Short Courses
These short courses will be offered on Monday 18 November 2024 in conjunction with the 2024 Directed Energy
Systems Symposium.
Continuous Learning Point (CLP) credits were awarded by DEPS for completion of the short courses.
Not all courses are open to all registrants. While all of the classes are unclassified, some have additional participation requirements,
which are defined here and specified in
the Classification section of each course description. Also see the
Security section
for this event.
- Distribution C - Restricted to employees of the U.S. Federal Government or its contractors and UK citizens with proper access.
- Distribution D - Restricted to employees of the U.S. Department of Defense or its contractors and UK citizens with proper access
- Secret - Restricted to those who have submitted the necessary security clearance and base access forms.
Registration for these short courses requires payment of a fee. See Course Registration & Fees at the end of this page.
Registration for a short course does not require registration for the Symposium.
Course 1. Radiometry for Passive and Active Imaging
Classification: Unclassified, Public Release
Instructor: Ron Driggers, University of Arizona College of Optical Sciences
Duration: Half-day course, runs 0800-1200
Credits awarded: 2 CLPs
Course Description: This course covers the generation (sources and radiometry), propagation (radiometry),
and measurement (detectors and radiometry) of optical radiation. The theory, units, approximations, instrumentation,
and applications will be presented in detail. The course emphasizes passive and active imaging applications.
Learning Outcomes:
- Understand how to measure optical radiation with physical (radiometric) and psychophysical (photometric) terms,
- Understand the basic radiometric quantities and the various units (Watts and photons per second)
- Know the types of sources, blackbodies, lasers, etc.
- Know the various type of detectors,
- Be able to calculate noise and SNR arising from measurement, and
- Understand the mathematical derivations behind the concepts in the course.
Topics to be covered include:
- Radiometric Units
- Transmission, Reflection, Absorption, Emission
- Radiometric Power and Photon Transfer
- Passive Imaging Radiometry
- Active Imaging Radiometry
- Resolved Radiometry
- Unresolved Radiometry
- Detectors and Sources of Noise
- Signal to Noise Ratio
- Applications of Radiometry in Active Targeting
Intended Audience: An undergraduate background in physics, science, or engineering is assumed. The student
should have a rudimentary knowledge of applied mathematics (integration, differentiation, etc.). The course should be
useful to those working in or wanting to enter the technical areas of passive and/or active imaging. This course will
teach the student how to derive the flux (Watts or photons per second) striking a target and returning to a detector
so that a signal to noise ratio (SNR) can be determined. The detectors and noise sources will be covered at a basic
level. Managers with some mathematics background will also benefit from the course.
Instructor Biography: Ronald G. Driggers is a Professor at the University of Arizona’s College of Optical
Sciences and works in the areas of electro-optical and infrared imaging systems. Previously, he was appointed to the
Senior Executive Service as the Superintendent of the Optical Sciences Division at the Naval Research Laboratory in 2008.
There, he managed the efforts of more than 200 scientists and engineers and over $100M in research and development programs.
Before 2008, he was the Director of the Modeling and Simulation Division at the U.S. Army’s Night Vision and Electronic
Sensors Directorate (NVESD) and a brief period as the Chief of the Electro-Optics and Photonics Division at the Army Research
Laboratory. Dr. Driggers received a doctorate in electrical engineering from the University of Memphis in 1990, is the
author of five books on Infrared and Electro-Optics Systems and has published over 160 research papers. He was
Editor-in-Chief of the Encyclopedia of Optical Engineering (Taylor and Francis). He was selected as the 2002 Army
Materiel Command’s Engineer of the Year, 2001 CERDEC Technical Employee of the Year, and 2001 NVESD Technical Employee
of the Year. He was a U.S. Naval Reserve Officer and was selected as the 2001 Naval Engineering Duty Officer of the Year
(William Kastner Award). He is also a Fellow of the International Society for Optical Engineering, the Optical Society of
America, and the Military Sensing Symposium. He was the Editor-in-Chief of SPIE’s flagship journal, Optical Engineering
from 2010-2015 and the Editor-in-Chief of the Optical Society of America’s journal Applied Optics from 2015-2021. Dr.
Driggers was awarded the Joseph Goodman book writing award (best optics related book) in 2024 for "Introduction to
Infrared and Electro-Optical Systems."
Course 2. Introduction to LIDAR Remote Sensing
Classification: CUI, Limited Distribution D
Instructor: Chris Valenta, Georgia Tech Research Institute
Duration: Half-day course, runs 0800-1200
Credits awarded: 2 CLPs
Course Description: Although LIght Detection And Ranging (LIDAR) systems have been around since the
invention of the laser, these instruments have seen remarkable development and deployment in the past decade.
From their use as part of the sensor suite for autonomous vehicles for navigation, to their use as an authentication
mechanism for smart phones and tablets, and to their use as remote sensing instruments to help forecast weather
and provide data for climate change research, LIDAR data products provide outstanding situational awareness for
their users. This course provides an introduction to the fundamentals and the theory of LIDAR; their major
components; optical, electrical, and mechanical performance analysis; applications; and data products.
At the end of the course, a successful student should be able to:
- explain how a LIDAR system operates and identify major components;
- analyze the performance of a LIDAR system and identify engineering tradeoffs;
- describe the different types of LIDARs and their applications;
- and understand how LIDARs can be used for directed energy applications.
This course was previously taught as a semester long undergraduate/graduate level
course and a longer version is offered as a professional short course through Georgia Tech Professional Education.
Intended Audience: This course is primarily intended for engineers and scientists who have taken college
level physics 2 who are looking to better understand LIDAR remote sensing technology. Additionally, managers and
non-technical persons will also be able to take away a fundamental understanding of the underlying key technologies.
Instructor Biography: Christopher R. Valenta is a Principal Research Engineer and associate division head
at the Georgia Tech Research Institute Electro-Optical Systems Laboratory and an Adjunct Professor in the School of
Electrical and Computer Engineering at the Georgia Institute of Technology. His diverse LIDAR experience spans
airborne and ground-based hard target LIDAR, bathymetric LIDAR, and multiple types of atmospheric LIDAR. Dr. Valenta
is the winner of the 2015 IEEE Microwave Magazine Best Paper Award, a 2020 SPIE Rising Researcher, and a registered
professional engineer in the state of Georgia.
Course 3. High Power Microwave Directed Energy Weapons and Their Effects
Classification: CUI, Limited Distribution C
Instructor: John Tatum, SURVICE Engineering Company
Day/Time: Half-day course, runs 0800-1200
Credits awarded: 2 CLPs
Course Description:
This course is an introductory course to High Power Radio Frequency/Microwave (HPM) Directed Energy Weapons (DEW) and their effects.
The course will cover what HPM weapons are, the type of weapons - Narrowband and Wideband, how the weapons are like, but different
from traditional Electronic Warfare (EW) and Electromagnetic Pulse (EMP), how the HPM energy couples in to a target's electronics
and their effects. The course will also cover some of the basic modeling and simulation tools for computing/estimating the probability
of target failure as a function of weapon power density and range. Finally, we will show an example of how to determine hardening
requirements for a notional helicopter against an HPM weapon. Some topics include:
- What are HPM DEW weapons?
- Why Does the Warfighter Care About HPM DEWs?
- What are the Types of HPM DEWs?
- How are HPM DEWs similar to EW and EMP, but different?
- How Does HPM DEW energy couple into a target?
- What are the Effects of HPM DEW?
- How can we Compute/Estimate the HPM DEW Level Required to Produce System Failure?
- How can we Protect our Systems Against HPM DEW Environments?
Intended Audience: This course is intended for those individuals that are looking for an introduction to High Power
Microwave Directed Energy Weapons and their effects on target systems. The course assumes that the student has some science/engineering
background and understands some Radio Frequency/Microwave theory and techniques.
Instructor Biography:
John T. Tatum is an electronic system's engineer with over 44 years of experience in Radar, Electronic Warfare (EW), Electromagnetic
(EM) Effects and Directed Energy Weapons (DEWs) and their effects. Mr. Tatum now works for the SURVICE Engineering Company as a Subject
Matter Expert (SME) EW and Radio Frequency Directed Energy Weapons (RF DEWs) and their effects. He also acts as a SME for the Defense
Systems Information Analysis Center (DSIAC) and provides information on RF DEW technology and effects.
Before SURVICE, Mr. Tatum worked for the US Army Research Laboratory (ARL) in Adelphi, Md. {formerly Harry Diamond Laboratories (HDL)}
in ARL's RF Electronics Division for almost 37 years, where he directed and participated in High Power RF/Microwave (HPM) effects
investigations on military systems and supporting infrastructure. Mr. Tatum also investigated the feasibility and effectiveness of
RF DEW concepts for various Army applications. Mr. Tatum was the Army chairman of the RF DE Joint Munitions Effectiveness Manual
(JMEM) Working Group and chaired RF Effects Panel for the OSD Technology Panel on DEW. He is a fellow of the Directed Energy
Professional Society (DEPS) and has published several papers on RF susceptibility assessments, system effects investigations
and effects data bases in both DoD and IEEE conferences. In his spare time, Mr. Tatum is a volunteer teacher for Science,
Technology, Engineering and Mathematics (STEM) to elementary, middle and high school students.
Course 4. Satellite Safety During Laser Firings & Laser Deconfliction
Classification: CUI, Limited Distribution C
Instructor: Thomas Nadobny
Duration: Half-day course; 0800-1200
Credits awarded: 2 CLPs
Course Description: This course is intended to teach the "Why, Who, What, How and What's New" of satellite
safety during laser firings. Special emphasis will be placed on one of the primary risk mitigation approaches: laser
deconfliction - the process by which satellites are protected from accidental illumination by lasers.
The Department of Defense uses a comprehensive risk analysis process for satellite safety -- deconfliction is a
critical piece of the testing process for DoD lasers and DoD test ranges. A knowledgeable and proactive approach by
the development and testing organizations can maximize safe firing opportunities and minimize frustration. The course
is also intended to help the laser community work together in this area and provide a consistent source of
information on current issues, capabilities developed by various DoD organizations, and what's in store for the
future. The course has recently been updated to include the Navy's development of a generic software-only safety
system that is available for DoD laser programs as well as the innovative new capability called Special Use Space
Ranges.
The goals of this course are to familiarize the student with the reasons behind the risk management process,
provide details on how to work effectively with the Laser Clearinghouse (LCH), share technical and operational
information on risk mitigation tools, and disseminate information on points of contact to simplify and clarify the
process. In addition, the course will cover efforts in the laser and satellite communities to standardize the process
and make the safety requirements align with risk assessment methodologies.
Topics to be covered include:
- Intro - who, what, where, when, how of satellite safety during laser firings
- Policy - defining the DoD risk management policy, process, and environment for satellite safety during laser
firings
- Implementation - hazard assessments, risk mitigation approaches, and the process for how we keep satellites
safe
- Technical details - how do we identify risks? What tools are available? Understanding the planning, analysis,
validation, and authorization process for risk mitigation solutions
- Future innovations - new deconfliction approaches, Space Ranges, and Probabilistic Risk Analysis
Intended Audience: Anyone who is currently involved or anticipates involvement in laser system development,
testing, or fielding will benefit from this course. Test planners and managers as well as those technically involved
with the testing are welcome.
Instructor Biography: TBD
Course 5. Tri-Service HEL Lethality
Classification: CUI, Limited Distribution D, US Attendance Only
Instructors:
- Ronak Patel, NSWCDD
- Sean Potter, NSWCDD
- Rebecca Browning, NSWCDD
- Michael Helle, NRL
Duration: Full-day course, runs 0800-1700
Credits awarded: 4 CLPs
Course Description: The Tri-Service Lethality short course consists of two distinct sessions as described below.
The Lethality Testing/Equipment Session will provide a discussion of all elements of HEL Lethality testing.
The course will address data collection standards to be applied during the planning and execution of the test to
assure meaningful and accurate data is collected. It will describe measurement techniques for measuring beam
profile and other laser parameters during the execution of the test. Experimental test setup and processes
will be described along with data acquisition requirements for targets, facility and test conditions as well
as the instrumentation and equipment necessary to acquire those measurements. The testing session will conclude
with a discussion of testing strategy for successful conduct of Dynamic Testing. This will include development
of test matrices to describe all the key test parameters as well as techniques and methods to execute HEL
Lethality full scale target testing.
The Modeling & Simulation Tools/Techniques Session will describe the models, codes and tools utilized
to analyze and predict Laser System performance in a variety of ground-based, air-based and at-sea based scenarios.
Model discussions will include high-fidelity physics based models as well as fast-running codes to provide vulnerability
assessment for system level modeling codes. The high-fidelity modeling will describe the key parameters and the physics
associated with laser / material interaction. Engineering-level modeling codes will be described that identifies the
key target and laser parameters used to analyze a wide set of target scenarios and engagements. The full scope of
end-to-end modeling will be described as used in DoD Analysis of Alternatives (AoA) decision processes. This session
will be concluded with a description and demonstration of the HEL JTO published Laser Lethality Knowledge Base.
Intended Audience: Students attending this course should have an undergraduate degree in science or engineering.
The course is tailored for the system program manager, system designer, and the lethality analyst who are interested in
learning the full gamut of HEL lethality and target vulnerability analysis and testing. Experience in the field would be
helpful but not necessary.
Instructor Biographies:
Course 6. Directed Energy Weapons System Modular Open Systems Approach
Classification: CUI, Limited Distribution D
Instructors:
- Chris Behre, NSWC Dahlgren Division
- Grace Unangst, MITRE
- Steve Davidson, MITRE
Duration: Half-day course, runs 1300-1700
Credits awarded: 2 CLPs
Course Description: This course will describe:
- The objectives of MOSA
- What this means to the program manager and lead engineer
- How do you implement MOSA on a DE program?
- Define modules
- Define and standardize interfaces
- Develop test plan to ensure interoperability
- Examples of service specific reference architectures
- Recent policy changes and their impact.
Intended Audience: US Government personnel and their contractors who are interested in the fundamental
skills required to achieve efficient definition, analysis, synthesis, evaluation and realization of directed energy
systems. The course is designed for decision makers, systems engineers, operations research analysts, program
managers and domain experts who are interested in learning how implementation of Modular Open Systems Architecture
policies and procedures affect systems engineering efforts for DE systems.
Instructor Biographies: Mr. Chris Behre has been working in Directed Energy for over 20 years, working for
the Department of Energy, then the Naval Surface Warfare Center Dahlgren Division and the Office of the Secretary of
Defense. He has developed and deployed Directed Energy Weapon Prototypes, established permissive Directed Energy
Policies and led the development of the Directed Energy Weapon System Modular Open Systems Approach, Reference
Architecture. Chris Behre is currently on detail as the Senior Engineer for Technology Maturation in the Joint
Directed Energy Transition Office, under the Principal Director for Directed Energy in the Office of the Under
Secretary of Defense for Research and Engineering. He has a Bachelor’s of Science in Electronic Engineering
from Old Dominion University and Masters of Science in Systems Engineering with a concentration in Directed
Energy Weapons, from the Naval Postgraduate School.
Grace Unangst is a Lead Systems Engineer at MITRE with 14 years of experience working on Navy Programs, and
nine years of experience with Directed Energy. Grace is the Task Lead for MITRE's Directed Energy Weapon System
Modular Open Systems Approach Reference Architecture, and Chair of the DEWS Subcommittee within the Sensor Open
Systems Architecture Consortium. Grace also leads MITRE's support to the Office of Naval Research for the High
Energy Laser Counter-ASCM Project. Grace previously worked on Solid State Laser-Technology Maturation, the Gun
Launched Guided Projectile Block 0, Solid State Laser Simulation Experiments, and the Hypervelocity Projectile.
In addition to Directed Energy, Grace has experience with Submarine Combat Systems, the NATO Evolved Seasparrow
Missile System, Littoral Combat Ships, and Electronic Warfare. Grace received a Bachelor of Science in Mechanical
Engineering from the University of Virginia, and a Master of Science in Systems Engineering from Worcester
Polytechnic Institute.
Dr. Steve Davidson is Chief Scientist for Systems Architecture in the Electronics Systems Innovation Center at
The MITRE Corporation (a role he started when he joined MITRE in July 2020). As such, he's a primary architecture
subject matter expert, leads architecture development on projects across MITRE's portfolio, and is co-Lead of
MITRE's Modular Open Systems Approach (MOSA) Technical Capability Area. He has been deeply involved in MOSA since
2010 has strongly influenced the development of many open systems architectures).
Steve was previously at Raytheon Space and Airborne Systems as Director of Product Family Development and Open
Systems Architecture, and prior to that held many other roles over his twelve years at Raytheon (including IRAD
Principal Investigator, technical lead, Chief Architect, Technology Area Director, etc.)
Steve spent the first 20 years of his professional career at MIT Lincoln Laboratory where he led networking
and missile defense projects, and worked in the fields of Air Defense, radar technology development, and the
development and fielding of electro-optic sensors (including laser radar). He holds a PhD in Physics from the
University of Colorado, Boulder. With a background in networking, RF sensors, lasers, and EO/IR sensors, his
career literally goes to DC from light.
Course 7. Introduction to Counter DEW
Classification: CUI, Limited Distribution D
Instructors: Mark Neice
Duration:Half-day course, runs 1300-1700
Credits awarded: 2 CLPs
Course Description: This course provides an introduction to the field of counter-DEW; specifically this
course will discuss the basic scientific aspects of protecting systems from DEW and review technologies available
to counter the effects of DEW on various types of systems. Future research directions in counter-DEW technology will
also be discussed. This course is intended to be an introduction to the subject and is intended to provide the
attendee with a basic understanding of the technologies, issues and solutions surrounding efforts to counter directed
energy weapon systems. At the end of the course you should have an understanding of (1) the basic operation &
effects of directed energy weapons, (2) material hardening approaches, (3) atmospheric propagation effects & use in
countering DEW, (4) operational techniques for counter-DEW, and (5) research directions for counter-DEW. Topics include:
- Review of DEW
- Sensor Hardening
- Propagation Effects
- Operational Techniques
- Directions in C-DEW
Intended Audience: This course is intended for for engineers, scientists, system analysts, program
managers, and military planners. Familiarity with basic optics and physics, such as that found in a two semester
university level introductory physics course is beneficial.
Instructor Biography: Mark Neice is the President of Directed Energy Consultants, providing DE subject-matter
expertise to the directed energy community. Mark is the former Executive Director of the Directed Energy Professional
Society (DEPS). DEPS fosters research and development in Directed Energy, to include high-energy laser and high-power
microwave technologies for national defense and civilian applications, through professional communication and education.
Mr. Neice is formerly the Director of the High Energy Laser Joint Technology Office, working for the Assistant Secretary
of Defense, Research and Engineering. There he supervised the research and development of solid-state, free electron &
gas laser devices, beam control technologies, lethality analysis, and the modeling & simulation tools that create
military applications of laser energy for combat operations.
A command pilot, Col (ret) Neice has time in the 4950th Test Wing, and as initial cadre of the Joint Stars test team.
He has over 7800 flying hours, mainly in the C-135 and B-707 variants, and is a member of the DoD Acquisition career force,
certified in program management; test & evaluation; systems engineering; and science & technology management. Mark holds a
Bachelor of Science in Enginerring Sciences from USAF Academy and a Masters of Science in Mechanical Engineering from the
University of Dayton.
Course 8. Deep-turbulence Limitations
Classification: CUI, Limited Distribution C
Instructor: Dr. Mark Spencer, USINDOPACOM
Duration: Half-day course, runs 1300-1700
CLPs awarded: 2 CLPs
Course Description: This course will start with a discussion on the lessons learned from recent
experimentation with deployed laser-weapon systems. It will then discuss the state of the art from an historical
perspective, including a discussion on some of the investments made in power scaling and beam control. This
course will also highlight recent field-test results and describe performance limitations, which manifest from
deep turbulence. In turn, this course will describe this multifaceted problem in earnest.
Fundamental topics covered:
- Lessons learned from recent deployments
- Past & future concepts including tiled arrays
- Deep-turbulence limitations in terms of the branch-point problem in adaptive optics
- Deep-turbulence limitations in terms of anisoplanatism
- Advanced topics covered:
- Turbulence thermal blooming interaction
- Branch-point-tolerant phase reconstruction
- Compensated beacon adaptive optics
- Imaging through deep turbulence using physics based deep learning
Intended Audience: This course is geared to those with a technical background who seek an overview
on the current state of the art in laser-weapon systems. Scientists and engineers, as well as technical
managers will benefit from this course.
Instructor Biography: Dr. Mark Spencer is a Senior Physicist at the Air
Force Research Laboratory, Directed Energy Directorate (AFRL/RD) and an
Adjunct Associate Professor of Optical Sciences and Engineering at the Air
Force Institute of Technology (AFIT), within the Department of Engineering
Physics. As the first-ever liaison from AFRL/RD, he currently serves as the
Directed Energy Staff Specialist at the US Indo-Pacific Command
(USINDOPACOM). Mark received his PhD degree in Optical Sciences and
Engineering from AFIT in 2014. In addition to being a Fellow of SPIE (the
international society for optics and photonics) and a Senior Member of
Optica (formerly the Optical Society of America), he is an active member of
the Directed Energy Professional Society and the Military Sensing Symposia.
Course 9. Wargaming Directed Energy
Classification: CUI, Limited Distribution D
Instructor: Dr. Garrett Darl Lewis, AFRL Directed Energy Directorate
Duration: Half-day course, runs 1300-1700
Credits awarded: 2 CLPs
Course Description: This course will introduce participants to the types and applications of contemporary
wargames, provide a history of wargaming, and propose principles on the capabilities and limitations of wargaming
based on the evidence provided by that history. It will establish a foundation in the roles, skills, and
opportunities associated with wargaming using practical examples and mini exercises. The second part of the course
presents an overview of processes used to organize, develop, and execute experimentation wargames for innovative and
futuristic concepts, with a particular emphasis on the development, adjudication, and analysis of directed energy
concepts. It will explore how different organizations develop games from the tactical to strategic levels to
influence and inform next generation warfare, and it will challenge participants to bring their own expertise to
bear in identifying the possibilities associated with bringing novel tools to the future force mix.
Intended Audience: The course is designed for junior and senior technical engineers and managers who seek
an understanding of experimentation wargaming and its application to support weapon system concept development and
transition to the warfighter.
Instructor Biography: Dr. Garrett D. Lewis is the Wargaming Principal Investigator within the Air Force
Research Laboratory's Directed Energy Directorate at Kirtland Air Force Base, New Mexico. In this role, Dr. Lewis
leads the directorate's wargaming efforts to promote robust development and employment of next generation directed
energy technology. Dr. Lewis incorporates robust modeling, simulation, and analysis techniques to support
development of directed energy requirements and doctrine within the laboratory and across Air Force, Joint, and
Coalition partners.
Prior to his current position, Dr. Lewis was a Postdoctoral Research Fellow at Washington University in St.
Louis, where he used game theory and machine learning techniques to understand the development of public policy,
with a special emphasis on science policy and public health. During his academic career, Dr. Lewis taught classes
in public policy, statistics and machine learning, game theory, and molecular biology. He earned his doctorate
from Princeton University after completing his Bachelor of Science at the California Institute of Technology.
Course 10. Systems Engineering for DE Systems
Classification: Unclassified, Public Release
Instructor: TBD
Duration: Half-day course, runs 1300-1700
Credits awarded: 2 CLPs
Course Description: This introductory course is designed to provide an appreciation of Systems Engineering
in the pursuit of the Directed Energy (DE) Weapons revolution. After many decades of Research & Development, emerging
DE weapons systems must navigate the technology's "valley of death" through thoughtful application of Systems
Engineering principles to successfully field new warfighter capabilities.
The course will introduce the principles of Systems Engineering, define DE's High Energy Lasers (HEL) and
High-Power Microwave (HPM) Systems, then review DoD guidance and tools in the context of the warfighters' missions.
Conceptual HEL/HPM applications will provide instantiation examples and enable interactive discussions.
At the end of the course, attendees will be better able to craft their programs to leverage proven DoD SE
processes and effectively integrate into existing and future DoD weapons systems/networks. The course will cover
the Systems Engineering Process throughout the Lifecycle. Topics include:
- The Big Picture/Overview
- First, SE Principles
- DE Weapon Systems Definitions: HEL & HPM
- Military Requirements and User Interactions
- DoD SE Guides to include Mission Engineering (ME), Digital Engineering, System-of-Systems (SoS), Modular Open Systems Architecture (MOSA), Software Engineering (SWE), and The Software Acquisition Pathway
- Systems Architecture and its application to DE Systems
- Tools to Enable Engineering Success: Modeling & Simulation (M&S) and How M&S supports DoD Processes
- Testing as an Integral Part of SE: the Different Types of Test & Evaluation (T&E)
- SE for High Energy Laser Weapon System Integration and T&E
- SE for HPM Weapon Systems and T&E
Intended Audience: This course is open to the public and requires no specific background as it is general
in nature, but rich in helping to understand the fundamental concepts of DE Weapon Systems and how to apply System
Engineering processes.
Instructor Biographies:
Course Fees |
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Half-day Courses
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Full-day Course
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Flat Fee |
$300
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$550
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Note: Two half day classes can be selected for the
price of a full-day class. |
Registration
Registration for the Systems Symposium and its short courses is now closed.
Persons requesting cancellation through 21 October will receive a full refund. Cancellations after
21 October are subject to a $100 cancellation fee. No refunds will be given for canceled short courses
after 11 November.
Last updated: 2 December 2024
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