56s
11h08mn50s
11h15mn33s
11h21mn45s
12h02mn10s
12h05mn57s
11h38mn27s
11h47mn11s
11h55mn11s
10h51mn39s
10h58mn16s
11h10mn51s
11h17mn24s
11h23mn25s
12h03mn35s
12h07mn20s
11h39mn33s
11h48mn37s
11h56mn17s
ns
sn
ns
sn
ns
ew
we
ns/e
ns/c
ns/w
70
125
110
100
90
77
75
60
75
60
970418
970418
970418
970418
1
2
3
4
1500
1500
1500
1500
11h20mn12s
11h29mn46s
11h39mn16s
11h45mn31s
11h21mn54s
11h31mn11s
11h41mn03s
11h47mn01s
ns/e
ns/c
ns/w
ew
90
76
95
82
970424
970424
1
2
1200
1200
14h36mn57s
14h43mn41s
14h37mn58s
14h45mn01s
ns/e
ns/c
56
72
970501
970501
970501
1
2
3
1500
1500
1500
12h03mn36s
12h11mn00s
12h18mn55s
12h04mn54s
12h12mn35s
12h20mn26s
ns/e
ns/c
ns/w
70
84
81
970502
970502
970502
970502
970502
1
2
3
4
5
3000
3000
3000
3000
3000
13h28mn39s
13h33mn47s
13h40mn20s
13h56mn38s
14h05mn14s
13h30mn30s
13h35mn41s
13h42mn31s
13h58mn48s
14h07mn22s
ns
sn
ns
sn
ew
98
101
115
114
114
Table 2: Listing of the TIR data acquired. The nomenclature of the fly direction is the
following. Altitude of 3000 m: ns=from North to South, sn=from South to North, ew=from
East to West, we=from West to East. Altitude of 1500 m: ns(sn)/e=from North to South
(South to North) at the East of the site, ns(sn)/c=from North to South (South to North) at
the center of the site, ns(sn)/w: from North to South (South to North) at the West of the site.
6
Date
Flight
line
Altitude
(m)
Starting
time
(U.T.)
Ending
time
(U.T.)
Flight
Direction
Number of
Numerized
Images
970515
970515
970515
970515
1
2
3
4
1500
1500
1500
1500
12h31mn28s
12h39mn14s
12h47mn48s
12h52mn27s
12h33mn24s
12h41mn12s
12h49mn47s
12h53mn46s
ns/e
ns/c
ns/w
we
105
104
105
70
970522
970522
970522
970522
970522
970522
970522
970522
970522
970522
1
2
3
4
5
6
7
8
9
10
3000
3000
3000
3000
3000
3000
1500
1500
1500
1500
10h31mn46s
10h36mn55s
10h43mn05s
10h48mn15s
10h58mn11s
11h06mn37s
11h16mn44s
11h20mn04s
11h24mn57s
11h29mn15s
10h33mn55s
10h39mn03s
10h44mn52s
10h50mn17s
11h00mn03s
11h08mn01s
11h18mn09s
11h21mn21s
11h26mn00s
11h30mn26s
ns
sn
ns
sn
ew
ns/c
ns/c
sn/w
ns/e
ew
115
115
96
112
101
76
75
70
57
65
970609
970609
970609
970609
970609
970609
970609
970609
970609
1
2
3
4
5
6
7
8
9
3000
3000
3000
3000
3000
3000
1500
1500
1500
11h51mn00s
11h55mn47s
12h02mn27s
12h07mn17s
12h14mn10s
12h21mn57s
12h33mn58s
12h44mn06s
12h51mn59s
11h52mn12s
11h57mn01s
12h04mn30s
12h08mn34s
12h15mn55s
12h23mn59s
12h35mn37s
12h45mn17s
12h53mn04s
ns
sn
ns
sn
ns
ew
ns/w
ns/c
ns/e
65
67
110
70
94
110
90
65
60
970612
970612
970612
1
2
3
1500
1500
1500
11h20mn30s
11h30mn33s
11h38mn37s
11h22mn00s
11h31mn40s
11h39mn49s
ns/e
ns/c
ns/w
81
60
64
Table 3: Listing of the TIR data acquired. The nomenclature of the fly direction is the
following. Altitude of 3000 m: ns=from North to South, sn=from South to North, ew=from
East to West, we=from West to East. Altitude of 1500 m: ns(sn)/e=from North to South
(South to North) at the East of the site, ns(sn)/c=from North to South (South to North) at
the center of the site, ns(sn)/w: from North to South (South to North) at the West of the site.
7
Date
Flight
line
Altitude
(m)
Starting
time
(U.T.)
Ending
time
(U.T.)
Flight
Direction
Number of
Numerized
Images
970624
970624
970624
970624
970624
970624
970624
970624
1
2
3
4
5
6
7
8
3000
3000
3000
3000
3000
1500
1500
1500
11h55mn50s
12h06mn44s
12h13mn56s
12h19mn34s
12h28mn08s
12h43mn08s
12h46mn59s
12h51mn07s
11h56mn56s
12h08mn29s
12h15mn13s
12h21mn06s
12h29mn50s
12h44mn41s
12h47mn56s
12h52mn26s
ns
ns
sn
ns
ew
ns/c
sn/w
ns/e
60
93
70
83
90
77
60
70
970708
970708
970708
970708
970708
970708
970708
970708
970708
970708
970708
1
2
3
4
5
6
7
8
9
10
11
3000
3000
3000
3000
3000
3000
3000
1500
1500
1500
1500
11h49mn12s
11h53mn05s
11h59mn47s
12h05mn08s
12h11mn38s
12h19mn56s
12h25mn08s
12h37mn28s
12h45mn03s
12h48mn54s
12h55mn07s
11h50mn35s
11h54mn59s
12h01mn38s
12h07mn02s
12h13mn26s
12h21mn29s
12h26mn50s
12h39mn10s
12h46mn50s
12h50mn29s
12h56mn40s
ns
sn
ns
sn
ns
we
ew
ns/e
ns/c
sn/c
ns/w
75
100
100
103
97
85
93
92
97
85
84
970728
970728
970728
1
2
3
1500
1500
1500
11h41mn56s
11h50mn55s
11h58mn18s
11h44mn09s
11h53mn08s
12h00mn33s
ns/e
ns/c
ns/w
120
120
119
970729
970729
970729
970729
970729
970729
970729
970729
1
2
3
4
5
6
7
8
3000
3000
3000
3000
3000
1500
1500
1500
12h49mn57s
12h54mn37s
13h00mn57s
13h07mn33s
13h15mn35s
13h54mn26s
13h58mn33s
14h02mn19s
12h51mn31s
12h56mn39s
13h03mn08s
13h09mn03s
13h17mn40s
13h56mn11s
14h00mn04s
14h04mn15s
ns
sn
ns
sn
ew
ns/e
sn/c
ns/w
83
108
115
80
110
95
82
105
Table 4: Listing of the TIR data acquired. The nomenclature of the fly direction is the
following. Altitude of 3000 m: ns=from North to South, sn=from South to North, ew=from
East to West, we=from West to East. Altitude of 1500 m: ns(sn)/e=from North to South
(South to North) at the East of the site, ns(sn)/c=from North to South (South to North) at
the center of the site, ns(sn)/w: from North to South (South to North) at the West of the site.
8
Date
Flight
line
Altitude
(m)
Starting
time
(U.T.)
Ending
time
(U.T.)
Flight
Direction
Number of
Numerized
Images
970904
970904
970904
970904
970904
970904
970904
970904
1
2
3
4
5
6
7
8
3000
3000
3000
3000
3000
1500
1500
1500
12h12mn42s
12h18mn27s
12h26mn08s
12h30mn07s
12h39mn37s
12h52mn23s
12h55mn36s
13h00mn53s
12h14mn45s
12h20mn27s
12h27mn51s
12h32mn16s
12h41mn36s
12h53mn45s
12h57mn03s
13h02mn35s
sn
sn
ns
sn(??)
ew
ns/e
sn/c
ns/w
110
108
92
114
107
74
80
90
970909
970909
970909
970909
1
2
3
4
1500
1500
1500
1500
11h26mn32s
11h29mn43s
11h35mn03s
11h44mn31s
11h27mn41s
11h30mn52s
11h36mn08s
11h45mn31s
ns/e
sn/c
ns/c
ns/w
62
63
58
54
970918
970918
970918
970918
970918
970918
970918
970918
1
2
3
4
5
6
7
8
3000
3000
3000
3000
3000
1500
1500
1500
11h20mn07s
11h25mn12s
11h32mn02s
11h37mn19s
11h46mn11s
11h57mn17s
12h06mn58s
12h16mn16s
11h23mn53s
11h29mn03s
11h35mn53s
11h41mn21s
11h49mn05s
12h00mn06s
12h09mn46s
12h19mn15s
ns
sn
ns
sn
ew
ns/e
ns/c
ns/w
200
205
205
215
155
150
150
160
Table 5: Listing of the TIR data acquired. The nomenclature of the fly direction is the
following. Altitude of 3000 m: ns=from North to South, sn=from South to North, ew=from
East to West, we=from West to East. Altitude of 1500 m: ns(sn)/e=from North to South
(South to North) at the East of the site, ns(sn)/c=from North to South (South to North) at
the center of the site, ns(sn)/w: from North to South (South to North) at the West of the site.
(??): to be checked.
9
2-Radiosoundings
The radiosoundings we used for the atmospheric corrections were launched around solar
noon by METEO FRANCE meteorological station close to the Nîmes airport. This station
was located 30 km toward the West of the experimental site, and its altitude was about 60 m
from sea level. The radiosoundings provided atmospheric profiles of pressure, temperature
and humidity. Measurement levels corresponded to a 250 mbar pressure decreasing scale,
and to characteristic points representing an inversion in temperature or humidity. This leads
to approximately 30 levels of measurements between 0 and 10 km.
10
References
Inframetrics (1991). INFRAMETRICS MODEL 760. Operator’s manual, Inframetrics
Incorporation.
Olioso, A., Braud, I., Chanzy, A., Ducros, Y., Gaudu, J.C., Gonzales-Soza, E, Lewan, L.,
Marloie, O., Ottlé, C., Prévot, L., Autret, H., Bethenod, I., Bonnefond, J.M., Bruguier,
N., Calvet, J.C., Chauki, H., Goujet, R., Jongschaap, R., Kerr, Y., Lagouarde, J.P., Laurent, J.P., McAnneney, J, Moulin, S., Thony, J.L., Weiss, M., & Wigneron, J.-P. (2001).
SVAT modeling over the Alpilles-ReSeDA experiment: experimental setup for monitoring energy and mass transfers. In: Agronomie, Alpilles-ReSeDA special issue.
Prévot, L., Baret, F., Chanzy, A., Olioso, A., Wigneron, J.P., Autret, H., Baudin, F., Bessemoulin, P., Bethenod, O., Blamont, D., Blavoux, B., Bonnefond, J.M., Boubkraoui, S.,
Bouman, B.A.M., Braud, I., Bruguier, N., Calvet, J.C., Caselles, V., Chauki, H., Clevers,
J.G.P.W., Coll, C., Company, A., Courault, D., Dedieu, G., Degenne, P., Delécolle, R.,
Denis, H., Desprats, J.F., Ducros, Y., Dyer, D., Fies, J.C., Fischer, A., Francois, C.,
Gaudu, J.C., Gonzalez, E., Gouget, R., Gu, X.F., Guérif, M., Hanocq, J.F., Hautecoeur,
J.F., Haverkamp, R., Hobbs, S., Jacob, F., Jeansoulin, R., Jongschaap, R.E.E., Kerr, Y.,
King, C., Laborie, P., Lagouarde, J.P., Laques, A.E., Larcena, D., Laurent, G., Laurent,
J.P., Leroy, M., McAneney, J., Macelloni, G., Moulin, S., Noilhan, J., Ottlé, C., Paloscia,
S., Pampaloni, P., Podvin, T., Quaracino, F., Roujean, J.L., Rozier, C., Ruisi, R., Susini,
C., Taconet, O., Tallet, N., Thony, J.L., Travi, Y., Van Leewen, H., Vauclin, M., VidalMadjar, D, Vonder, O.W., & Weiss, M. (1998). Assimilation of multisensor and multitemporal remote sensing data to monitor vegetation and soil: the Alpilles ReSeDA project.
In: IGARSS’98 International Geoscience and Remote Sensing Symposium, Tsang L. Ed.,
IEEE, Institute of Electrical and Electronics Engineers, Piscataway (USA), Sensing and
managing the environment, vol. 5, pp. 2399–2401.
11