This document discusses the importance of aviation mission survivability training for Army aviators. It outlines how the Army Aviation Mission Survivability (AMS) program takes a holistic approach, focusing on technical, crew-level, and collective training scenarios to ensure aviators can identify threats and respond appropriately. Simulation and threat emulation systems are important training tools to help aviators develop reflexive responses for reacting safely to threats. The goal is to maximize preserving aviation combat power through realistic training that will help aviators survive in future high-threat environments.
UAS: Unmanned Aircraft Systems 2009 Summit Prog Reg V3Mark Wilson
A training, education, and networking program focused on UAS Sense & Respond developments, current and future uses across the military, plus UAS subsystems & platforms.
In the aftermath of the September 11, 2001 attacks on the World Trade Center Towers, and the inability of First Responders to effect a rescue of any victims above the aircraft impact points, the SKYSCRAPER EMERGENCY RESPONSE TEAM or IN-S.E.R.T., strategy was crafted with colleagues within academia, industry and government. Formulated with input from key members of the Detroit Fire Department, inclusive of the late General Manager Weylin Gildon, and the Chicago Fire Department, IN-S.E.R.T. was designed as a means to effectively rescue disaster victims trapped in historically inaccessible areas. In this case, the upper floors of a burning high-rise, while using off-the-shelf firefighting technology and modified first response rescue methodologies structured to epitomize operational simplicity. Moreover, it is to serve as a global first response template to be utilized by emergency teams in multiple countries benefitting from strict protocols of cooperation/collaboration.
IN-S.E.R.T. teams, strategically based around the world and equipped with Boeing C-17 Globemasters modestly modified for this mission, would be capable of responding to any emergency, anywhere.
This paper was presented to 18 Argonne National Laboratory scientists and 2 FEMA representatives for review on 18 October, 2001.
Copyright GHHLLC 2001-2008
248-695-0009
UAS: Unmanned Aircraft Systems 2009 Summit Prog Reg V3Mark Wilson
A training, education, and networking program focused on UAS Sense & Respond developments, current and future uses across the military, plus UAS subsystems & platforms.
In the aftermath of the September 11, 2001 attacks on the World Trade Center Towers, and the inability of First Responders to effect a rescue of any victims above the aircraft impact points, the SKYSCRAPER EMERGENCY RESPONSE TEAM or IN-S.E.R.T., strategy was crafted with colleagues within academia, industry and government. Formulated with input from key members of the Detroit Fire Department, inclusive of the late General Manager Weylin Gildon, and the Chicago Fire Department, IN-S.E.R.T. was designed as a means to effectively rescue disaster victims trapped in historically inaccessible areas. In this case, the upper floors of a burning high-rise, while using off-the-shelf firefighting technology and modified first response rescue methodologies structured to epitomize operational simplicity. Moreover, it is to serve as a global first response template to be utilized by emergency teams in multiple countries benefitting from strict protocols of cooperation/collaboration.
IN-S.E.R.T. teams, strategically based around the world and equipped with Boeing C-17 Globemasters modestly modified for this mission, would be capable of responding to any emergency, anywhere.
This paper was presented to 18 Argonne National Laboratory scientists and 2 FEMA representatives for review on 18 October, 2001.
Copyright GHHLLC 2001-2008
248-695-0009
Available online at httpdocs.lib.purdue.edujateJournal.docxcelenarouzie
Available online at http://docs.lib.purdue.edu/jate
Journal of Aviation Technology and Engineering 3:2 (2014) 2–13
Crew Resource Management Application in Commercial Aviation
Frank Wagener
Embry-Riddle Aeronautical University
David C. Ison
Embry-Riddle Aeronautical University–Worldwide
Abstract
The purpose of this study was to extend previous examinations of commercial multi-crew airplane accidents and incidents to evaluate
the Crew Resource Management (CRM) application as it relates to error management during the final approach and landing phase of
flight. With data obtained from the Federal Aviation Administration (FAA) and the National Transportation Safety Board (NTSB), a x2
test of independence was performed to examine if there would be a statistically significant relationship between airline management
practices and CRM-related causes of accidents/incidents. Between 2002 and 2012, 113 accidents and incidents occurred in the researched
segments of flight. In total, 57 (50 percent) accidents/incidents listed a CRM-related casual factor or included a similar commentary within
the analysis section of the investigation report. No statistically significant relationship existed between CRM-related accidents/incidents
About the Authors
Frank Wagener currently works for Aviation Performance
Solution
s LLC (APS), dba APS Emergency Maneuver Training, based at the Phoenix-Mesa
Gateway Airport in Mesa, Arizona. APS offers comprehensive LOC-I solutions via industry-leading, computer-based, on-aircraft, and advanced full-flight
simulator upset recovery and prevention training programs. Wagener spent over 20 years in the German Air Force flying fighter and fighter training aircraft
and retired in 2011. He flew and instructed in Germany, Canada, and the United States. He holds several international pilot certificates including ATP,
CPL, CFI, as well as a 737 type rating. He graduated with honors from the Master’s in Aeronautical Science Program at Embry-Riddle Aeronautical
University. Correspondence concerning this article should be sent to [email protected]
David C. Ison has been involved in the aviation industry for over 27 years, during which he has flown as a flight instructor and for both regional and
major airlines. He has experience in a wide variety of aircraft from general aviation types to heavy transport aircraft. While flying for a major airline, Ison
was assigned to fly missions all over the world in a Lockheed L-1011. Most recently, he flew Boeing 737–800 aircraft throughout North and Central
America. He worked as an associate professor of aviation for 7 years at a small college in Montana. He is currently Discipline Chair–Aeronautics and an
assistant professor of aeronautics for Embry-Riddle Aeronautical University–Worldwide. Ison has conducted extensive research concerning aviation
faculty, plagiarism in dissertations, statistics in aviation research, as well as the participation of women and minorities in aviation. His previo.
A monte carlo simulation for evaluating airborne collision risk in intersecti...MEHenry
The Intersecting Operations (IO) Model was developed to define a set of separation standards for converging and intersecting runway operations which statistically mitigates collision risk for modeled airport geometries and associated parameters. The IO Model incorporates synthetic trajectory models that account for the variation within historical environmental variables and actual flight data informed by NOP and ASDE-X sources. This model provides a simulation by which analysts can statistically determine an area of unacceptable risk and propose a risk mitigation methodology for these areas.
М.Г.Гоман, А.В.Храмцовский, М.Шапиро «Разработка моделей аэродинамики и моделирование динамики самолета на больших углах атаки», доклад на международной конференции «Тренажерные технологии и обучение», прошедей в ЦАГИ, г.Жуковский, 24-25 мая 2001 г.
M.Goman, A.Khramtsovsky and M.Shapiro "Aerodynamics Modeling and Dynamics Simulation at High Angles of Attack", presentation at the International conference on Simulation Technology & Training held at TsAGI, Zhukovsky (Russia), on 24 May 2001.
FAA Advanced Qualification Program (AQP) and CRM for Military & .docxlmelaine
FAA Advanced Qualification Program (AQP) and CRM for Military & Single Seat Pilots: Applications in CRM
ASCI 516 Applications in CRM
Module 8 Presentation
Military History of CRM
Military interest in CRM to prevent errors increased when training suggested an enhancement of mission effectiveness was also shown
In the Air Force, CRM was first considered as a way to take advantage of developments in training to update existing training for aircrew coordination
1980’s training programs in the Air Force, Army and Navy were generally referred to as Aircrew Coordination Training (ACT)
2
CRM in the Military
In 1970, civil aviation took the lead in CRM, and the military began implementing this type of training in the early 1980’s
3
Air Carrier and Military Aviation
Commonalities
Navigation
Weather
Controlling aircraft in flight
4
Differences
Purpose of organization
Qualifications of crews
Rank distinctions
Responsibilities of the crews
Labor relations
Miscellaneous factors (ie. Training)
5
Differences - Task
Task environment
Mission tasks
Decision goals
Time elements
Mission Alterations
Equipment
6
Differences - People
Entry level experience of military vs. civilian pilots
Promotion in military often means accepting jobs not related to flying
Motivation
Study of pilots who were both commercial airline and military reserve pilots showed military offers more of the “fun flying” and camaraderie
7
Differences - Organization
Rank and position
Officer/enlisted relations possible inhibitor of assertiveness
Rank reversals considered likely to add tension to cockpit relations
Formality that exits in military cockpit (based on recognition of rank differences) may act as barrier to effective communications
8
Military aircrew are often given duties that may interfere with their flying
safety officer
logistics officer
legal officer
maintenance officer
EEO program oversight
Scheduling
ordering A/C parts
train
investigate accidents
lecture
hold inspections
sit on promotion boards
fill out fitness reports
keep records
counsel subordinates
report to superiors
9
Training
Airlines are in business of transporting people safely – training is make that possible
Military trains for accomplishment of mission
virtually all peacetime flying is training activity
10
Military ACT/CRM Programs
By 1989 the Air Force/Navy/Army had at least one CRM-type program
Most programs are generally stand-alone lecture/discussion sessions, lasting 1-3 days
Videotapes developed for the airlines are often incorporated directly into programs
11
CRM For General Aviation
The Single Pilot
CRM For General Aviation
“No man is an island” and no pilot flies in a protective bubble.
How we interact with every person we come into contact with before and during a flight can significantly affect the outcome of that flight
Learning how to handle yourself and those around you is one of the keys to being a safer pilot
Crew Resourc ...
FAA Advanced Qualification Program (AQP) and CRM for Military & .docxnealwaters20034
FAA Advanced Qualification Program (AQP) and CRM for Military & Single Seat Pilots: Applications in CRM
ASCI 516 Applications in CRM
Module 8 Presentation
Military History of CRM
Military interest in CRM to prevent errors increased when training suggested an enhancement of mission effectiveness was also shown
In the Air Force, CRM was first considered as a way to take advantage of developments in training to update existing training for aircrew coordination
1980’s training programs in the Air Force, Army and Navy were generally referred to as Aircrew Coordination Training (ACT)
2
CRM in the Military
In 1970, civil aviation took the lead in CRM, and the military began implementing this type of training in the early 1980’s
3
Air Carrier and Military Aviation
Commonalities
Navigation
Weather
Controlling aircraft in flight
4
Differences
Purpose of organization
Qualifications of crews
Rank distinctions
Responsibilities of the crews
Labor relations
Miscellaneous factors (ie. Training)
5
Differences - Task
Task environment
Mission tasks
Decision goals
Time elements
Mission Alterations
Equipment
6
Differences - People
Entry level experience of military vs. civilian pilots
Promotion in military often means accepting jobs not related to flying
Motivation
Study of pilots who were both commercial airline and military reserve pilots showed military offers more of the “fun flying” and camaraderie
7
Differences - Organization
Rank and position
Officer/enlisted relations possible inhibitor of assertiveness
Rank reversals considered likely to add tension to cockpit relations
Formality that exits in military cockpit (based on recognition of rank differences) may act as barrier to effective communications
8
Military aircrew are often given duties that may interfere with their flying
safety officer
logistics officer
legal officer
maintenance officer
EEO program oversight
Scheduling
ordering A/C parts
train
investigate accidents
lecture
hold inspections
sit on promotion boards
fill out fitness reports
keep records
counsel subordinates
report to superiors
9
Training
Airlines are in business of transporting people safely – training is make that possible
Military trains for accomplishment of mission
virtually all peacetime flying is training activity
10
Military ACT/CRM Programs
By 1989 the Air Force/Navy/Army had at least one CRM-type program
Most programs are generally stand-alone lecture/discussion sessions, lasting 1-3 days
Videotapes developed for the airlines are often incorporated directly into programs
11
CRM For General Aviation
The Single Pilot
CRM For General Aviation
“No man is an island” and no pilot flies in a protective bubble.
How we interact with every person we come into contact with before and during a flight can significantly affect the outcome of that flight
Learning how to handle yourself and those around you is one of the keys to being a safer pilot
Crew Resourc.
The Problem:
September 11, 2001 proved the High-rise rescue operational inadequacies of municipally based fire/rescue services. It is imperative that this problem is quickly addressed using both existing and proposed technologies and methods.
A Solution:
IN-S.E.R.T. is a dedicated emergency response unit operated as an extension of The United States Coast Guard (USCG) F.E.M.A. and existing fire/rescue departments in any major city. Team members will have at their disposal a range of fire/rescue and fire suppression technologies designed to facilitate High-rise rescue operations. The potential flexibility of IN-S.E.R.T makes it a template for a broad spectrum of emergency responses not limited to High-rise rescue. Therefore, it has value beyond that immediately observable.
Technology, Equipment, Methods:
Specially trained personnel will benefit from the decades old expertise of the acclaimed “Smoke Jumpers” of the Western/Pacific Northwestern United States and Red Adair’s legendary pyro-containment methodologies. Additionally, they will benefit from newly developed Victim Extraction At Altitude (VEAA)techniques.
FE Based Crash Simulation of Belly Landing of a Light Transport AircraftRSIS International
Crash survivability is one of the key features to be
attended during the design of an airworthy aircraft. Belly/crash
landing is the most common phenomenon to be considered in
developing a crashworthy product. That makes it essential to
have redundant structure to enhance the safety of occupants and
also limit the damage to easily repairable state in case of such
event. Even from the certification point of view, it is necessary to
investigate this event by test/analysis. Recent development of
advance computing and their capability to simulate such
phenomenon to acceptable accuracy under given conditions
conveniently replace the need for test which is otherwise costly.
At the same time, one has to be cautious while selecting the
modeling parameters to simulate the condition near to reality.
Taking advantage of this feature an effort is made to simulate the
belly landing and its consequences on the structure complying to
the guidelines of the federal aviation regulations. This paper
presents the methodology adopted to successfully simulate the
belly landing phenomenon for a light transport aircraft flying
prototype.
1. ARMY AVIATION MAGAZINE 38 OCTOBER 31, 2013
H
istorical Perspective - Employ-
ment of aviation capability pro-
vides tremendous impact to the
balance of forces on any battlefield as
evidenced when balloons were intro-
duced for observation and adjusting
field artillery fires.
The introduction of manned air-
craft changed warfare and ever since,
man has been designing methods of de-
stroying the opponent’s aviation force.
From installing machine guns on air-
craft for direct action to the introduc-
tion of man-portable surface to air mis-
siles during Vietnam, the methods used
to target aircraft continue to advance.
Addressing this threat during the
early days of aviation included design-
ing aircraft capable of withstanding
weapons effects. Most combat aircraft
developers today will agree this is a
course of action with diminishing re-
turns. Exchanging fabric encased air-
craft with sheet metal and wood struc-
tures with titanium is fairly straight
forward; hardening the aircraft struc-
ture with full armor results in signif-
icant size, weight, and power issues.
Hence, today’s combat aircraft are
designed with vulnerability reduction
as a part of the engineering process re-
sulting in a more survivable scenario
if hit with a weapons system.
During the 1980s there was con-
siderable discussion within the Army
aviation community concerning sur-
viving the hostile environment en-
countered on battlefields.
In the October 1984 issue of “Avia-
tion Digest,” CW2 Charles Butler au-
thored an article titled Threat Air De-
fense. At the time, he was assigned to
the Threat Branch at Fort Rucker, AL.
In his article, he mentions “Knowl-
edge of the enemy, knowledge of his
weapons and of their capabilities” was
something no aviator should leave
home without.
CW2 Butler lists Threat Air De-
fense Countermeasure Rules, the first
of which establishes the goal of deny-
ing the enemy the ability to acquire
targets. In closing his article he states
“Though threat air defense should
command our respect, it is hardly un-
beatable. By realistic training, a true
awareness of the threat and proper use
of counter-measures, this giant can be
cut to size.”
CW2 Butler listed several passive
and active counter-measures which
continue to hold value today. The sur-
vivability scenario is enhanced with
additional installed equipment capa-
ble of warning the aircrew through de-
tection and displays.
Some of these systems provide de-
coys to the inbound threat systems
through automatic expendables or
aircrew action. The development of
these survivability systems is essen-
tially a never ending process because
advancements in threat systems is an
ever evolving industry.
The recent combat experiences dur-
ing prolonged conflict in Afghanistan
and Iraq have produced some mean-
ingful tactical skills while at the same
time allowed others to atrophy.
These operations pitted Army Avia-
tion against an enemy with limited sur-
face to air capability. The integration
of an advanced infrared threat counter-
measure system produced a large pop-
ulation of aviators more reliant upon
systems and less reliant upon tactics.
There seems to be a prevailing at-
titude among many aviators today if
you simply turn the aircraft surviv-
ability equipment (ASE) on, it will
take care of you.
Certainly, our ASE systems have
proven largely successful against an
Preserving Aviation
Combat PowerBy CW5 Michael S. Kelley
SPECIAL FOCUS
Aviation Mission
Survivability
An AH-64D Apache launching flares during
a Man-portable Aircraft Survivability Trainer
(MAST) test at Yuma Proving Ground, AZ.
U.S.ARMYPHOTOBYCW5MICHAELS.KELLEY
2. ARMY AVIATION MAGAZINE 40 OCTOBER 31, 2013
enemy with no air power or effective
surface to air threat systems.
Facing an enemy with advanced in-
tegrated air defense systems (I-ADS)
and a robust command and control ca-
pability would most likely result in a
catastrophic outcome.
Aviation Mission Survivability
Training
The Army Aviation Mission Sur-
vivability (AMS) program is a holis-
tic approach to preserving aviation
combat power. During initial training
as aviators at the U.S. Army Aviation
Center of Excellence (USAACE) and
initial readiness level progressions at
the units, aviators focus on the tech-
nical aspects of employing their as-
signed airframe.
Individual tasks are practiced and
evaluated both in scope of the evalu-
ator-trainee perspective and complete
one task prior to moving onto the next.
Once an aviator or crew member
achieves readiness level one, they are
partnered with experienced pilots-in-
command and other aircrew as appro-
priate. Following this, the unit surviv-
ability officer begins to add scenarios
to already scheduled training flights.
Crew level training encompass-
es the understanding of aircraft sur-
vivability equipment capabilities and
limitations, employment of the air-
craft, and an understanding of threat
systems. This relates specifically to
own-ship protection.
Once all personnel are trained as in-
tegrated aircrew the unit training ad-
vances to collective scenarios.
Collective scenarios should be relat-
ed to the unit’s Mission Essential Task
List (METL) and incorporated into
every training mission. Command-
ers should leverage their AMS officers
(AMSO) to prioritize this effort.
The most effective piece of aircraft
survivability equipment on-board our
aircraft is the aircrew.
Scenario based training events with-
in simulation and in the actual aircraft
are critical to achieving reflexive im-
mediate actions on contact, safely ex-
ecuted with precision. Simply stated,
tactics are used to deny our enemies
the ability to effectively engage aircraft
with threat systems.
When tactics fail and the enemy
gets a shot, it is imperative to properly
identify the threat system being used
and select the most effective maneu-
ver to counter the threat system’s ef-
fectiveness.
Improperly identifying the threat
system typically results in incorrect
counter-tactics often exacerbating the
threat risk. With weapon fly out times
measured in seconds, aircrew must be
trained to immediately identify threat
systems based on ASE indications and
visual signatures presented.
They must instinctively select the
proper tactics, techniques, and pro-
cedures (TTP) to prevent or mitigate
weapons effects while keeping the air-
craft safe from obstacles.
This consideration is not limited to
the aircraft whose ASE detected and
declared the threat. Since all aircraft in
a flight formation operate with essen-
tially the same tactical employment
techniques, the instinctive reaction is
required for all aircraft in the flight re-
gardless of which aircraft was initially
targeted.
Failure to employ this methodol-
ogy may result in subsequent aircraft
in the flight being targeted by threat
systems. These tasks must be accom-
plished during an engagement scenar-
io where there is little time to contem-
plate solutions.
Therefore, the training scenarios
must be presented in as close to real-
world engagement solutions as possi-
ble and include AMSO evaluation of
the crew and collective responses.
Training Devices Designed to Enable
Commanders
The challenge for aviation com-
manders is to refocus a cohort of sea-
soned aviators, with over a decade of
combat experience from counter-in-
surgency missions to a decisive action
fight. The desired end-state will be to
maximize the preservation of aviation
combat power while providing the
ground maneuver force capable and
continued lethal air support and robust
re-supply capability.
In order to achieve the desired end-
state in a fiscally constrained environ-
ment, commanders must rely upon
simulation and aircraft embedded
threat emulation systems to create re-
alistic training environments with peer
and near-peer enemy force structure.
These systems must generate threat
capability as close to real-world sys-
tems as possible.
The Aviation Combined Arms Tac-
tical Trainer (AVCATT) was recently
upgraded to integrate installed aircraft
survivability systems, including hos-
tile fire indicator (HFI).
Fielding this capability provides
aviation commanders the ability to
train HFI in simulation prior to first
unit equipped with the actual system.
Threat system visual signatures
were modeled with more realism mak-
ing them usable to train aviators to ac-
curately identify threat systems en-
gaging them.
There is a vast difference between
A Man-portable Aircraft Survivability Trainer (MAST) with Weapons Engagement Signature
Simulator (WESS) engaging a UH-60 at Ft. Hood TX.
U.S.ARMYPHOTOBYCW4DAMIANBALTHASER
3. ARMY AVIATION MAGAZINE 42 OCTOBER 31, 2013
identifying a man-portable air de-
fense system (MANPAD) in a picture
to how it actually looks when fired.
Commanders can use these systems
to ensure assigned aircrews are fully
trained as individual crews and collec-
tively. The after action review (AAR)
capability supports a discussion based
evaluation of crew and collective re-
action of an ambushed “aerial con-
voy” or flight.
The Man-portable Aircraft Surviv-
ability Trainer (MAST) became a pro-
gram of record in first quarter FY13.
With its fielding to the combat
training centers, participating aviation
units now have a system which inter-
acts with installed Common Missile
Warning System (CMWS), providing
declaration to the aircrews and a visu-
al signature for positive reinforcement
of confidence in the system.
The MAST includes an adjudica-
tion capability emulating a more real-
istic probability of kill when CMWS
is operational.
In the article titled Combat Imper-
atives Help 101st CAB Flightcrews
Accomplish Mission found in the Ju-
ly-September 2013 issue of Aviation
Digest, the authors discuss critical el-
ements concerning combat losses.
The factors presented are, in part,
due to lack of routine application of
evasive maneuver techniques during
training flights at home station.
If the unit trains at a three to five
rotor disk separation on all flights at
home station, never building in ma-
neuver room for the combat scenario,
the potential to relearn these hard les-
sons will continue.
As aircraft advance with digital
cockpit displays, bussed systems, inte-
grated computer technology and gov-
ernment owned threat emulation soft-
ware the technology exists to place
aircrews in a simulated threat environ-
ment. These embedded devices would
emulate threat systems and ASE re-
sponses through multi-function dis-
plays (MFDs) without having actual
ASE systems installed. This threat en-
vironment would not require expen-
sive emitters or personnel.
This capability will provide emulat-
ed threat in the real world, creating the
most realistic flight training scenarios
during every training flight.
This will provide commanders the
ability to train against active threats
programmed into the aircraft by the
AMS officers.
Aircrew interaction with ASE dur-
ing these events will emulate the real-
world systems. Integration of this
capability into the aerial gunnery pro-
gram will provide realistic ASE dec-
laration associated with the target as-
signments.
This survivability-lethality integra-
tion will enable crews to train with all
systems providing accurate indica-
tions associated with target engage-
ment scenarios.
Prior to the bussed aircraft solu-
tions, this integrated training capabil-
ity with currently available govern-
ment owned material and software
solutions was not possible on Army
platforms.
Achievable Goals
Albert Einstein stated: “We can-
not solve our problems with the same
thinking we used when we created
them.” Army Aviation’s approach to
resolving survivability requirements
on tomorrow’s battlefields falls within
this description.
Shifting from the Aviation Tacti-
cal Operations Officer to the Aviation
Mission Survivability program man-
aged by the AMS Officer is the begin-
ning of a complete solution.
In the 1992 after action review for
Operations Desert Shield and Des-
ert Storm, Army Aviation identified
units that did not begin training for the
threat in earnest until after they were
deployed. A little over two decades
after Operation Desert Shield/Desert
Storm, MAJ Jamie LaValley provided
an article to the July-September 2013
Aviation Digest titled “A Hard Lesson
Learned” where he discusses the re-
quirement for additional threat based
tactical flight training throughout the
aviator’s career. He later discusses
weapons and tactics training, certifi-
cation and instructor requirements.
A comprehensive tactics and threat
training program established within
each aviation unit will provide the en-
vironment necessary to inculcate air-
crews with the instinctive skills to sur-
vive combat environments.
Establishing senior survivability
officers as tactics evaluators through a
training and certification process is es-
sential to a long term solution.
Clear measurement of crew and
unit capabilities to engage in aviation
operations in simulated combat envi-
ronments will provide commanders a
better gauge of their unit’s combat ef-
fectiveness.
The preservation of aviation com-
bat power is the focus of the aviation
mission survivability program.
CW5 Michael S. Kelley is the Branch
Aviation Mission Survivability Officer,
assigned to the U.S. Army Aviation
Center of Excellence, Fort Rucker, AL.
An Aviation Combined Arms Tactical Trainer (AVCATT) screen shot of a missile engaging the
CH-47D and the aircraft deploying countermeasures in the simulation.
AMSOCOURTESYPHOTO
vv