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\fBData Report
.br
for
.br
The 1988-89 PASSCAL Basin and Range
.br
Passive-Source Seismic Experiment 
.br
Part I:  Large Aperture Array Data\f
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\fIsubmitted by
Thomas J. Owens, University of South Carolina
George E. Randall, University of Nevada-Reno
.sp
for the
PROJECT SCIENCE TEAM\f
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\fB*** PASSCAL DATA REPORT #90-001 ***\f
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ABSTRACT
.sp
.LP
This report describes the data from the
1988-89 PASSCAL Basin and Range Passive Source Seismic Experiment,
collected by the triggered large aperture array
consisting of 7 prototype PASSCAL recorders with
3-component intermediate period seismometers.
A total of 214 seismic events with known locations,
and many smaller local events without locations
are included in this data distribution.
Data formats, auxiliary information, calibration
information, and organization of the distribution
data tape are discussed.
.ls 2
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.NH
Introduction
.PP
The 1988-89 PASSCAL Basin and Range Passive Source Seismic Experiment
consisted of two deployments.
The Large Aperture Array of 7 PASSCAL data recorders
was deployed from August 17, 1988 until April 29, 1989.
The Large Aperture Array used 3-component mid-period
sensors, and each site operated independently
in a triggered mode.
A Small Aperture Array, consisting of the Lawrence
Livermore National Laboratory (LLNL) Configurable Seismic Monitoring
System (CSMS), was deployed from August 1988 through
October 1988.
The Small Aperture Array used 3-component short-period 
sensors, and operated in a continuous recording mode
with digital telemetry to a central recording site.
.PP
The study area was in the region of the Stillwater Range
in Nevada (see Figures 1 and 2), and was chosen to coincide
with the center of the crossing refraction profiles
of the 1986 PASSCAL Basin and Range Lithospheric
Experiment.
This location was chosen so that a comparison of
lithospheric modeling techniques, principally
receiver function modeling, and refraction and reflection
modeling, could be compared in a coincident study area.
.PP
The experiment team consisted of a field crew,
and project scientists.
The field crew, Randy Kuehnel and Thom Morin, deserve
a great deal of credit for the success of the field
operation.
Their consistent dedication and effort
made both array deployments operate as
smoothly as possible, and aided greatly in the
preliminary data processing.
The project scientists consisted of
T.J. Owens, D. McNamara (University of Missouri, 
now at University of South Carolina),
G.E. Randall, K.F. Priestley (both at University of Nevada-Reno),
and G. Zandt (at the LLNL Insitute for Geophysics and Planetary
Physics).
.PP
The instrumentation for the Large Aperture Array
consisted of 7 prototype PASSCAL data recorders, with 
3-component mid-period (Kinemetrics SV-1 and SH-1)
seismometers.
Sites were constructed with separate insulated buried
vaults for recorders and seismometers, and were
powered with batteries recharged with solar panels.
Most sites (SUN,NYC,GRN,SHP,CHB,ADR) were placed in locations
either directly on or slightly above hardrock. The other sites
(FNC,ANT) were chosen based on spatial constraints only.  Brief
site descriptions are given in Appendix A. Johnson (1977) provides
a more detailed summary of the geology of this region.
Site locations are given in Table 1.
.PP
This was the first major experiment to make use of the PASSCAL
recorder, and the recording parameters varied
often for test purposes.
Typically, each recorder operated in a triggered mode, with
some units occasionally operating with an additional
low sample rate continuous data stream.
The triggered data streams were recorded
with sampling rates typically of 20 samples
per second, although occasionally 50 and
100 samples per second were recorded.
The triggers were STA (Short-term average) to LTA (Long-term
average) ratios with the LTA
window of 100 seconds, and the STA window 6 seconds.
The STA/LTA ratio was initially 2.5, but was 
increased to 2.8 which successfully lowered
the false trigger rate during the winter months and preserved the
data triggering.
The triggered data streams typically had pre-event buffers of 30 seconds 
and an overall record length of 150 seconds.
Most of the recording was done in 16 bit mode,
although some data was recorded with the 32 bit
mode.
.PP
During the course of the experiment 
GOES clocks were used at the sites.
Clock lock problems existed early in the project
but were fixed by mid-December.
Table 2 summarizes the dates when GOES clocks were
added to each site.
Prior to these dates, clocks were set manually to GMT
during service visits if clock lock appeared to be a problem.
Therefore, data recorded prior to the dates in Table 2 are
suitable for single station studies, but are not reliable enough
for detailed array analysis.
In addition, from Julian Day 097 to 109 and from Days 114 - 119,
the clock antenna at Chocolate Butte was uprooted by cattle and
therefore the clock was not locked in these time periods.  A similar
problem occurred twice at Anderson Ranch somewhere between Days 080 and
119.  It was temporarily corrected once on Day 094, but users 
are warned to be wary of the timing at Anderson Ranch during
this period.
.PP
The instrumentation for the Small Aperture Array
consisted of the LLNL CSMS system, with 13
continuously recorded digitally telemetered 
stations. One station was co-located with a station
from the large aperture array (FNC), and operated with
mid-period (Kinemetrics SV-1 and SH-1) seismometers.
The  remaining 12 stations used short period (Geotech
S-13) 3 component seismometers.
Time information was derived from an OMEGA clock
at the central recording site, and rebroadcast
to synchronize the field sites.
The field sites used digital telemetry via radio
links to pass the 100 sample per second 
data to the central recording site,
where data was continuously recorded onto either
optical disk or 8 mm tape for later demultiplexing
and analysis.
.PP
This data report summarizes the data available
from the Large Aperture Array.
The data from the Small Aperture Array is not yet
ready for distribution and will be summarized
in Part II of this report at a later date.
The standard distribution tape for this experiment is trace data
for located seismic events.  Supplementary raw data for
unlocated events is also available to interested researchers.
.NH
Description of Data Distribution
.PP
The Large-Aperture Array data has been provided to IRIS in three
subsets, each of which is a UNIX file structure.  The contents of
the subsets is described below.  The entire data distribution
totals just over 207 Mbytes in size.
.PP
All of the trace data in this data distribution is in SAC format. 
SAC is an acronym for "Seismic Analysis Code", a general purpose
software package for the manipulation of seismic data developed at
Lawrence Livermore National Laboratory (LLNL).  It is available
through IRIS or LLNL.  In this data distribution, we have
separated out seismic events from spurious or culturally-induced
triggers.  Due to our limited duration recording
window, we also eliminated
triggers due to teleseismic surface waves that occasionally
triggered the stations.  After this initial culling of the data,
we searched the Quick Determination of Epicenters (QDE)
listings obtained through the toll-free modem number of the
National Earthquake Information Center (NEIC).  Local and regional
events not found in the QDEs were often found in the Nevada
Regional Catalog distributed by the Seismological Laboratory of
the University of Nevada-Reno.
.PP
We were able to identify most seismic triggers using this method,
however many smaller local events or mine blasts could not be
assigned a location from either catalog.  These were retained and
are distributed in two subsets 
as part of the "Raw Data Distribution" described
below.  All events with known locations were assigned an event
number and trace data from these events make up the third, and
primary, subset of this distribution.  
This data is termed the "Numbered Event Data" and is
described in the next section.
.NH 2
Numbered Event Data
.PP
A total of 214 separate seismic events with known locations make
up the numbered event data.  These events are listed in Table 3.
Our numbering scheme was as follows:
.ls 1
.TS
center, tab(|);
ll.
001-299|P-wave triggers
701-999|Teleseismic S-wave Triggers
301-599|Other Teleseismic Body Wave Triggers
.TE
.ls 2
.PP
In the cases of an S-wave trigger, the event number assigned was
the P-wave trigger number plus 700 and for the other teleseismic
triggers, the event numbers assigned were the P-wave trigger
number plus 300.  For example the Fiji Island event of 4/16/89
triggered some sites on the P-wave, PP-wave, and S-wave.  These
were assigned event numbers 181, 481, and 881 respectively.
.PP
The numbered event trace data is distributed using the following
file naming convention:
.ce
$EX.EVT.STA.C$
.ce 0
where $EX$ is the 2-letter experiment identification code.  In
this case, the code used was "$lv$" for Lovelock, the nearest town to the
array, was used; $EVT$ is the assigned event number, column 1 in
Table 3; $STA$ is the 3-letter station abbreviation, column 1
in Table 1; $C$ is the component identifier, $z$ for Vertical
component (positive up), $n$ for North component (positive north),
or $e$ for East component (positive east).
.PP
The trace data amplitudes are given in units of microvolts.  The
event and station latitude, longitude, and depth or elevation as
well as the proper component orientations have been entered into
the proper SAC header fields.  The numbered event data
distribution is organized in the following UNIX directory
structure:
.ls 1
.TS
center, tab(|);
ccc
ccc
rnl.
Directory|Size|Description
Name|(Mb)|of Contents
=
.sp .25
NV8889_LAA/|72.9|Main Directory
.sp .5
\./calb|8.9|Calibration Traces
\./tele|22.1|Teleseismic events
\./others|21.5|Local and Regional Events
\./tele.std|19.3|Standardized teleseismic data
\./general_info|0.1|all non-trace data files
\./data_report|1.0|text and figures of this report
.TE
.ls 2
.NH 3
Teleseismic Data
.PP
The geographic distribution of teleseismic data is shown in Figure
3.  A typical event that triggered for both P- and S-waves
is plotted in Figure 4a and b.  The
NV8889_LAA/tele.std directory contains the teleseismic traces
standardized to a sampling rate of 20 samples/sec and a record
length of 150 sec.  In tele.std,
the mean of each trace has been removed and a
Hanning taper applied to the first and 
last 7.5 sec of each trace.  Also,
for each event, the traces at all stations recording the event have been
synchronized to a common reference time to allow for more accurate
array analysis.  Some low signal-to-noise ratio traces and events
with other quality control problems have been discarded from this
directory.  This directory contains the data used in the research
portion of this study. 
The NV8889_LAA/tele directory contains teleseismic events saved at
their original sampling rate and record length.   
Some data in NV8889_LAA/tele may be found to
suffer from the Picket Fence sampling problem described in the next
section.
.NH 3
Local/Regional Data
.PP
The NV8889_LAA/others directory contains all of the trace data for
non-teleseismic events recorded by the Large-Aperture Array.
Figures 5 and 6 show typical regional and local events.
Each trace has the original sampling rate and record length.  Since we
have not used this data in our research to date, we have not made
thorough attempts to cull low signal-to-noise ratio events or
other events with data quality problems from this data set. 
One correctable data quality problem that occurred with some regularity
during the experiment was that the PASSCAL data logger occasionally
became hung in a mode where it stored a constant of 10 digital counts
between every other data point.  In these cases, users need only to
remove these points from the data trace.  The resulting record is
half the normal length, but the actual data has not been corrupted.
In SAC, the "decimate 2 filter off" function fixes
this problem, if users redefine the
sampling interval to the original value after decimation.
This problem became known as the "Picket Fence" mode.  It was 
eventually corrected via hardware/software upgrades.
.NH 2
Calibration
.PP
The Kinemetrics SV-1 and SH-1 seismometers were
carefully calibrated in the laboratory prior to
deployment.
The SV-1/SH-1 sensors are moving-coil electromagnetic seismometers
with a nominal natural period of 5 seconds.
Damping resistors were added to the seismometer
circuit to obtain a nominal damping of 0.7 critical.
After the initial installation and debugging period,
a routine calibration procedure was 
established and applied at each site
during the service visits.
Each calibration was assigned a number
and the file named in the same manner as in Section 2.1,
except that the experiment identifier is
"lvc" to distinguish it as a calibration
pulse from the Lovelock data set.
.PP
Our calibration procedure used a battery, cable,
and resistor network to inject a step of current
equally into the  calibration coils
of all three seismometers simultaneously.  
The current was equal
for each of the three coils, but unknown,
so true amplitude calibration is not available.
Kinemetrics documentation lists a nominal calibration coil
force constant of 0.12 Newtons/ampere for the SV-1 and 0.08
Newtons/ampere for the SH-1.
We obtained the effective mass of 1.36 Kg for the SV-1 and 1.1 kg 
for the SH-1 from Kinemetrics by phone.
The tabulated observed relative amplitudes in Table 4 should be corrected
by multiplication by 1.213 ([1.1/0.08]/[1.36/0.12]) to
account for the different coils and effective masses of the SV-1 and
SH-1 seismometers, which accelerate the SV-1 more than the SH-1 for the
same calibration current.
.PP
Calibration pulses were repeated manually for sufficient duration
to fill at least one trigger window (150 seconds),
and provided multiple calibration pulses per calibration
file.
A single calibration pulse was cut from each
calibration file for analysis.
An unpublished code of D.B. Harris of LLNL
was used to fit synthetic calibration pulses
to the observed pulses.
The code uses a grid search followed by a
conjugate gradient least squares optimization
to find a best fit to the observed calibration pulse's
free period, fraction of critical damping, amplitude, and bias.
Tabulated calibration information consists of free period,
fraction of critical damping, and observed amplitude relative to
the vertical for each horizontal component.
Some calibrations are not reported because the station
had excessive noise which degraded the parameter
estimation.
A few calibrations were discarded because we
identified instrumental or recording problems
with the calibration.
The calibration information for each available 
calibration is given in Table 4.
The parameters did not normally vary significantly at each site
unless a seismometer was changed.
.PP
The calibration data is provided in SAC format in the NV8889-LAA/calb
directory.  It is sorted into station subdirectories, e.g. all of the
Anderson Ranch calibrations are in NV8889_LAA/calb/ADR.  
Some calibration traces in these directories 
suffer from the Picket Fence problem described in Section 2.1.2
of this report.
.NH 1
Raw Data Distribution
.PP
Since events for which no catalogued location exists may still be
of interest to other researchers, we have included supplementary
data distributions of our raw data.  Two subsets are available:
1988 data and 1989 data.  The 1988 subset totals 95 Mb and the
1989 data totals 40 Mb.  The data is organized in day directories
as follows:
.ls 1
.TS
center, tab(|);
ll.
RXXX/events|Seismic event traces
RXXX/calb|Calibration traces
RXXX/inst|Potential instrument problems
.TE
.ls 2
where $XXX$ is the Julian Day.  If no triggers of a certain type
occurred on a given day, that subdirectory will not exist.  If all
three subdirectories are empty, the R$XXX$ directory will not
exist.  Within each subdirectory, the trace data naming convention
is:
.ce
$sHR.MN.SC.UNIT.DS.C$
.ce 0
where $HR$ is the hour of the first data point in the trace, $MN$
is the minute of the first data point, $SC$ is the second of the
first data point, $UNIT$ is the PASSCAL recorder serial number,
$DS$ is the Data Stream that recorded the trace, and $C$ is the
Channel number, either 1, 2, or 3.
.PP
Each subdirectory also contains a tab-delimited file (called
event.lst, calb.lst, inst.lst respectively) consisting of 4
fields:  Field 1 - Channel 1 trace filename; Field 2 - trigger
type indicator; Field 3 - Event number, if applicable, null field
otherwise; Field 4 - Pertinent comments by the field crew.  Field
2 may include: tele - teleseismic event; loco - local event; regi -
regional event; nuke - known underground nuclear explosion; calb -
calibration trigger; inst - potential instrument problem; eqke -
general undifferentiated seismic event.
Some traces in the Raw Data Distribution may suffer from the Picket
Fence sampling problem described in Section 2.1.2.
.PP
For convenience, all of the event.lst files have been combined
into two files, eventlists.1988 and eventlists.1989, in the
directory NV8889_LAA/general_info distributed with the numbered
event data.  In addition, we have included files calblists.1988 and
calblists.1989 in this directory to allow correlation of calibration
triggers with the numbered calibrations distributed with the numbered 
event distribution.  
Also in the general_info directory are database files
containing information by site that will allow users to correlate
instrument serial numbers to a specific site.  A sample entry is:
.nr PS 9
.DS
STATION NO:  07     STATION NAME:  Anderson Ranch           AKA:  adr
STATION LATITUDE:  39.972     LONGITUDE:  -118.094     ELEVATION:  1520.000
CHANGES:

DATE:  09/28/88     TIME:  22:00
INSTRUMENT TYPE:  ref     SERIAL #:  0027
STATUS:  u     LTA:  100.     STA:  6.     STA/LTA:  2.8
PRE-EVENT MEMORY:  30.     EVENT RECORD LENGTH:  150.     DATA FORMAT:  32
COMMENTS:  No GOES clock; usual 20 Hz, 3 channel trigger but no 1 Hz co
           ntinuous stream.
CHANNEL  01:     COMPONENT:  z     SERIAL #:  sv-170   +-DIRECTION:  u
                 PRE-AMP GAIN:  512     DAMP GAIN FACTOR:  1.00
CHANNEL  02:     COMPONENT:  n     SERIAL #:  sh-252   +-DIRECTION:  n
                 PRE-AMP GAIN:  512     DAMP GAIN FACTOR:  1.00
CHANNEL  03:     COMPONENT:  e     SERIAL #:  sh-260   +-DIRECTION:  e
                 PRE-AMP GAIN:  512     DAMP GAIN FACTOR:  1.00
.DE
.nr PS 10
.bp
The data in the R$XXX$ subdirectories give amplitudes in counts. 
To convert counts to volts, use the formula:
.EQ
V~=~ {counts*S*DGF} over PAG
.EN
where $PAG$ is the preamp gain, $DGF$ is the Damping Gain Factor
required due to the manner in which damping resistance was added
to the seismometer circuit, and the scale factor $S$ is given by
.EQ (for\ 16\ bit\ data)
S~=~ 3.75 over 32768
.EN
and
.EQ (for\ 32\ bit\ data)
S~=~ 3.75 over 32768 sup 2
.EN
.NH 1
Data Report Format
.PP
We have included in the directory NV8889_LAA/data_report a
complete version of the text in UNIX troff format and the figures
in PostScript format.  On our Sun Microsystems workstations, the
data report may be printed using:
.ce
eqn nv8889_laa.txt | tbl | ptroff -ms
.ce 0
.PP
The Figures may be printed on a PostScript printer using:
.ce
lpr figure*.ps
.ce 0
.bp
.NH 1
Acknowledgements
.PP
This project could not have been completed without the expertise,
enthusiasm, and endless efforts of Jim Fowler, PASSCAL Project
Engineer.  Technical, logistical and administrative assistance by
Tim Ahern, Richard Boaz, Diane DePolo, Wally Nicks, Glen Offield,
Sally Owens, Bill Prothero, and Austin Wilson was valuable.  
This project was supported by IRIS grants to the 
University of Missouri-Columbia, the University of South Carolina, 
and the University of Nevada-Reno.  
T.J. Owens was also supported by the UMC Research Council during
the Fall of 1988.  
.NH 1
References
.PP
Johnson, M., Geology and mineral deposits of Pershing County, Nevada,
Bulletin 89, Nev. Bur. Mines & Geology, 1977.
.NH 1
Data Distribution
.PP
The Data referenced in this report may be obtained through:
.DS
IRIS Data Management Center
8701 Mopac Blvd., Suite 205
Austin, TX 78759
Telephone: (512) 471-0403, 0404, or 0405
.DE
.bp
.NH 1
Appendix A - Large Aperture Array Site Descriptions
.LP
ADR. Located on the western flank of the Stillwater Range on
basalt and andesite flow units of Pliocene age.
.LP
CHB. Located  in the Buena Vista Hills  in an  area underlain by a
gabbroic complex of Jurassic age. 
.LP
FNC. Located on the eastern side of the Buena Vista Valley on a
westward dipping alluvial fan of Quaternary age. This deposit is
characterized by poorly sorted, unconsolidated sands, silts and
gravels derived from the adjacent Stillwater Range.  Bedrock was
estimated to be at a depth of less than 30 meters. 
.LP
GRN. Located in the northeastern portion of the array on the
western flanks of the Stillwater Range along vertical pinnacles of
highly weathered and fractured, Late Oligocene to Late Miocene,
rhyolite. Local rhyolite accumulations occur as thick flows and
shallow intrusives associated with plug domes.
.LP
NYC. Located on the western slope of the Stillwater Range on
highly mylonitized phyllite of the upper Triassic Auld Lang Syne
Group.
.LP
SHP. Located on the eastern slope of the Humbolt Range, on a plug
of Tertiary basalt.  Some seismometer instability due to frost
heaving and lack of insulation occurred. This was the only site
that was not buried completely.
.LP
SUN. Located along the eastern slope of the Humbolt Range in a
mine that penetrated into thickly bedded upper Triassic limestone
and dolomite of the Dun Glenn formation.
.LP
ANT. This site was chosen because the array needed a central site
to increase wavenumber resolution across the array. We found that
the data were of poor quality due to higher frequency
reverberations within the thick Quaternary alluvium of the Buena
Vista Valley floor. The site was removed in November of 1988
because of low data quality.
.bp
.ls 1
.nr PS 10
.nr LL 6.5
.TS
center, tab(|);
c s s s s
c s s s s
c s s s s
c c c c c
c c c c c
l n n n l.
TABLE 1
=
.sp
Large Aperture Array
Station Locations
.sp
=
.sp .5
Station ID|Latitude|Longitude|Elevation|Station Name
|(Deg. N)|(Deg. W)|(meters)
.sp .5
=
.sp
ADR|39.972|118.094|1520.0|Anderson Ranch
ANT|40.113|117.974|1241.7|Antelope
CHB|40.032|118.133|1347.0|Chocolate Butte
FNC|40.096|117.885|1487.0|Fencemaker Flat
GRN|40.218|117.878|1317.0|Granite Hills
NYC|40.051|118.007|1475.0|New York Canyon
SHP|40.217|118.058|1341.0|Shiprock
SUN|40.139|118.099|1335.0|Sunnyside
.sp
=
.TE
.sp 2
.TS
center, tab(|);
c s 
c s
c s
l l
l l.
TABLE 2
=
.sp
Large Aperture Array
Installation Date of Upgraded GOES Clock
.sp
=
.sp .5
Station ID|Date
.sp .5
=
.sp
ADR|12/13/88
ANT|
CHB|01/12/89
FNC|12/03/88
GRN|12/03/88
NYC|12/03/88
SHP|12/20/88
SUN|12/06/88
.sp
=
.TE
.bp
.nr PS 9
.LP
.ls 1
.TS
center, expand, tab(|);
csssssss
csssssss
cccccccc
cccccccc
ccnnnnnl.
TABLE 3
=
.sp
Event Locations
.sp
=
Evt|Date|Origin|Latitude|Longitude|Depth|Mb|Region
ID||Time|(Deg)|(Deg)|(Km)
_
.sp
001|08/17/88|015911.1|7.658S|107.264E|58|6.0|JAVA.
002|08/17/88|113452.4|26.912S|70.855W|39|5.6|NEAR COAST OF NORTHERN CHILE
003|08/17/88|123813.7|27.208S|70.812W|37|5.3|NEAR COAST OF NORTHERN CHILE
007|08/17/88|170000.0|37.297N|116.307W|0|5.4|SOUTHERN NEVADA. "KEARSARGE"
004|08/20/88|230910.3|26.663N|86.620E|70|6.5|NEPAL-INDIA BORDER REGION.
005|08/21/88|111548.8|23.293N|108.346W|10|4.9|GULF OF CALIFORNIA
006|08/21/88|135143.4|42.795S|85.877W|10|5.8|WEST CHILE RISE
008|08/26/88|215323.1|38.810N|118.069W|20||Near Lovelock, NV
009|08/27/88|012517.7|11.303N|141.455E|33|5.2|WEST CAROLINE ISLANDS
010|08/27/88|163017.6|15.838S|172.144W|33|6.0|SAMOA ISLANDS REGION
011|08/30/88|122824.9|37.540N|118.353W|5||CALIFORNIA-NEVADA BORDER REGION.
012|08/30/88|180000.1|37.086N|116.069W|0|5.0|SOUTHERN NEVADA. "BULLFROG"
013|08/30/88|190345.0|37.086N|116.069W|0||BULLFROG COLLAPSE? OT/Location estimated
014|08/31/88|164516.0|31.789N|115.796W|5|4.9|BAJA CALIFORNIA. ML 5.1 (PAS).
015|09/01/88|165252.3|17.065N|99.265W|33|5.0|GUERRERO, MEXICO
016|09/02/88|102748.5|54.030N|161.491E|47|5.1|NEAR EAST COAST OF KAMCHATKA
017|09/05/88|061318.7|18.532N|70.391W|33|5.5|DOMINICAN REPUBLIC REGION.
018|09/07/88|115325.4|30.336N|137.364E|499|6.0|SOUTH OF HONSHU, JAPAN
718|09/07/88|115325.4|30.336N|137.364E|499|6.0|SOUTH OF HONSHU, JAPAN *** S-WAVE 
019|09/13/88|005845.9|29.806N|138.364E|447|5.8|SOUTH OF HONSHU, JAPAN
020|09/14/88|035957.4|49.801N|78.791E|0|6.1|EASTERN KAZAKH SSR
021|09/14/88|221407.6|23.387S|67.945W|124|5.8|CHILE-ARGENTINA BORDER REGION
022|09/15/88|184803.2|1.404S|77.896W|189|5.8|ECUADOR. 
722|09/15/88|184803.2|1.404S|77.896W|189|5.8|ECUADOR. *** S-wave 
023|09/16/88|000652.9|22.952S|175.413W|33|4.9|TONGA ISLANDS REGION
024|09/16/88|021614.9|20.362S|178.364W|500|5.2|FIJI ISLANDS REGION
025|09/16/88|024535.8|20.170S|177.770W|500|4.7|FIJI ISLANDS REGION
026|09/16/88|062729.0|17.785S|169.065E|33|4.9|VANUATU ISLANDS
027|09/17/88|062014.6|29.900N|114.100W|10|4.4|BAJA, CA from NEIC via phone
028|09/17/88|152353.7|44.910N|152.945E|43|5.3|KURIL ISLANDS REGION
029|09/19/88|025630.7|38.432N|118.320W|5|4.5|CALIFORNIA-NEVADA BORDER REGION.
030|09/19/88|032215.8|38.461N|118.341W|5||CALIFORNIA-NEVADA BORDER REGION.
031|09/19/88|114619.8|38.450N|118.349W|7|2.5|Hawthorne, NV aftershock
032|09/19/88|185837.7|23.003S|175.508W|33|5.4|TONGA ISLANDS REGION
033|09/19/88|210145.8|38.478N|118.111W|5||CALIFORNIA-NEVADA BORDER REGION.
034|09/20/88|001609.1|38.937N|118.063W|5||CALIFORNIA-NEVADA BORDER REGION.
035|09/21/88|095851.8|46.129N|152.142E|38|5.9|KURIL ISLANDS
036|09/21/88|144334.9|41.790N|118.847W|22|2.8|Local near Denio, NV.	
037|09/21/88|182955.7|38.460N|118.340W|9|3.2|Local near Hawthorne, NV
038|09/21/88|235926.7|16.073S|173.481W|33|5.5|TONGA ISLANDS
039|09/22/88|105255.0|38.462N|118.340W|12|3.0|Local near Hawthorne, NV
040|09/22/88|222836.3|23.030N|167.860W|10|5.5|HAWAII REGION
041|09/23/88|154855.6|38.957N|118.171W|0|3.5|California/Nevada border
117|09/24/88|043759.8|38.459N|118.343W|0|2.3|California/Nevada border
042|09/26/88|082321.4|35.402N|140.864E|45|5.9|NEAR E COAST OF HONSHU, JAPAN 
043|09/28/88|143847.9|38.462N|118.353W|11|2.3|California/Nevada border
044|09/28/88|164810.0|38.898N|117.830W|14|2.5|North of Hawtorne Nevada       
195|09/30/88|000404.0|41.535N|121.627W|5||NOT IN QDES LOC EST. BY COMPARISON W/#045
045|09/30/88|003014.8|41.535N|121.627W|5||NORTHERN CALIFORNIA. ML 4.1
046|09/30/88|004004.4|41.534N|121.598W|5||NORTHERN CALIFORNIA
047|09/30/88|214501.1|19.356S|177.555W|548|5.4|FIJI ISLANDS REGION
747|09/30/88|214501.1|19.356S|177.555W|548|5.4|FIJI ISLANDS REGION *** S-WAVE 
048|10/01/88|094324.5|35.305S|106.059W|10|5.6|EASTER ISLAND CORDILLERA
049|10/02/88|160930.0|27.100N|110.100W|10|4.7|GULF OF CALIFORNIA from NEIC via phone
050|10/03/88|004557.8|10.227S|161.243E|130|5.5|SOLOMON ISLANDS
051|10/04/88|003410.7|41.420N|121.593W|5||NORTHERN CALIFORNIA. ML 3.2
052|10/04/88|153757.7|3.533S|150.437E|33|5.4|NEW IRELAND REGION
053|10/08/88|044624.4|18.693S|172.429W|33|6.7|TONGA ISLANDS REGION
753|10/08/88|044624.4|18.693S|172.429W|33|6.7|TONGA ISLANDS REGION *** S-WAVE 
054|10/08/88|211420.1|36.098N|117.860W|6||CALIFORNIA-NEVADA BORDER REGION.
055|10/08/88|212606.3|36.098N|117.860W|6||CALIFORNIA-NEVADA BORDER REGION.
056|10/09/88|080030.1|38.457N|118.313W|5||CALIFORNIA-NEVADA BORDER REGION.
057|10/10/88|055211.6|42.830N|144.230E|63|5.6|HOKKAIDO, JAPAN  REGION. 
757|10/10/88|055211.6|42.830N|144.230E|63|5.6|HOKKAIDO, JAPAN  REGION. S-wave
058|10/10/88|071921.2|23.161S|171.969E|33|5.6|LOYALTY ISLANDS REGION
059|10/10/88|182030.0|28.344S|177.670W|57|6.5|KERMADEC ISLANDS REGION
759|10/10/88|182030.0|28.344S|177.670W|57|6.5|KERMADEC ISLANDS REGION *** S-WAVE 
060|10/11/88|133005.1|40.279N|125.632W|10|3.6|OFF COAST OF NORTHERN CALIFORNIA 
061|10/13/88|140000.0|37.089N|116.049W|0|5.9|SOUTHERN NEVADA. *** "DALHART" 
062|10/13/88|161807.8|37.089N|116.049W|0|4.3|SOUTHERN NEVADA. *** "DALHART COLLAPSE" 
063|10/17/88|055653.5|51.237N|159.551E|33|5.7|OFF EAST COAST OF Kamchatka
064|10/17/88|141445.5|38.218N|118.453W|6|2.9|Regional event near Hawthorne, NV
065|10/17/88|190441.3|38.764N|115.200W|24|3.4|Regional event south of Ely, NV
066|10/18/88|185738.7|40.253N|118.177W|0|2.1|Local mine blast
067|10/18/88|220305.6|38.326W|118.453W|9|3.2|Regional event near Mina, NV
068|10/19/88|000841.2|36.987N|141.701E|49|5.6|NEAR EASTCOAST OF HONSHU JAPAN.
069|10/19/88|074505.0|38.740N|116.437W|5||NEVADA. ML 3.4 (NEIS).
070|10/19/88|134444.8|34.940N|118.735W|5||SOUTHERN CALIFORNIA. ML
071|10/19/88|160823.1|37.223N|118.392W|5||CALIFORNIA-NEVADA BORDER REGION
072|10/19/88|224754.0|33.183N|115.583W|5|4.5|SOUTHERN CALIFORNIA. Imperial Valley
073|10/20/88|173300.7|38.802N|122.735W|5||NORTHERN CALIFORNIA.
074|10/22/88|023818.6|37.398N|118.411W|12|3.7|Regional event near Bishop, CA
075|10/22/88|160413.4|49.061N|156.179E|50|5.6|KURIL ISLANDS
076|10/23/88|063745.0|49.120N|156.215E|33|5.6|KURIL ISLANDS
077|10/23/88|133811.1|49.205N|156.239E|33|5.3|KURIL ISLANDS
078|10/24/88|052637.1|41.257N|118.570W|8|2.8|Northwest of Winnemucca, NV
079|10/25/88|144321.0|38.707N|123.848W|5||NEAR COAST OF NORTHERN CALIFORNIA
080|10/26/88|052325.5|38.446N|118.354W|5|3.2|Regional event near Hawthorne, NV
081|10/26/88|141426.2|38.454N|118.358W|8|3.8|Regional event near Mina, NV
082|10/27/88|031632.91|39.029N|117.987W|0|3.5|Local event near Hawthorne,NV.
083|10/27/88|080232.8|38.365N|118.424W|5||CALIFORNIA-NEVADA BORDER REGION.
084|10/27/88|081411.60|38.460N|118.354W|0|2.6|South of Hawthorne,NV
085|10/27/88|083903.29|38.460N|118.359W|0|2.6|South of Hawthorne,NV
086|10/28/88|144930.2|16.198S|174.342W|140|5.4|TONGA ISLANDS
786|10/28/88|144930.2|16.198S|174.342W|140|5.4|TONGA ISLANDS *** S-wave
087|10/28/88|200253.37|37.595N|116.772W|0|3.1|South of Warm Springs,NV
088|10/31/88|020812.5|23.305S|66.665W|204|5.0|JUJUY PROVINCE,ARGENTINA.
089|11/01/88|224752.43|40.880N|118.691W|0|2.5|Local mine Blast
090|11/03/88|144711.1|13.793N|90.696W|69|5.6|NEAR COAST OF GUATEMALA
790|11/03/88|144711.1|13.793N|90.696W|69|5.6|NEAR COAST OF GUATEMALA *** S-wave
091|11/03/88|200329.48|39.393N|119.565W|0|2.8|Local mine blast
092|11/07/88|035002.8|22.179S|175.008E|33|5.6|SOUTH OF FIJI ISLANDS
093|11/09/88|201459.7|36.987N|116.009W|5||CALIFORNIA-NEVADA BORDER REGION
094|11/10/88|050800.1|37.357N|121.868W|5|4.7|CENTRAL CALIFORNIA
096|11/20/88|053926.8|33.461N|118.145W|5|5.1|SOUTHERN CALIFORNIA.
796|11/20/88|053926.8|33.461N|118.145W|5|5.1|SOUTHERN CALIFORNIA. *** S-wave
097|11/21/88|230131.69|40.257N|118.162W|0|1.7|Local mine blast
098|11/22/88|075739.2|37.396N|118.515W|5||CALIFORNIA-NEVADA BORDER REGION
099|11/22/88|145445.76|39.358N|118.466W|0|2.4|Local mine blast
100|11/23/88|201122.6|38.568N|117.738W|5||11 NEVADA. ML 2.8 (NEIC)
101|11/25/88|234602.9|48.124N|71.246W|20|5.9|SOUTHERN QUEBEC
102|12/03/88|113825.0|34.151N|118.139W|10|4.5|SOUTHERN CALIFORNIA
103|12/04/88|123358.9|39.319N|118.162W|0|3.0|Near Fallon Nevada
104|12/05/88|160531.4|15.320S|173.400W|33|6.1|TONGA ISLANDS
105|12/07/88|074124.2|40.949N|44.293E|10|6.2|TURKEY-USSR BORDER REGION
106|12/07/88|074544.2|41.056N|44.481E|10|5.8|WESTERN CAUCASUS
107|12/07/88|225359.58|41.085N|119.120W|0|2.6|West of Winnemucca NV.
108|12/08/88|121720.00|40.246N|117.751W|0|2.1|Local mine blast
109|12/08/88|125859.8|6.876N|82.827W|10|5.7|SOUTH OF PANAMA
809|12/08/88|125859.8|6.876N|82.827W|10|5.7|SOUTH OF PANAMA *** S-wave
110|12/09/88|190909.64|38.090N|118.861W|0|2.9|Local mine blast
111|12/10/88|203000.0|37.199N|116.209W|0|5.1|SOUTHERN NEVADA."MISTY ECHO"
112|12/13/88|040138.9|71.067N|7.775W|10|5.7|JAN MAYEN ISLAND REGION
114|12/16/88|055303.5|33.984N|116.695W|5|4.9|SOUTHERN CALIFORNIA
115|12/16/88|095717.4|29.670S|178.000W|33|6.2|KERMADEC ISLANDS
116|12/30/88|174136.95|37.532N|118.403W|0|3.0|Local mine blast 
118|12/24/88|042657.5|23.386S|66.392W|223|5.9|JuJuy Province, Argentina
119|01/02/89|015210.4|18.326S|174.548W|122|6.0|TONGA ISLANDS
819|01/02/89|015210.4|18.326S|174.548W|122|6.0|TONGA ISLANDS S-wave
120|01/03/89|044111.2|29.526N|131.454E|33|5.7|RYUKYU ISLANDS REGION
121|01/09/89|050821.0|36.311N|115.115W|5||CALIFORNIA-NEVADA BORDER REGION.
122|01/09/89|134237.2|46.794N|153.733E|33|5.9|KURIL ISLANDS
822|01/09/89|134237.2|46.794N|153.733E|33|5.9|KURIL ISLANDS, S-wave
123|01/11/89|122332.1|44.577N|129.723W|10|4.7|OFF COAST OF OREGON
124|01/11/89|155202.5|44.554N|129.653W|10|4.7|OFF COAST OF OREGON
125|01/12/89|194740.5|46.694N|153.981E|33|5.6|KURIL ISLANDS
126|01/13/89|180156.2|46.497N|153.662E|33|5.6|KURIL ISLANDS
127|01/14/89|231326.43|39.716N|117.339W|0||Local mine blast
128|01/19/89|065328.0|33.922N|118.629W|10|5.2|SOUTHERN CALIFORNIA.
129|01/20/89|121041.56|39.288N|119.672W|0||Local Mine Blast
130|01/22/89|222018.8|41.742N|144.359E|33|6.0|HOKKAIDO, JAPAN  REGION.
131|01/25/89|093056.93|38.459N|118.328W|0||Local Mine Blast
132|01/27/89|083451.9|56.188N|164.440E|33|5.8|KOMANDORSKY ISLANDS REGION
133|01/30/89|040621.0|38.900N|111.600W|10|5.4|UTAH
134|01/31/89|173925.3|22.292N|107.179W|10|5.2|OFF COAST OF CENTRAL MEXICO
135|02/04/89|192411.2|5.929N|82.808W|33|5.8|SOUTH OF PANAMA
136|02/07/89|040300.5|21.852S|66.931W|179|5.4|SOUTHERN BOLIVIA
137|02/10/89|111526.7|3.03N|126.92E|33|6.0|TALAUD ISLANDS. 
437|02/10/89|111526.7|3.0300N|126.920E|33|6.0|TALAUD ISLANDS.
138|02/10/89|200559.2|37.064N|115.976W|0|5.1|SOUTHERN NEVADA. 
162|02/10/89|        |37.064N|115.976W|0||Collapse from Evt 138 explosion?
139|02/13/89|145124.4|57.460N|33.107W|10|5.2|NORTH ATLANTIC OCEAN
140|02/13/89|151447.4|57.409N|33.279W|10|5.2|NORTH ATLANTIC OCEAN
141|02/14/89|062026.9|10.434S|161.283E|78|6.1|SOLOMON ISLANDS
841|02/14/89|062026.9|10.434S|161.283E|78|6.1|SOLOMON ISLANDS *** S-wave
142|02/14/89|154353.7|35.067N|119.145W|10||CENTRAL CALIFORNIA.
143|02/15/89|053136.3|39.273N|117.331W|5||NEVADA.
144|02/16/89|215037.8|45.327N|151.785E|95|5.7|KURIL ISLANDS
210|02/17/89|012316.2|39.312N|117.428W|0|2.6|Regional
145|02/18/89|071704.0|34.017N|117.733W|6||SOUTHERN CALIFORNIA.
211|02/18/89|140245.0|39.226N|117.333W|10|3.3|Nevada Regional
197|02/19/89|120041.9|39.309N|115.939W|10|3.4|Nevada Regional
198|02/20/89|073211.3|39.244N|117.375W|10|2.4|Nevada Regional
199|02/22/89|092859.0|39.256N|117.401W|4|2.9|Nevada Regional
200|02/22/89|094944.6|39.230N|117.338W|0|3.5|Nevada Regional
146|02/22/89|102541.4|56.217N|153.629W|7|5.7|KODIAK ISLAND REGION
147|02/24/89|161500.0|37.128N|116.122W|0|4.4|SOUTHERN NEVADA."KAWICH,"
148|02/25/89|112637.7|29.759S|177.918W|47|6.4|KERMADEC ISLANDS
848|02/25/89|112637.7|29.759S|177.918W|47|6.4|KERMADEC ISLANDS *** S-wave
149|02/27/89|151307.0|38.915N|111.674W|10|3.4|UTAH.
150|02/28/89|130157.9|23.086S|61.585W|575|5.5|PARAGUAY
151|03/01/89|024202.2|43.769N|148.985E|44|5.7|KURIL ISLANDS REGION
152|03/02/89|071345.6|18.413N|68.676W|129|5.4|MONA PASSAGE.
153|03/06/89|143942.0|35.800N|140.400E|33|5.7|NEAR EAST COAST OF HONSHU, JAPAN 
154|03/06/89|221646.0|33.000N|115.600W|10|4.4|SOUTHERN CALIFORNIA
463|03/09/89|023700.5|13.743S|34.298E|33|5.7|MALAWI Triggered on PKP
155|03/09/89|140500.0|37.143N|116.067W|0|5.0|SOUTHERN NEVADA "INGOT,"
464|03/10/89|214946.1|13.781S|34.226E|33|6.1|MALAWI Triggered on PKP
156|03/11/89|050454.3|17.723S|174.798W|175|6.3|TONGA ISLANDS
856|03/11/89|050454.3|17.723S|174.798W|175|6.3|TONGA ISLANDS *** S-wave
157|03/11/89|122145.0|37.881N|116.018W|5||SOUTHERN NEVADA
201|03/12/89|133133.4|40.285N|117.766W|7|2.5|Nevada Regional
202|03/12/89|225659.9|39.860N|119.381W|3|2.2|Nevada Regional
158|03/15/89|233410.7|38.376N|119.353W|5||CALIFORNIA-NEVADA BORDER REGION
203|03/15/89|234207.8|38.404N|119.404W|7|3.4|Nevada Regional
159|03/16/89|093400.5|29.992S|178.119W|57|5.7|KERMADEC ISLANDS
160|03/17/89|193306.9|34.350S|178.650W|44|5.9|SOUTH OF KERMADEC ISLANDS
204|03/19/89|031918.8|39.356N|120.003W|9|2.5|Nevada Regional
161|03/20/89|010633.1|59.927N|153.718W|127|5.0|SOUTHERN ALASKA.
205|03/25/89|073529.7|39.924N|117.837W|6|2.6|Nevada Regional
206|03/25/89|133530.2|39.236N|117.373W|0|2.7|Nevada Regional
165|03/26/89|180336.3|38.752N|122.595W|5||N CALIF
214|03/30/89|203929.6|19.371S|176.052W|229|5.5|FIJI ISL REGION
166|04/03/89|174631.3|37.350N|121.868W|5|4.5|CENTRAL CALIFORNIA
167|04/05/89|234748.3|21.135S|69.211W|114|5.8|NORTHERN CHILE
867|04/06/89|234748.3|21.135S|69.211W|114|5.8|NORTHERN CHILE S-wave
168|04/06/89|080540.0|19.602S|169.467E|33|6.3|VANUATU ISLANDS
868|04/06/89|080540.0|19.602S|169.467E|33|6.3|VANUATU ISLANDS S-wave
169|04/07/89|133211.6|51.337N|30.008W|10|5.1|NORTH ATLANTIC RIDGE
170|04/07/89|200728.2|33.540N|118.006W|5|4.5|SOUTHERN CALIFORNIA
171|04/08/89|012220.5|57.251N|143.615W|10|4.9|GULF OF ALASKA
172|04/08/89|030601.4|15.680S|173.004W|33|5.5|TONGA ISLANDS
173|04/09/89|050750.3|51.533N|178.440W|32|5.2|ANDREANOF ISLANDS, ALEUTIAN IS
174|04/11/89|035638.8|49.387N|159.259E|33|6.3|KURIL ISLANDS REGION
874|04/11/89|035638.8|49.387N|159.259E|33|6.3|KURIL ISLANDS REGION S-wave
175|04/13/89|004311.2|39.488S|75.081W|33|5.9|OFF COAST OF CENTRAL CHILE
875|04/13/89|004311.2|39.488S|75.081W|33|5.9|OFF COAST OF CENTRAL CHILE S-wave
176|04/14/89|125209.2|19.200N|144.860E|33|5.8|MARIANA ISLANDS
177|04/14/89|130247.8|18.052S|178.423W|571|5.4|FIJI ISLANDS REGION
877|04/14/89|130247.8|18.052S|178.423W|571|5.4|FIJI ISLANDS REGION S-wave
207|04/15/89|061407.4|38.155N|117.864W|10|2.9|Local mine blast
178|04/15/89|142641.6|8.430N|61.070W|25|5.8|VENEZUELA. Felt in southern
179|04/15/89|203411.5|30.021N|99.321E|33|6.2|SICHUAN PROVINCE, CHINA
479|04/15/89|203411.5|30.021N|99.321E|33|6.2|SICHUAN PROVINCE, CHINA *** PP Phase
180|04/16/89|105116.6|4.735N|32.671W|10|5.4|CENTRAL MID-ATLANTIC RIDGE
181|04/16/89|194814.9|20.989S|179.034W|611|5.6|FIJI ISLANDS REGION
881|04/16/89|194814.9|20.989S|179.034W|611|5.6|FIJI ISLANDS REGION S-wave
481|04/16/89|194814.9|20.989S|179.034W|611|5.6|FIJI ISLANDS REGION *** PP phase
182|04/18/89|123353.6|23.718S|179.914E|536|5.8|SOUTH OF FIJI ISLANDS
882|04/18/89|123353.6|23.718S|179.914E|536|5.8|SOUTH OF FIJI ISLANDS S-wave
196|04/19/89|000822.9|31.323S|177.906W|33|5.8|KERMADEC ISLANDS REGION
183|04/19/89|144856.0|17.859N|105.303W|10|5.1|OFF COAST OF JALISCO, MEXICO
184|04/19/89|223929.0|37.263N|115.100W|5||SOUTHERN NEVADA
185|04/20/89|080851.5|9.170S|79.034W|64|5.7|OFF COAST OF NORTHERN PERU
186|04/20/89|124552.7|38.489N|117.831W|5|4.3|NEVADA
187|04/20/89|225954.9|57.123N|121.950E|33|6.0|EASTERN USSR
887|04/20/89|225954.9|57.123N|121.950E|33|6.0|EASTERN USSR S-wave
188|04/22/89|151545.4|38.165N|117.805W|5||NEV. ML 3.2
189|04/22/89|152312.9|38.162N|117.806W|5||NEV. ML 2.9
190|04/23/89|192110.0|66.918N|156.241W|33|5.7|ALASKA
191|04/25/89|021324.5|30.042N|99.477E|33|6.1|SICHUAN PROV CHINA
491|04/25/89|021324.4|30.042N|99.477E|33|6.1|SICHUAN PROV CHINA *** PP phase
192|04/25/89|142901.1|16.874N|99.411W|23|6.4|NEAR COAST OF GUERRERO, MEX.
193|04/25/89|171837.9|35.890N|140.414E|71|5.4|NEAR E COAST OF HONSHU, JAPAN.
194|04/27/89|022005.8|30.694N|140.734E|93|6.0|S OF HONSHU, JAPAN.
894|04/27/89|022005.8|30.694N|140.734E|93|6.0|S OF HONSHU, JAPAN. S-wave
208|04/26/89|204316.2|38.517N|119.268W|10|2.8|Local mine Blast
209|04/26/89|210108.7|38.514N|119.271W|13|2.6|Local Mine Blast
212|04/28/89|074816.0|13.100N|89.700W|33||El Salvador
213|04/28/89|023425.0|17.800N|105.200W|33||Jalisco, Mexico
=
.TE
.nr PS 10
.bp
.nr PS 10
.nr LL 6.5
.TS
center, expand, tab(|);
c s s s s s s s s s
c s s s s s s s s s
c s s s s s s s s s
c c c s c s s c s s
c c c c c c c c c c
c c c c c c c c c c
c c c c c c c c c c
l l n n n n n n n n.
TABLE 4
=
.sp
Large Aperture Array
Seismometer Calibration Parameters 
.sp
=
.sp .5
||Vertical Component|East Component|North Component
_
.sp .25
Sta|Date|Free|Fraction|Free|Fraction|Relative|Free|Fraction|Relative
Cal ID||Period|Critical|Period|Critical|Ampl.|Period|Critical|Ampl.
||(sec)|Damping|(sec)|Damping||(sec)|Damping|
.sp .5
=
.sp
ADR 003|10/18/88|4.92|0.71|4.23|0.64|0.606|4.23|0.66|0.586
ADR 011|10/25/88|4.91|0.71|4.20|0.63|0.593|4.23|0.64|0.572
ADR 018|11/02/88|4.91|0.71|4.23|0.63|0.595|4.21|0.63|0.566
ADR 042|11/17/88|4.99|0.71|4.15|0.61|0.598|4.14|0.63|0.574
ADR 043|11/17/88|5.00|0.71|4.16|0.59|0.587|4.14|0.62|0.577
ADR 058|12/02/88|5.01|0.75|4.23|0.60|0.567|3.99|0.63|0.587
ADR 074|12/06/88|4.85|0.71|4.08|0.62|0.577|4.08|0.63|0.565
ADR 075|12/13/88|5.09|0.70|4.06|0.61|0.619|3.98|0.61|0.616
ADR 093|01/04/89|5.00|0.71|3.98|0.60|0.595|3.92|0.62|0.593
ADR 094|01/04/89|5.00|0.71|3.98|0.60|0.594|3.92|0.62|0.592
ADR 105|01/13/89|5.08|0.70|4.12|0.58|0.573|4.03|0.57|0.577
ADR 106|01/13/89|5.08|0.70|4.12|0.58|0.574|4.06|0.55|0.551
ADR 109|02/07/89|5.14|0.72|4.05|0.59|0.582|3.98|0.61|0.587
ADR 110|02/07/89|4.99|0.71|3.97|0.59|0.583|3.91|0.60|0.591
ADR 117|02/15/89|4.91|0.72|3.99|0.56|0.541|3.92|0.59|0.543
ADR 130|03/01/89|5.00|0.68|4.06|0.59|0.584|4.07|0.60|0.567
ADR 131|03/09/89|5.07|0.70|3.98|0.58|0.606|3.99|0.61|0.586
ADR 138|03/21/89|5.08|0.71|4.07|0.59|0.587|4.07|0.60|0.575
ADR 146|04/04/89|4.85|0.71|3.98|0.60|0.574|3.97|0.63|0.563
ADR 168|04/29/89|4.92|0.71|4.06|0.61|0.585|4.06|0.63|0.575
ADR 169|04/29/89|5.00|0.69|4.14|0.60|0.578|4.14|0.61|0.555
.sp .25
_
.sp .25
ANT 016|10/26/88|5.47|0.80|4.21|0.64|0.412|4.15|0.62|0.549
ANT 021|11/02/88|5.15|0.81|3.84|0.72|0.401|3.81|0.37|0.465
ANT 031|11/08/88|5.61|0.76|3.82|0.69|0.549|3.69|0.66|0.654
.sp .25
_
.sp .25
CHB 004|10/18/88|4.61|0.70|4.59|0.59|0.547|4.76|0.63|0.559
CHB 012|10/26/88|4.68|0.70|4.70|0.59|0.573|4.76|0.64|0.589
CHB 019|11/02/88|4.60|0.72|4.47|0.61|0.589|4.61|0.64|0.577
CHB 025|11/08/88|4.60|0.69|4.53|0.59|0.571|4.54|0.63|0.588
CHB 051|11/20/88|4.53|0.73|4.28|0.58|0.563|4.45|0.61|0.566
CHB 107|01/13/89|4.54|0.68|4.14|0.57|0.611|4.06|0.53|0.553
CHB 132|03/09/89|4.37|0.90|4.15|0.58|0.639|4.11|0.57|0.599
CHB 139|03/21/89|4.54|0.82|4.22|0.59|0.677|4.22|0.58|0.667
CHB 147|04/04/89|4.76|0.81|4.29|0.60|0.713|4.21|0.58|0.711
CHB 148|04/04/89|4.62|0.83|4.31|0.59|0.680|4.24|0.59|0.668
CHB 156|04/19/89|4.61|0.82|4.52|0.59|0.652|4.52|0.57|0.627
CHB 167|04/29/89|4.60|0.81|4.37|0.60|0.684|4.44|0.58|0.648
.sp .25
_
.sp .25
FNC 032|11/08/88|5.15|0.73|4.38|0.61|0.664|4.06|0.74|0.737
FNC 040|11/12/88|5.01|0.77|4.44|0.60|0.582|4.14|0.70|0.628
FNC 055|11/29/88|5.00|0.73|4.27|0.58|0.640|4.14|0.69|0.633
FNC 061|12/03/88|4.92|0.71|4.12|0.59|0.657|4.05|0.67|0.645
FNC 062|12/03/88|4.92|0.72|4.15|0.62|0.672|4.05|0.63|0.627
FNC 067|12/06/88|5.00|0.72|4.13|0.60|0.664|4.00|0.67|0.654
FNC 068|12/06/88|4.99|0.70|4.04|0.58|0.683|3.99|0.68|0.668
FNC 078|12/13/88|4.91|0.75|3.99|0.59|0.669|4.13|0.63|0.577
FNC 079|12/13/88|5.14|0.71|4.13|0.58|0.688|4.14|0.65|0.643
FNC 090|12/20/88|5.07|0.73|4.13|0.58|0.667|4.05|0.62|0.621
FNC 096|01/04/89|5.07|0.76|4.05|0.59|0.658|3.91|0.67|0.663
FNC 100|01/13/89|5.07|0.72|4.05|0.56|0.655|3.93|0.64|0.649
FNC 101|01/13/89|5.08|0.70|4.05|0.58|0.679|4.05|0.61|0.627
FNC 120|02/15/89|4.99|0.71|3.98|0.57|0.654|3.88|0.66|0.656
FNC 126|02/23/89|4.93|0.71|4.07|0.65|0.724|3.92|0.64|0.643
FNC 127|03/01/89|4.93|0.68|4.08|0.53|0.630|3.92|0.69|0.668
FNC 135|03/09/89|5.06|0.67|4.19|0.55|0.649|4.13|0.63|0.644
FNC 144|03/21/89|4.93|0.71|4.16|0.59|0.645|4.05|0.63|0.627
FNC 153|04/04/89|4.84|0.72|4.07|0.61|0.656|4.00|0.66|0.637
.sp .25
_
.sp .25
GRN 002|10/15/88|4.76|0.71|3.82|0.54|0.452|4.45|0.61|0.466
GRN 009|10/19/88|4.78|0.72|3.81|0.54|0.452|4.47|0.62|0.468
GRN 017|10/26/88|4.78|0.72|3.99|0.57|0.447|4.61|0.63|0.464
GRN 020|11/02/88|4.69|0.71|3.77|0.57|0.463|4.30|0.62|0.490
GRN 033|11/08/88|4.84|0.76|3.74|0.62|0.491|4.52|0.69|0.484
GRN 034|11/08/88|4.70|0.68|3.67|0.55|0.486|4.29|0.60|0.494
GRN 041|11/13/88|4.62|0.64|3.69|0.54|0.461|4.30|0.59|0.472
GRN 044|11/17/88|4.83|0.69|3.50|0.50|0.482|4.14|0.59|0.504
GRN 056|11/30/88|4.67|0.69|3.50|0.51|0.475|3.96|0.58|0.507
GRN 057|11/30/88|4.71|0.64|3.45|0.50|0.476|4.03|0.57|0.505
GRN 064|12/03/88|4.76|0.70|3.38|0.49|0.483|4.06|0.59|0.492
GRN 069|12/06/88|4.69|0.69|3.51|0.50|0.449|4.06|0.59|0.476
GRN 070|12/06/88|4.91|0.68|3.37|0.53|0.526|4.07|0.57|0.510
GRN 076|12/13/88|4.70|0.69|3.52|0.51|0.460|3.92|0.55|0.489
GRN 077|12/13/88|4.69|0.68|3.51|0.49|0.453|3.98|0.54|0.479
GRN 088|12/20/88|4.83|0.71|3.43|0.51|0.484|4.13|0.58|0.484
GRN 089|12/20/88|4.76|0.69|3.44|0.47|0.462|4.13|0.58|0.472
GRN 095|01/04/89|4.70|0.65|3.42|0.52|0.484|4.00|0.63|0.501
GRN 099|01/13/89|4.77|0.73|3.29|0.48|0.463|3.84|0.57|0.498
GRN 113|02/07/89|4.77|0.72|3.37|0.51|0.468|3.98|0.59|0.489
GRN 114|02/07/89|4.75|0.71|3.35|0.49|0.463|3.92|0.59|0.501
GRN 118|02/15/89|4.68|0.72|3.28|0.49|0.459|3.92|0.59|0.493
GRN 119|02/15/89|4.68|0.72|3.28|0.49|0.459|3.92|0.59|0.493
GRN 137|03/14/89|4.70|0.73|3.53|0.54|0.470|4.07|0.61|0.497
GRN 142|03/21/89|4.78|0.72|3.52|0.50|0.454|4.20|0.59|0.467
GRN 143|03/21/89|4.76|0.71|3.51|0.48|0.450|4.20|0.58|0.479
GRN 151|04/04/89|4.92|0.75|3.51|0.48|0.450|4.15|0.59|0.485
GRN 152|04/04/89|4.62|0.75|3.44|0.51|0.450|4.13|0.61|0.461
GRN 158|04/19/89|4.62|0.68|3.61|0.53|0.475|4.07|0.54|0.479
GRN 163|04/29/89|4.61|0.67|3.49|0.49|0.467|4.15|0.60|0.509
.sp .25
_
.sp .25
NYC 007|10/18/88|5.48|0.75|4.47|0.64|0.627|4.39|0.63|0.669
NYC 015|10/26/88|5.61|0.75|4.11|0.73|0.756|4.31|0.62|0.701
NYC 022|11/03/88|5.55|0.74|4.31|0.64|0.666|4.22|0.62|0.711
NYC 029|11/08/88|5.70|0.72|4.31|0.61|0.676|4.13|0.63|0.759
NYC 030|11/08/88|5.70|0.73|4.30|0.62|0.684|4.23|0.62|0.727
NYC 038|11/12/88|5.45|0.75|4.23|0.62|0.637|4.22|0.59|0.676
NYC 045|11/18/88|5.85|0.72|4.28|0.61|0.699|4.07|0.59|0.756
NYC 046|11/18/88|5.63|0.74|4.13|0.61|0.664|4.13|0.60|0.692
NYC 065|12/06/88|5.60|0.75|4.06|0.59|0.657|3.91|0.59|0.701
NYC 066|12/06/88|5.64|0.67|4.07|0.54|0.669|3.91|0.52|0.702
NYC 080|12/13/88|5.39|0.76|3.91|0.54|0.631|3.83|0.59|0.697
NYC 091|12/20/88|5.38|0.76|3.92|0.58|0.643|3.75|0.58|0.689
NYC 092|12/20/88|5.78|0.68|4.07|0.58|0.727|3.90|0.59|0.753
NYC 097|01/04/89|5.63|0.71|4.00|0.55|0.669|3.77|0.54|0.709
NYC 102|01/13/89|5.31|0.75|3.90|0.55|0.621|3.68|0.52|0.663
NYC 121|02/15/89|5.39|0.77|3.75|0.53|0.631|3.76|0.55|0.650
NYC 124|02/22/89|5.40|0.68|3.90|0.53|0.648|3.68|0.56|0.731
NYC 125|02/22/89|5.78|0.80|4.14|0.59|0.645|4.08|0.59|0.665
NYC 145|03/21/89|5.78|0.76|4.05|0.59|0.658|3.81|0.55|0.686
NYC 154|04/04/89|5.62|0.60|4.14|0.58|0.740|3.90|0.57|0.782
NYC 155|04/04/89|5.63|0.60|4.14|0.58|0.736|3.90|0.57|0.777
NYC 160|04/19/89|5.29|0.53|4.30|0.60|0.751|4.00|0.59|0.810
.sp .25
_
.sp .25
SHP 001|10/14/88|5.16|0.76|4.61|0.68|0.512|4.29|0.60|0.515
SHP 005|10/18/88|5.08|0.78|4.70|0.64|0.478|4.39|0.60|0.482
SHP 013|10/26/88|5.31|0.76|4.69|0.66|0.505|4.37|0.59|0.507
SHP 035|11/12/88|5.30|0.73|4.52|0.63|0.510|4.22|0.58|0.536
SHP 047|11/18/88|5.15|0.73|4.38|0.63|0.510|4.15|0.59|0.524
SHP 048|11/18/88|5.24|0.71|4.39|0.62|0.528|4.20|0.58|0.531
SHP 054|11/29/88|5.24|0.74|4.16|0.64|0.549|3.97|0.58|0.551
SHP 059|12/03/88|5.25|0.73|4.23|0.66|0.559|3.99|0.55|0.520
SHP 071|12/06/88|5.31|0.71|4.22|0.63|0.573|3.91|0.59|0.580
SHP 081|12/14/88|5.08|0.75|4.21|0.62|0.512|3.91|0.59|0.528
SHP 136|03/13/89|5.08|0.72|4.38|0.63|0.540|4.00|0.55|0.523
SHP 140|03/21/89|5.08|0.69|4.38|0.61|0.538|4.17|0.56|0.521
SHP 149|04/04/89|4.92|0.62|4.47|0.62|0.545|4.23|0.58|0.541
SHP 161|04/19/89|4.61|0.54|4.68|0.67|0.585|4.38|0.56|0.544
SHP 165|04/29/89|4.94|0.68|4.53|0.63|0.527|4.23|0.58|0.532
.sp .25
_
.sp .25
SUN 006|10/18/88|4.92|0.65|4.23|0.65|0.656|4.07|0.62|0.528
SUN 014|10/26/88|4.93|0.65|4.23|0.64|0.653|4.08|0.63|0.531
SUN 023|11/03/88|5.01|0.68|4.20|0.66|0.676|3.99|0.64|0.556
SUN 024|11/03/88|4.92|0.64|4.29|0.63|0.646|3.92|0.64|0.571
SUN 028|11/08/88|4.68|0.72|4.15|0.70|0.616|3.84|0.68|0.544
SUN 036|11/12/88|4.84|0.66|4.13|0.67|0.658|3.92|0.64|0.542
SUN 037|11/12/88|4.82|0.67|4.15|0.66|0.636|3.99|0.64|0.518
SUN 049|11/18/88|4.93|0.64|4.07|0.65|0.666|4.07|0.65|0.666
SUN 050|11/18/88|4.84|0.68|4.15|0.64|0.624|4.15|0.64|0.624
SUN 052|11/29/88|4.75|0.66|4.07|0.66|0.639|3.99|0.63|0.522
SUN 053|11/29/88|4.92|0.65|4.13|0.63|0.650|3.91|0.61|0.543
SUN 060|12/03/88|4.93|0.65|4.13|0.63|0.644|3.92|0.65|0.548
SUN 072|12/06/88|4.93|0.65|4.00|0.66|0.691|4.06|0.62|0.511
SUN 073|12/06/88|4.82|0.63|4.07|0.65|0.651|3.92|0.63|0.551
SUN 082|12/14/88|4.83|0.67|4.07|0.60|0.634|3.98|0.63|0.536
SUN 083|12/14/88|4.84|0.67|4.07|0.60|0.632|3.99|0.63|0.529
SUN 098|01/05/89|4.99|0.63|3.91|0.61|0.696|4.04|0.58|0.499
SUN 103|01/13/89|5.08|0.62|4.00|0.56|0.645|3.75|0.65|0.611
SUN 104|01/13/89|5.00|0.62|3.84|0.59|0.674|3.84|0.64|0.577
SUN 111|02/07/89|5.01|0.65|3.68|0.57|0.678|3.90|0.61|0.536
SUN 112|02/07/89|4.84|0.67|3.74|0.57|0.618|3.75|0.62|0.530
SUN 122|02/15/89|4.83|0.64|3.82|0.57|0.621|3.81|0.61|0.526
SUN 123|02/15/89|4.85|0.66|3.84|0.57|0.617|3.82|0.60|0.529
SUN 128|03/01/89|4.84|0.64|3.85|0.60|0.652|3.90|0.63|0.532
SUN 129|03/01/89|4.78|0.66|3.92|0.59|0.613|3.91|0.60|0.515
SUN 133|03/09/89|5.01|0.67|4.04|0.58|0.624|3.99|0.60|0.524
SUN 134|03/09/89|4.92|0.65|4.00|0.61|0.638|3.91|0.60|0.538
SUN 141|03/21/89|5.06|0.63|3.84|0.63|0.727|3.75|0.64|0.603
SUN 150|04/04/89|4.92|0.66|3.99|0.59|0.633|3.84|0.63|0.552
SUN 162|04/19/89|4.91|0.65|3.98|0.60|0.637|3.89|0.62|0.548
SUN 166|04/29/89|4.94|0.65|3.89|0.59|0.646|3.92|0.64|0.550
.sp .5
=
.TE
.bp
.nr LL 6.5i
.nr PS 10
.LP
.NH 1
Figure Captions
.sp
.LP
Figure 1.  Basemap of Nevada.  Heavy lines show the locations of the
1986 PASSCAL Basin and Range Active-Source Seismic Experiment.  The 
1988-89 Passive-Source Experiment was located in an area with a radius
of 20 km around the intersection of the 1986 lines.
.sp
.LP
Figure 2.  Expanded map of stations locations.  Boxes are the stations
of the Large Aperture Array, diamonds are the stations of the Small
Aperture Array, and small triangles are the sites of the 1986 Active
Source Experiment.
.sp
.LP
Figure 3.  Distribution of Teleseismic Events recorded by the Large
Aperture Array.  
Distance increases radially outward, back azimuth increases clockwise.
.sp
.LP
Figure 4A.  P-wave trigger for Event 156 recorded by the Large
Aperture Array.
.sp
.LP
Figure 4B.  S-wave trigger for Event 156 recorded by the Large
Aperture Array.  Using our numbering scheme, this is event number
856.  Trigger occurred 9 minutes, 41 seconds after the
P-wave trigger shown in Figure 4A.  
.sp
.LP
Figure 5.  Trigger for Event 155, NTS shot "INGOT", recorded by
the Large Aperture Array.
.sp
.LP
Figure 6.  Trigger for Event 208, a Nevada mine blast,
recorded by the Large Aperture Array.