-------�
experiment. In addition, the MDS could display in real-time selected para-
meters and tower profiles. Data from the 10-m, 30-m and 60-m towers were
transmitted by ARLFRD radio links to the command post near the 150-m tower.
The 150-m tower data were transmitted to the command post by shielded signal
cable to the data acquistion computer in the command post, a distance of about
50 m.
At least three different types of noise were observed in the 1-sec data
during the SHIS# 2 experiments—large "hits", which drove the instrument
output voltages outside their 0-5 VDC range; "channel-skipping," in which the
data from one input channel was skipped and replaced by the data from the
next sequentially polled channel, with the shift of the data continuing to
the end of the 16-channel multiplexor; and "high frequency" noise bursts that
caused a few seconds of data to oscillate unrealistically at consistent
periods within each 5-minute averaging period. These three types of noise are
more fully described in the Third Milestone Report (Lavery et al 1982) and in
the HBR Quality Assurance Report (Greene and Heisler, 1983).
The large "hits" were generally easy to identify and remove from the
data; the other two types of noise were less so. ARLFRD developed a "fil-
tering" routine that examined the second-to-second cha'nges in instrument
output and replaced values that exceeded what they regarded as reasonable
limits for such changes; these limits are shown in Table 3. Data removed
from the 1-sec data by this filtering procedure were replaced by linear
interpolation in time between the last good value and the next good value.
Besides sampling output data from 86 meteorological sensors, voltages were
converted to engineering units, derived measurements computed from measured
values, and the raw 1-sec data base was filtered to remove obvious spurious
data. A new flagged 1-sec data base was produced, and calculated 5-min and
Ihour averages were compiled into two additional data bases using only data
with "good" flags in the 1-sec data. The filtering and flagging process
resulted in data flagged as follows:
24
-------�
TABLE 3. ALLOWABLE SECOND-TO-SECOND SENSOR CHANGES USED TO
FILTER RAW DATA IN PROCESSING THE 1-SEC DATA BASE
Sensor Max
Units
U, V, prop
W prop
cup anemometer
wind vane
temperature
delta-T
fast temperature
Voltage Increment
0.200
0.200
0.200
0.150
0.100
0.100
0.100
Approx. Change In
2.0 m/sec
0.8 m/sec
2.0 m/sec
16.0 degrees
1.6 degrees C
0.4 degrees C
1.6 degrees C
25
-------�
11 " (blank) good data
"0" Over maximum range limit
"U" Under minimum range limit
"L" Lost (first affected channel in channel-skip)
"M" Moved (reassigned from previous channel by
skip-correction)
"T" Tower noise limit exceeded
"S" Several (more than one) flag from the above
Only the " " and "M" flags indicate valid data.
In 5-min and 1-hour data bases, data quality flags have been appended
to values averaged from the 1-sec data as follows:
E (excellent): 97% or more of points in average are valid
blank: 75% to 97% of points in average are valid
S (suspect): 50% to 75% of points in average are valid
B (bad): less than 50% of points in average are valid
UVW anemometer data in the 1-sec data base were treated by cali-
bration factors determined by ERT at the FMF large wind tunnel at Research
Triangle Park, NC. Also, correction factors for non-cosine response were
found and applied to the data. Responses of the Climatronics instruments
were generally a few percent lower than those derived by Clarke (1982) for
the R.M. Young instruments. Stall regions of the Climatronics may also be
wider; and the over-response for non-stalled props between 92 deg and 95 deg
and between 265 deg and 268 deg for the V-prop seems not to have occurred
with R.M. Young instruments.
The reason for this latter effect may be the propeller shaft extensions
on the Young instrument. Another possible contributor is a general divergence
of flow around the Climatronics UVW system. A smoke streak in the FMF tunnel
26
-------�
(Greene 1985) into the center of the vertical W-arm rose quite noteceably as
it approached the equiptment; this accounting for the fact that the W-props
frequently turned in a positive (upward) sense when the horizontal arms were
being tested for response. For complete details, the Quality Assurance Pro-
ject Report for SHIS #2 (Greene, 1985) should be consulted.
3.1.2 Pariods Of Data Collection
Table 4 shows the dates and times of the experiments and the concurrent
periods of meteorological tower data collection. No meteorological data were
collected for the first three experiments, October 5, 6 and 7. Collection
began with experiment #4, which began on October 23 at 2300 hours MDT and
ended on October 11 at 0900 hours. No data were recorded during experiment
#13 due to wind flow from the wrong (westerly) direction.
3.2 TOWER METEOROLOGICAL DATA TAPE FILES
Data are stored at the National Computer Center, Environmental Research
Center, Research Triangle Park, North Carolina on Sperry UNIVAC 1100/83
systems magnetic tape, nine track, odd parity, ASCII-quarter word mode,
density 6250 8PI, tape number 004972. Record length is 132 characters, and
the block size is 1320 words or 40 records per block. UNIVAC users may
assign the tape, @ASG,T HBR.U9S//////Q,004972 using UNIVAC Executive Control
Language (ECL). Upon request, copies can be furnished and translated into
formats acceptable to any computer using 9-track tape drives.
3.2.1 Meteorological Data Tape File Index
Four sets of tower meteorological data files are recorded on tape number
004972. The first set, file numbers 1 to 176, contain data from Tower A, 5-
minute averages, as illustrated in Table 5. There are 16 tape files for each
experiment; the data fields in each file correspond to one or more meteorolog-
ical measures as illustrated in Table 6. With the tape files partitioned in
this manner, given a particular experiment, the parameter desired can be
27
-------�
TABLE 4. PERIODS OF SHIS #2 EXPERIMENTAL HOURS OF
METEOROLOGICAL TOWER DATA
Experiment No.
1
2
3
4
5
6
7
8
9
10
11
12
13*
14
15
Date
Oct. 1982
5
6
7
10-11
12
12-13
13-14
14-15
20
21-22
22-23
23-24
25
25-26
28-29
Times
MDT
—
—
—
10/2300-11/0900
12/0000-0700
12/2300-13/0800
13/2000-14/0800
14/2300-15/0800
20/0100-0900
21/2100-22/1000
22/2200-23/0900
23/2300-24/1100
—
25/2100-26/1000
28/2200-29/1000
* Experiment 13 was terminated due to unfavorable weather.
28
-------�
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29
-------�
TABLE 6. TOWER A DATA TAPE FILES
File
Type
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Data
Fields
10
10
10
10
10
10
10
10
6
6
10
3
10
9
10
9
U -
V -
U -
SU -
SV -
sw -
s -
D -
SX -
DX -
UX -
VX -
SO -
XI -
T -
TC -
DT -
UW -
TF -
WT -
ST -
X2 -
Data Measure
Westerly wind component from props, m/s
Southerly wind component from props, m/s
Vertical wind component from props, m/s
Sigma u, Standard deviation of component of
horizontal wind speed along mean wind
direction from props, m/s
Sigma v, Standard deviation of component of
horizontal wind speed perpendicular to mean
wind direction from props, m/s
Sigma w, Standard deviation of vertical
wind component from props, m/s
Scalar mean wind speed from props, m/s
Scalar mean wind direction from props, deg
Scalar mean wind speed from cups, m/s
Scalar mean wind direction from vane, deg
Westerly wind component average from cup &
vane, m/s
Southerly rfind component average from cup &
vane, m/s
Sigma theta, Standard deviation of wind
direction from props deg
Sigma theta, Standard deviation of wind
direction from cup & vane; Yamartino
algorithm deg
Temperature from steel -encapsulated plati-
num resistance thermometric device (RTD), C
Calculated temperature = T + DT, C
Temperature difference from reference temp-
erature (RTD) , C
Vertical momentum flux, u'w' from props,
where u is total horizontal speed, (m/s)2
Temperature from "fast response" platinum
bead thermistor, C
Vertical heat flux, w't1 from w-prop and
tf, m/s C
Variance of tf, C
Sigma theta, Standard deviation of wind
direction from cup & vane, deg
30
-------�
TABLE 6a. TOWER A METEOROLOGICAL RECORD TYPES
Tape Record Measures Levels
Type
1 U - Westerly Wind Component 2m, 5m, 10m, 20m, 30m,
40m, 60m, 80m, 100m, 150m
2 V - Southerly Wind Component "
3 W - Vertical Wind Component "
4 SU - Sigma U, Turbulence Measure "
of U
5 SV - Sigma V, Turbulence Measure "
of V
6 SW - Sigma W, Turbulence Measure "
of W
7 S - Scalar Mean Wind Speed, Props "
8 D - Scalar Mean Wind Direction, Props "
9 SX, DX - Scalar Mean Wind Speed and 20m, 40m, 60m
Direction, Cup-and-Vane
10 UX, VX - Scalar Averaged U and V
Components, Cup-and-Vane
11 SD - Sigma Theta, Props 2m, 5m, 10m, 20m, 30m
40m, 60m, 80m, 100m, 150m
12 XI - Sigma Theta, Cup-and-Vane " 20m, 40m, 60m
Equation 25, (Yamartino, 1984)
13 T, TC - Slow RTD Temperature and 2m, 5m, 10m, 20m, 30m,
Calculated TC = [T(2m)+DT] 40m, 60m, 80m, 100m, 150m
14 DT - Slow RTD Temperature Differnce "
from T(2m)
15 UW - Correlation of S vs. W "
TF, WT, ST, X2, - Fast Thermistor
16 Temperature, Correlation of TF vs.
W, Variance of TF, Sigma Theta
Cup-and-Vane
31
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quickly accessed. Of the measures recorded, Table 6, 11, V, W, T, DT, TF, SX
and DX are simple 5-minute averages of direct, sometimes corrected, instru-
ment output. All the rest were derived indirectly from algorithms using one
or more of the direct instrument outputs. Table 6a indicates the tower levels
where data */ere measured.
The second set of data files, file numbers 177 to 352, contain data from
Towers B, C, and P, 5-minute averages as indicated in Table 7. There are
16 tape files for each experiment, the record types in each file correspond-
ing to one or more meteorological measures as shown in Table 8. Record types
differ from those in the first set since data from one or more towers are
combined on each file, although the measures contained are the same as in the
first set, with the exception of the last file (16) in each experiment where
only X2, sigma-theta values for cup & vane anemometers are available for
Towers B, C, and P.
The third set of data files, numbers 353 to 363, contain meteorological
data from Tower A, 1-hour average as illustrated in Table 9. There are 11
tape files, one for each experiment, with data measures arranged in the same
sequence as in the first set, 5-minute values.
The fourth set of data files, numbers 364 to 374, contain meteorolog-
ical data from Towers B, C, and P, 1-hour averages as illustrated in Table
9. There are 11 tape files, one for each experiment, with data measures
arranged in the same sequence as in the second set, 5-minute values.
3.2.2 Tape File Records
The first five records of each file contain alphabetic ASCII characters
of identification information and column headings for the data fields in the
records that follow. The first five records are FORTRAN, formatted (132A1).
Column headings are coded in the last two heading records, where the first
record identifies columns of date, time and the meteorological measures,
and the second record identifies tower levels where the data were observed.
33
-------�
TABLE 8. TOWERS B, C, P METEOROLOGICAL RECORD TYPES
Tape Record
Type
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
U -
V -
W -
SU
SV
SW
s -
D -
sx,
ux,
SD
XI
- T,
DT
UW
.
X2
Measures
Westerly Wind Component
Southerly Wind Component
Vertical Wind Component
- Sigma U, Turbulence Measure
of U
- Sigma V, Turbulence Measure
of V
- Sigma W, Turbulence Measure
of W
Scalar Mean Wind Speed, Props
Scalar Mean Wind Direction, Props
DX - Scalar Mean Wind Speed and
Direction, Cup-and-Vane
VX - Scalar Averaged U and V
Components, Cup-and-Vane
- Sigma Theta, Props
- Sigma Theta, Cup-and-Vane
Equation 25, (Yamartino, 1984)
TC - Slow RTD Temperature and
Calculated TC
- Slow RTD Temperature
Difference from T
- Correlation of S vs. W
- Sigma Theta, Cup-and-Vane
Towers Levels
B
C
B
P
8
C
B
P
B
C
P
B
C
P
B
C
B
P
5m,
2m,
11
11
ii
U
11
U
n
1m,
18m
11
5m,
2m,
1m,
18m
1m,
20m
2m,
9m,
5m,
20m
5m,
60m
5m,
2m,
1m,
18m
20m,
5m,
10m,
, 60m
20m,
5m,
10m,
, 60m
5m,
, 30m
5m,
60n
10m,
, 30m
10m
20m,
5m,
20m,
, 60m
30m
10m
30m
30m
10m
30m
10m
10m
30m
10m
30m
34
-------�
TABLE 9. METEOROLOGICAL DATA - 1-HOUR AVERAGES
TAPE FILE NUMBERS
Experiment No.
4
5
6
7
8
9
10
n
12
14
15
TOWER A
353
354
355
356
357
358
359
360
361
362
363
TOWERS B, C, P
364
365
366
367
368
369
370
371
372
373
374
35
-------�
All data records following the first five alphabetic heading records
have data fields arranged as shown in Table 10.
TABLE 10. DATA RECORDS FORMAT
Position Contents FORTRAN Format
1 to 4 Year 1982 14
5 to 6 Month 10 12
7 to 8 Day 12
9 to 10 Hour 00-23 12
11 to 12 Minute 00-55 12
13 to 14 Second 00 12
15 to 16 Blank 2X
17 to 24 Meteorological Data F8.3
25 Data Quality Flag Al
26 to 132 Meteorological Data & (F8.3.A1)
Data Quality Flags
Table 11 is a printout of the heading records from the first 16
files, experiment #4, from the first set of meteorological data files from
Tower A. All five heading records and the first two data records are
presented for tape file #1, while only the last two heading records and two
data records are shown for tape files #2 to #16. It illustrates how the
alphabetic heading records identify columns of data fields in the data
records that follow. Each data record contains 5-minute averages of
observed or derived meteorological measures from the levels on Tower A as
indicated by the notations on the heading records.
Table 12 is a similar printout, experiment #4, from the second set of
meteorological data files from Towers B, C, and P. There are six alphabetic
36
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header records in the first block of each file since and extra record is
needed to specify the three towers. All six header records and the first
two data records are presented for tape file #177, while only the last
three heading records and two data records are shown for tape files #178 to
#192.
Table 13 is a printout of an illustration of the first block of the
first file, experiment #4 from the third set for data files, 1-hourly
averages from Tower A. Since only eight or nine hours of observations were
taken during each experiment, all meteorological measures were placed on
one file for each experiment. A complete set of header records are pre-
sented on the first block of each file, while two header records identify
measures and tower levels ahead for each of 16 groups of data.
Table 14 shows a printout of the first block of the first file, exper-
iment #4, from the fourth set of data files containing 1-hour averages of
meteorological data from Towers B, C, and P. As in the preceding set for
data files, Each file contains 1-hourly averages for one experiment. A
complete set of header records are presented on the first block of each file,
while three header records identify measures, towers and tower levels for
each of the 16 groups of data.
42
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SECTION 4
TRACER GAS DATA
4.1 TRACER GAS RELEASE SYSTEM
Two tracer gases, SF6 and CF3BR (Freon 13B1), were released at different
heights from either Tower A, the 150-m tower, or from the boom of a mobile
crane operating on one of three roads east of HBR. The roads were culverted,
graded and graveled to support the 150-ft crane that lifted an oil-fog gener-
ator and the tracer gas release tubes. The SF6 release was collocated with
the oil-fog release and dispersed from a common nozzle. Occasionally, the
SF6 and the oil-fog were released from the tower while the CFSBr was released
from the crane at a different location.
The SF6 and CFSBr tracer gases were stored in individual compressed gas
cylinders at ground level. Piping carried each gas through a linear mass
flow meter (LFM) system to the point of discharge into the atmosphere. A
time history of each tracer release was used to describe the rate and the quan-
tity of release of tracer. The LFM measured and displayed the rate of gaseous
tracer discharge via real-time digital display, the total amount of gas
discharged via a digital counter, and an analog output voltage directly
proportional to the flow rate. The voltage was logged and monitored on a
strip chart recorder. Pre- and post-test release weights of tracer gas cylin-
ders were measured by certified scales. Beginning and ending times of tracer
release and the time and character of any deviations from the design rate-of-
release were logged. Table 15 presents the hourly average tracer release
rates (g/sec) for both gases for each experiment along with the locations
and height of release. Tracer release points (TRP) are shown in Figure 7aand
are determined with respect to the base of Tower A. Elevation at release
point (HT) is determined with respect to ground elevation at release point.
45
-------�
TABLE 15. TRACER RELEASE DATA - EMISSIONS (Q) SF6 AND CF3Br
Hour
End
Fxp #4
0200
0300
0400
0500
0600
0700
0800
EXP #5
0100
0200
0300
0400
0500
0600
0700
EXP #6
0000
0100
0200
0300
0400
0500
0600
0700
0800
EXP #7
0200
0300
0400
0500
0600
0700
0800
EXP #8
0000
0100
0200
0300
0400
0500
0600
0700
0800
SF6
Q Ht.
g/sec m
- 10/11/82
0.7/ 20
0.77 20
0.90 30
0.76 40
0.84 20
0.86 30
0.86 30
- 10/12/82
0.70 40
0.54 30
0.49 25
0.49 25
0.60 20
0.60 20
0.68 30
- 10/13/82
0.37 40
0.37 40
0.32 30
0.32 30
—
0.50 40
0.37 35
0.37 35
0.37 30
- 10/14/82
0.52 30
0.52 30
0.46 20
0.46 20
0.51 15
0.51 15
0.43 25
- 10/15/82
0.26 30
0.24 20
0.24 10
0.24 10
0.23 40
0.23 35
0.23 35
0.23 30
0.23 30
CF3BR
Release
Point
4(216)
M
H
ii
H
H
H
2(203)
H
H
H
H
H
u
5(111)
n
u
n
_
2(203)
n
n
u
2(203)
n
n
n
u
n
n
3(215)
11
II
II
II
II
II
tl
U
(continued)
46
Q
g/sec
1.45
1.42
1.23
1.35
1.34
1.34
1.39
1.31
1.32
1.32
1.33
1.33
1.26
1.32
1.32
1.35
1.35
1.56
1.33
1.33
1.30
1.37
1.37
1.37
1.37
1.36
1.36
1.31
1.09
1.01
1.00
1.00
0.97
0.97
0.97
0.96
0.98
Ht.
m
-
10
20
30
10
20
20
25
15
20
20
15
15
25
30
30
20
20
—
30
25
25
20
20
20
15
15
10
10
5
20
10
5
5
30
25
25
30
15
Release
Point
-
4(216)
n
n
n
n
n
2(203)
u
n
n
n
ii
it
5(111)
11
"
M
_
2(203)
u
n
u
2(203)
u
n
ii
u
u
n
3(215)
n
n
u
n
u
11
u
11
-------�
TABLE 15. Continued
TRACER RELEASE DATA - EMISSIONS (Q) SF6 and CF3Br
SF6
Hour Q Ht.
End g/sec m
EXP #9 - 10/20/82
0500 0.20 30
0600 0.20 30
0700 0.20 40
0800 0.20 40
0900 0.20 40
EXP #10 - 10/22/82
0100 0.22 30
0150 0.22 30
0200
0300 0.23 50
0400 0.23 50
0500 0.21 70
0600 0.21 70
0700 0.21 70
0800 0.21 70
0900 0.21 70
1000 0.21 70
1100 0.21 70
EXP #11 - 10/23/82
0000 0.27 40
0100 0.27 40
0200 0.27 40
0300 0.27 40
0400
0500 0.29 50
0600 0.29 50
0700 0.29 50
0800 0.29 25
0900 0.29 25
EXP "#12 - 10/24/82
0200 0.31 75
0300 0.31 75
0400 0.30 50
0500 0.30 50
0600 0.30 75
0700 0.31 75
0800
0900 0.30 50
1000 0.30 50
1100 0.30 50
CF3BR
Rel ease Q
Point g/sec
2(203) 0.90
0.90
0.93
0.93
0.93
2(203) 0.96
0.96
TWR A 1.53
1.53
1.31
1.31
1.31
1.31
1.31
1.31
1.31
2(203) 0.94
0.94
0.94
0.94
TWR A 1.31
1.31
1.31
1.35
1.35
TWR A 1.13
1.35
1.35
1.35
1.32
1.32
"
1.34
1.34
1.34
(continued)
47
Ht.
m
20
20
20
20
20
20
20
--
30
30
30
30
30
30
30
30
30
20
20
20
20
--
25
25
25
10
10
40
40
50
25
25
25
--
40
40
40
Release
Point
2(203)
"
"
"
"
2(203)
n
TOR A
"
11
"
"
"
n
"
"
2(203)
"
11
"
-
TWR A
"
"
"
"
TWR A
1
1
1
1
1
1
1
1
-------�
TABLE 15. Continued
TRACER RELEASE DATA - EMISSIONS (Q) SF6 and CFSBr
Hour
End
EXT #14
2300
2357
0100
0200
0300
0400
0500
0600
0700
0800
0900
1000
EXP #15
0000
0100
0200
0300
0400
0450
0500
0600
0645
0700
0800
0900
1000
1058
Q
g/sec
SI- fa
Ht
m
CF3BR
. Release
Point
Q
g/sec
Ht.
m
Release
Point
- 10/25-26/82
0.
0.
—
--
0.
0.
0.
0.
0.
0.
0.
0.
28
29
--
—
30
30
30
30
30
30
30
30
b
5
-
-
40
40
40
40
40
40
40
40
10/29/82
0.
0.
0.
0.
0.
0.
--
0.
0.
--
0.
0.
0.
0.
Tracer Release
TRP
30
30
30
30
29
29
—
28
28
—
27
27
27
28
20
20
20
20
40
40
--
50
50
—
50
50
50
50
Points
1 (R-80)
2 (203)
3 (215)
4 (216)
5 (111)
TWR A
TWR C
TWR C
"
-
-
2(203)
"
11
"
"
11
"
"
0
1
-
.
0
0
0
0
-
1
1
1
.89
.09
—
__-
.94
.93
.93
.94
— _
.33
.33
.33
10
2
-
_
20
20
20
20
--
35
35
35
TWR C
"
-
-
2(203)
"
"
"
-
TWR A
11
"
KR-80)
"
11
11
"
11
TWR A
"
"
n
11
"
a
1
1
1
1
1
1
-
1
1
1
1
1
Azimuth Range
deg
330.
313.
312.
312.
271.
0.
282.
m
1 574
0 454
2 334
1 324
7 391
0 0
9 829
.9
.8
.9
.9
.7
.0
.1
.36
.36
.36
.36
.36
.36
—
.34
.34
.34
.34
.34
X
m
-287
-332
-248
-241
-391
0
-807
40
40
40
40
40
40
--
40
40
40
40
40
.5
.6
.1
.3
.5
.0
.2
TWR
11
"
11
11
"
11
11
11
"
"
Y
m
497.9
310.2
225.0
217.5
11.9
0.0
179.6
A
Z
m
21
17
12
.7
.4
.9
12.4
12
3
86
.5
.7
.7
All azimuths, ranges and coordinates (X,Y,Z) are relative to the base of
tower A (TWR A).
Datum (Z=0) = 1600 m MSL.
48
-------�
4.2 TRACER GAS SAMPLING SYSTEM
Tracer samples were collected in 2-liter Tedlar bags at about 110
locations on the ridge at a height of approximately 0.5 m above the ground.
ARLFRD operated 125 samplers during each approximately 8-hour experiment.
Each sampler contained 12 individual pumps, each of which intermittently
(1-sec every 28 sec) filled a Tedlar bag over the period of interest. Thus,
each sampler could take sequential 1-hour samples over a 12-hour period or
sequential 10-minute samples over a 2-hour period. Twenty samplers were used
to get 10-minute averages at five locations. The remaining 105 samplers were
used to get 1-hour samples. Two of the 1-hour samplers were operated on the
30-m Tower B and one on the 10-m Tower C.
The bag samples were collected by means of modified EMI AQSIII or sim-
ilar type of air sampler. Each sampler used 12 separate pumps, bags, and
external tubes to draw in ambient air to fill 12 individual 2-liter Tedlar
bags. The system was battery powered and electronically programmed in func-
tion and timing. Time was set and maintained by a crystal-controlled digital
clock accurate to within 1 minute per month. Beginning and ending sampling
times for the individual (sequential) whole air samples were controlled by
this clock. The actual local time (MOT) for the beginning of the sampling
sequence for each unit was preprogrammed during the servicing by sampling
team technicians about 20 hours prior to the start of each experiment.
The sampler locations are shown in Figure 7. Samplers were deployed
in rows parallel to the axis if HBR, often at points surveyed in a 20 x 20-m
grid. Locations were selected on the basis of observations during the prelim-
inary flow study performed in June 1982, wind tunnel and tow-tank simulations
done by EPA FMF, and meteorological data collected by PNM. Tables 16 and 17
summarize the characteristics of the sampling grid.
49
-------�
: Mil
.
?• -is/ r\\\i\\\\-\i ^ ^-
u
TJ
to
ta
•«
<
to
CO
n.
0)
n
to
03
u
o.
o
•o
CO
0)
o
CO
O
o
V-i
0)
r-1
D.
CO
w
CO
CO
60
1-1
CU
O
CO
J-i
H
0)
S-i
60
z
Oo
50
-------�
!«5'
;:«*iiin
8 S
" 3
in
c
O
(J
O
O)
o
o
Q.
(I)
in
-------�
TABLE 16. PRIMARY SAMPLER LOCATIONS
A. Four Primary Sampler Rows on Windward Face Of HBR
#1 10 HI above base of Tower B
- 16 locations centered on Tower B
- 80-m horizontal spacing covering 1200 m
n 25 m above ffl
- 17 locations centered on Tower B
- 40-m horizontal spacing out to 200 m, 30 m spacing to
460 m from center; total range is 920 m.
#3 25 m above #2
- 21 locations centered on Tower B
- 40-m horizontal spacing covering 800 m
#4 follows the crest of HBR; mean height is 10 m above #3
- 22 locations centered on Tower B
- nominal 40-m spacing covers 860 m
B Three Secondary Rows on Windward Face of HBR
#1 lies among hillocks at base of HBR
- 5 locations centered on Tower B; middle is at Tower B,
adjacent 2 atop hillocks near the road, 2 ends are in
low areas adjacent to these
#2 lies between primary rows #1 and #2, 13 m above #1
- 4 samplers centered on Tower B
- 100 m spacing covers 300 m
#3 lies between primary rows #2 and #3, 13 m above #2
- 4 samplers centered on Tower B
- 100 m 'spacing covers 300 m
C Two Lee-Side Rows
- 5 samplers in each row, centered on Tower B
- 100-m spacing along and between rows
- covers 500 m along each row
- covers out to 280 m west of crest
51
-------�
TABLE 17. ADDITIONAL SAMPLERS
Collocated Samplers: two locations along center of grid;
one on primary row #1, one an primary row #3.
10-minute Samplers: five locations; one at grid center along
primary row #2; two along primary row #1, 80 m to either side
of center; two along primary row #2, 280 m apart, centered
20 m south of grid center
Background Samplers: one on the east side of Waughan Arroyo;
one near the acoustic radar near the substation on the high
ground of the east arroyo; data are not available at this time.
"Edge" Samplers: one to the north of the grid on the road
up to the top of HBR beyond the lidar; one to the south
where the San Juan River flows through a gap in the ridge;
data are not available at this time.
Elevated Samplers: one on Tower C at 8 m; two on Tower B at
14 m and 25 m.
The grid was designed to give wide horizontal coverage near the base of
the ridge and highest resolution between half way up and the crest. Three
primary rows followed height contours and the fourth primary row ran near the
crest. Samplers were deployed less densely in the lee. Some samplers near
the top of the ridge were placed deliberately on rocky promontories or crests,
some in cols, and some in the lee of rocky escarpments in an effort to measure
concentrations in different exposures and to capture possible effects of
flow separation.
Three elevated samplers were mounted on the shorter meteorological
towers, 14 m and 25 m on Tower B at the base on the ridge, and one at 8 m on
Tower C on the crest. The upper sampler on Tower B was at 30 m through
Experiment #8, whereafter it was lowered so it would not affect the meteor-
ologocal measurements at 30 m.
52
-------�
Within the main grid, two samplers were deployed at each of two sites as
collocated samplers. The intent of these samplers was to provide QC informa-
tion relating to the representativeness and reproducibility aspects of the
precision of tracer measurements made by the intermittent 1-hour samplers. In
fact the data from these pairs of samplers probably give the best estimates of
the total precision of the concentrations (Greene, 1985).
At five locations, four samplers were set out to take samples only
10 minutes long to provide some basis for estimating the variability of concen-
trations within each sampling hour and the utility of modeling for short time
periods. These sampler sites were selected to give some spatial coverage of
the intended impact area.
Other samplers were set out to get concentration data farther afield.
"Background" samplers were deployed to the east of the ridge in the expected
approach flow. One sampler was near the power substation by the Doppler
acoustic sounder in case SF6 were emitted there or ad vected from Farmington;
one was near the east side of the main arroyo northeast of the experiment
site to measure any tracer that might drift over from the San Juan Power
Plant. A third sampler was located part-way up the ridge about a mile NNE of
the release area to become an "edge" sampler, and a fourth remote sampler was
located north of the San Juan River near the outlet of the arroyo to the east
of HBR. Data from these samplers are not available for inclusion with sam-
plers on HBR, but will be available at a later time.
Table 18 shows the list of all sampler site by number with locations
indicated by range and azimuth from the base of Tower A, and by X,Y coordi-
nates with an origin at Tower A. Elevations Z, are measured from a datum of
1600 m MSL.
53
-------�
TABLE 18. TRACER GAS SAMPLER NETWORK
Sampl er
ID
1
2
3 B
4
5
101
102
103
104
105
106
107
108
109 Cl
110
111
112
113
114
115
116
117
118
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
8
(deg)
274.1
281.9
289.1
293.7
305.5
335.7
331.1
326.5
320.4
312.7
305.5
305.4
296.2
290.0
287.6
278.2
274.4
268.4
262.5
257.9
253.7
250.2
247.6
327.6
320.9
315.3
308.4
305.5
305.1
301.9
298.1
297.2
294.9
287.8
289.4
284.8
281.2
281.4
277.9
274.5
269.4
263.2
258.7
R
(m)
536.6
500.2
533.1
489.7
520.2
791.2
735.5
666.5
634.4
595.9
578.2
630.2
627.6
572.6
638.4
660.9
614.4
664.7
705.0
754.6
813 9
873.7
994.9
793.0
744.1
691.4
671.3
668.3
691.2
656.1
657.3
706.2
653.7
665.6
727.1
677.5
689.8
736 2
694.4
700.7
763.5
803.6
849.9
X
(m)
-535.2
-489.3
-503.7
-448.4
-423.8
-325.4
-354.9
-368.0
-404.7
-437.9
-470.9
-513.9
-563.0
-537.9
-608.4
-654.2
-612.6
-664.4
-699.1
-737.8
-781.4
-822.2
-873.7
-425.1
-468.9
-486.0
-526.1
-544.0
-565.6
-556.7
-579.6
-627.9
-592.7
-633.6
-685.9
-654.9
-676.6
-721.7
-687.7
-698.5
-763.4
-797.9
-833.3
Y
(m)
37.9
103.5
174.6
196.9
301.7
721.2
644.2
555.6
488.6
404.3
335.5
364.8
277.2
196.2
193.2
94.5
46.9
-18.5
-91.5
-158.3
-227.9
-295.7
-359.9
669.5
577.7
491.8
416.9
388.2
397.3
347.2
310.0
323.0
275.6
203.9
241.1
173.3
134.3
145.4
96.2
54.8
-7.9
-95.2
-167.2-
Z
(m)
17.3
21.5
20.0
23.1
20.0
35.9
34.6
30.7
29.2
31.9
30.1
41.9
41.9
30.4
41.9
42.3
27.9
29.2
30.4
31.3
29.8
28.2
29.2
53.5
54.5
54.1
54.5
57.5
67.3
54.5
52.6
67.6
53.8
55.1
67.9
52.9
57.2
67.6
55.1
52.9
55.4
54.8
54.5
(Continued)
54
-------�
Table 18. TRACER GAS SAMPLING NETWORK (Continued)
Sampl er
ID
301
302
303
304
305
306
307
308
309
310 C2
311
312
313
314
315
316
317
318
319
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416 C
417
418
419
420
'421
422
501
502
503
9
(deg)
323.4
319.4
316.5
314.5
311.2
308.3
305.3
299.5
296.6
293.1
290.2
287.5
284.1
278.1
275.7
273.2
270.5
268.6
266.2
322.5
318.9
316.3
313.6
310.7
308.1
305.3
303.6
300.9
297.9
293.7
290.9
288.6
286 4
283.7
282.5
278.7
278.1
273.4
270.1
268.1
266.7
307.6
301.7
295.8
R
(m)
845.9
817.0
802.7
774.7
765.6
760.6
745.2
741.6
741.5
762.2
765.7
773.1
757.9
785.5
808.9
823.6
838.2
869.7
878.5
880.7
845.2
836.5
829.5
844.4
821.4
800.2
787.5
782.2
786.1
795.6
804.4
807.7
799.9
815.8
826.9
848.1
919.6
869.3
900.5
925.7
955.8
961.2
961.8
972.8
X
(m)
-504.6
-531.3
-552.1
-552.9
-575.9
-596.7
-608.1
-645.4
-663.1
-701.2
-718.7
-737.5
-735.0
-777.7
-804.9
-822.4
-838.2
-869.5
-876.5
-536.8
-554.8
-577.7
-600.7
-640.0
-646.6
-653.1
-656.2
-671.2
-694.1
-728.5
-751.5
-765.4
-767.3
-792.4
-807.2
-838.3
-910.4
-867.8
-900.5
-925.2
-954.3
-761.3
-818.6
-875.9
Y
(m)
678.9
620.7
582.7
542.6
504.4
471.6
430.7
365.3
331.8
298.7
264.1
232.1
184.9
110.1
80.2
45.4
8.0
-20.9
-58.8
698.3
637.6
604.9
572.1
550.8
506.6
462.3
435.2
401.7
368.9
319.8
287.0
257.9
226.1
193.6
179.6
128.1
129.8
51.1
0.9
-30.8
-54.4
586.9
504.9
423.0
X
(m)
79.1
79.4
79.4
78.5
79.4
78.8
78.2
78.8
79.8
79.4
80.4
81.3
78.8
78.5
79.4
79.4
79.4
79.1
79.1
92.2
82.5
80.9
86.2
92.2
89.2
89.2
90.1
87.7
97.4
84.6
86.5
86.2
85.5
84.6
86.5
87.1
87.9
83.7
84.0
86.5
85.8
80.1
70.9
73.9
(Continued)
55
-------�
Table 18. TRACER GAS SAMPLING NETWORK (Continued)
Sampl er
ID
504
505
506
601
602
603
604
605
606
701 C
702 B
703 B
71X Tl
72X T2
73X T3
74X T4
75X T5
809 Cl
810 C2
9
(deg)
290.2
284.7
279.7
307.4
300.3
296.6
289.9
286.2
281.9
282.5
289.1
289.1
297.3
281.4
291.7
301.9
280.9
290.0
293.1
R
(m)
993.2
1024.0
- 1062.1
1061.1
1062.8
1069.3
1096.2
1098.8
1155.1
826.9
533.1
533.1
565.3
589.5
678.4
748.8
788.5
572.6
762.2
X
(m)
-932.2
-990.7
1046.9
-843.2
-918.1
-955.9
-1031.0
-1055.1
-1130.4
-807.2
-503.7
-503.7
-502.4
-577.8
-630.2
-635.9
-774.0
-537.9
-701.2
Y
(m)
342.8
259.2
178.9
644.2
535.5
479.2
372.4
306.7
237.4
179.6
174.6
174.6
259.1
116.6
250.9
395.4
150.2
196.2
298.7
Z
(m)
67.6
72.4
71.5
76.1
73.4
74.9
71.8
76.4
65.7
96.2
34.0
48.9
29.2
29.2
55.4
79.4
78.8
30.4
79.4
All angles (0), ranges (R), and coordinates (X,Y), are centered at
base of tower A.
Datum : Z = 0 = 1600 m MSL
B = Tower B
C = Tower C
Cl = Collocated (109, 809)
C2 = Collocated (310, 810)
Tl, T2, T3, T4 = 10-minute samplers
56
-------�
4.3 TRACER ANALYSIS SYSTEM
A box with 12 compartments was assigned to each sampler for identifica-
tion and transportation of the bags to HBR and then back to Farmington for
analysis. The Tedlar bags were analyzed for SF6 and CF3BR (Freon) by elec-
ron-capture gas chromatographs (GC). The GC systems are automated adaptions
of the 1972 Lovelock prototype. A functional diagram of the analysis proce-
dure is shown in Figure 8. The sample bag was checked in and assigned to a GC
for analysis, a calibrated volume of air from the sample was injected into
the GC, the output of the electron-capture detector (ECD) was analyzed by an
electronic integrator to yield areas proportional to the concentration of tfce
two tracers, and these areas were translated to concentrations by efficiency
curves determined from calibrations performed with "known standard" mixtures
of the two tracers. Calibration concentrations were corrected for pressure
and temperature in the GCs.
4.3.1 Analytical Procedures
The analytical procedures were in large part automated. The configura-
tions of the principal components of the data acquisition system is shown in
Figure 9. The voltage outputs of the GCs1 electronic capture detector were
recorded on strip charts, where their characteristics could be examined to
ensure that the GCs were functioning properly, and the inputs to the Spectra
Physics SP4000 Integrator, which calculated the peak areas from the voltage
trace, were reliable. This microcomputerized integrator supported all four
GCs at Farmington. It communicated peak areas, date and time of analysis,
and internal constants involved in integration to a Perkin-Elmer mini-
computer (P/E 7/16), which calculated the tracer concentrations (ppt) from
the output of the SP4000. The peak areas, date and time of analysis, and
concentrations were then stored in disk files, which were used for follow-up
analyses and for development of archive tapes. These files were reconciled
with the sample check-in files to determine that all samples analyzed corres-
ponded to those checked in. A summary printout after each GC analysis run
provided visual assurance of matching of the data with the sample ID.
57
-------�
Bag
ChecJc-in
GC
Analyses
Peak
Area
Integration
Analyses
of
Standards
Samples
of
Standard
Mixtures
Computer
Storage and
Calculation
Audit By
Independent
Standard
Mixtures
Figure 8. Tracer gas analysis procedure
(From Lavery et al., 1983)
58
-------�
GC
1
GC
8
GC GC
3 4
SP4000
Integrator
1
Printer
;
I
Floppy
Disks
I
P/E
7/16
(CON i 1 CRT
• I- I
• , .
5x5 MB
Hard Disk
9T
800/1600
Cpl
9T
800/1600
cpi
Plotter
Devices available but not online during data acquisition
Figure 9. Tracer gas data acquisition system
(From Lavery et al., 1983)
59
-------�
Although the laboratory in Farmington had eight GC systems available, only
four GCs were used in the analysis of SHIS #2 tracer samples.
A decision was made a the beginning of SHIS #2 to present tracer concen-
tration data not only as Chi (ppt) as was done in SHIS #1, CCB, but also as
normalized values, Chi/Q, nanoseconds/meter3, (ns/m3). The concentrations
detected by the GCs were divided by emission rate of tracer released during
the hour of sampling. The emission rate Q(g/sec) is an average mass release
rate from the time at which the release valve was opened to the time at which
it rfas closed. In some cases, this period was less than 1 hour, but in most
cases it was several hours. The start and stop times for the release are
referenced to the beginning and end times of each experiment hour.
4.4 TRACER GAS DATA TAPE FILES
Data are stored at the National Computer Center, Environmental Research
Center, Research Triangle Park, North Carolina Carolina on Sperry UNIVAC
1100/83 systems magnetic tape, nine track, odd parity, ASCII-quarter word
mode, density 6250 BPI, tape number 004972. Record length is 132 character,
and the block size is 1320 words, or 40 records per block.
UNIVAC users may assign the tape, @ASG,T HBR,U9S//////Q,004972. Upon
request, copies can be furnished and translated into fromats acceptable to
any computer using nine-track tape drives.
4.4.1 Tape File Index
There are 22 data tape files, one for each experiment for each tracer,
numbered 375 to 396 following the hourly meteorological data records on tape
number 004972. The first 11 files, 375 to 385, contain SF6 concentrations,
and the next 11, 386 to 396, contain data for CF3Br (Freon 13B1). Table 19
shows how tape files are related to experiments.
60
-------�
TABLE 19. TRACER GAS CONCENTRATION DATA
TAPE FILE NUMBERS
SF5 CF3BR
Experiment No.
4
5
6
7
8
9
10
11
12
U
15
375
376
377
378
379
380
331
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
4.4.2 Tape File Records
The first five records of each file contain
alphabetic ASCII characters of identification information and column headings
for the data fields in the records that follow. The first five records are
FORTRAN formatted (132A1). Column headings are coded in the last two header
records.
All data records following the first five alphabetic header records
have data fields arranged as indicated in Table 20.
61
-------�
TABLE 20. TRACER DATA RECORDS FORMAT
Position
1
2 to 4
5 to 9
10
11 to 14
15 to 20
21 to 27
28 to 40
41 to 42
43 to 44
45 to 48
49 to 50
51 to 52
53 to 56
57 to 58
59 to 67
68 to 79
80 to 81
82 to 88
89 to 93
Contents FORTRAN Format
blank
Sampler ID
Bag #
blank
Tracer ID
blank
Tracer cone.
Label
Hour start
Minute start
Label
Hour end
Minute end
Label
Day
Month
Sampl er type
blank
Tracer cone.
Emission rate
IX
13
15
IX
A4
6X
F7.0
11 Al
12
12
A4
12
12
A4
12
9A1
12A1
2x
F7.0
F5.2
Heading
blank
ID
Bag #
blank
Gas (SF6.13B1)
blank
Chi/Q (ns/ra3)
'sampler ran1
HR (00 to 23)
MN (00 to 50)
1 to '
HR (00 to 23)
MN (00 to 50)
' on '
Day of month
DATE (Oct 1982)
SMP/TYPE
'HR SAMP'
'TOVIR SAMP'
'10 MIN SAMP1
blank
CHI (ppt)
Q(gm/sec)
62
-------�
Table 21 is a printout of the first block, 40 records, of block num-
ber 375. It illustrates how the alphabetic header records identify columns
of the data fields that follow. Data records are listed in chronological
order starting with the first hour of the experiment.
63
-------�
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-------�
SECTION 5
OPTICAL CROSSWIND ANEMOMETER DATA
5.1 OPTICAL ANEMOMETER NETWORK
An optical crosswind anemometer measures the path averaged crosswind
speed of the component of flow in the horizontal plane and perpendicular to
the path over a 1ine-of-sight between a transmitter and receiver. This
method avoids the problems of local obstructions and of low-speed nonlineari-
ties to which conventional anemometers are subject. At HBR, heights of the
paths were generally between 0.5 and 5 m; the ends of the paths were about
1 m or less above the surface. This anemometer operated around the clock
with occasional servicing.
Three optical anemometers were used in SHIS #2. Figure 7 shows the
alignment of all three paths on HBR. The first transmitter-receiver set was
aligned parallel to the ridge in the targeted area and slightly upwind of the
base of the ridge (path A). The second set was installed along the crest of
HBR (path B), and a third set was placed on the lee (west) slope of HBR.
The lengths of paths vary between 300 and 600 m. Data are recorded as 10-
minute averages of wind speed component (m/s) at right angle, crosswind, to
the alignment (path) of the transmitter-receiver set.
5.2 OPTICAL ANEMOMETER DATA TAPE FILES
Data are stored at the National Computer Center, Environmental Research
Center, Research Triangle Park, North Carolina on Sperry UNIVAC 1100/83
systems magnetic tape, nine track, odd parity, ASCII-quarter word mode,
density 6250 BPI, tape number 004972. Record length is 132 characters, and
the block size is 1320 words, or 40 records per block.
65
-------�
5.2.1 Tape File Index
There are 3 data tape files, one for each optical anemometer path
(A,B,C), numbered 397,398 and 399 following the tracer gas concentration on
tape number 004972. Table 22 shows how tape files are related to the data.
TABLE 22. OPTICAL ANEMOMETER TAPE FILE NUMBERS
File Number Contents
397 Path A (East base of HBR), 10 Oct 82 to 29 Oct 82,
all experiments, 10-minute averages, m/s.
398 Path B (Ridge crest), 11 Oct 82 to 29 Oct 82, all
experiments, 10-minute averages, m/s.
399 Path C (West of HBR), 13 Oct 82 to 29 Oct 82, all
experiments, 10-minute averages, m/s.
5.2.2 Tape File Records
The first seven records of each day's hourly record of 10-minute
average crosswind data have alphabetic ASCII characters of identification
and column headings for the data fields in the records that follow for that
day. There is one record for each hour of data with 6 field of 10-minute
averages.
All data records following the seven header records for each day have
data fields arranged as indicated in Table 23.
66
-------�
TABLE 23. OPTICAL ANEMOMETER DATA FORMAT
Position
1 to 3
4 to 8
9 to 15
16
18
25
27
34
36
43
45
52
54
to
to
to
to
to
to
to
to
to
to
17
24
26
33
35
42
44
51
53
60
Contents
FORTRAN
Hour (MDT)
blank
Crosswind, m/s
blank
Crosswi
blank
Crosswi
blank
Crosswi
blank
Crosswi
blank
nd
nd
nd
nd
Crosswind,
, m/s
, m/s-
, m/s
, m/s
m/s
13
5X
F7
2X
F7
2X
F7
2X
F7
2X
F7
2X
F7
Format
.2
.2
.2
.2
.2
.2
Heading
Hour (MDT)
blank
10-minute averages
blank
10-minute
blank
10-minute
blank
10-minute
blank
10-minute
blank
10-minute
averages
averages
averages
averages
averages
Table 24 is a printout of a sample of the first day's record of data
showing the header records and data records from file number 397.
67
-------�
o
H
25
5
es
H
fa
3
en
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68
-------�
SECTION 6
TETHERSONDE DATA
6.1 TETHERSONDE NETWORK
Two tethersonde instruments were operated to measure temperature,
horizontal wind speed and direction, pressure and humidity. One tether-
sonde was operated by UPL to obtain vertical profiles from the ground up to
about 300 m in the area east of HBR. A second sonde was operated by ATDD
next to the source of SF6 tracer gas release, either the crane of the
150-m tower, so as to record temperature, wind speed and direction at the
height and concurrently with the tracer release.
The WPL sonde was operated near Tower . B at the base of HBR until
October 15, then was moved east to near the doppler sounder location through
the end of SHIS #2. The mode of operation for this tethersonde was to run
vertical profiles from the surface up to about 300-m altitude. When the
sonde was flown from the first location near the base of HBR, the balloon
was often blown past the crest of the ridge when its altitude was only 300
m or less above the ground. The profiles were therefore not generally
vertical but slanted towards the region of tighter streamline compression
over the ridge. The difference in speed between the ascent and descent
modes, however, may be as much as 0.5 m/s since WPL let out or hauled in
the tether typically at about 0.5 m/s.
A scan was taken from the sondes approximately every 13 seconds, so
that effective vertical resolution of WPL profiles was about 4 to 7m. An
69
-------�
ascent and descent were made once per hour during experimental periods. The
accuracy of the reported heights, calculated from pressure and temperature
measurements by the hypsometric equation, is probably about 5 m because of
response time of the temperature probe and changes in ambient pressure
during the course of the flight.
Since the ATDD sonde was held at the altitude of the tracer release
and did not operate in an ascent-descent mode, wind speed errors would not
appear due to tether hauling. Only temperature, wind speed and direction
were recorded by the ATDD sonde.
i
The tethersondes used at SHIS #2 by WPL and ATDD were manufactured by
A.I.R., Inc. The characteristics of the probes listed in Table 25, are
those supplied by the manufacturer.
TABLE 25. CHARACTERISTICS OF A.I.R. TETHERSONDES
Sensor Range Precision Resolution Response
Temp. -70 to 50C 0.5 C
Wet -70 to 50 C 0.5 C
Press 0 - 100 mb 1 mb
0.1 C
0.1 C
3 - 5 sec
12 sec
0.1 mb 1-2 sec
Wind 0-20 m/s 0.25 m/s 0.1 m/s 2.4 m
speed
Wind 2 - 358 deg 5 deg 1 deg 15 m
direction
Description
2mm epoxy-coated
bead thermistor
As Temp, wetted
bulb by wick
Aneriod capsules
w/moving dia-
phram capacitor
3-cup anemometer
light chopper
Balloon as vane;
senses with mag-
netic compass
70
-------�
6.2 TETHERSONDE DATA TAPE FILES
Data are stored at the National Computer Center, Environmental Re-
search Center, Research Triangle Park, North Carolina on Sperry UNI VAC
1100/83 systems magnetic tape, nine track, odd parity, ASCII-quarter word
mode, density 6250 BPI, tape number 004972. Records length is 132 charac-
ters, and the block size is 1320 word or 40 records per block.
6.2.1 Tape File Index
There are 28 data tape files, 13 for WPL sonde data, numbers 400 to
412, and 15 files of ATDD data, number 413 to 427. These files follow the
optical anemometer data files on tape number 004972. Table 26 indicates
the periods of operation.
71
-------�
TABLE 26. TETHERSONDE TAPE FILE NUMBERS
File No.
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
WPL - Tethersonde
Experiment No.
2
3
4
5
6
7
8
9
10
11
12
13
14
ATDD - Tethersonde
4
5
6
7
8
9
10
11
12
13
14
15
Date
10/5-6/82
10/7-8/82
10/11/82
10/12/82
10/12-13/82
10/14/82
10/14-15/82
10/20/82
10/22/82
10/22-23/82
10/24/82
10/25/82
10/25-26/82
10/11/82
10/12/82
10/12-13/82
10/14/82
10/14-15/82
10/20/82
10/22/82
10/22-23/82
10/24/82
10/25/82
10/25-26/82
10/29/82
72
-------�
TABLE 27. TETHERSONDE DATA FORMAT
Position
1 to 2
3 to 4
5 to 6
7 to 8
9 to 10
11 to 12
13 to 14
15
16 to 22
23 to 29
30
31 to 37
38 to 43
44 to 50
51
52 to 58
59 to 64
65 to 71
1 to 2
3
4 to 5
6
7 to 8
9
10 to 16
17
18 to 25
26
28 to 34
35
WPL-Tethersonde
Contents FORTRAN Format
Month
Day
Year
blank
Hour
Minute
Second
blank
Pressure, tubs
Height, m
blank
Temperature, C
Rel Hum, %
Mixing Ratio
blank
Wind Dir, deg
Wind Spd, m/s
Potential
Temp, K
ATDD
Hour
*
Minute
*
Second
blank
Temp, C
Data Quality Flag
Wind Speed, m/s
Data Quality Flag
Wind Dir, Deg
Data Quality Flag
12
12
12
2X
12
12
12
IX
F7.2
F7.1
IX
F7.1
F6.1
F7.1
IX
F7.1
F6.1
F7.1
Tethersonde
12
Al
12
Al
12
IX
F8.1
Al
F8.1
Al
F8.1
Al
Heading
MO
DY
YR
blank
HR
MN
SC
blank
Pres.
Ht.
blank
Temp.
RH.
M.R.
blank
Dim.
Spd.
P.T.
HR
:
MN
;
SC
blank
Temp
blank =
B = bad
WS
blank =
B = bad
WD
blank =
B = bad
good
good
good
73
-------�
6.2.2 Tape File Records
For the WPL sonde data, the first six records of each ascent-descent
sounding are header records and have ASCII alphabetic characters of identi-
fication and column headings for the data records that follow. Since there
was one sounding per hour for each experiment, there were about eight
soundings recorded in the tape files, separated by six header records.
There is one data record for every 13 seconds of sounding.
For ATDD tethersonde, since the observations were held to the point
of the SF6 tracer release, there was no ascent-descent profile. Data
consisted only of temperature, wind speed and wind direction every 13
seconds near the location and height of tracer release. There are twelve
alphabetic header records proceeding each group of 1-hour observations.
All data records following the six header records for every
sounding have data fields arranged as indicated in Table 27.
74
-------�
Table 28 is a printout of the first block, 40 records, from tape
file number 400, the first file of WPL tethersonde data. It illustrates
how the data are presented with the heading records and the first data
records at the beginning of a tethersonde ascent. Table 29 is a printout
of the first block, 40 records, from tape number 414, the second file of
ATDD tethersonde data. The first file, 413, was not representative of the
remaining tape files. It shows the arrangement of header records and the
data files prepresenting temperature and wind conditions at the point of
tracer release.
75
-------�
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77
-------�
SECTION 7
PUBLIC SERVICE COMPANY OF NEW MEXICO METEOROLOGICAL DATA
7.1 ADDITIONAL METEOROLOGICAL DATA
Public Service Company of New Mexico (PNM) maintains a network of
meteorological stations around HBR, Figure 10, and these data were made avail-
able by PNM for this data base as half-hour averages for the month of October
1982. Data were available from ten stations in the network. The most valu-
able of these stations would be numbers 103 and 105, both located on top of
HBR. Station 103 is located about 5 km SW of the experiment area near the
San Juan River, an 105 is just to the north of the experiment area. In
addition, station 105 records .temperature, solar radiation and net radiation,
along with values of wind speed, direction and sigma-theta that all stations
report.
7.2 PNM DATA TAPE FILES
Data are stored at the National Computer Center, Environmental Research
Center, Research Triangle Park, North Carolina on Sperry UNIVAC 1100/83
systems magnetic tape, nine track, odd parity, ASCII-quarter word mode,
density 6250 BPI, tape number 004972. Record length is 132 characters, and
the block size is 1320 words or 40 records per block.
7.2.1 Tape File Index
There are 4 data tape files, number 428 to 431. These files follow
the tethersonde data files on tape number 004972. Table 30 indicates how
the data from the ten PNM stations are arranged within the files.
78
-------�
Figure 10. PNM air quality and meteorological monitoring sites
(From Lavery et al., 1983)
79
-------�
TABLE 30. PNM DATA TAPE FILE NUMBERS
File No.
Contents
Data
425
Stations: 102, 103, 104
Wind Speed & Direction,
Sigma-Theta
426
Stations: 105, 106
Wind Speed & Direction,
Sigma-Theta, Temperature
Solar & Net Radiation
427
Stations: 107, 108, 109
Wind Speed & Direction,
Sigma-Theta
428
Stations: 110, 112
Wind Speed & Direction,
Sigma-Theta
Heights of instruments at the ten stations are:
Station
102
103
104
105
106
107
108
109
110
112
Instrument Level (m)
9.4
9.4
8.9
10.5
9.0
9.5
9.5
9.5
9.4
9.0
80
-------�
TABLE 31. PNM DATA FORMAT
Position
1 to 2
3 to 4
5 to 6
7 to 8
9 to 10
11 to 18
19
20 to 27
28
29 to 36
37
38 to 45
46
47 to 54
55
56 to 63
64
65 to 72
73
74 to 81
82
83 to 90
91
1 to 2
3 to 4
5 to 6
7 to 8
9 to 10
11 to 18
19
20 to 27
28
29 to 36
37
38 to 45
46
47 to 54
55
56 to 63
64
65 to 72
73
74 to 81
82
83 to 90
91
Contents FORTRAN Format Heading
File 425
Month
Day
Year
Hour
Minute
Sta.102, Wind Dir
Flag
Sta.102, Wind Spd
Flag
STA.102, Sigma-T
Flag
Sta.103, Wind Dir
Flag
Sta.103, Wind Spd
Flag
Sta.103, Sigma-T
Flag
Sta.104, Wind Dir
Flag
Sta.104, Wind Spd
Flag
Sta.104, Sigma-T
Flag
File 426
Month
Day
Year
Hour
Minute
Sta.105 Wind Dir
Flag
Sta.105 Wind Spd
Flag
Sta.105 Sigma-T
Flag
Sta.105 Temp
Flag
Sta.105 Net Rad
Flag
Sta.105 Sol Rad
Flag
Sta.106 Wind Dir
Flag
Sta.106 Wind Spd
Flag
Sta.106 Sigma-T
Flag
12
12
12
12
12
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
12
12
12
12
12
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
MM
DD
YY
HH
MM (0,30)
WD (deg)
blk=good, m=missing
WS (m/s)
bl k,m
ST (deg)
bl k,m
WD (deg)
bl k,m
WS (m/s)
blk,m
ST (deg)
blk,m
WD (deg)
bl k,m
WS (m/s)
blk,m
ST (deg)
bl k,m
MM
DD
YY
HH
MM (00,30)
WD (deg)
bl k,m
WS (m/s)
bl k,m
ST (deg)
bl k,m
T (C)
blk,m
NR (ly/min)
bl k,m
IN (ly/min)
bl k,m
WD (deg)
blk,m
WS (m/s)
bl k,m
ST (deg)
bl k,m
81
-------�
TABLE 31.
Position
1 to 2
3 to 4
5 to 6
7 to 8
9 to 10
11 to 18
19
20 to 27
28
29 to 36
37
38 to 45
46
47 to 54
55
56 to 63
64
65 to 72
73
74 to 81
82
83 to 90
91
1 to 2
3 to 4
5 to 6
7 to 8
9 to 10
11 to 18
19
20 to 27
28
29 to 36
37
38 to 45
46
47 to 54
55
56 to 63
64
PNM DATA FORMAT (Continued)
Contents FORTRAN Format Heading
File 427
Month
Day
Year
Hour
Minute
Sta.107 Wind Dir
Flag
Sta.107 Wind Spd
Flag
Sta.107 Sigma-T
Flag
Sta.108 Wind Dir
Flag
Sta.108 Wind Spd
Flag
Sta.108 Sigma-T
Flag
Sta.109 Wind Dir
Flag
Sta.109 Wind Spd
Flag
Sta.109 Sigma-T
Flag
File 428
Month
Day
. Year
Hour
Minute
Sta.110 Wind Dir
Flag
Sta.110 Wind Spd
Flag
Sta.110 Sigma-T
Flag
Sta.112 Wind Dir
Flag
Sta.112 Wind Spd
Flag
Sta.112 Sigma-T
Flag
12
12
12
12
12
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
12
12
12
12
12
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
F8.3
Al
MM
DD
YY
HH
MM (00,30)
WD (deg)
bl k,m
WS (m/s)
blk,m
ST (deg)
bl k,m
WD (deg)
blk.m
WS (m/s)
bl k,m
ST (deg)
bl k,m
WD (deg)
bl k,m
WS (m/s)
bl k,m
ST (deg)
bl k,m
MM
DD
YY
HH
MM (00,30)
WD (deg)
blk.m
WS (m/s)
blk,m
ST (deg)
bl k,m
WD (deg)
blk.m
WS (m/s)
blk.m
ST (deg)
bl k,m
82
-------�
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83
-------�
SECTION 8
SUMMARY
3.1 Principal Accomplishments
The Hogback Ridge field study achieved its objective of extending the
modeling data base to include a detailed set of meteorological tower data,
tracer concentration, tethersonde and optical anemometer data from a two-
dimensional ridge site. The field program has produced a set of about 179
tracer-hours for model testing, evaluation, and refinement.
Like SHIS #1, SHIS #2 has verified the basic concepts of experimental
design. The release of gaseous and visible tracers from a mobile crane or
fixed tower, using real-time meteorological data to guide the selection of
release locations and heights, has resulted in a data base that covers a
wide variety of dispersion conditions and concentration patterns. The
meteorological data from four towers were archived in real-time via an
onsite system of minicomputers that unfortunately introduced some noise
into the archived data during the first few experiments. Subsequent onsite
modifications to the data system were successful in reducing this noise,
and later ARLFRD and ERT scientists developed procedures to eliminate the
noise from all of the archived meteorological data.
The entire data base from SHIS #2 reside on one reel of 9-track compu-
ter tape, and it is available to the scientific community either as a direct
copy of the tape or by interactive computer access with the UNIVAC computer
at NCC at Research Triangle Park.
84
-------�
REFERENCES
1. Clarke, J. F., J.K.S. Ching and J. M. Godowitch, 1982. An Experiment
Study of Turbulence in an Urban Environment. EPA Technical Report,
EPA-600/52-82-062, U.S. Environmental Protection Agency, Research
Triangle Park, North Carolina, 150 pp.
2. Crow, L. W., 1975. Meteorological Data Analysis Based on Monitoring
Stations and Meteorological Data, January - December 1974. Joint
Environmental Program No. 153, Loren W. Crow Associates, Denver, Colo-
rado.
3. Greene, B. R., 1985. Complex Terrain Model Development. Quality Assur-
ance Project Report for Small Hill Impaction Study #2. EPA Document
No. P-B876-350, U.S. Environmental Protection Agency, Research Triangle
Park, North Carolina, 259 pp.
4. Hovind, E. L., M. W. Edelstein and V. C. Sutherland. Workshop on Atmos-
pheric Dispersion Models in Complex Terrain. EPA-600/9-79-041. U.S.
Environmental Protection Agency, Research Triangle Park, North Carolina,
1979.
5. Lavery, T. F., A. Bass, D. G. Strimaitis, A. Venkatram, B. R. Greene,
P. J. Drivas, and B. Egan. EPA Complex Terrain Model Development Pro
gram: First Milestone Report - 1981. EPA-600/3-82-036, U.S. Environ-
mental Protection Agency, Research Triangle Park, North Carolina, 304 pp,
6. Lavery, T. F., D; G. Strimaitis, A. Venkatram, B. R. Greene, D. C.
DiCristofaro, B. A. Egan. EPA Complex Terrain Model Development: Third
Milestone Report - 1983. EPA-600/3-83-101, U.S. Environmental Protec-
tion Agency, Research Triangle Park, North Carolina, Research Triangle
Park, North Carolina, 271 pp.
7. Moore, G. E., R. G. Ireson, C. S. Liu, R. E. Morris, A. B. Hudischewsky,
and T. W. Tesche 1981. Air Quality and Meteorology of Northwestern New
Mexico, Draft Final Report No. 81203. Arizona Public Service.
8. Strimaitis, D. G., A. Venkatram, B. R. Greene, S. R. Hanna, S. Heisler,
T. F. Lavery, A. Bass, and B. A. Egan, 1983. EPA Complex Terrain Model
Development Program: Second Milestone Report - 1982. EPA-600/3-83-015,
U.S Environmental Protection Agency, Research Triangle Park, North
Carolina, 375 pp.
9. Truppi, L. E. and G. C. Holzworth, 1983. EPA Complex Terrain Model
Development Program: Description of a Computer Data Base from Small Hill
Impaction Study #1, Cinder Cone Butte, Idaho. U.S. Environmental Pro-
tection Agency, Research Triangle Park, North Carolina, 98 pp.
10. Yamartino, R. J., 1984. A Comparison of Several Single Pass Estimates
of the Standard Deviation of Wind Direction, J. Climate Appl. Meteor.,
23 1362-1366.
85
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