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COMMERCE BUSINESS DAILY ISSUE OF OCTOBER 23,1997 PSA#1957R&D Contracting Directorate, Bldg 7, 2530 C Street, WPAFB, OH
45433-7607 A -- SENSOR TECHNOLOGIES INTEGRATION LABORATORY -- PART 1 OF 3 SOL
PRDA No. 97-18-AAK POC Contract Alan Struckman, Contract Negotiator,
937-255-2902, or Vicki A. Fry, Contracting Officer, 937-255-2902 WEB:
click here to view the supplemental package,
www.wl.wpafb.af.mil/contract/hp.htm. E-MAIL: click here to contact the
Contract Negotiator, struckac@aa.wpafb.af.mil. INTRODUCTION: Wright
Laboratory (WL/AAKR) is interested in receiving proposals (technical
and cost) on the research effort described below. Technical and cost
proposals in response to this Program Research and Development
Announcement (PRDA) shall be received by 08 Dec 97, 1500 Eastern Time,
addressed to the attention of Mr. Alan Struckman, WL/AAKR, Building 7,
2530 C Street, Wright-Patterson AFB, OH 45433-7607. This is an
unrestricted PRDA. Small businesses are encouraged to propose on this
PRDA. Proposals submitted shall be in accordance with this
announcement. Proposal receipt after the cutoff date and time specified
herein shall be treated in accordance with restrictions of FAR
52.215-10; a copy of this provision may be obtained from the
contracting point of contact. There will be no other solicitation
issued in regard to this requirement. Offerors should be alert for any
PRDA amendments that may permit subsequent submission of proposal
dates. Information incorporated in a supplemental package is necessary
for proposal preparation. The Wright Laboratory Guide titled "PRDA and
BAA Guide for Industry," dated November 1992, also provides information
specifically designed to assist offerors in understanding the PRDA
proposal process. The "PRDA and BAA Guide for Industry" and the
supplemental package of proposal information are available through
either of the following methods: (1) Download from the Internet -- The
"PRDA and BAA Guide for Industry" is available on the Wright
Laboratory R&D Contracting Home Page
(www.wl.wpafb.af.mil/contract/hp.htm) under "A Contracting Toolbox,"
"PRDA/BAA Indexed Guide"). The supplemental package is available on the
same home page. If using this method to obtain the information, please
confirm receipt by providing your name, address and telephone number
via e-mail or fax to Alan Struckman, Contract Negotiator. Fax number is
(937) 255-3985. E-mail address is struckac@aa.wpafb.af.mil. (2) You may
submit a request for the packages in writing if you are unable to
access or download the information from the home page. Written requests
should be addressed to Mr. Struckman, WL/AAKR, Bldg 7, 2530 C Street,
Wright-Patterson AFB OH 45433-7607, telephone (937) 255-2902. B --
REQUIREMENTS: (1) Technical Description: Wright Laboratory intends to
award one or more Indefinite Delivery/Indefinite Quantity (ID/IQ)
contracts to design solutions for Automatic Target Recognition (ATR)
and Sensor Fusion (SF) technology domains for the Wright Laboratory
Combat Information Technology Division (WL/AAC) and any successor
organization. This program, called Sensor Technologies Integration
Laboratory (STIL), has the objectives to: Design, develop, improve,
analyze, model, test, evaluate and demonstrate sensor databases,
development and evaluation environments, systems, algorithms, and
technologies; Apply advanced engineering and computer technologies to
improve capability, reliability, maintainability, and affordability
throughout the ATR and SF hardware/software life-cycle. Research and
development shall be performed in the following seven topic areas: (a)
Data Management -- Topic Area 01: WL/AAC requires the development of
innovative techniques for data collection planning and execution,
ground truthing, massive data storage, data basing and retrieval, and
data distribution to meet the requirement for an on-site heterogeneous
Automatic Target Recognition (ATR)/Sensor Fusion (SF) database and
database tools capable of providing data to WL and other DoD programs
performing ATR and SF research. The contents of this database to
consider, but not be limited to, include: Imagery Intelligence (IMINT)
and Signal Intelligence (SIGINT) products; synthetic signatures; on
and off board sensor data; performance results; ground truth; and
collateral data (i.e. DMA, LANDSAT, models.) In order for the database
to fulfill data requirements of an ATR/SF R&D effort, a full
understanding of the multiple data types and data collecting sensors
(EO, IR, hyperspectral, multi-frequency RF) is necessary.
Cost-effective and intelligent strategies for collecting ATR and SF
developer/evaluators requirements and data, that adequately promotes
ATR development, training, testing and evaluation is of interest.
Participation in data collection planning to enhance single and
multiple ATR and sensor fusion application programs will result in
increased utility of collected data. Paramount in such planning is
execution flexibility in the face of equipment and logistical problems
and delays. Collection episodes can be single sensor or include
multiple sensor phenomenologies collected either in series or
simultaneously. Such planning will include overall, end-to-end life
cycle cost for the complete data management activity. Innovative
techniques will be required to obtain ground and image truth
information, as well as screening, characterizing, and databasing data
collected from highly dynamic (moving target), time and space varying
episodes using multiple sensors over highly disparate collection
geometries and time scales. Such datais especially difficult to
correlate and associate as to content in space and time. Understanding
sensor and data phenomenology provides the necessary knowledge to
develop image metric tools for identifying image level artifacts and
anomalies, and to inform ATR developers and evaluators of these sensor
anomalies and data artifacts within the imagery prior to algorithm
developers/evaluators receiving the data. Data characterization tools
are also required to show evaluators what data exists in the database
in order to develop sequestered data sets for independent evaluation
and for assessment of the kinds of evaluations to be performed with
data. With the ability to accurately collect ground and image truth of
time/space variant and dynamic targets, the need exists to
continuously enhance the current heterogeneous ATR and SF database to
handle temporal and geo-registered data from multiple sensors, and
fused data from advanced systems. Engineering judgment is required to
determine the optimal data base structure given the data
characteristics, such as relational, object oriented, or flat files or
other structure or hybrid combinations thereof. Knowledge of existing
environments (i.e. Khoros, CORBA, C, Matlab) is required for data tool
or toolkit insertion to promote ATR development and evaluation. In
order to enhance ATR and SF Research, design and development of
intelligent techniques for data access and distribution are required.
These intelligent techniques include but are not limited to: visually
organizing large amounts of data to quickly identify pertinent data
before disseminating it; facilitating this visualization process by
utilizing the latest data visualization and human factors research into
the design; and developing intelligent product agents to pull together
related relevant data that may be useful to the user. Intelligent
product agents should include but not be limited to: techniques for
either intelligent data pulling, where the user interactively works
with the visualization and product agent tools; and intelligent data
pushing, where pertinent dataset(s) are identified, gathered and
disseminated by the database automatically up to the data recipient's
appropriate security level. In order for intelligent push and pull
technology to be successful, users must be able to remotely access or
query the WL/AAC database. Therefore, techniques are required to
disseminate data at the appropriate security level via the World Wide
Web up to the highest classified network available, or appropriate
electronic media. Additional requirements for the data management
effort are to field technical questions from data recipients, as many
users tend to be narrow experts in a related technology and lack the
insight into the data collection and generation process that would
allow them to state their requirements in a succinct and efficient
manner, provide hardcopy documentation when appropriate and to update
data and dataset description as applicable via the WWW. (b) Laboratory
Environments -- Topic Area 02: WL/AAC has a requirement for an onsite
world-class ATR and SF research and development laboratory
environment. The contractor shall develop a laboratory architecture
compatible with but not limited to: the Common Object Request Broker
Architecture (CORBA); the Defense Model and Simulation Office's (DMSO)
High Level Architecture (HLA); the Joint Modeling and Simulation
System (J-MASS), and Khoros. CORBA will allow network services and
applications to be viewed as objects that share common interfaces,
rather than treated as separate entities that have to be linked
directly in fixed, hard-coded relationships. Khoros is an integrated
software environment that couples strong scientific data visualization
and processing with software development tools and application
programming interfaces (APIs) to allow easy user extensibility. The
architecture shall consider information distribution, as STIL will
contain large databases that will distribute data electronically, and
information security considerations, as STIL will contain data from
unclassified public releasable, to International Traffic in Arms
Regulation (ITAR) data, to top secret/SCI requiring division-wide
sharing, contractor/government interchange, and outside world access.
These requirements will drive design issues regarding World Wide Web
encryption and design, and firewall concerns, including integration of
secure networking through the firewall, and demilitarized zones. In
addition, viewing network traffic by applications rather than
protocols, segmenting the network into zones, going with virtual LANs
where appropriate, and exploring VPDNs (virtual private data networks)
are actions to consider. Optimization of supercomputer architecture
and interconnects with workstations for a variety of computer systems
ranging from desktop workstations to state-of-the-art parallel and
multiple processor systems are of high interest. Packages such as
CORBA, X-Windows and Khoros will be available to develop software
graphical user interface tools. Connectivity is required between STIL
and: High Performance Computing (HPC) sites; the World Wide Web; the
Office of Secretary of Defense's (OSD's) Virtual Distributed Laboratory
(VDL); and classified networks (i.e. Secret Internet Protocol Routed
Network (SIPRNET), Joint Worldwide Intelligence Communication System
(JWICS)). In considering network design, the Distributed Object Model
(DOM) paradigm applies the well-established benefits of object-oriented
programming, including rapid development, reusability, and built-in
security to the enterprise. DOM allows distributed objects to interact
without knowing anything about their location. The environment
contractor shall be responsible for integrating tools,
algorithms/systems, models and databases into the STIL environment,
working with other contractors awarded under this PRDA via an associate
contractor clause. This will involve designing common wrappers or
interfaces to allow algorithms to communicate successfully with other
environment objects. Ultimate goals include the integration ofthe STIL
environment into other modeling and simulation environments such as
the Avionics Collaborative Engineering Environment (CEE). This might
entail a common infrastructure for distributed loosely coupled
applications. Multiple Object Request Brokers (ORBs) may be required
because of the heterogeneous nature of computing environments. Long
term goals of a real-time environment are important. (c) ATR/SF
Evaluation -- Topic Area 03: The contractor shall perform tasks in the
actual evaluation of air-to-air and/or air-to-ground target
recognition algorithms and/or sensor fusion algorithms. The evaluation
methodology should encompass ATR/SF algorithms, single and
multi-sensor data inputs, correlation and tracking functions, real-time
SF systems, and performance estimation of ATR/SF systems. Evaluation
tasks include but are not limited to: experiment design, considering
performance requirements, availability of measured and synthetic data,
and algorithm functionality; data collection activities, including
establishing data requirements, selecting targets and backgrounds, and
documenting ground and air truth; development of performance metrics,
considering program requirements and standard community metrics and
developing innovative metrics as required; execution of tests,
including accessing data from the WL database or other sources, running
algorithms on that data, and scoring, analyzing, and reporting the
results; and performance estimation, including extrapolating results
through system modeling. Single and multi-sensor algorithms will employ
data from a variety of sensors, including synthetic aperture radar
(SAR), high range resolution radar (HRR), forward looking infrared
(FLIR), electro-optic (EO) multi-spectral, and signal intelligence. An
evaluation methodology is required which addresses the differences in
phenomenology, acquisition geometry, and sensor design while
maximizing standardization in tool development, performance metrics,
and results presentation. Multi-sensor applications will pose
challenges to the algorithm evaluator in the areas of experiment design
and understanding the impact of registration errors. An approach is
required which addresses difficulties in assembling multi-sensor data
sets and considers approaches to developing measured, synthetic, or
hybrid data sets. An approach is required to quantify the effect of
reference based and image/signal based misregistration on algorithm
performance. Test procedures will be adapted to specific targeting
missions, including adaptation of software models for weapon delivery
constraints and time lines, as well as, aircraft survivability, as
required to predict increased mission effectiveness provided by the
ATR/SF systems. (d) Target Modeling -- Topic Area 04: Innovative
solutions in the areas of computational electromagnetic (CEM)
predictions for complex targets, integration and application of target
phenomenology and signature exploitation technology, computer aided
design (CAD) model development and construction technologies, and
validation technologies are sought. In the area of CEM predictions for
complex targets, expansion of the current state of the art for
prediction techniques involving complex targets is desired. Innovative
solutions and computer codes that employ asymptotic methods, frequency
domain methods, and time domain methods should be investigated, as well
as efficient and accurate methods of combining low and high frequency
techniques into hybrid prediction codes demonstrating a major increase
in CEM capabilities. The contractor also should consider ways to
hybridize measured data with predicted data to form a more robust
overall solution. CEM techniques that predict radiation, as well as
scattering phenomena, involving whole targets or components should be
investigated. The CEM techniques developed in all cases should strive
for rapid generation of solutions as a function of frequency and
incident and/or observation angle. Stochastic and perturbation
techniques that address the technical challenge of augmenting static
deterministic synthetic data to reflect the dynamic nature of ATR
scenarios, target configuration variation, and target intra-class
variability where appropriate should be examined. An additional area of
interest is the investigation and demonstration of methods to
synthesize scattering from ground clutter in both rural and urban
environments. The contractor should demonstrate performance of CEM
codes on multiple high performance computing (HPC) platforms and
workstations, and provide and demonstrate technologies which stress
workstation to HPC platform connectivity and functionality. It is
strongly encouraged that prediction codes be written using an object
oriented design and C++ programming language. Target phenomenology and
signature exploitation technology that can be integrated into
promising identification algorithms should be identified. The goal of
phenomenology/signature exploitation is to develop additional robust
sources of target information for use in ATR development. CAD model
construction techniques and technologies which improve their accuracy
or fidelity, increase the level of automation, and decrease the time
required to build CAD geometry models for complex targets are sought.
Efficient and accurate techniques of sampling target geometry and
materials from a variety of sources including photographs, line
drawings, blue prints, scale models and the actual target body should
be considered. These construction techniques will be demonstrated via
building multiple CAD geometry models. A variety of CAD development
software should be used to demonstrate these advanced construction
techniques including but not limited to ACAD, BRL-CAD, and Euclid. In
the validation technologies area the contractor should investigate,
develop, and demonstrate efficient, computer based, validation methods
that perform quantitative comparisons of truth data to synthetic data.
This truth data can take many forms such as radar cross section
measurements; measured antenna radiation patterns; physical target
dimensions, details, andmeasurements; or observed or measured data
resulting from target interrogation by active or passive means.
Synthetic data is the obvious predicted or computer generated
counterpart to truth data (e.g. radar cross section predictions or CAD
target models). The comparison metrics should allow for rapid
determination of error margins. Technology which indicates means to
reduce these error margins should also be developed and demonstrated.
The contractor should investigate, develop, and demonstrate methods to
incorporate CEM advancements, signature exploitation techniques, CAD
model geometries, and validation technologies into 1-on-1 and
few-on-few modeling and simulation (M&S) tools. These enhanced M&S
tools will be used to demonstrate the value that improved phenomenology
modeling provides to the overall simulation results. (e) Radar
Algorithm Development -- Topic Area 05: The objective of this thrust
area is the development of automated detection, tracking,
discrimination, classification and identification algorithms using
radar sensors. The scope includes both air and ground targets and
includes both high frequency (10 GHz and above) and low frequency (100
MHz -- 1 GHz). The signatures of interest include wide band signatures
such as high range resolution signatures and resonance signatures,
imaging signatures such as SAR and ISAR signatures, and multi-modal
signatures such as full polarimetric, wide angle, and multi-aperture
(e.g. interferometric SAR). A key element of the algorithm development
will include the use of EM modeling to understand the phenomenology
basis of the signature characteristics, to motivate sound algorithms
based on fundamental EM principles, and to generate synthetic
signatures for use, along with measured data, in algorithm development.
Both model-based and learning-based algorithms are desired with
particular interest in hybrid algorithms that leverage the respective
strengths of each basic approach. Algorithm approaches that scale to
difficult problems (problems that havelarge combinatorics -- e.g.,
target type x configuration x articulation state x obscuration x ) are
of particular interest. Algorithm approaches should scale favorably in
the following dimensions: the amount of measured data required for
training, the amount of memory required to store target
representations, and the amount of computation required to recognize
the target. Sublinear growth with problem complexity is desired for
each of these dimensions. END OF PART 1 (0294) Loren Data Corp. http://www.ld.com (SYN# 0007 19971023\A-0007.SOL)
A - Research and Development Index Page
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