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Securing General Aviation
December 15, 2005
Bart Elias
Specialist in Aviation Safety, Security, and Technology
Resources, Science, and Industry Division
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Securing General Aviation
Summary
General aviation ( GA) – a catch- all category that includes about 57% of all
civilian aviation activity within the United States – encompasses a wide range of
airports, aircraft, and flight operations. Because GA plays a small but important role
in the U. S. economy, improving upon GA security without unduly impeding air
commerce or limiting the freedom of movement by air remains a significant
challenge. However, policymakers have received mixed signals about the relative
security risk posed by GA, due to its diversity and a general lack of detailed
information regarding the threat and vulnerability of various GA operations. While
some recent high- profile breaches of GA security point to persisting vulnerabilities
and limited intelligence information suggests a continued terrorist interest in using
GA aircraft, it is evident that GA airports, aircraft, and operations vary significantly
with regard to security risk. While the small size and slow speed of most GA aircraft
significantly limits the risk they pose, some experts still fear that they could be used
as a platform for a chemical, biological, radiological, or nuclear attack. Certain
sectors of GA such as crop dusters and larger business aircraft present more specific
risks because of their unique capabilities and aircraft characteristics.
Because various segments of GA differ significantly in terms of their perceived
risk, mitigation strategies should arguably be tailored to some degree based on risk.
In step with the premise that security measures should be predicated on assessments
of risk, a provision in the FY2006 Department of Homeland Security Appropriations
Act ( P. L. 109- 90) requires the DHS to examine the vulnerability of high- risk sites to
possible terrorist attacks using GA aircraft. Based on an analysis of risk, a variety of
options exist for mitigating security risks that can be tailored to specific GA airports
and operations. These include surveillance and monitoring; airport access controls;
background checks and vetting of pilots, airport workers, and others having access
to GA facilities; and physical protections for airports and aircraft. Steps may also be
taken to address unique security risks in agricultural aviation, at flight schools, and
among business and charter operators. Besides these steps to enhance GA security
at airport and operator sites, homeland security efforts since 9/ 11 have focused
extensively on restricting access to airspace around sensitive locations. These
airspace restrictions have been highly contentious because they have a direct impact
on the freedom of movement by air, they are costly and resource intensive to
implement effectively, and their effectiveness in preventing terrorist attacks in some
cases is thought to be questionable.
GA security has remained a topic of considerable interest in the 109th Congress.
In addition to the requirement to assess risks posed by GA aircraft called for in P. L.
109- 90, both H. R. 2649 and H. R. 3397 propose options to enhance GA security.
Addressing lingering concerns over restricted airspace violations in the Washington,
DC area that complicate the task of protecting sites from aerial attack, H. R. 3465
calls for increased penalties for violators and mandatory training for pilots. GA user
groups have largely opposed these measures, calling instead for a risk- based
approach to GA security that they maintain does not unduly impede air commerce or
compromise aviation safety. This report will be updated as needed.
Contents
What is General Aviation? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
General Aviation Flight Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
General Aviation Aircraft Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
General Aviation Airports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
The Economic Impact of General Aviation . . . . . . . . . . . . . . . . . . . . . . . . . . 6
The Security Challenge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Security Vulnerabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Risk Factors Associated with General Aviation . . . . . . . . . . . . . . . . . . . . . . . . . 13
Possible Options to Mitigate the Security Risks of General Aviation . . . . . . . . . 17
Security Risk Assessments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Surveillance and Monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Airport Watch Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Behavior Pattern Recognition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Airport Access Controls . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Background Checks and Vetting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Physical Security Measures for Airports . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Physical Security Measures for Aircraft . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Securing Agricultural Aviation Operations . . . . . . . . . . . . . . . . . . . . . . . . . 31
Flight School Security . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Security Best Practices for Business and Charter Aviation . . . . . . . . . . . . . 33
The TSA Access Certificate Program . . . . . . . . . . . . . . . . . . . . . . . . . 33
Access to Ronald Reagan Washington National Airport . . . . . . . . . . . 34
Security Measures for Charter Operations . . . . . . . . . . . . . . . . . . . . . . 35
Airspace Restrictions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
Airspace Restrictions Around Washington, DC . . . . . . . . . . . . . . . . . 36
Security- Related Flight Restrictions Throughout the United States . . 37
Presidential Airspace Restrictions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Policy Issues Regarding Airspace Restrictions . . . . . . . . . . . . . . . . . . 38
Surveillance and Monitoring of Restricted Airspace . . . . . . . . . . . . . . 38
Airspace Protection and Homeland Defense . . . . . . . . . . . . . . . . . . . . 39
Related Legislative Actions in the 109th Congress . . . . . . . . . . . . . . . . . . . . . . . 41
List of Figures
Figure 1. The General Aviation Fleet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
List of Tables
Table 1. U. S. General Aviation Fleet and Activity . . . . . . . . . . . . . . . . . . . . . . . . 3
1 See Associated Press. “ U. S. Uncovers Al- Qaida Plot in Pakistan; The Terrorist Group
Allegedly Planned to Fly an Airplane into the American Consulate.” Telegraph- Herald
( Dubuque, Iowa), May 3, 2003, p. A7.
2 See Report of the Aviation Security Advisory Committee Working Group on General
Aviation Airport Security ( October 1, 2003); and Transportation Security Administration,
Security Guidelines for General Aviation Airports. Information Publication A- 001 ( May
2004).
3 National Commission on Terrorist Attacks Upon the United States. The 9/ 11 Commission
Report. New York: W. W. Norton & Co., p. 391.
4 Federal Aviation Administration. “ Washington, DC Metropolitan Area Special Flight
Rules Area; Proposed Rule.” Federal Register( 70) 149 ( August 4, 2005), p. 43251.
Securing General Aviation
When the term general aviation ( GA) is mentioned, the image most likely to be
conjured is one of a small single- engine airplane droning over America’s farmland
on a tranquil summer’s day. In the post- 9/ 11context, this pastoral image of GA has
been tarnished to a degree by knowledge that the 9/ 11 hijackers trained in small
general aviation aircraft in the United States and amid lingering concerns that GA
aircraft could be used in a future terrorist attack. While some recent high- profile
breaches of GA security have pointed to persisting vulnerabilities, and limited
intelligence information may suggest a possible terrorist “ fixation” 1 on using aircraft
to attack U. S. interests, GA aircraft vary significantly with regard to the risks they
pose. The threats and vulnerabilities of a small single- engine airplane operating in
rural settings is intuitively quite different than the risk characteristics of large
business jets operating in and near major metropolitan areas. Most experts agree that
an adaptive approach to securing GA aircraft and airports that takes into account the
unique risk characteristics of the various distinct components of GA is needed to
assure that security needs are adequately met and balanced with economic
considerations of the GA industry. 2
Policymakers have received mixed signals about the relative risk posed by
general aviation. While the 9/ 11 Commission asserted that “[ m] ajor vulnerabilities
still exist in ... general aviation security,” 3 the commission did not further elaborate
on the nature of those vulnerabilities nor did it make specific recommendations
pertaining to GA security. The FAA has noted that “[ w] hile the DHS has no specific
information that terrorist groups are currently planning to use general aviation ( GA)
aircraft to perpetrate attacks against the United States, it remains concerned that ( in
light of completed and ongoing security enhancements for commercial aircraft and
airports) terrorists may turn to GA as an alternative method for conducting
operations.” 4 In other words, while GA aircraft and airports may not be optimally
suited for terrorist objectives, the hardening of commercial operations may make
them an attractive alternative to terrorists seeking to identify and exploit
CRS- 2
5 CRS calculations based on Federal Aviation Administration. FAA Aerospace Forecasts
– Fiscal Years 2005- 2016. March 2005.
6 The set of regulations specified in Title 14, Code of Federal Regulations, Part 91 – General
Operating and Flight Rules, apply to all civil aircraft operating in the national airspace
system. Like GA aircraft, non- revenue airline flights are subject to these rules, but are not
subject to additional safety and security regulations specifically applicable to revenue air
carrier operations.
vulnerabilities in aviation security. In this context, GA airports and aircraft are
viewed as comparatively soft targets that may be exploited by terrorists because of
known weaknesses and vulnerabilities. This view focuses primarily on the
vulnerability of general aviation and does not systematically assess risk with regard
to the interaction between these vulnerabilities, the threat posed by GA aircraft, and
the potential consequences of a terrorist attack using GA aircraft . In fact, there is
considerable debate over the threat element of the risk equation for GA operations.
While GA advocates argue that the threat is minimal, some policymakers and
security experts have expressed concern that, to the contrary, GA may pose a
significant security threat. Part of the difficulty in resolving this debate is the
diversity of operations and aircraft types that make up GA, making a single threat
assessment for all sectors of the GA industry arguably inappropriate. To put the
threat into context, the following discussion provides an overview of the variety of
aircraft types, flight operations, and airport characteristics that make up GA. This
discussion is followed by an analysis of the existing vulnerabilities in GA security,
the terrorist threat posed by GA aircraft, and how these elements factor into a risk-based
assessment of GA security. Based on this analysis, possible approaches to GA
security are discussed and ongoing initiatives and legislative proposals currently
under consideration are reviewed.
What is General Aviation?
In a sense general aviation ( GA) is a catch- all phrase that encompasses about
57% of all civil aviation activity within the United States, measured in terms of
overall flight hours. 5 Therefore, it is often easier to frame general aviation in terms
of what it is not rather than what it is. In this context, GA refers to most aviation
operations not conducted by scheduled passenger airlines, large air cargo operators,
or the military. To add to the confusion, commercial charter operations are often
grouped in with GA and non- revenue flights, such as maintenance test flights and
repositioning flights conducted by passenger and cargo airlines, are usually operated
under regulations often regarded as “ general aviation” flight rules. 6 Thus, virtually
all flight activity outside the scope of scheduled passenger or cargo air carrier flights
and military operations may be considered GA. This encompasses a wide variety of
aircraft types and flight operations. Table 1 shows the distribution of aircraft and
flight operations formally categorized as GA.
General Aviation Flight Operations
As indicated in Table 1, recreational flying in personal aircraft ( personal flying)
and flight instruction, the typical activities one might expect to see at a small to mid-
CRS- 3
sized GA airport, comprises slightly more than half of all GA operations and
accounts for about 75% of all aircraft in the total GA fleet. Business and corporate
flying – which encompasses anything from small businesses flying cancelled checks
or regional salesmen flying to customer sites in small single- engine aircraft, to
companies ferrying crews to offshore oil rigs by helicopter, to operations of large
corporate jets and professionally managed fractional- ownership fleets – makes up
about one- quarter of all GA operations. On- demand charter services, referred to as
air taxi services, and air tours are also considered GA operations and make up about
5% of all general aviation operations. In addition to these major categories, there are
a wide variety of additional GA operations such as aerial advertising ( banner towing
and skywriting), aerial application ( crop- dusting), aerial photography, mapping and
data collection, traffic reporting, air ambulance and medical evacuation, and search
and rescue, that account for the remaining 14% of all GA operations.
Table 1. U. S. General Aviation Fleet and Activity
CATEGORY
Number of
Aircraft
Percent of
GA Fleet
Hours
Flown
( Millions)
Percent of
Operations
Corporate 10,500 5.0 3.2 11.7
Business 25,000 11.9 3.4 12.4
Personal 146,700 70.0 11.3 41.2
Instructional 12,700 6.1 4.4 16.1
Air Taxi/ Charter 2,600 1.2 1.2 4.4
Air Tours 200 0.1 0.2 0.7
Aerial Application 3,300 1.6 1.1 4.0
Aerial Observation 4,200 2.0 1.3 4.7
Aerial Other 800 0.4 0.1 0.4
External Load 200 0.1 0.1 0.4
Other Work 1,700 0.8 0.4 1.5
Sightseeing 900 0.4 0.2 0.7
Medical Services 900 0.4 0.5 1.8
TOTAL 209,700 100.0 27.4 100.0
Source: U. S. Department of Transportation, Federal Aviation Administration.
Administrator’s Fact Book ( August 2005).
CRS- 4
General Aviation Aircraft Types
Because of the diversity of operations considered under the broad definition of
general aviation, GA encompasses a wide spectrum of aircraft types. Registered
general aviation aircraft in the United States – numbering about 210,000 – range in
size and purpose from very light sport aircraft with maximum takeoff weights of less
than 1,320 pounds used strictly for recreational flying to very large business jets
weighing more than 100,000 pounds used for long- range transcontinental and
international travel. The composition of the current GA fleet is shown in Figure 1.
Single- engine piston aircraft make up the large bulk of the fleet ( 69%). The large
majority of these aircraft are comparably small in size, most weighing less than 5,000
pounds maximum takeoff weight including payload. Experimental aircraft, mostly
small home- built airplanes, make up an additional 10% of the current fleet. Thus,
while GA is quite diverse, the typical image of a GA aircraft as a small, light, single-engine
airplane is an accurate portrayal of the large majority ( about 75%) of the GA
fleet.
Source: Federal Aviation Administration. FAA Aerospace Forecasts – Fiscal
Years 2005- 2016. March 2005.
Although turbojet aircraft are a fast- growing segment of the GA fleet, they
comprise only about 4% of the current GA fleet, and this is not expected to change
much over the next 10 years. Nonetheless, the growing number of turbojet aircraft
has important implications for GA security as these heavier, faster, and more capable
aircraft become more and more prevalent. While the numbers of piston aircraft are
expected to remain flat and the numbers of GA turboprops are expected to grow only
Single Engine Piston
69%
Multi Engine Piston
8%
Turboprop
3%
Turbojet
4%
Piston Rotorcraft
1%
Turbine Rotorcraft
2%
Experimental
10% Other
3%
Figure 1. The General Aviation Fleet
CRS- 5
7 Federal Aviation Administration. FAA Aerospace Forecasts – Fiscal Years 2005- 2016.
March 2005.
8 Ibid.
9 See Report of the Aviation Security Advisory Committee Working Group on General
Aviation Airport Security ( October 1, 2003); and Transportation Security Administration,
Security Guidelines for General Aviation Airports. Information Publication A- 001 ( May
2004).
10 Federal Aviation Administration. Administrator’s Fact Book ( August 2005).
slightly ( about 1.3% annually), the numbers of GA turbojets is forecast to grow at a
brisk pace of about 6% per year over the next ten years. By 2016 it is expected that
there will be almost 16,000 GA turbojets in service in the United States compared to
about 8,750 today. 7
While the numbers of GA turbojets is expected to increase dramatically over the
next 10 years, it is important to bear in mind that small, single- engine aircraft will
remain the large majority of the GA fleet by 2016. The FAA expects that over the
next 10 years, propeller driven single- engine airplanes, two- seat light sport aircraft,
and small home- built experimental airplanes will continue to make up more than
75% of the GA fleet. 8 Security experts recognize that both the threats and
vulnerabilities of these smaller aircraft are significantly different than the threats and
vulnerabilities of medium and large sized GA turbojets and turboprops. Another
segment of the GA industry is helicopters ( rotorcraft), which make up only about 3%
of the total GA fleet but are involved in several diverse and unique flight operations
that introduce their own distinct set of security threats and vulnerabilities. The
diversity of GA aircraft types and operations flown suggests that a one- size- fits- all
approach to security is not practical – a tenet that both the GA industry and the TSA
agree on. 9
General Aviation Airports
Like GA flight operations and aircraft types, general aviation airports also vary
significantly in their size and purpose and range from unpaved private airstrips with
runways less than 2,000 feet in length located in remote, unpopulated areas to busy
general aviation reliever airports situated in major metropolitan areas and converted
military airbases with runways of sufficient length to handle the largest of jets.
In the United States, there are more than 19,000 total landing facilities including
both public- and private- use facilities. Only about 450 of these airports serve
regularly scheduled commercial passenger flights. The remainder consists of a wide
variety of GA airports, heliports, and seaplane bases. Of these, almost 5,000 are
public use, of which about 3,500 have paved runways. A large number of private use
airports – over 4,500 out of about 14,000 total airports – also have paved runways.
About 3,500 public use GA airports and another 1,000 private use landing facilities
have lighted runways for night operations. 10 The FAA’s National Plan of Integrated
Airport Systems ( NPIAS) – a compilation of those airports eligible for federal
Airport Improvement Program ( AIP) funding because they are considered vital to the
nation’s aviation infrastructure – includes 278 GA reliever airports that primarily
CRS- 6
11 General Aviation Manufacturers Association. General Aviation Statistical Databook
2004 ( Updated February 14, 2005). Washington, DC.
12 See Report of the Aviation Security Advisory Committee Working Group on General
Aviation Airport Security, and Transportation Security Administration, Security Guidelines
for General Aviation Airports.
13 Federal Aviation Administration. FAA Aerospace Forecasts, Fiscal Years 2005- 2016.
serve GA operations in major metropolitan areas, plus slightly more than 2,500
additional GA airports – mostly located in rural areas – that serve as critical links
between various communities and the national airspace system. Only these airports
are specifically eligible for federal AIP funds to implement security enhancements
such as hangars to secure aircraft or improved perimeter fencing.
Airports that exclusively serve GA vary widely in terms of their proximity to
densely populated areas, their levels of activity, and the types of operations
conducted. To illustrate, consider Peachtree - Dekalb County Airport ( PDK), a busy
general aviation reliever located near Atlanta, Georgia. According to the FAA, PDK
experiences an average of 639 operations per day, 64% by transient GA aircraft.
According to a recent survey, PDK ranks 20th among the busiest GA airports in the
United States. 11 While PDK has an air traffic control tower, even at this relatively
busy airport, the tower closes during late night and early morning hours. Almost 600
aircraft are based on the field including 56 jets and 13 helicopters. Contrast this with
Red Stewart Airfield ( 40I) in Waynesville, Ohio – a 2,400 foot long grass strip
located roughly midway between Dayton and Cincinnati. The airport – considered
an “ uncontrolled field” because it has no operating control tower – sees less than 50
operations per day. The airport is home to only 44 aircraft – 40 small single- engine
airplanes, 2 ultralights, and 2 gliders – that account for most ( 89%) of the flight
activity at the airport.
Most security experts agree that applying identical or inflexible security
measures at GA airports that vary so widely in their characteristics is likely to yield
an unsatisfactory solution that could either overburden small airport operators or fail
to mitigate potential vulnerabilities unique to specific airports or specific types of
airports. Therefore, a risk- based strategy implementing security measures tailored
to the unique characteristics and vulnerabilities of specific airports is generally
thought to be preferable and has been advocated by aviation security experts and
representatives from the GA industry. 12
The Economic Impact of General Aviation
According to the FAA, general aviation directly generated $ 13.7 billion and
178,000 jobs in 2000 and its overall economic impact was $ 40.7 billion ( roughly
0.4% of the Gross Domestic Product) and 511,000 jobs. 13 The U. S. Government
Accountability Office ( GAO) provided a much higher estimate of the economic
impact of GA, reflecting statistics often cited by the industry, stating that GA
accounts for about 1.3 million jobs and contributes about $ 100 billion to the U. S.
CRS- 7
14 U. S. Government Accountability Office. General Aviation Security: Increased Federal
Oversight is Needed, but Continued Partnership with the Private Sector Is Critical to Long-
Term Success. ( November, 2004) GAO- 05- 144.
15 Federal Aviation Administration. FAA Aerospace Forecasts, Fiscal Years 2005- 2016. p.
V- 1.
16 Jim Hoffer. “ Security Practically Non- Existent at Many Small Airports.”
17 Robert Ross. “ Keeping GA Safe and Secure.” Professional Pilot, September 2005, p. 70.
economy. 14 While these larger figures probably take into consideration a broad reach
of GA’s indirect impact on travel and transportation- related business, the general
picture provided by these various statistics is that GA is a relatively small but
important component of the U. S. economy. As noted by the FAA, GA provides “ on-the-
spot efficient and direct aviation services to many medium and small- sized
communities that commercial aviation cannot or will not provide.” 15 GA also plays
an increasingly important role in training pilots and mechanics to serve the airline
industry. Additionally, GA operations provide wide- ranging capabilities critical to
our economy such as emergency medical services, overnight package delivery to
small and mid- sized communities, helicopter transport to support oil drilling in
offshore and remote locations, and the aerial application of pesticides to support
agriculture.
The potential economic impact of security on GA could be quite significant.
Since the terrorist attacks of September 11, 2001, GA airport operators and the
industry have largely relied on their own initiatives and resources to implement
security enhancements. These efforts have been somewhat limited because large
scale security enhancements to protect GA assets across the country are expected to
be rather substantial. For example, responding to criticism over a perceived lack of
security at GA airports, Aircraft Owners and Pilots Association ( AOPA) president,
Phil Boyer, speculated “[ w] e might be talking about $ 40 billion to fence every small
airport in this country, where in the world is that money coming from?” 16 While a
$ 40 billion estimate may appear somewhat extreme – the TSA has spent slightly less
than $ 20 billion on all aviation security screening and enforcement at commercial
airports in the four years since it was created following the 9/ 11 attacks – and
erecting fences at every airport in the country may not be the most appropriate course
of action, Boyer’s concerns highlight the ongoing challenge of adequately funding
GA security initiatives, balancing these initiatives with other homeland security
needs, and doing so in a manner that does not create an undue economic burden on
the GA industry. At the same time, the GA industry has a vested interest in
implementing security measures to adequately secure and protect airplanes from theft
and vandalism. A recent article in a GA trade publication noted that while the intent
of tightening GA security has largely been seen as a means to prevent terrorism, “... a
more immediate benefit could be a stronger bottom line for GA.” 17
The Aviation Security Advisory Committee ( ASAC) Working Group on
General Aviation Airport Security – an industry group assembled to assist the TSA
in developing security guidelines for GA airports – concluded that “... a flexible,
common- sense approach to general aviation airport security is mandatory if the
CRS- 8
18 Report of the Aviation Security Advisory Committee Working Group on General Aviation
Airport Security. October 1, 2003. Department of Homeland Security, Transportation
Security Administration, p. 3.
industry is to retain its economic vitality and prosper.” 18 Securing general aviation
operations without incurring large costs and without imposing burdensome
restrictions on legitimate general aviation operators is likely to remain a significant
challenge for policymakers.
The Security Challenge
GA security poses significant challenges for policymakers and security experts
because GA is highly diverse, geographically dispersed, and relatively open
compared to commercial airports servicing passenger airlines and other protected
infrastructure such as nuclear reactors and chemical plants. The security threat is not
so much to GA assets themselves, but rather, from terrorists seeking to exploit GA
assets to attack critical infrastructure or high profile targets. However, some GA
assets could themselves become terrorist targets. For example, some corporate
aviation operators have expressed concern that aircraft carrying high profile business
leaders and executives, such as presidents of major U. S. corporations, could be
targeted. Nonetheless, the primary threat identified regarding GA is the concern that
aircraft may be used by terrorists to launch an attack against critical facilities or
infrastructure.
A secondary threat is that terrorists may infiltrate or otherwise exploit GA to
gain knowledge and/ or access to the airspace system in the United States. It is known
that some of the 9/ 11 hijackers trained in small GA airplanes in the United States
before carrying out their attack using commercial jets. Consequently, following 9/ 11,
there was a specific focus both from a law enforcement and a policy perspective on
the security of flight schools within the United States. The Aviation and
Transportation Security Act ( ATSA; P. L. 107- 71) originally called on the
Department of Justice to implement a program to conduct background checks of all
alien applicants seeking flight training in the United States in aircraft weighing more
than 12,500 pounds and mandated security training for flight school employees.
Vision 100 ( P. L. 108- 176) placed the responsibility for these flight school
background checks in the hands of the TSA and expanded the program to include a
notification requirement when foreign students initiate training in lighter aircraft
weighing less than 12,500 pounds. These measures were enacted in direct response
to the perceived threat that terrorists may infiltrate flight schools in order to gain
operating knowledge of aircraft and the U. S. national airspace system.
Since September 11, 2001, policies toward broader GA security issues of
protecting aircraft and airports from being exploited in terrorist attacks have focused
on providing general guidelines and implementing cooperative arrangements between
the GA industry and the TSA for carrying out security enhancements without
imposing a rigorous statutory or regulatory framework. The GA industry has argued
that inflexible statutory or regulatory measures could impose unnecessary burdens
on certain sectors of the GA industry and could be extremely costly to carry out
CRS- 9
19 See, for example, Jim Hoffer. “ Security Practically Nonexistent at Many Small Airports.”
WABC TV- New York Eyewitness News, February 5, 2004.
20 Aircraft Owners and Pilots Association. General Aviation and Homeland Security: A
Security Brief by the Aircraft Owners and Pilots Association. Frederick, MD ( January 23,
2004).
21 Vickie Chachere. “ Police: Student pilot who crashed Cessna into Florida building
inspired by bin Laden.” Associated Press Newswires, January 7, 2002.
22 David McHugh. “ Small Plane Crashes Near German Parliament.” Associated Press
Newswires, July 22, 2005.
effectively. Legislative actions addressing GA security have focused primarily on the
vetting of foreign flight school applicants, GA pilots, and more recently, prospective
charter and lease customers. Regulatory actions have primarily focused on airspace
restrictions and protections, mostly around the nation’s capital, in addition to
addressing statutory mandates for vetting certain individuals with access to GA
airports and aircraft. Physical security of GA airports and aircraft has largely been
left to aircraft owners and pilots, airport operators, and local authorities. While
aircraft owners and pilots have generally favored this approach to avoid potentially
restrictive federal security regulations, it has created a perceived burden on airport
operators and local authorities to identify and address security needs at the airport
level. The TSA has issued guidelines, largely based on industry recommendations,
but the federal involvement in terms of both regulatory activity and funding for GA
security initiatives has been relatively limited. This approach has led the media and
some policymakers and security experts to voice concerns over what they perceive
to be persisting vulnerabilities at some GA airports.
Security Vulnerabilities
Some media reports have raised significant concerns over what has been
described as “ practically nonexistent” security at many small general aviation ( GA)
airports. 19 GA advocates have countered that small general aviation aircraft do not
pose a significant threat and point out that many GA airports have taken reasonable
steps, largely on their own initiative, to enhance security. 20 However, security
concerns remain and a few high- profile incidents pointing to vulnerabilities in GA
security have attracted considerable attention and raised concerns among some
policymakers and security experts.
In the first of these high- profile incidents following the terrorist attacks of
September 11, 2001, a student pilot intentionally crashed a small single engine
airplane into a skyscraper in downtown Tampa, Florida on January 5, 2002. The
pilot, described as a troubled youth, reportedly had expressed support for Osama bin
Laden and the 9/ 11 terrorist attacks, but acted alone and had no known ties to any
terrorist groups. 21 More recently, on July 22, 2005, a small ultralight crashed near the
German parliament building and Chancellor’s office in Berlin in what was described
by German air traffic control officials as a suspected suicide. 22 The crash prompted
German officials to establish a no- fly zone over central Berlin and again raised
concerns in the United States over protecting key assets from possible attacks using
CRS- 10
23 Hugh Williamson. “ Ban on Small Aircraft Flying Over Berlin.” Financial Times
( London), July 25, 2005.
24 The White House Office of the Press Secretary. Press Briefing by Ron Noble, Under
Secretary of the Treasury for Enforcement and Carl Meyer, Special Agent, United States
Secret Service. September 12, 1994. Robert Pear. “ Crash at the White House: The Pilot.”
The New York Times, September 13, 1994, p. 20.
25 CRS analysis of NTSB Aviation Accident Database and Synopses from 1962- 2004
( available at [ http:// www. ntsb. gov/ ntsb/ query. asp]).
26 Richard Liebson. “ 1 Held in Drunken Joy Ride in Cessna.” The Journal News ( White
Plains, NY), June 23, 2005, p. 1A.
GA aircraft as this incident occurred just over two months after a high- profile breach
of the protected airspace around Washington, DC, by an unauthorized single- engine
airplane that prompted evacuations of the White House and the U. S. Capitol. 23 While
these incidents have received significant attention given the focus on aviation
security following the attacks of September 11, 2001, GA aircraft have been used
maliciously in earlier incidents of this kind. Most notably, in the early morning of
September 12, 1994, a suicidal individual with a history of mental illness, reportedly
despondent over personal and business problems, intentionally crashed a stolen small
single- engine airplane on the south lawn of the White House. 24 While the small
airplane was completely destroyed and the perpetrator was killed in the crash,
property damage was minimal and the incident posed no threat to those in the White
House.
Although these events have attracted substantial media interest, such incidents
are relatively rare. While they identify real vulnerabilities in GA security, GA
advocates caution that they should be properly viewed in the broader context of risk
assessment which fully takes into account the security threat to critical infrastructure
posed by these aircraft as well as the nature and scope of specific vulnerabilities.
First, while each of these cases highlight the potential threat of general aviation
aircraft, it is important to note that in each of these cases, damage caused by the
aircraft was relatively limited and no injuries or deaths to persons on the ground
occurred. Second, while the incidents in Tampa and Berlin and the 1994 White
House incident point to a legitimate concern over suicidal pilots, a cursory review of
National Transportation Safety Board ( NTSB) aviation accident data revealed that
since 1962, suspected suicides using GA aircraft are extremely rare, occurring at a
rate of less than 2 incidents per year. 25 Perhaps more notably, none of these incidents
resulted in any deaths of persons on the ground.
Recent high- profile thefts of GA aircraft in 2005 have also raised security
concerns because they point to vulnerabilities in GA operations that could be
exploited by terrorists. For example, in an incident that occurred on June 22, 2005,
a 20- year old Connecticut man allegedly stole an aircraft from a Danbury,
Connecticut flight school and took two teenage accomplices on a late- night “ drunken,
three- hour joyride” before landing on a taxiway at the Westchester County, New
York airport. 26 More recently, on October 9, 2005, a 22- year old Georgia man
allegedly stole a Cessna Citation VII business jet from the St. Augustine, Florida
airport and took friends – reportedly unaware that the airplane had been stolen – on
CRS- 11
27 Mike Morris. “ Bufurd Man, 22, Accused of Stealing Jet.” The Atlanta Journal-
Constitution, October, 12, 2005.
28 U. S. Department of Justice. Marcos Daniel Jiménez, United States District Attorney for
the Southern District of Florida. “ Defendant Sentenced for Transporting Stolen Lear Jet and
Possession of False Identification Documents.” Press Release, January 5, 2005: Miami, FL.
29 Aircraft Owners and Pilots Association. General Aviation and Homeland Security.
30 Ibid.; Testimony of Mr. Andrew Cebula, Senior Vice President, Government and
Technical Affairs, Aircraft Owners and Pilots Association, Before the Senate Committee
on Commerce, Science, and Transportation Regarding General Aviation Security, June 9,
2005.
31 Statement for the Record of Robert S. Mueller III, Director, Federal Bureau of
Investigation, Before the Joint Intelligence Committee Investigation into September 11, U. S.
Congress, June 18, 2002
a late- night joyride of more than 300 miles, landing at Gwinnett County ( Georgia) -
Briscoe Field airport near Atlanta. 27 While thefts of jets are extremely rare, in
another incident that occurred on December 15, 1997, an individual with falsified
FAA credentials stole a Lear Jet from the Fort Lauderdale Executive airport in
Florida and piloted the airplane to Nicaragua to use the plane for charter flight
operations. 28
Like suspected suicides using aircraft, thefts of small GA aircraft are relatively
rare and thefts of jet aircraft are virtually unheard of. The AOPA notes that,
historically, only about a dozen GA aircraft are stolen each year and recent trends
suggest that owners and operators of these airplanes are taking steps to reduce their
vulnerability to theft. 29 Specifically, the AOPA cites statistics from the Aviation
Crime Prevention Institute, Inc. indicating that while 13 GA aircraft were stolen in
2002, only 6 ( 5 light single- engine aircraft and one medium- sized twin- engine
aircraft) were stolen in 2003.30 Arguably, these statistics do not indicate that GA
aircraft are not vulnerable to theft, but rather may simply suggest that existing
vulnerabilities in GA security are rarely exploited. While airplane thefts may be rare,
high- profile thefts, like the cases cited above, provide some evidence that individuals
with knowledge of GA airports and aircraft could exploit existing security
vulnerabilities and access aircraft relatively easily.
The Terrorist Threat
While none of the events discussed above has been linked to terrorism, some
limited intelligence information that has been made public suggests a continued
terrorist interest in using GA aircraft to carry out attacks both domestically and
overseas. For example, a crop duster pilot in Florida identified 9/ 11 suicide hijacker
Mohammed Atta as an individual who had approached him in early 2001 inquiring
about the purchase and operation of crop duster aircraft. 31 Similarly, U. S. authorities
presented evidence that Zacharias Moussaoui – who was arrested prior to the 9/ 11
attacks after raising suspicions surrounding his desire to train in large aircraft
simulators and pleaded guilty to conspiring with the 9/ 11 hijackers – made similar
inquiries about starting a crop dusting company while living in Norman, Oklahoma.
CRS- 12
32 United States of America v. Zacharias Moussaoui ( Defendant). Indictment. In the U. S.
District Court for the Eastern District of Virginia, Alexandria Division. December 2001
Term.
33 U. S. Central Intelligence Agency. Terrorist CBRN: Materials and Effects.
34 U. S. Central Intelligence Agency. Unclassified Version of Director of Central
Intelligence George J. Tenet's Testimony before the Joint Inquiry into Terrorist Attacks
Against the United States, 18 June 2002.
35 Associated Press. “ U. S. Uncovers Al- Qaida Plot in Pakistan; The Terrorist Group
Allegedly Planned to Fly an Airplane into the American Consulate.” Telrgraph- Herald
( Dubuque, Iowa), May 3, 2003, p. A7.
36 Ibid.
Evidence was also presented that Moussaoui was in possession of a computer disk
containing information regarding the aerial application of pesticides. 32 This evidence
raised concerns at the Central Intelligence Agency ( CIA) that al Qaeda has
“ considered using aircraft to disseminate [ biological warfare] agents.” 33
The CIA also suggested that, in initially planning the 9/ 11 attacks, one of Osama
bin Laden's associates proposed that the World Trade Center be targeted by small
aircraft packed with explosives, but bin Laden himself altered the plan to use large
commercial jets instead. 34 If true, this suggests that terrorists engaged in some
deliberative process of weighing the pros and cons of general aviation as compared
to commercial airlines in planning the 9/ 11 attacks. While the terrorists favored
commercial aircraft in carrying out their attack on September 11, 2001, in the
post- 9/ 11 environment, heightened security measures at commercial airports could
make GA assets considerably more attractive to terrorists than in the past. While it
is unlikely that small GA aircraft packed with conventional explosives could cause
the amount of destruction inflicted on September 11, 2001, large jet aircraft in the
GA fleet or smaller aircraft carrying chemical, biological, radiological, or nuclear
( CBRN) weapons may pose a more formidable threat.
Although no publically available intelligence on terrorist operations since
September 11, 2001, has indicated any specific threat involving GA aircraft
domestically, evidence indicates that al Qaeda has maintained a continued interest
in using small aircraft to attack U. S. interests overseas. For example, on April 29,
2003, Pakastani authorities apprehended Waleed bin Attash ( a. k. a., Khallad, Tawfiq
bin Attash), the suspected mastermind of the U. S. S. Cole bombing and a known
associate of the 9/ 11 hijackers, and five other suspected al Qaeda operatives in
Karachi, Pakistan. Soon after the arrests, authorities uncovered a plot to crash a
small, explosives- laden airplane into the United States consulate office in Karachi
illustrating al Qaeda’s continued interest in using aircraft to attack U. S. assets. 35 The
DHS subsequently issued a security advisory indicating that al Qaeda was planning
to use GA aircraft to attack warships in the Persian Gulf as well as the U. S. Consulate
in Karachi, Pakistan. While the advisory characterized these threats as a
demonstrated " fixation" on using aircraft in attacks against U. S. assets, it was
strongly criticized by GA interests as being overly alarmist and overstating the
potential threat posed by small GA aircraft. 36
CRS- 13
37 Aircraft Owners and Pilots Association. General Aviation and Homeland Security: A
Security Brief by the Aircraft Owners and Pilots Association. ( January 23, 2004, Frederick,
MD).
38 Based on information from Cessna Aircraft Company, Information Manual: Skyhawk
Model 172P, May 12, 1981, and Piper Aircraft Corporation, Piper Warrior II Information
Manual, Revised September 12, 1990.
39 While weight is not the only consideration in evaluating explosive force, it is meaningful
for comparing the potential threat posed by aircraft and vehicles that differ in terms of their
payload capacity.
Risk Factors Associated with General Aviation
In examining the security risk posed by aircraft that could be utilized in suicide
attacks or as launch platforms for conventional weapons, the threat posed by general
aviation aircraft is largely a function of aircraft weight, payload capacity ( including
fuel capacity), and speed. Other factors would likely play a relatively small role in
the overall threat posed by particular aircraft. For example, aircraft agility – a rough
measure of its capability to maneuver and evade countermeasures – may be
considered a factor in the risk equation, albeit a relatively minor one. A small two-seat
sport aircraft might be quite agile, but its small size, relatively slow speed, and
limited payload capacity may significantly limit the threat posed by such an aircraft.
GA interests point out that most GA aircraft are capable of carrying less payload than
a typical light car. 37 For example, both the Cessna 172 and Piper Warrior – very
popular single- engine aircraft – have maximum takeoff weights of less than 2,500
pounds and useful payloads ( including allowances for fuel and passengers) of less
than 1,000 pounds. 38 By contrast, the truck bomb used in the April 19, 1995,
Oklahoma City bombing was believed to have contained about 5,000 pounds of
improvised explosives and the truck bomb involved in the February 26, 1993
bombing at the World Trade Center in New York City was believed to contain a
1,300 pound device. While these events involved unusually large explosive devices,
typical light GA aircraft would only be able to carry a device a small fraction of this
size. Thus, at least with regard to being used as a platform for conventional
explosives, the threat posed by light GA aircraft is relatively small compared to
trucks which have significantly larger payload capacities. 39
However, as ground based security measures such as setbacks, barriers, and
access controls are implemented around critical infrastructure, terrorists may view
GA aircraft as a possible means to circumvent these defenses. While many forms of
ground transportation, especially trucks, can accommodate significantly larger
payloads than almost all GA aircraft, some observers fear that aircraft may be used
in a terrorist attack because they cannot be as easily thwarted by blockades, barriers,
or other physical security measures. Nonetheless, executing an attack that involves
loading a GA aircraft with a large quantity of explosives may be difficult without
raising some suspicion at the airport, at least domestically where airport operators
and pilots have been instructed to be vigilant for such unusual activities.
While the threat posed by light GA aircraft carrying conventional explosives is
limited by the size and speed of these aircraft , some experts argue that small aircraft
CRS- 14
40 U. S. Central Intelligence Agency. Terrorist CBRN.
41 See CRS Report RL31831, Terrorist Motivations for Chemical and Biological Weapons
Use: Placing the Threat in Context, by Audrey Kurth Cronin.
42 White House Homeland Security Council, David Howe, Senior Director for Response and
Planning. Planning Scenarios: Executive Summaries ( July 2004, Version 2.0).
may pose a significant threat if used as a platform to launch a chemical, biological,
radiological, or nuclear ( CBRN) attack over a densely populated area. In these cases,
payload capacity and speed may not be considered as significant components of the
risk equation. Rather, with regard to the CBRN threat, the most significant element
associated with small GA aircraft appears to be their unique capability to fly at
relatively low altitudes above densely populated areas and large congregations of
people on the ground. In fact, the slow speed of these smaller aircraft and the ease
at which doors and windows on non- pressurized airplanes and helicopters can be
operated in flight may actually pose a greater threat of certain types of attacks, such
as chemical and biological attacks, as compared to larger, faster aircraft. Agricultural
aircraft used for spraying crops with pesticides and fertilizers pose a unique threat as
a platform for a biological or chemical attack because they are specifically designed
for aerial dispersal and could be exploited by terrorists for this specific purpose.
However, the chemical and biological threat using GA aircraft may not be as
ominous as some fear. First, many chemical agents must be released in rather high
concentrations. Some, such as cyanides, may only be effective as a chemical weapon
if dispensed in an enclosed area therefore greatly limiting the threat of aerial
dispersion. 40 While other chemical agents – such as caustic mustard agents and
military nerve agents – may be effective in open air settings, the limited payload of
small GA aircraft may limit the scope of an aerial attack using such agents. Second,
aerial dispersion of either chemical or biological agents over populated areas or large
congregations of individuals is likely to be easily detected. If a suspected aerial
dispersion of a chemical or biological agent is promptly reported, a timely public
health response could significantly limit the impact of such an attack. In general,
experts believe that if any chemical or biological attack were to occur – whether
using a small airplane or some other method to attack – it would likely be on a small
scale physically, but may have a large psychological impact on the population. 41
More specifically, in terms of using small GA aircraft to carry out such an
attack, the greatest threat appears to be to large, open- air assemblies such as major
outdoor sporting events and concerts. In fact, one of several homeland security
planning scenarios – developed by the White House Homeland Security Council in
partnership with the DHS – describes the potential effects of an adversary using a
light aircraft to spray a chemical blister agent into a packed college football stadium
holding 100,000 people. 42 The scenario’s predicted impact includes 70,000
hospitalizations due to exposure, including many permanent impairments and 150
deaths, but notes that expedient decontamination could reduce injuries by one half.
This would likely be a worst case scenario in which an extremely large assembly of
people could potentially be victimized. Even in densely populated areas, this degree
of impact from an aerial attack not specifically targeting a large outdoor assembly is
unlikely because it might be expected that many individuals would be indoors or
CRS- 15
43 U. S. Central Intelligence Agency. Terrorist CBRN.
44 Staff Summary of Responses by the Nuclear Regulatory Commission to Correspondence
from Rep. Edward J. Markey ( D- MA), Member, Energy and Commerce Committee, U. S.
House of Representatives. Security Gap: A Hard Look At the Soft Spots in Our Civilian
Nuclear Reactor Security. March 25, 2002.
adequately protected by buildings and other structures. Nonetheless, while such an
attack may be limited in terms of its physical impact, it may cause widespread fear
and panic.
By comparison, the threat from radiological and nuclear devices appears to be
much greater in terms of the potential for mass casualties and physical destruction.
A small- scale explosive radiological dispersal device – a so- called “ dirty- bomb” –
could easily fit inside a backpack, 43 and a pilot carrying such a device on to a small
airplane may not arouse any particular suspicion at an airport. However, the threat
from such devices is not unique to GA aircraft as these devices could reach their
intended target by other means, including being carried in a small car or even being
carried by a pedestrian. Most experts concede that, once in the hands of terrorists,
it may be difficult to stop an attack with a radiological or nuclear device because
many options are available to deliver the weapon to its intended target. Using GA
aircraft is one of many means for launching such an attack. However, there is no
reason to believe that GA aircraft are any more appealing to terrorists nor any more
vulnerable than other possible methods of attack.
Concerns have also been raised over the potential threat that an aircraft attack
may pose to a nuclear power plant, a chemical plant, or other potentially vulnerable
infrastructure where a terrorist attack could inflict widespread damage and mass
casualties. A review of security measures at nuclear reactors prepared by the office
of Representative Markey identified several perceived vulnerabilities at nuclear
reactor sites suggesting that these facilities may be vulnerable to 9/ 11- style attacks
using general aviation aircraft. Based on information provided by the Nuclear
Regulatory Commission, Representative Markey’s office issued a report on nuclear
reactor security that included an assessment of the vulnerability of these facilities to
an attack by aircraft. 44 The report noted that while 21 out of 103 reactors in the
United States are located within 5 miles of an airport, 96% of U. S. nuclear reactors
did not factor the impact from even a small aircraft into their design. Four reactors
were evaluated during their design to consider impacts from aircraft weighing up to
12,500 pounds which would include most GA aircraft except for business jets and
large twin engine aircraft. Three Mile Island in Pennsylvania was cited as the only
facility where portions were designed to withstand the impact of large airliners in
addition to smaller aircraft. In contrast, the report noted that some European
countries, including Switzerland and Germany in particular, incorporate safety
features such as reinforced concrete walls and spatial separation of critical safety
systems to withstand the crash of certain types of military and commercial aircraft.
Other examinations of the potential threat to nuclear facilities from aircraft have
focused on perceived vulnerabilities of spent- fuel pools used to cool expended
nuclear fuel. However, power companies maintain that a study modeling the impact
CRS- 16
45 Gary Stoller. “ Nuclear Plants near Airports May Be at Risk.” USA Today, June 10, 2003.
46 Robert M. Jefferson. Nuclear Safety: General Aviation Is Not a Threat ( May 16, 2002),
p. 4 and p. 1. Available from Aircraft Owners and Pilots Association, Frederick, MD.
47 Ibid, p. 1.
of an aircraft crash into a spent- fuel pool wall concluded that while such a scenario
could crush or crack the wall, it would not likely cause a release of radiation45.
A report prepared for the AOPA by Robert Jefferson, a nuclear reactor safety
consultant, concluded that the threat to nuclear reactors from small general aviation
aircraft is “ practically non- existent” and “... it is unlikely that a terrorist would choose
a light general aviation vehicle to threaten a nuclear power plant.” 46 Jefferson’s
analysis concluded that even the impact of an airliner like those used in the 9/ 11
attacks would, in all likelihood, be unable to penetrate the outer containment vessel
and argued that the analysis referenced by Representative Markey significantly
overstates the risk potential and “... overlooks the fact that by their very design,
nuclear power plants are inherently resistant to [ airborne attacks].” 47 The report also
concluded that the proximity of nuclear reactors to GA airports does not increase the
exposure of these facilities to terrorist threats.
Although the specific threat posed to nuclear facilities by GA aircraft remains
a contentious issue, the FAA has kept in force restrictions on circling, loitering, or
otherwise flying in a suspicious manner around nuclear facilities. Arguably, these
measures would provide little deterrent against a well- planned terrorist attack.
However, they highlight the continued concern over possible airborne threats to
nuclear facilities, whatever the true risk may be. More elaborate measures to protect
nuclear facilities, such as implementing anti- aircraft defense capabilities around
nuclear facilities, are wrought with operational and policy complexities including
high costs, questionable effectiveness, and a potentially high risk of shooting down
an errant GA pilot who meant no harm.
While light GA aircraft appear to pose a relatively limited threat by themselves
in terms of physically damaging critical infrastructure, larger GA aircraft pose a
potentially more formidable threat. Due to the size and speed of some of these
aircraft, particularly mid- sized and large business jets, they could inflict significant
damage on buildings and critical infrastructure if used in a suicide attack. These
aircraft have significantly larger payload and fuel capacities which would have a
direct bearing on the degree of physical damage they could cause to buildings and
infrastructure. Thus, in terms of both assessing risk and identifying options for
mitigating the security risk posed by GA, the distinction between small GA aircraft
that make up the large majority of the fleet and larger business jets has important
implications. While small aircraft appear to pose a greater threat as possible
platforms for chemical or biological attacks, large business jets appear to pose more
of a threat from being exploited in a suicide attack scenario similar to the September
11, 2001, attacks using commercial airliners. Because the various sectors of GA
appear to pose distinct threats, risk mitigation strategies arguably should be tailored
to some degree to address the specific security threats posed by different sectors of
CRS- 17
the GA industry as well as the specific nature of potential security vulnerabilities that
also vary across different types of aircraft and flight operations.
Possible Options to Mitigate the Security Risks of
General Aviation
A variety of options exist for mitigating security risks posed by GA aircraft and
flight operations, many of which have been implemented or are currently under
development or consideration. As previously discussed, the selection of mitigation
options may need to be tailored to specific vulnerabilities and threats of different
sectors of the GA industry which may differ significantly in their degree and scope.
While a wide range of options are available, many of the more extensive and costly
options for providing security may not be economically feasible, practical, or
necessary at smaller GA airports away from major population centers. Several
available options center on traditional security techniques to improve access controls
and surveillance around GA facilities and better protect aircraft against theft and
unauthorized use. Additional options include procedures for vetting individuals with
authorized access to aircraft and aviation facilities, and procedures for clearing
passengers. Another possible option for enhancing GA security would be to address
law enforcement and homeland security response to suspicious activities and
improved intelligence tracking of such incidents to identify patterns indicative of
possible terrorist activity. Finally, in terms of adopting a layered security system to
augment measures put in place at airports, airspace restrictions and defenses may be
considered to protect high- profile sites and critical infrastructure from the threat of
aerial attacks.
Costs, in terms of direct implementation and oversight costs as well as the
indirect costs related to disruption of air commerce and freedom of movement, are
likely to be important considerations in assessing the utility and feasibility of
implementing specific options to enhance GA security. For example, implementing
broadly applied security requirements for all GA airports may impose significant cost
challenges, particularly to small, rural airports where the need for such measures may
be questionable. Also, airspace restrictions tend to be highly contentious because
while they directly impact air commerce and the freedom of movement, they are
viewed by some experts as being of questionable value in preventing a terrorist attack
unless coupled with elaborate air defense capabilities. Deploying air defense
capabilities on a large scale to protect against possible aircraft attacks carries a
relatively high cost and involves extensive commitments of resources and
collaboration between the FAA, the DHS and the Department of Defense ( DoD).
The costs and benefits associated with various mitigation options can be analyzed in
a risk analysis framework – examining the threat and vulnerability of specific sectors
of the GA industry – to better understand the tradeoffs between various options.
Because of the diversity of GA airports, aircraft, and flight operations, and the
varied threats and vulnerabilities posed by different sectors of the GA industry, a
logical starting point in mitigating security risk would be to perform systematic risk
analyses or security risk assessments examining specific components of GA. The
FY2006 Department of Homeland Security Appropriations Act ( P. L. 109- 90)
CRS- 18
contains a provision requiring the DHS to examine the vulnerability of high- risk
areas and facilities to possible attack from GA aircraft. This mandate focuses on the
specific vulnerability of critical infrastructure to attack, which relates more closely
to the threat to critical infrastructure and other significant sites posed by GA aircraft
as discussed in this report. In this report vulnerability has referred instead to the
specific weaknesses in security measures to protect GA airports and aircraft that
could be exploited to gain unauthorized access to facilities and aircraft. A
comprehensive risk assessment and risk mitigation strategy would likely take into
account both the threat and vulnerability associated with GA operations as well as the
potential cost of consequences associated with possible terrorist attack scenarios.
Security Risk Assessments
Security risk can be viewed as a function of: 1) the threat or threats posed by a
specific type of flight operation or activity measured in terms that attempt to quantify
the probability of various terrorist attack scenarios; 2) the vulnerability or
susceptibility of existing security weaknesses measured in probabilistic terms
reflecting the likelihood that they could be exploited by terrorists; and 3) the possible
consequences measured in terms of predicted damage or associated cost. Using this
risk analysis framework, the relative effectiveness of mitigation options can be
evaluated in terms of how specific security enhancements might reduce vulnerability
and how resources could be allocated in a manner to mitigate threats based on their
likelihood and their potential consequences. The anticipated risk reduction can then
be compared to expected costs in an attempt to determine the most cost effective
strategies for enhancing GA security.
For passenger airline operations, a layered approach to aviation security has
been implemented. This layered system includes passenger name checks against
watch lists, passenger and baggage screening, access controls at airports, hardened
cockpit doors, and armed air marshals and pilots on passenger airlines. The layered
approach has a unique advantage in reducing vulnerability by adding additional
safeguards to foil terrorists, thereby greatly reducing the overall vulnerability of the
entire system. In probabilistic terms, the vulnerability of the entire security system
is the combined or joint probability that each individual layer could be breached or
circumvented. Thus, while the threat of terrorism still exists, most experts would
agree that, in the case of passenger airlines, the risk of terrorism has been
significantly mitigated by greatly reducing the vulnerability that security weaknesses
could be exploited by terrorists through the implementation of a multi- layered
security system.
In the case of GA, a systematic examination of security risk has not been
completed. However, many experts acknowledge that various security vulnerabilities
and threats exist. An analysis of GA security by the International Civil Aviation
Organization ( ICAO) concluded, “[ t] he challenge of designing general aviation
security measures focuses on the need to thoroughly define the threat. Before
CRS- 19
48 Donald Spurston. “ Security Requirement for GA Operations Should be Based on Threat
Assessment.” ICAO Journal, Number 8, 2002, p. 18.
49 Transportation Security Administration. Security Guidelines for General Aviation
Airports. Information Publication A- 001, May 2004.
security standards can be developed, there must be a clear picture of the problem.” 48
One challenge often cited and already noted in this report is the diversity of GA
airports. In many respects, the characteristics of GA airports are much more diverse
than those of commercial passenger airports. Yet recognition of this diversity is not
always acknowledged in discussions of GA security risk. In contrast, commercial
passenger airports are stratified in a tiered system based on their security needs:
commercial airports are placed into one of five categories ( Category X, I, II, III, IV)
based on factors such as the volume of passengers, the level of international
operations, and the proximity to critical locations like Washington, DC. A similar
model could be adopted to categorize GA airports based on their security risks and
the particular security needs of certain classes of GA airports, or in some cases for
specific operators of large fleets of GA aircraft. Toward this goal, the TSA provided
as part of its security guidelines for GA airports an airport characteristics
measurement tool where airports are scored based on a variety of factors including
their proximity to metropolitan areas and sensitive sites; surrounding airspace; the
number of based aircraft; runway lengths; the numbers and types of flight operations;
and the presence of maintenance, repair, and overhaul ( MRO) facilities. 49 Using this
tool, airports are scored on a scale ranging from 0 to 64. Based on the scoring,
airports will fall within one of four bands, and the TSA has provided suggested
security enhancements for each of the four bands. However, because use of this
assessment tool is voluntary, and because the process is relatively generic and does
not consider site- specific factors, it provides only a rudimentary risk assessment tool
and process for GA airport operators.
While the requirement established under the FY2006 Department of Homeland
Security Appropriations Act ( P. L. 109- 90) mandates a broad examination of the
security threat posed by GA, more detailed security risk assessments can be done
either at the airport level or, for some larger operators, such as fractional- ownership
fleets, at the operator level. Due to the diversity of GA airports and the kinds of
operations that they accommodate, the risk picture is likely to vary widely. For
example, some small airports in mid- western and mountain states might have few
security measures in place and therefore may be considered vulnerable. However
because of their remote location – away from major population centers – these
airports may pose little threat. On closer examination, it may be found that such
airports may not be particularly vulnerable to terrorist infiltration based on several
factors. For example, a remote location away from any high- profile sites or densely
populated areas might not be particularly attractive to terrorists, and the close- knit
community of airport users in small, rural communities may be more likely to spot
outsiders and detect suspicious activity. On the other hand, a busy GA reliever
airport near a major metropolitan airport may pose a greater risk. Even if such an
airport has implemented various security measures to mitigate risk, it may still be
regarded as more vulnerable than a rural airport because terrorists may be able to
more easily blend in with large numbers of individuals accessing the airfield, and
CRS- 20
50 Transportation Security Administration. DHS- Vulnerability Identification Self- Assessment
Tool ( VISAT).
51 Robert Olislagers. “ General Aviation Security: The Ups & Downs of Threat
Management.” Airport Magazine, May/ June 2005, pp. 59- 61.
52 Ibid.
while some access controls may be in place, they may not be adequate for preventing
motivated terrorists from circumventing these measures or exploiting weaknesses in
access controls.
The TSA’s approach to risk assessment to meet the sector- specific security plans
called for in Homeland Security Presidential Directive( HSPD)- 7: Critical
Infrastructure Identification, Prioritization, and Protection is the ongoing
development of a Vulnerability Information Self Assessment Test ( VISAT) for GA
airports. VISAT programs have already been developed for other transportation
infrastructure including maritime, rail, bridges, and mass transit, and others are under
development for other transportation sectors including rail and trucking HAZMAT. 50
The GA VISAT, currently under development, is designed to be a self- guided,
computer- based assessment tool designed to assess risk and mitigation at GA
airports. However, this TSA approach to assessing security risk at GA airports has
been criticized over its lack of understanding and differentiation of GA from the air
carrier environment and its extensive reliance on standards developed for nuclear
power plant security that do not adequately address the public access needs of GA
airports. 51 Critics have argued that the TSA should instead, incorporate more updated
threat and risk management standards developed by FEMA that more fully address
public access needs. 52 While some of these recommendations may be incorporated
into the final assessment tool issued by the TSA to assess security risk at GA airports,
a comprehensive, standardized tool to perform detailed analyses of security risks in
the GA sector does not currently exist. Many experts believe that such a tool could
be extremely beneficial for identifying risks and designing security programs for
specific airports or specific categories of GA airports.
Based on detailed analyses, cost- effective security programs that address the
specific degree and nature of risk at specific airports can be designed and
implemented. Various combinations of security measures are available and can be
tailored for airport- specific or operator- specific security plans. These include various
approaches to: surveillance and monitoring; airport access controls; and physical
security measures to protect aircraft. These specific security systems implemented
by airports and operators may be augmented by broader initiatives such as the vetting
of GA pilots and airport workers at the federal level and establishing specific
procedures and defenses to protect airspace near critical locations such as key federal
facilities in Washington, DC. In the following discussion, these various approaches
and the challenges associated with applying them to GA security are analyzed in
further detail.
CRS- 21
Surveillance and Monitoring
Surveillance and monitoring of GA operations is a challenge. Of the 5,286
public use landing facilities in the United States, only about 500 have operating
control towers and most of these are located at airports with regularly scheduled
commercial service. Only the busiest airports that cater exclusively to GA aircraft
have operating control towers. These airports usually are geographically large and
congested making surveillance for security purposes from the tower difficult. What’s
more, even at the limited number of GA airports with operating control towers, most
towers are not operated on a continuous basis and close during late night and early
morning hours. While language in a Senate- passed amendment to the FY2006 DHS
Appropriations bill ( see S. Amdt. 1106 to H. R. 2360) would have required “ an
assessment of whether unmanned air traffic control towers provide a security or alert
weakness to the security of general aviation aircraft”, the security role of staffed
control towers is unclear. During operating hours, controllers remain busy
performing air traffic separation and control functions, making it difficult for them
to spot unusual activity or detect unauthorized aircraft usage unless suspicions are
raised by unusual requests, improper phraseology, or procedural violations.
Therefore, the mere presence of a operating control tower appears to provide little
additional security to a GA airfield.
Smaller GA airports, most of which do not have operating control towers, are
usually not attended by airport management or fixed- base operators ( FBOs) on the
field 24 hours a day. Depending on the frequency of traffic, an airport may be
attended only during daylight hours, or sometimes during limited evening hours.
Aircraft may still use many of these airports during late night and early morning
hours as runway lights can be controlled from the cockpit using onboard radios.
Airport access controls and surveillance during these unattended hours presents a
unique challenge to airport operators. On the one hand, accessability is important to
meet the needs of air commerce by allowing operations such as late night arrivals and
departures for business trips and overnight cargo delivery to small communities.
Furthermore, maintaining airport accessibility at night provides a critical safety
function allowing pilots sufficient alternate landing sites if required to deviate for
weather or mechanical reasons. Providing adequate site security for GA airports
while allowing airport access for these purposes, including access for transient
aircraft, presents a daunting challenge.
Full time security is a costly option for many small airports. Remote sensing
and surveillance using cameras and motion sensors, for example, may offer a
somewhat more cost effective alternative, but requires close coordination with local
security forces and law enforcement to respond to suspected threats or security
breaches. Uncertainty and high false alarm rates in detection systems can drive up
costs associated with security response and can lead to complacency that may limit
the effectiveness of these systems. However, these remotely monitored security
systems provide an alternative to security monitoring for many airport sites where
full time on- site security is cost prohibitive. At least one vendor provides tailored
security packages, integrating alarms, cameras, entry and access controls, fencing,
CRS- 22
53 Robert Ross. “ Keeping GA Safe.”
54 Transportation Security Administration. “ General Aviation – Hotline.”
55 Testimony of Mr. Andrew Cebula, Senior Vice President, Aircraft Owners and Pilots
Association. Before the Senate Committee on Commerce, Science, and Transportation on
General Aviation Security, June 9, 2005.
lighting, and motion and acoustic sensors. 53 A key element of these types of
integrated security systems are their monitoring capabilities, including remote
internet- based monitoring of cameras and other intrusion detection devices, and the
capability to tie into local law enforcement networks for coordinated response.
However, these integrated systems can be quite costly to install, maintain, and
operate. Consequently, the GA community, in coordination with the TSA, has
applied a long- established method of providing security and surveillance in
residential neighborhoods – the neighborhood watch concept – to GA airports
throughout the United States.
Airport Watch Program. To enhance surveillance at airports, the TSA, in
cooperation with the AOPA and the National Response Center, launched an airport
watch program at GA airports in December, 2002.54 The airport watch program is
similar to a neighborhood watch program and relies on the cooperation and
participation of pilots, airport tenants, and airport workers to observe and report
suspicious activity. Educational and training materials have been made available to
these individuals to increase their awareness regarding potentially suspicious activity,
and a hotline – 1- 866- GA- SECURE – has been set up to log reports of suspicious
activity. Under the program, instructional materials advise observers to call local law
enforcement using 911 if they believe the situation potentially poses an immediate
threat. The AOPA has provided funding and resources since the program’s inception
to provide educational and informational materials for pilots and for signage – similar
to neighborhood watch signs – at airports. According to the AOPA, the organization
has spent more than $ 1 million from its own funds developing, promoting, and
providing support for the Airport Watch Program. 55 Congress has supported the
Airport Watch program in appropriations language, and the FY2006 Department of
Homeland Security Act ( P. L. 109- 90; H. Rept. 109- 241 and H. Rept. 109- 79) provides
an additional $ 275,000 for additional promotion of the program.
Since its inception, the Airport Watch program has been credited with alerting
authorities to suspicious activities at GA airports on several occasions. For example,
the AOPA cited one peculiar incident as a demonstration of the effectiveness of the
airport watch concept. In August 2004, two men of “ Middle Eastern appearance”
presented themselves at an airport near St. Louis offering cash to charter a helicopter
and presenting driver’s licenses from two different states as identification. The
charter operator also noted that the men were driving a vehicle registered in a third
state and observed the men removing “ odd shaped luggage” from that vehicle in
preparation for the flight. Based on these observations, the charter operator stalled
the suspicious individuals and notified the FBI and local law enforcement who
responded and arrested the two individuals. The suspicious characters turned out to
be reporters on assignment to demonstrate how easily terrorists could hijack a
CRS- 23
56 Aircraft Owners and Pilots Association. Proof AOPA Airport Watch Concept Works.
August 12, 2004. Frederick, MD: AOPA.
57 See Testimony of Mr. Andrew Cebula.
helicopter. 56 The AOPA noted several other successes of the Airport Watch program
including the capture of a suspected con man in Kansas who attempted to rent aircraft
at several facilities, and several cases of suspicious inquiries regarding aircraft
rentals, charter flights, flight instruction, and use of hangar storage space. These
incidents all resulted in responses by federal law enforcement authorities, although
none have been specifically linked to terrorism. 57
Despite the benefits and successes of the Airport Watch Program, which have
been achieved at a relatively low cost, there are several challenges to implementing
a successful watch program. A major limitation of the Airport Watch Program is that
it may be difficult – especially for untrained observers – to distinguish suspicious
behavior from normal activities. Past terrorist attacks have indicated that terrorists
are likely to use methods that avoid arousing suspicion. In essence, terrorists have
in the past hid in plain site and may be likely to do so in the future.
In the case of general aviation, the all too obvious example of a clandestine
rendezvous where cargo is loaded from a suspicious vehicle on to a small aircraft at
a remote area of the airport may likely be regarded as too risky by terrorist groups to
attempt. Rather, terrorists may try to blend in as well as possible. This could lead
to two undesired consequences: high false alarm rates and racial and ethnic profiling
by well intentioned pilots and airport tenants. High false alarm rates could place a
strain on local law enforcement, especially in rural areas and small communities
where law enforcement support is limited. Other limitations to these types of
programs are that the response time of local law enforcement is often slow, and local
law enforcement – especially in small, rural communities – may not be adequately
integrated with homeland security systems to receive a timely notification when an
incident is reported, although observers are specifically instructed to dial 911 if they
believe the situation poses an immediate threat. Another difficulty is that local law
enforcement may become complacent if a large number of false alarms are reported
at local airports. Despite these obvious limitations, Airport Watch is regarded by
many as a model program in the sense that it raises awareness and provides a
relatively inexpensive means of providing surveillance. The program could
potentially be improved by providing more detailed information and training to
pilots, airport tenants, and airport workers in observational techniques – such as
behavioral pattern recognition – to improve the quality of information provided to the
Airport Watch hotline or relayed through other notification channels.
Behavior Pattern Recognition. One challenge in implementing an Airport
Watch Program is that it is highly dependent on the observations and reporting of
untrained individuals. This difficulty is compounded by the fact that suspicious
terrorist activities may not appear out of the ordinary to the casual observer. While
convicted terrorist Zacharias Mossaoui’s peculiar inquiries about flying large jet
aircraft and his obvious lack of qualifications to seek such training did raise
suspicions at the flight school where he sought advanced jet training, terrorist
behavior patterns are likely to be much more subtle. None of the 9/ 11 terrorist pilots
CRS- 24
58 Robert Olislagers. “ General Aviation Security.”, p. 61.
59 Ibid.
60 Ibid.
nor Mossaoui attracted similar attention during their initial training in small GA
aircraft. Qualified pilots seeking to rent light aircraft also may attract little attention
and a pilot loading a small single- engine airplane with dangerous chemicals or
biological agents may look no different than a pilot loading his personal effects on
board for a weekend getaway. While single incidents like this typically arouse little
suspicion, aggregate behavior that might appear somewhat odd or suspicious could
collectively signal possible terrorist or criminal activity.
An additional downside of programs like the Airport Watch Program is that they
could result in unintended racial or ethnic profiling by well intentioned observers.
For example, would the individuals in the St. Louis incident cited by AOPA have
raised similar suspicions if they were not of “ Middle Eastern appearance”? Besides
the potential for falsely targeting individuals in certain racial and ethnic groups, there
is also the danger that, conversely, untrained observers may not notice suspicious
behavior patterns exhibited by other individuals. Intelligence sources suspect that al
Qaeda is seeking to recruit non- Middle Eastern individuals for the very reason that
they may be less likely to raise suspicions. More specific guidance and training to
airport workers, tenants, and pilots could improve the effectiveness of the Airport
Watch Program and other surveillance operations.
A possible solution to overcome some of these limitations involves the
implementation of behavioral pattern recognition techniques. As described in a
recent commentary on GA security, behavioral pattern recognition was highlighted
as being “... designed to maximize detection while minimizing, if not eliminating,
issues of civil liberties.” 58 Behavioral pattern recognition – which is in use at
airports worldwide and has been highlighted in numerous profiles of Israel’s El Al
airlines’ pre- boarding security screening – examines deviations from normative
behavioral patterns. It has been suggested that behavioral pattern recognition could
be applied in the GA environment by providing specific training to maintenance and
line workers, for example, making them an integral part of an airport’s security
network rather than having a small number of employees responsible for security. 59
One challenge in behavioral pattern recognition is that single events may not
stand out, but aggregate samples of slightly unusual activity may provide tell- tale
signs of preparations for launching a terrorist attack. However, assimilating and
correctly interpreting this data remains a significant challenge. For this reason, a
“ reporting tree” 60 is recommended for guiding decisions about responding to
suspicious behavioral patterns. The “ reporting tree” concept is integrated into the
TSA’s security training for flight schools, which is a required security training
element for flight school employees under Title 49, Code of Federal Regulations,
§ 1552.21 et seq., but has not yet been expanded to other aspects of GA security. A
reporting tree might include notifying a supervisor, such as a chief flight instructor
or flight school manager, about strange inquires or behaviors by a student pilot, and
escalating this information up the reporting tree to law enforcement or federal
CRS- 25
officials only if the behavior is repeatedly demonstrated and, in aggregate, raises
enough concern that it warrants further action. In this manner, the Airport Watch
program, in coordination with specific training and guidance in techniques such as
behavioral pattern recognition and the use of reporting trees, has the potential to
contribute to the intelligence gathering function at a relatively low cost by enlisting
the support of a broad segment of the GA community.
Airport Access Controls
Controlling access to general aviation airports is a significant challenge for
many reasons. First, as already discussed, few general aviation airports are
continuously attended or monitored, and doing so is likely to be costly and resource
intensive. Second, general aviation airports support a wide variety of operations and
consequently must provide limited public access to support and sustain these varied
operations including late night cargo operations, training flights, and maintaining
adequate numbers of landing facilities that are continuously available for safety in the
case of diversions due to weather or mechanical difficulties.
Providing airport access for transient operators also presents a unique security
challenge for GA airports, especially during hours when the facility is not attended.
However, restricting airports from transient access has significant consequences both
for air commerce and for safety. For example, restricting access after hours may
impede air commerce and business, especially in remote areas that rely significantly
on the presence of a GA airport. Professionals who use GA aircraft to conduct
business in these areas may be reluctant to do so if they run the risk of being denied
access to the airport because of a late running business meeting that extends beyond
the operating hours of the airport, for example. Also, for safety reasons, sufficient
numbers of GA airports need to remain accessible, at least for landing aircraft, to
provide suitable alternate airports in case of emergency or diversion due to weather.
Supporting airport access during non- attended hours poses significant security
challenges. Access control measures must adequately accommodate transient users
or the airport runs the risk of becoming inaccessible to certain users. Various options
exist for providing both local and transient operators with adequate access to the
flight line. For example, at airports implementing access controls to aircraft storage
and operations areas, keypad locks can be installed to control access to flight lines.
Codes could be provided to transient operators in case they need to access aircraft
after hours and could be changed frequently to prevent unauthorized access.
Alternatively, more sophisticated access controls can be implemented using key code
or card reader systems where transient operators are provided with codes or cards that
expire and cannot be used after a certain period.
Display of identification badges in aircraft operations areas may also improve
security by identifying those individuals with authorized access to these areas. This
can alert observers and security personnel to possible unauthorized access. TSA
security guidelines for GA airports suggest that airport identification credentials
include features such as a photograph showing a full- face image, the holder’s full
name, the airport name, employer information, a unique identification number, the
CRS- 26
61 Transportation Security Administration. Security Guidelines for General Aviation
Airports.
62 P. L. 108- 458, Sec. 4022.
63 Aircraft Owners and Pilots Association. Pilot ID Process Needs to be Convenient,
Inexpensive, AOPA Reminds the FAA. Frederick, MD, July 8, 2005.
64 In this context, the flight line refers generally to those areas of an airport where aircraft
are accessible including hangars, tie- down areas, and ramps ( aprons).
scope of access and movement privileges through easily interpretable means such as
color- coding, and a clear expiration date. 61
Pilots, for whom access privileges at multiple airports is needed, require a
standardized identification that is easily recognizable at all airport facilities.
Presently, FAA certificates do not contain photographs of the certificate holder.
However, current regulations require pilots to carry government issued photo
identification, such as a driver’s licence, and present that identification along with
their pilot credentials upon the request of a law enforcement officer or federal
official. ATSA ( P. L. 107- 71) directed the FAA to study ways to improve pilots
licenses such as including photos. While the FAA, in response, has taken steps to
make newly issued pilot certificates more tamper- resistant and more difficult to
forge, many pilots still carry older style paper certificates that can be easily forged.
The Intelligence Reform and Terrorism Prevention Act of 2004 ( P. L. 108- 458, Sec.
4022) requires the FAA to begin issuing improved pilot certificates that include a
photograph of the holder and have the capability to accommodate a digital
photograph, a biometric identifier, and any other unique identifiers that the FAA may
determine to be necessary. While specific plans for issuance of the new pilot
certificates with photographs have not yet been announced by the FAA, statutory
language provides for the use of designees such as designated pilot medical
examiners to issue these new licenses in an effort to “ minimize the burdens on
pilots.” 62 Advocates for GA pilots have pushed for the use of designated aviation
medical examiners for issuance of the new certificates, noting that forcing pilots,
particularly pilots in rural areas, to travel to an FAA flight standards district office
would be, in their opinion, an unacceptable burden. 63
While these new pilot credentials must include the capability to store biometric
information, the use of biometrics for identification purposes and access controls in
the GA environment introduces many complex technical and policy questions.
Implementing biometric access controls at GA airports may be feasible in some
cases, but presents significant challenges because of the need to obtain and encode
biometric information for transient operators as well as those local tenants, pilots,
operators, and airport workers who are authorized to have unescorted access to the
flight line. 64 While biometrics have distinct advantages in terms of logging and
tracking access to restricted areas, privacy issues, cost, and logistics may make them
difficult to implement effectively in the GA airport environment. However,
biometrics may play a more significant role at the GA operator level of security
where they could be implemented to control access to operator facilities such as
aircraft storage and maintenance hangars. Biometrics may also be used on more
limited sets of individuals and integrated into ID card access systems for local aircraft
CRS- 27
owners, operators, pilots and airport workers. Doing so may allow security efforts
to focus more directly on those individuals at an airport that pose more of an
unknown threat, such as charter passengers not known to their flight crews and other
airport visitors.
Background Checks and Vetting
Because GA airports must maintain a level of reasonable public accessibility to
facilitate the freedom of movement by air and air commerce, surveillance, access
controls, and physical security measures to protect aircraft and facilities, if needed,
must be designed to accommodate a diverse set of legitimate airfield uses. For this
reason, implementing access controls and physical security on par with commercial
passenger airports is likely to be unrealistic. However, conducting background
checks and vetting individuals who routinely access GA airports is seen as a possible
technique for assessing potential threats and also as a possible means to focus
security resources on conducting surveillance and applying access control measures
on visitors who are of an unknown risk.
Vetting of transportation workers and others who routinely access transportation
facilities has been a cornerstone of several statutorily mandated projects related to
transportation security. For example, the TSA is required to conduct background
checks of workers at commercial passenger airports, and the TSA has several
ongoing projects, such as the Transportation Worker Identification Credential
( TWIC) Program and various airport access control pilot studies, that are attempting
to integrate background checks and vetting with the use of biometric access
credentials. While it may be some time before these programs reach maturity and can
be considered for application in the GA environment, there are already several
statutory requirements for vetting GA pilots, pilot applicants, and more recently,
prospective aircraft charter and lease customers.
The most widely known of these GA programs is the TSA’s alien flight training
rule ( Title 49, U. S. C. § 44939; Title 49 Code of Federal Regulation, Part 1552),
which requires the TSA to conduct background investigations of non- U. S. applicants
seeking flight training in the United States for aircraft weighing more than 12,500
pounds and requires flight schools or flight instructors to notify the TSA whenever
a non- U. S. applicant wishes to initiate flight training in smaller aircraft weighing less
than 12,500 pounds. In response to law enforcement and intelligence information
revealing that the 9/ 11 hijackers and accomplice Zacharias Moussaoui received flight
training in the United States and amid concerns that foreign terrorists could further
infiltrate flight schools in the United States, the Aviation and Transportation Security
Act ( ATSA, P. L. 107- 71) initially placed the Department of Justice in charge of
conducting fingerprint- based record checks for alien flight school applicants seeking
training to fly aircraft weighing more than 12,500 pounds. Under Vision 100 ( P. L.
108- 176), this responsibility was moved to the TSA, the process was streamlined to
limit the impact of the process on legitimate flight training activities, and reporting
requirements were expanded to include a notification requirement whenever foreign
flight school applicants initiate flight training in the United States in smaller aircraft
weighing less than 12,500 pounds.
CRS- 28
65 Transportation Security Administration. “ Threat Assessment Regarding Citizens of the
United States and Alien Holders Who Hold or Apply for FAA Certificates; Final Rules.”
Federal Register, 68( 16), pp. 3756- 3769 ( January 24, 2003).
66 See, e. g., Llewellyn King. “ Adm. Loy, You Know Better: Rescind This Rule.” White
House Weekly, 24( 10), March 11, 2003, 1- 2.
67 Transportation Security Administration. Memorandum to the Dockets from Pamela
Hamilton, Director of Aviation Initiatives Regarding TSA Rulemaking Docket No. TSA-
2002- 13732 and TSA Rulemaking Docket No. TSA- 2002- 13733. March 16,2004.
68 Title 14 CFR § 1544.101 and § 1544.230.
A lesser known component of TSA’s efforts to vet pilots ( whether they be GA
pilots, charter pilots, or airline pilots), aircraft mechanics, and dispatchers is the use
of threat assessments to screen holders of and applicants for FAA certificates, ratings,
or authorizations. Rules pertaining to the security threat assessments for FAA
certificate holders and applicants were promulgated on January 24, 2003.65 Under
these rules, the TSA notifies the FAA whenever a FAA certificate holder or applicant
is determined to present a security threat. The FAA, in turn, will deny, suspend, or
revoke the individual’s FAA certificate as appropriate. While parallel rules were
initially issued to carry out security threat assessments for both alien applicants and
citizen applicants, the rule pertaining to U. S. citizens was criticized because it lacked
adequate safeguards for redress and remedy if FAA certificate actions were taken in
response to what the TSA determined to be a security threat. Critics argued that the
rule gave the TSA significant power over the issuance of pilot certificates and other
aviation credentials without any oversight or redress for the TSA to demonstrate the
specific evidence or basis for its decision to identify a certificate holder or applicant
as a security threat. 66 In response to concerns raised regarding the TSA’s power over
security- related certificate actions and the lack of an adequate redress process, Vision
100 ( P. L. 108- 176, Sec. 601) mandated the TSA to establish a redress and remedy
process entitling U. S. citizens subject to certificate action on the basis of a security
threat assessment to a formal redress hearing before an administrative law judge and
an appeals process before a panel convened by the Transportation Security Oversight
Board. The TSA has not yet issued revised rulemaking to conform with the statutory
requirements set forth in Vision 100, and therefore, existing regulations to enforce
FAA certificate actions on the basis of security threat assessments no longer apply
to U. S. citizens. 67 However, security threat assessments for alien FAA certificate
holders and applicants remains unchanged.
Although security threat assessments for citizen pilots, mechanics and other
FAA certificate holders and applicants has been suspended until the TSA develops
a process and issues rulemaking to conform with statutory requirements for redress
and remedy, regulations still require fingerprint- based criminal history records checks
for charter pilots who fly aircraft weighing more than 12,500 pounds. 68 However,
other GA pilots – who make up the majority of the more than 600,000 active pilots
in the United States – are not required to submit to any formal background screening
or checks. Some critics of background checks and vetting maintain that they are
costly and an unnecessary intrusion into the privacy of citizens. On a pragmatic
level, some question whether background checks for GA are needed at all,
particularly at small, rural airports where pilots, ramp workers, and others who
CRS- 29
69 See CRS Report RL32802, Homeland Security: Air Passenger Prescreening and
Counterterrorism, by Bart Elias, William Krouse, and Ed Rappaport.
70 See Title 31 Code of Federal Regulations, Part 103.
frequent the airport are largely known to each other. Nevertheless, background
checks and other vetting activities have been looked upon favorably by policymakers
as a core component of a layered security system and could be further expanded in
their application to GA operators.
One area where background checks and security threat assessments is being
incorporated into GA operations is for the vetting of prospective charter and lease
customers. Under statutory provisions set forth in the Intelligence Reform and
Terrorism Prevention Act of 2004 ( P. L. 108- 458, Sec. 4012), the TSA is charged
with the task of setting up a mechanism for charter and aircraft lease operators to
voluntarily submit the names of prospective clients seeking access to aircraft
weighing more than 12,500 pounds for screening against the consolidated terrorist
watch list. Aircraft operators may deny individuals access to aircraft if their name
is found to match watch list records. While the legislative language limited the
applicability of this vetting procedure to aircraft weighing more than 12,500 pounds,
the feasibility of extending this capability to charters and leases of smaller aircraft,
based on the initial experience with larger aircraft, was debated during consideration
of this legislation. While terrorist database screening of prospective charter and
lease customers as legislated is voluntary, policymakers may also consider whether
mandatory screening of aircraft charter and lease customers is warranted. However,
because the capability to screen names against terrorist watch list information is tied
to the functionality of the controversial Secure Flight program for prescreening
airline passengers, implementation of a charter and lease customer prescreening
mechanism – which is currently not operational – may be further delayed by ongoing
difficulties in meeting congressionally mandated safeguards for data and privacy
protections and redress and remedy for aggrieved individuals who are erroneously
identified as suspected or known terrorists. 69 Presently, language in the FY2006
Department of Homeland Security Appropriations Act ( P. L. 109- 90) prohibits full-scale
deployment of the Secure Flight system until the GAO certifies that these
lingering concerns are adequately addressed.
Besides prospective charter and lease customers, the screening of prospective
aircraft purchasers can serve as an important deterrent to prevent terrorists or
organizations that support terrorism from acquiring aircraft that could be used in a
terrorist attack. Under Department of the Treasury regulations, promulgated to meet
requirements of the USA PATRIOT Act ( P. L. 107- 56), aircraft sales must comply
with various information sharing, reporting, and records keeping requirements aimed
at identifying suspicious transactions and preventing money laundering. 70 However,
because many other large- scale financial transactions such as the sale of houses,
boats, and cars must be similarly reported, the volume of transactions may make it
difficult to quickly identify suspicious aircraft transactions. The main intent of these
regulations is to spot potential attempts to launder illegal funds in support of terrorist
or criminal activities, and therefore the regulations are not specifically designed to
vet purchasers of GA aircraft against terrorist watch lists. The capability to detect
CRS- 30
71 Transportation Security Administration. Security Guidelines for General Aviation
Airports.
72 Ibid.
73 Ibid.
aircraft sales to suspected terrorists or their associates and vet aircraft purchasers
against terrorist watch lists under these reporting requirements remains unclear.
Physical Security Measures for Airports
Other than surveillance, access controls, and background checks, there are a
variety of other options for enhancing the general physical security of airport
facilities. One of the most obvious of these measures is erecting physical barriers,
such as chain- link perimeter fencing, around security sensitive locations on the
airfield. However, the TSA cautions that while physical barriers such as fencing,
walls, electronic boundaries, and even natural barriers can protect airport areas from
unauthorized access, these methods by themselves will not prevent determined
intruders from gaining access. The TSA further notes that excessive spending on
extensive perimeter enhancements may actually be detrimental to an airport’s overall
security posture to the extent that these efforts take away from opportunities to
improve upon other aspects of security. 71 Besides fencing, protective lighting can
often serve as an effective deterrent against theft, vandalism, unauthorized access,
and other illegal activity at night. 72
While various combinations of physical barriers and lighting may deter
unauthorized access at airports, the TSA notes that storing aircraft in hangars
provides one of the most effective method of securing GA aircraft. 73 However, at
many GA airports, hangar space is in short supply and the demand for hangars make
them very costly, especially for some small, privately owned aircraft. Language in
the Century of Aviation Reauthorization Act – Vision 100 ( P. L. 108- 176, Sec. 149)
provides greater flexibility in the allocation of federal Airport Improvement Program
( AIP) funds for the construction of hangars at GA airports. Also, to foster private
investment in hangar construction, additional language in Vision 100 ( P. L. 108- 176,
Sec. 165) provides assurances for long- term lease agreements between tenant aircraft
owners who build hangars using their own funds and airport operators.
Physical Security Measures for Aircraft
While surveillance, access controls, and physical security measures at airports
can provide effective deterrents, these measures may be costly and challenging to
implement at many GA airports, especially smaller airports. Measures to physically
secure aircraft can be viewed as either an additional layer of security to prevent theft
and unauthorized access to aircraft at airports with extensive surveillance and access
controls or as a primary means of security at some airports with more limited security
capabilities.
Physical security measures for aircraft may include cabin and ignition locks that
may already exist for certain aircraft as well as supplemental immobilizing devices
CRS- 31
74 Mike Morris. “ Buford Man, 22, Accused of Stealing Jet.”
75 U. S. Government Accountability Office. General Aviation Security: Increased Federal
Oversight Is Needed, but Continued Partnership with the Private Sector Is Critical to Long-
Term Success. GAO- 05- 144, November 2004.
such as propeller, throttle, control surface, and tie- down locks. The TSA’s Security
Guidelines for General Aviation Airports recommends storing aircraft in locked
hangars, consistent use of aircraft door locks, using keyed ignitions when appropriate,
and not leaving keys in aircraft as some basic steps to secure GA aircraft. The
guidelines also recommend using an auxiliary lock such as commercially available
propeller, throttle, or tie down locks to further protect GA aircraft. The TSA suggests
that “[ p] ilots should employ multiple methods of securing their aircraft to make it as
difficult as possible for an unauthorized person to gain access to it.” However, it is
apparent that this common sense advice is not always heeded. In the October 2005,
theft of a Cessna Citation VII business jet, it was reported that the aircraft – which
does not need a key to start – was left unlocked. 74
While building or renting secured hangar space may be cost prohibitive to many
light aircraft owners, locks and other security devices may provide a common sense,
cost effective means to reduce the vulnerability of GA aircraft to theft. Given that
aircraft are high value assets, locks may offer a relatively low- cost means to reduce
vulnerability. Purchasing and installing secondary locks could benefit aircraft owners
and operators by providing added protection against theft and unauthorized access.
In the absence of explicit federal standards or requirements, some states have
taken initiatives to require specific actions for securing GA aircraft. New Jersey, for
example, has implemented a state- wide “ two- lock rule” requiring any aircraft parked
or stored at a GA facility within the state for more than 24 hours to either secure the
aircraft with two distinct locking devices or disable the aircraft in a manner to
prevent theft or illegal use. 75 The Strengthen Aviation Security Act ( H. R. 2649)
would require airport operators to ensure that “... all general aviation aircraft, while
parked at such airports, are secured by a visible immobilizing device ( such as a prop
lock).” Propeller locks and throttle locks may provide relative low cost, relatively
effective deterrents to unauthorized use and theft of aircraft.
Securing Agricultural Aviation Operations
The specific intelligence and law enforcement evidence pointing to al Qaeda’s
interest in crop dusting aircraft in the months leading up to 9/ 11 suggests that the
agricultural sector of general aviation should be particularly alert to suspicious
activities. Because agricultural aviation operations largely take place in rural
environments, away from highly populated areas, increased awareness of this threat
coupled with operators increasing their vigilance and taking steps to secure their
aircraft may serve as an adequate deterrent. However, the unique capabilities of
aircraft, both airplanes and helicopters, used in aerial application make them
specifically attractive to terrorists. For this reason, the TSA recommended to
operators of agricultural aircraft that they use multiple security devices – such as
throttle and control locks, propeller locks, and hidden ignition switches – to secure
aircraft, store aircraft in hangars with electronic security systems and steel doors, and
CRS- 32
76 Transportation Security Administration. Security Guidelines for General Aviation
Airports.
77 Regulatory Consultants, Inc. “ Secure Your Operation Today.” Agricultural Aviation,
July/ August 2005, 17- 18.
78 Jean Heller and Alicia Caldwell. “ Flight Schools: Breach of Trust Difficult to Prevent.”
St. Petersburg Times, January 8, 2002.
79 Transportation Security Administration. Security Guidelines for General Aviation
Airports.
when hangars are not available, park heavy equipment in a manner to prevent the
movement of aircraft. 76 The National Agricultural Aviation Association has provided
additional guidance to operators of agricultural aircraft advising them to: secure
pesticide storage areas; implement procedures for the shipping and receiving of
chemicals; secure facilities and limit access; post security signs; improve lighting of
storage areas; secure fences and gates; conduct security inspections to check for signs
of intrusion or tampering; maintain logs to track visitor access to facilities; coordinate
with local law enforcement and fire departments; and develop site security plans as
required to comply with HAZMAT regulations. 77
Flight School Security
Besides agricultural aircraft operations, another sector of GA flying that has
raised security concerns has been flight schools. Flight schools have been
spotlighted, in large part, because of intense media coverage of the apparent relative
ease that some of the 9/ 11 hijackers were able to obtain flight training in the United
States, and the reported lack of safeguards to prevent incidents like the intentional
crash of a small single- engine airplane into a downtown Tampa, Florida building
piloted by a student pilot who stole the aircraft while conducting an unsupervised
pre- flight inspection. 78
To address lingering concerns over flight school security, Vision 100 ( P. L. 108-
176) requires specific flight school security awareness training for all flight school
employees. To meet this statutory requirement, the TSA has developed a
standardized computer- based flight school security awareness training program,
although flight schools have the option of developing their own security training
program that must obtain TSA approval. New hires must receive initial security
awareness training within 60 days of employment, and employees must complete
annual recurrent training in security awareness. The training indoctrinates flight
school employees on fundamentals of security awareness, security practices, and
appropriate responses to suspicious events. In addition to the statutory requirement
for security awareness training, the TSA has issued several recommendations for
flight schools in its security guidelines for GA airports. 79 These recommendations
largely focus on increasing surveillance and supervision of students and renter pilots
and better controlling access to aircraft and aircraft keys. Other steps that may be
taken by flight schools to improve security include background checks of prospective
employees, particularly prospective flight instructors and maintenance personnel;
establishment of formal written security procedures for employees and customers;
CRS- 33
80 National Business Aviation Association. NBAA Best Practices for Business Aviation
Security. Washington, DC: National Business Aviation Association, Inc.
81 David Esler. “ TSAAC: Business Aviation’s New Ticket to Enter?” Business &
Commercial Aviation, May 2003, pp. 200- 210.
display of identification by employees; and various access controls and surveillance
measures for the flight line.
Security Best Practices for Business and Charter Aviation
In addition to agricultural aviation and flight schools, another sector of GA with
unique security needs is business aviation. Larger, faster business jets introduce
unique security concerns because of their size and speed as well as their relatively
high value and, in some instances, the prominence of passengers carried on board
these aircraft. While business jets make up a relatively small percentage of general
aviation aircraft, their larger size, heavier payload, and faster speed introduce unique
risks. Chartered business jets and turboprops also pose a unique risk because, unlike
corporate or privately owned aircraft, flight crews often do not know their
passengers.
In coordination with the TSA, the National Business Aviation Association has
implemented a program promoting aviation security best practices among business
aircraft operators. 80 The program focuses on various facets of operator security
including identifying security roles within an operator’s organization; providing
security training to flight department personnel; establishing sound physical security
measures to control access to facilities and aircraft; issuing photo IDs for crew
members; conducting pre- flight security inspections of aircraft; matching baggage to
passengers; maintaining positive control of baggage; and developing and keeping up
to date site specific security and emergency response plans.
The TSA Access Certificate Program. Based in part on the NBAA’s
initiatives regarding aviation security best practices, the TSA initiated a pilot
program for implementing security protocols for business aircraft operators in the
spring of 2003. The program, dubbed TSAAC for TSA Access Certificate, is
currently being implemented on a trial, proof- of- concept basis at select airports on
the east coast. Corporate aircraft operators that implement TSA- approved security
programs under TSAAC are currently granted unimpeded access to international
airspace, whereas other operators must currently enter and depart U. S. airspace
through one of eight designated " portal" countries. 81 The TSAAC program was
initially offered as a pilot program to operators based at Teterboro Airport ( TEB) in
New Jersey. The program has since been expanded to include operators at
Westchester County Airport ( HPN) in New York, and Morristown Airport ( MMU)
in New Jersey. While the specifics of the TSAAC program are regarded as security
sensitive information, the program generally requires operators to implement security
procedures similar to the operational security measures required for charter aircraft
operators who fly aircraft weighing more than 12,500 pounds. Elements of the
program include various aspects of physical security measures for aircraft, vetting of
customers and other visitors, control of passengers and baggage, access controls for
the flight line and aircraft operations areas, and the utilization of threat intelligence.
CRS- 34
82 National Business Aviation Association. TSA Access Certificate ( TSAAC) – Updated
December 23, 2003. Washington, DC: National Business Aviation Association, Inc.
83 Transportation Security Administration. TSA and National Business Aviation Association
to Expand General Aviation Security Partnership Program. Press Release, December 30,
2004.
84 Transportation Security Administration. Ronald Reagan Washington National Airport:
Enhanced Security Procedures for Certain Operations; Interim Final Rule. Federal Register,
70( 137), 41586- 41603 ( July 19, 2005).
85 See CRS Report RS22234, Protecting Airspace in the National Capital Region, by Bart
Elias.
The TSAAC is regarded by many in the industry as being a means for business
aircraft operators to gain "... equal access to airspace and airports as currently given
to scheduled air carriers." 82 This may include access to various flight restricted areas
throughout the United States. While the TSAAC has been hailed by the business
aircraft industry as a potential model for broader security initiatives covering the
business aircraft sector of GA, the program has been slow to evolve and is still
limited in its scope of applicability. While it was announced on December 30, 2004
that the TSAAC program would be further expanded to additional airports83,
progress to evaluate and identify additional benefits of the program have slowed.
Report language submitted by the House Committee on Appropriations ( H. Rept. 109-
241; P. L. 109- 90) signaled strong support for the TSAAC program, encouraging the
TSA to move forward with the program during FY2006.
Access to Ronald Reagan Washington National Airport. TSAAC has
been regarded by many in the business aviation community as a model for granting
business aircraft operators access to restricted airspace. Toward that objective, the
TSAAC served as an important starting point for implementing regulations allowing
GA flights to resume at the Ronald Reagan Washington National Airport ( DCA) as
mandated under Vision 100 ( P. L. 108- 176). Because DCA is in such close proximity
to Washington, DC, it had generally been off limits to GA operators since the
terrorist attacks of September 11, 2001. However, on August 18, 2005, DCA
reopened to GA operators on a very limited basis under an interim final rule detailing
extensive security requirements for GA operators to gain access to the airport. 84 In
addition to adhering to security protocols similar to those outlined in the TSAAC
program, operators wishing to fly to and from DCA must: have their flight crews
cleared by background checks; submit passenger and crew member names for vetting
against terrorist watch lists; submit to physical screening of passengers, crew
members, and baggage; transition into DCA from one of 12 designated gateway
airports; and post designated armed security officers on each flight to and from DCA.
Operators must reimburse the TSA for the direct costs associated with these security
measures which in effect makes access to DCA cost prohibitive for most GA
operators. As currently implemented, the security provisions for access to DCA are
designed primarily to accommodate larger charter operators and high- end corporate
aircraft. The program is not currently available to privately- owned aircraft, but the
TSA indicated that the program may be expanded in about one year based on the
initial experience with charter and corporate operators. 85
CRS- 35
86 See Title 49, Code of Federal Regulations, § 1544.101( e).
87 See Title 49, Code of Federal Regulations, § 1544.101( b) and ( f).
Security Measures for Charter Operations. While corporate and
privately owned aircraft primarily deal with passengers known to the pilots and
operators, passenger charter aircraft present unique security challenges because
customers are sometimes unknown or unfamiliar. Charter aircraft weighing more
than 12,500 pounds maximum takeoff weight must adhere to specific security
regulations referred to as the twelve- five security program in reference to the aircraft
weight criteria. 86 Twelve- five security program requirements include passenger
identification checks, fingerprint- based criminal history records checks for flight
crew members, application of specific bomb and hijacking notification procedures
and requirements, and implementation of a TSA- approved operator security program.
Each operator must designate a security coordinator within the organization, provide
training and information to employees with security- related duties, and have
procedures in place to coordinate with law enforcement entities responding to
security threats. Although cockpit doors are not a requirement for twelve- five
operations, if an aircraft has a cockpit door, procedures must be in place to restrict
access to the flight deck.
In addition to these requirements of the twelve- five security program, operators
of passenger charter flights in aircraft weighing more than 100,300 pounds maximum
gross weight or and aircraft with 61 or more passenger seats must implement
additional security measures laid out in the TSA’s private charter program, including
a requirement for physical screening of passengers and accessible baggage. 87 Also,
regardless of aircraft weight, if a passenger- carrying charter flight loads or unloads
passengers at a designated sterile area of a commercial airport ( that is, beyond the
security screening checkpoint), that operation must also adopt the private charter
security program. The private charter program prohibits passengers from carrying
weapons, explosives, and incendiary devices, and requires that metal detectors and
x- ray systems used in the screening of charter passengers meet standards established
by the TSA. However, physical screening of passengers can be conducted by TSA-approved
private screeners and is not typically carried out by federal screeners unless
arrangements are made to enplane and deplane from the sterile area of commercial
airports. Private charter operators of these larger aircraft must establish procedures
to prevent unauthorized access to aircraft and other access controlled areas as
specified in t