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An Integrated, Subsurface Characterization System for Real-Time, In-Situ Field Analysis
Federal Manufacturing & Technologies
Chris W. Baumgart, James Creager, John Mathes, Tom Pounds AI VanDeusen, and Barry Warthen .
KCP-613-5742
Published February 1996
Approved for public release; distribution is unlimited.
Prepared Under Contract Number DE-AC04-76-DP00613 for the United States Department of Energy 4lliedSig nal
- A E R O S P A C E
DISCLAIMER .-
This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade names, trademark, manufacturer, or otherwise, does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof.
Printed in the United States of America.
This report has been reproduced from the best available copy.
Available to DOE and DOE contractors from the Office of Scientific and Technical Information, P. 0. Box 62, Oak Ridge, Tennessee 37831; prices available from (615) 576-8401, FTS 626-8401.
Available to the public from the National Technical Information Service, U. S. Department of Commerce, 5285 Port Royal Rd., Springfield, Virginia 22161.
Copyright 0 1996 by AlliedSignal Inc. The Government is granted for itself and others acting on its behalf a paid-up, nonexclusive, irrevocable worldwide license in this data to reproduce, prepare derivative works, and perform publicly and display publicly.
A prime contractor with t h e United S ta tes Department of Energy under Contract Number DE-AC04-76-DP00613.
AlliedSignal Inc. Federal Manufacturing & Technologies P. 0. Box 419159 Kansas City, Missouri 64141 -61 59
KCP-6 1 3-5742 Distribution Category UC-706
Approved for public release; distribution is unlimited.
AN INTEGRATED, SUBSURFACE CHARACTERIZATION SYSTEM FOR REAL-TIME, IN-SITU FIELD ANALYSIS
Chris W. Baumgart, James Creager, John Mathes, Tom Pounds, AI VanDeusen, and Barry Warthen
Published February 1996
Paper submitted to Fourth International Conference, On-Site Analysis January 22-24,1996 Orlando, FL
&lliedSig nal A E R O S P A C E -
An Integrated, Subsurface Characterization System For Real-Time, In-Situ Field Analysis
Chris W. Baumgart, James Creager, John Mathes, Tom Pounds, A1 VanDeusen, Barry Warthen
AlliedSignal Federal Manufacturing & Technologies* P.O. Box 4339, Station A Albuquerque, NM 87 196
INTRODUCTION
This paper describes current efforts at AlliedSignal Federal Manufacturing & Technologies
(FM&T) to develop and field an in-situ, data analysis platform to acquire, process, and
display site survey data in near real-time. In past years, FM&T has performed a number of
site survey tasks. Each of these surveys was unique in application as well as in the type of
data processing and analysis that was required to extract and visualize useful site
characterization information. However, common to each of these surveys were the
following specific computational and operational requirements:
1. A capability to acquire, process, and visualize the site survey data in the field
2. A capability to perform all processing in a timely fashion (ideally real-time)
Operated for the United States Department of Energy under Contract No. DE-AC04-76- DP006 13. 0 Copyright AUiedSignal, Inc., 1996
3. A technique for correlating (or fusing) data streams from multiple sensors .-
Two more general, but no less important, requirements include system architecture
modularity and positioning capability. System modularity would provide the ability for the
processing of datasets from multiple sensors through the use of a common data format for
all input data. Positioning capability is also a requirement to allow for the registration of
the collected multiple data sets.
There are many potential applications for a workstation that meets all these requirements,
providing in-situ, real-time survey data analysis. These include:
1. Survey, evaluation, and remediation of numerous Department of Defense and
Department of Energy waste sites
2. Real-time detection and characterization of unexploded ordnance and landmines
3. Survey, evaluation, and remediation of industrial waste sites
4. Location of underground utility lines
5. Providing law enforcement agencies with real-time surveys of crime scenes
In order to support these subsurface characterization tasks with their real-time, in-situ
requirements, we began an internally funded.development effort in Ey95 to build an
integrated data acquisition, processing, and visualization platform that is capable of
performing in-situ data processing, interpretation, and visualization in real-time.
THE INTEGRATED SUBSURFACE CHARACTERIZATION SYSTEM
The Integrated Subsurface Characterization System (ISCS) is a three-year effort (FY95-
97) which is designed to provide hardware and software elihancements to the subsurface
characterization programs currently being performed at AlliedSignal FM&T/AIbuquerque.
At the present time, our sensor suite consists of 4 different ground penetrating radars
(100-MHz, 300-MHz ground contact radars, a 500-MHz air contact system, and a 1-GHz
air contact system), an EM-3 1 conductivity meter, and a cesium vapor magnetometer.
Figure 1 shows a system concept for the ISCS project. ISCS is a field-portable, analysis
workstation that serves as the focus of the data acquisition, analysis, and interpretation
processes. A common data format will be used to ensure that all data streams viewed by
ISCS will be correctly interpreted and placed in a format that will aid in the registration
and correlation of multiple data streams.
ISCS itself consists of two main components: (1) a hardware component consisting of
specially designed interface boards which are used to port and condition data from the
particular sensor into the wokstation and (2) a software component consisting of data
analysis and feature extraction codes which are written uniquely for each type of sensor,
and data fusion and visualization codes that are written uniquely for each type of
application. Data archival will also be an important task provided by ISCS.
FY95 ACCOMPLISHMENTS
The fust year of the ISCS project was heavily oriented towards the acquisition of sensors
and the collection of field data to provide a working database of subsurface data. Surveys
that were performed included (1) a survey of a classified waste IandfU at Sandia
National Labs; (2) two surveys in support of injected barrier experiments, one at Sandia
and one at Hanford; and (3) a survey in support of a murder investigation carried out by
the Drug Enforcement Agency. The surveys in (1) and (2) are the subject of two poster
papers also being presented at this conference.
We subsequently used these site survey data to develop basic data registration and feature
extraction routines for ISCS. We also developed a generic hardware interface that allows
ISCS to acquire data directly off the commercial off-the-shelf radar units that were used
for the surveys.
Figure 2 shows an example of some of the site survey data that was collected last year at
Sandia’s Technical Area II. This particular waste landfill was used by Sandia for 40 years
and contains a significant amount of classified buried waste from the weapons
development program. Sandia now has a requirement to assess the magnitude of the
:I
effort required to remediate this site. AlliedSignal performed a survey of this site with
100- and 300-MHz ground penetrating radar. The figure shows processed (not raw) data
from the 300-MHz survey. In this figure, multiple burial sites down to 10 feet can easily
be seen. The primary purpose of a survey such as this one is to provide an estimate of the
amount of buried waste that will have to be dealt with during remediation:
Figure 3 shows an example of some of the data that was collected in support of a Sandia
experiment on injected barriers used for waste containment. This experiment was
designed to assess the viability of a subsurface grout injection technique that can be used
to form subsurface barriers to contain buried waste or to mitigate waste plumes.
AlliedSignal’s task was to perform post-injection characterization of the barriers to
determine the extent, depth, and integrity of the barriers. This Figure shows an example
of some of the GPR data collected on one of the injected barriers.
PROJECT STATUS
Currently, ISCS consists of:
A Pentium-based analysis workstation and the capability to acquire data directly off
the 100- and 300-MHz radar units.
Feature extraction and signal processing routines to process the collected radar data.
A survey wheel to provide data registration capability.
A commercial plotting package to display raw and processed data.
. * I
- 1
In FY96, we expect to:
0 Build additional hardware interfaces for the other sensor systems
Define a common data format for collected sensor data
Develop sensor fusion methodologies to fuse the multiple sensor data streams
Design processing algorithms specific to the applications we are performing (waste
site versus injected barriers versus UXO/mines)
Incorporate GPS survey capability
Improve our data visualization capability
SUMMARY
Development of the ISCS system will continue throughout the rest of FY96, with a
working prototype completed by August 1996. When completed, ISCS will provide a
capability to acquire, process, and visualize survey data in the field in near real-time. Data
processing software will be customized for the particular sensor or application need.
I
GSSI SIR-1OA GPR ANTENNAS:
SURVEY WHEEL &A 4 \ OTHER POSITION
INFO//
FIELD PC FOR
/ n n \ / I mwl
Band Removal Hilbert Transform Digitization FFT Multi-channels FIWIIR Filters I .................................................................................................................
Feature Extraction Data registration w/ other channels User interface Data display Data archive to Disk
~ - 3 1 CONDUCTIVITY PROB
ASCS2.PPT 7/11/95
c
\
Figure 1. Architecture for the Integrated Subsurface Characterization System (ISCS)
Technical Area 2 - Sandia National Laboratories Hilbert Transform Magnitude
300 MHz GPR
-100 -80 -60 -40 -20 0 20 40 60 . 80 ' 100 ' I20 . 140 ' 160 ' 180 ' 260 ' 220 ' 240 ' 260 ' 2bO ' 3bO ' 3iO ' 3iO ' 360 ' 3iO ' 460 '
Eas t-W e s t (feet) I
Figure 2. Example of survey data collected at Sandia's Technical Area 11 classified waste landfill &lliedSignal
A ~ R O S P A C ~
!
1
I
D e P t h
Individual injections (top layer example) Instrumentation cables
\ .O
,100
,200
1300
,400
,500
S a m P 1 e
0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 Track Angle [Degrees]
Figure 3. Example of survey data collected on a subsurface injected barrier
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