DIRECTED ENERGY PROFESSIONAL SOCIETY UK/US Directed Energy Workshop 22-26 July 2024 Swindon, United Kingdom General Workshop Overview Short Courses Workshop Contacts Attendee Info Location & Hotel Local Weather Companions Registration & Fees Security Presenter Info Call for Papers Submissions Release Forms Exhibitor Info Exhibits Event Hosting   Short Courses The following short courses are being offered by DEPS on 22 and 26 July 2024 in Swindon, UK in conjunction with the UK/US Directed Energy Workshop. Note that not all courses are open to all registrants. While all of the classes are unclassified, some have additional participation requirements, which are listed below and are identified in the Classification field in the course descriptions. Also see Security, available here. Open/Public Release - Any registrant may participate. Limited Distribution C - Restricted to U.S. and U.K. citizens who are employees of their respective federal governments or its contractors participating under the current Information Exchange Agreements. Limited Distribution D - Restricted to U.S. and U.K. citizens who are employees of their respective Departments of Defense or its contractors participating under the current Information Exchange Agreements. Continuous Learning Point (CLP) credits will be awarded by DEPS for completion of these professional development short courses. See Course Registration & Fees at the end of this page. Monday AM Courses An Intuitive Introduction to the Physics of High Energy Lasers (Limited D) Beam Control for Laser Weapon Systems (Open) Laser Deconfliction (Limited D) Monday PM Courses Introduction to HPM Systems (Open) Principles and Practicalities of HPM Sources and Amplifiers (Open) Systems Engineering for DE Systems (Open) Friday AM Courses Intro to HEL Systems (Open) HPM Effects and Data Analysis (Limited C) Friday Full-Day Courses Atmospheric Laser Propagation (Limited C) Tri-Service Laser Vulnerability (Limited D) Friday PM Course HEL Modeling (Limited C) Course 1.  An Intuitive Introduction to the Physics of High Energy Lasers Classification: Unclassified, Limited Distribution D Instructor: Zack George, Modern Technology Solutions, Inc. Duration: Half-day course; 0800-1200, Monday, 22 July CEUs awarded: 2 CLPs Course Description: High Power Laser (HEL) weapons show promise to greatly improve the US military's ability to fight, offering speed of light engagement, deep magazines, and ability to "dial-an-effect". This half day short course will cover the language used and basic physics of the technology of DE weapons by approaching the topics with intuitive explanations and minimal use of complex mathematics. Topics to be covered include: The basic nature of light and RF radio waves HEL lethality analysis HEL Propagation in a real atmosphere and its effect on weaponization Lasers, how they work, and laser weaponization issues A HEL example to tie it all together Intended Audience: The course is designed for people new to the field who need to quickly develop an understanding of the key topics in order to be successful technical managers of DE projects. It should help them speak the language, enable them to ask the hard questions, and accurately translate expectations between the non-technical warfighter, the acquisition community, and the scientists and engineers doing the work. However, anyone who is new to the field and just wants an insightful look at the technology of DE weapons will also benefit. Those with a technical background will gain the most from the course content, but since many of the principles are explained with basic concepts, non-technical majors should achieve significant insight as well. Instructor Biography: TBD Course 2.  Beam Control for Laser Weapon Systems Classification: Unclassified, Open/Public Release Instructor: Jack McCrae, Air Force Institute of Technology Duration: Half-day course; 0800 - 1200, Monday, 22 July CEUs awarded: 2 CLPs Course Description: This course closely follows the material presented in six chapters of the DEPS-published textbook entitled: "Beam Control for Laser Systems, 2nd Edition." Topics covered include: Optics fundamentals (Chapter 2) Systems engineering (Chapter 3) Classical controls (Chapter 5) Modern controls (Chapter 6) Optical train components (Chapter 11) Adaptive optics (Chapter 14) Please note that graduates of this course will be able to purchase a copy of "Beam Control for Laser Systems, 2nd Edition" at a significantly reduced cost. The material presented in this textbook is tutorial in nature with exercises at the back of each chapter. A companion CD also provides solutions with MATLAB code for these exercises. An intended outcome of this course is that graduates will be able to complete these exercises as independent learners. Intended Audience: This course is for those who seek a foundational overview. Scientists and engineers, as well as technical managers will benefit from the topics covered. Instructor Biography: Course 3.  Laser Deconfliction Classification: Unclassified, Limited Distribution D Instructor: LeAnn Brasure, ManTech Duration: Half-day course; 0800-1200, Monday 22 July CEUs awarded: 2 CLPs Course Description: This course is intended to teach the "Why, Who, What, How and What's New" of Laser Deconfliction (LD) - the process by which assets are protected from accidental illumination by lasers. Predictive Avoidance (PA), protecting space assets and Airspace Deconfliction (AD), protecting air assets, will also be covered in the course. As the AD process is not as mature as the PA process, it will not be covered in as much detail. PA and AD are critical pieces of the testing process for DoD and NSF laser systems and a knowledgeable and proactive approach by the testing organization can maximize test windows 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 other groups, and what's in store for the future. The course has recently been updated to include the Navy's recent development of a software-only safety system and a commercially available system. The goal of this course is to familiarize the student with the reasons behind PA, the process for working with the Laser Clearing House (LCH) as well as tools and points of contact available to hopefully simplify and clarify the process. In addition, the course will cover efforts in the community to standardize the process and make the safety requirements more in line with current probabilistic risk assessment methodology. Topics to be covered include: Intro (who, what, where, when, how) Policy - Defining the environment, present and future Implementation - How do we keep assets safe How do we identify risks, to include tools available Intended Audience: Anyone who is currently involved or anticipates involvement in laser testing will benefit from this course. Test planners and managers as well as those technically involved with the testing are welcome. Instructor Biographies: LeAnn Brasure works for ManTech supporting the DE JTO as part of their technical team. She graduated from the University of Michigan with a BS in Physics and was commissioned as a second lieutenant in the Air Force. She obtained her Masters Degree in nuclear physics through the Air Force Institute of Technology and retired from the Air Force after 24 years of active duty service. During her active duty time she had assignments including WSMC (Vandenberg AFB), AFTAC (Patrick AFB) as well as a physics instructor at the Air Force Academy. She began to focus on solid state lasers during her assignment as an AFRL Laboratory Representative at Lawrence Livermore National Laboratory. Her last assignment was with AFRL at Kirtland AFB as the Solid State Laser Branch Chief. Her role as a part of the HEL JTO team is to monitor current technology projects and help define new technology development programs such as the JTO's Predictive Avoidance and Airspace Deconfliction effort. In addition, she has recently begun work on international agreements, helping the JTO craft multi-service agreements to facilitate international collaboration. Course 4.  Introduction to High Power Microwave Systems Classification: Unclassified, Open/Public Release Instructor: TBD Duration: Half-day course; 1300-1700, Monday, 22 July CEUs awarded: 2 CLPs Course Description: This course will provide an introduction to RF Directed Energy weapons, also known as High Power Microwave (HPM) weapons. The course consists of five parts: 1) a general introduction to the basic terms and concepts, 2) prime power and pulsed power systems needed to drive HPM devices, 3) HPM sources to include concepts and examples, 4) HPM narrowband and wideband antennas, and 5) design and fabrication of HPM systems. At the end of the class, students will know what RF-DEWs are and how they differ from classical Electronic Warfare and nuclear EMP. Students will learn the various ways to design and develop HPM subsystems to include the fundamental concepts through the practical construction of such systems (science and engineering). Technology discussions will show the difference between narrow band (NB) and ultra-wide band (UWB) sources, antennas and diagnostics, as well as the principal elements of the power systems needed to support them. The course concludes with a examples of HPM systems developed in the recent years. Topics to be covered include: Definitions, motivation, notional concepts Technology - Power Sources and Power Conditioning, Microwave Oscillators, Antennas, Diagnostics System level design for multiple application Intended Audience: Newcomers to the field of RF-DEW or managers with some background in science and engineering will benefit the most from this course. Instructor Biography: Course 5.  Principles and Practicalities of HPM Sources and Amplifiers Classification: Unclassified, Open/Public Release Instructors:     -  Prof. Kevin Ronald, Universiaty of Strathclyde     -  Prof. Whyte, University of Strathclyde     -  Dr. MacInnes Duration: Half-day course; 1300 - 1700, Monday, 22 July CEUs awarded: 2 CLPs Course Description: At the conclusion of this course, students will understand the overall physics principles describing and governing HPM sources, as well as important physical processes essential to enable such sources and constraining their realistic performance range. Students will also understand the operation of several important types of microwave sources and be able to extend this understanding to interpret the principles of emerging new technology appearing, from time to time in the literature. Topics to be covered include: Brief Summary of EM theory including: Maxwell's eqn's (integral and differential); Wave eqn; Solutions for the wave equation - waveguide modes and their dispersion Principles of EM wave-particle coupling: Fundamentals; physical principles of practical schemes; Slow wave, fast wave and crossed field schemes; differences between amplifiers and oscillators; configuration of important classes of source; examples of state of the art HPM sources Underpinning Physics including: Electron emission mechanisms and limitations; vacuum systems and requirements; signal launching schemes Intended Audience: Undergraduate degree in Physics or Electrical Engineering beneficial - especially for the theoretical aspects, but not essential to benefit overall. Insight into the performance of different source types should be accessible without deep technical expertise and therefore is of potential benefit to management as well as scientists and engineers. The material should be accessible to inexperienced new staff but should also provide some insight into ongoing research of interest to senior practictioners. Instructor Biographies: Prof. K Ronald, was awarded the degree of BSc in Physics in 1992 by the University of Strathclyde and the degree of PhD for research investigating explosive electron emission in fast wave oscillators by the same institution in 1997. Prof. Ronald has 30 years experience of research in HPRF/HPM spanning work on sources, applications in accelerator physics and plasma physics and in fundamental geophysical plasma physics research. Particular areas of interest include diagnostics and current drive in tokamaks, Auroral Kilometric Radiation (AKR), parametric scattering of EM waves in plasma (laboratory and geophysical), cold cathode techniques, muon accelerators, high power microwave sources for applications in communications, RADAR, biochemical spectroscopy. Course 6.  Systems Engineering for DE Systems Classification: Unclassified, Open/Public Release Instructor: Harry Sinsheimer, DEPS Duration: Half-day course, runs 1300-1700, Monday, 22 July CEUs 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 to be covered in this course include: The Big Picture/Overview 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 Biography: TBD Course 7.  Introduction to High Energy Laser Systems Classification: Unclassified, Open/Public Release Instructor: Dr. Lawrence Grimes, AFRL Duration: Half-day course; 0800 - 1200, Friday, 26 July CEUs awarded: 2 CLPs Course Description: This lecture will introduce the field of HEL weapons and their associated technologies using an interweaving of technical requirements, history, and accomplishments. The basic attributes of HEL weapons will be covered, leading into discussions of laser-material interaction, lethality, potential weapon applications, system requirements, laser power scaling, propagation, and beam control. DoD interest in tactical applications, current technical issues, and areas of research emphasis will be highlighted. Intended Audience: This course is geared to those with a technical background who seek an overview of HEL technology and the current state of the art. Individuals who are beginning to work in the field or technical managers who wish an integrated overview would benefit from the class. Instructor Biography: TBD Course 8.  HPM Effects and Data Analysis Classification: Unclassified, Limited Distribution C (US), Confidential (UK) Instructor: Timothy Clarke, Air Force Research Laboratory Day/Time: Half-day course; 0800-1200, Friday, 26 July CEUs awarded: 2 CLPs Course Description: This course will provide a basic overview of Radio Frequency Directed Energy (RF DE) and its effects on electronic systems. The course will cover what RF DE is, how it is similar to but different from classic Electronic Warfare (EW) and Nuclear generated Electromagnetic Pulse (EMP), and how it penetrates targets systems and produces effects ranging from temporary interference to permanent damage. We will also discuss the statistical nature of RF coupling to electronics and effects and how effect levels are best described as a probability of effect or failure. Finally we will describe some RF effects models and how they can be used to estimate probability of target effect. Topics include: RF DE Systems-Narrow Band and Wide Band RF RF Propagation and Coupling Effects on Electronic and Probability of Effect Effects Investigation Methodology RF Effects Models and Simulation Intended Audience: The course is intended for anyone who wants to learn to the basics of RF DE and how it effects on electronics, Even though it does not require a bachelor's degree in science or engineering, it is meant for individual with some back ground in science or engineering and/or in technical program management. Instructor Biography: Dr. Timothy Clarke is the High Power Electromagnetics (HPEM) Effects Technology Manager at the Air Force Research Laboratory (AFRL), Kirtland Air Force Base, New Mexico. He has worked in the area of HPEM for about 15 years. His PhD is from the Department of Applied Mathematics and Theoretical Physics, Cambridge University. Course 9.  Atmospheric Laser Propagation Classification: Unclassified, Limited Distribution C Instructors:     -  Steven Fiorino, AFIT     -  Jack McCrae, AFIT Duration: Full-day course; 0800-1700, Friday, 26 July CEUs awarded: 4 CLPs Course Description: This course addresses how to characterize and quantify the major effects of the atmosphere on directed energy weapons propagation. A first principles atmospheric propagation and characterization code called the Laser Environmental Effects Definition and Reference (LEEDR) is described and demonstrated. LEEDR enables the creation of climatologically- or numerical weather prediction (NWP)-derived vertical profiles of temperature, pressure, water vapor content, optical turbulence, and atmospheric particulates and hydrometeors as they relate to line-by-line or band-averaged layer extinction coefficient magnitude at any wavelength from 200 nm to 8.6 m. Applying those atmospheric effects to High Energy Lasers (HELs) is addresses by introducing and demonstrating a high-fidelity scaling-law HEL propagation coded called the High Energy Laser End-to-End Operational Simulation HELEEOS. The course outline is as follows: Intro to atmospheric structure and constituents Atmospheric boundary layer Aerosol / fog / clouds Atmospheric radiative / propagation effects Extinction, refraction Optical turbulence, scintillation Laser Environmental Effects Definition and Reference (LEEDR) HEL thermal blooming effects in the atmosphere Optics, beam control: turbulence / thermal blooming compensation Coherent beam combining High Energy Laser End to End Operational Simulation (HELEEOS) Intended Audience: US Government personnel and their direct contractors who have program requirements for or are interested in methods and tools to assess realistic environments and environmental effects for HEL modeling and simulation, HEL mission planning, and/or military systems operations. The course assumes the students have some technical background in radiative transfer through the atmosphere--either via an undergraduate degree or career experience. Instructor Biographies: Steven T. Fiorino received his BS degrees in geography and meteorology from Ohio State (1987) and Florida State (1989) universities. He additionally holds an MS in atmospheric dynamics from Ohio State (1993) and a PhD in physical meteorology from Florida State (2002). He is a retired USAF Lt Col who is currently an Associate Professor of atmospheric physics within the Engineering Physics Department at AFIT and is the director of the AFIT Center for Directed Energy. His research interests include microwave remote sensing, development of weather signal processing algorithms, and atmospheric effects on military systems such as high-energy lasers and weapons of mass destruction. Dr. Fiorino is a member of SPIE, AMS, AIAA, OSA, and DEPS. Jack E. McCrae, Jr. received his Ph.D. in Physics from the Air Force Institute of Technology in 1997, an M.S. in Physics (Optics) from the Air Force Institute of Technology in 1993, and a B.S. in Physics from the Massachusetts Institute of Technology in 1984. He is a retired Air Force Colonel with 27 years of service and currently a Research Assistant Professor with the Center for Directed Energy in the Engineering Physics Department at AFIT. His research interests include optics, lasers, quantum and non-linear optics, laser radar, atmospheric propagation and imaging. Course 10.  Tri-Service Laser Vulnerability Testing, Modeling, Simulation and Assessment Process Classification: Unclassified, Limited Distribution D Instructors:     -  Mr. Robert Ulibarri, AFRL     -  Dr. Darren Luke, AFRL     -  Dr. Michael Shekya, AFRL Duration: Full-day course; 0800-1700, Friday 26 July CEUs awarded: 4 CLPs Course Description: The Tri-Service Laser Vulnerability Testing, Modeling, Simulation and Assessment Process short course consists of two distinct sessions as described below. The content is focused on target vulnerability testing/modeling to understand laser effectiveness for single engagements with limited consideration for mission context. This course does not cover mission level models that analyze weapon effectiveness, concept of operation, tactics, techniques and procedures in larger military scenarios. The Laser Effects Testing and and Equipment session will provide a discussion of all elements of Laser/material interaction testing. The course will address the Joint Directed Energy Transition Office (JDETO) data collection standards that can be applied during the planning and execution of the test. This portion of the course will provide an overview of both laser and target specific measurement techniques that should be collected during the execution of the test. Examples of experimental test setup and processes will be presented along with a discussion related to targets, facility and test conditions selections as well as the instrumentation and equipment necessary to acquire critical measurements This will include development 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 laser/material interaction and predict target effects. Model discussions will include high-fidelity physics-based models as well as fast-running codes to provide vulnerability assessment for inputs to 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 parameters used for engagement analysis supporting a wide set of target scenarios and engagements. 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: Mr. Robert Ulibarri is a Senior General Engineer with AFRL working in the laser effects branch. He has been involved in effects testing and analysis for over 20 years specifically on testing related activities. He is currently the program manager for the Directed Energy Directorate's Laser Vulnerability Research Program focusing on the evaluation of tactical targets of interest to the Air Force. He has conducted numerous complex laser effects field tests involving such facilities as White Sands Missile Range's High Energy Laser System Test Facility and several wind tunnel related activities at Arnold Engineering and Development Center. He is currently supporting numerous customers including OUSD(R&E), MDA, DOT&E and AF/LCMC. He has a Mechanical Engineering degree from the University of New Mexico. Dr. Darren Luke is a Senior Research Engineer for the Air Force Research Laboratory, Laser Effects, Modeling and Simulation Branch. He holds a PhD in Structural Engineering from the University of New Mexico. He has 16 years of experience in high fidelity model development for laser effects applications with an emphasis in thermal transport, laser-material interaction, high temperature progressive damage plasticity, fracture mechanics, fluid dynamics, V&V methods, uncertainty quantification, and finite element and particle methods. Dr. Luke has led numerous laser vulnerability studies evaluating the vulnerability of tactical and strategic targets for several US High Energy Laser programs. Dr. Michael Sheyka has a Ph.D.in Mechanical Engineering from the University of New Mexico and has been a Mechanical Engineer for the Air Force Research Laboratory (AFRL) since 2015. He is currently the Laser Effects Modeling and Simulation Branch engineering level modeling and assessments principal investigator. He currently manages the laser vulnerability assessment team, performs high fidelity modeling and analysis, and provides briefings and test support. His technical expertise includes laser-material interactions, finite element and hydrodynamic simulation, testing and modeling, uncertainty quantification, and optimization methodologies. Course 11.  HEL Modeling Classification: Unclassified, Limited Distribution C Instructor: Dr. Lawrence Grimes, AFRL Duration: Half-day course; 1300-1700, Friday, 26 July CEUs awarded: 2 CLPs Course Description: This course will provide a survey of modeling and simulation tools used in HEL system analysis and how they can be used together at every level of the modeling and simulation (M&S) pyramid. The course will include a description of HEL modeling tools in three levels of M&S to include: 1) Engineering/Physics, 2) Engagement, and 3) Mission. Each of these areas will be covered during the half-day course with an emphasis on end-to-end system modeling, model fidelity/complexity trade-offs, examples of specific types of analysis applications, and operational considerations necessary to represent HEL capabilities accurately in engagement and mission-level environments. At the end of the course, the student should expect to gain a familiarity with the broad scope of HEL modeling, many of the existing tools, and examples of how to use them together for various types of analytical applications. Topics to be covered include: Survey of many existing HEL modeling tools Methods to use the tools together to perform end-to-end system modeling Overview of the levels of the M&S pyramid and how to use them for different analysis objectives Operational considerations necessary to accurately represent HEL capabilities in engagement and mission-level environments Intended Audience: US Government personnel and their contractors who are interested in methods and tools to assess realistic end-to-end HEL system performance through available modeling and simulation tools. The course is designed for systems engineers, operations research analysts, program managers or technologists who are interested in learning the applications of modeling and simulation techniques to evaluate HEL system performance and operational effectiveness. Technical managers or professionals with experience in HEL systems or individuals who are beginning to work in the field would benefit from the class. Instructor Biography: TBD Course Fees     Half-Day Full-Day    Full-time RDA students $0 $0    Others $300 $550      Note: Two or more half-day classes can be purchased for $275/each. Registration Full-time RDA students can register for short course separate from the 2024 UK/US Directed Energy Workshop by selecting one of the following options. Students also registering for the workshop, and all others, should use the UK/US DE Workshop registration form instead. Complete this RDA Student Short Course form to register on-line. Note that on-line registration does not require on-line payment. Some organizations have installed web filters that prevent on-line registration from inside their facilities. If this appears to be true for you, please try again off-site or use the registration option below. Print this registration form (in PDF format) and follow the instructions provided. Persons requesting cancellation through 24 June will receive a full refund. Cancellations after 24 June are subject to a $100 cancellation fee. No short course refunds will be given after 15 July. Copyright © Directed Energy Professional Society   DHTML/JavaScript Menus by OpenCube   DEPS Policies and Terms of Use Last updated: 3 June 2024