HOSTILE DRONES:
THE HOSTILE USE OF DRONES
BY NON-STATE ACTORS
AGAINST BRITISH TARGETS
January 2016

The Remote Control project is a project of the Network for
Social Change hosted by Oxford Research Group. The
project examines and challenges changes in military
engagement, in particular the use of drones, special
operations forces (SOF), private military and security
companies (PMSCs) and cyber and intelligence activities.

Chris Abbott is the founder and executive director of Open Briefing. He is
also an honorary visiting research fellow in the School of Social and
International Studies at the University of Bradford and was the deputy
director of the Oxford Research Group until 2009.
Matthew Clarke is an associate researcher at Open Briefing. He is also a
freelance campaigner and analyst. He has worked in business, politics and
the European NGO community.
Steve Hathorn is a senior analyst at Open Briefing. He is an intelligence
analyst with nearly 30 years’ experience in the British Army, Defence
Intelligence Staff, National Criminal Intelligence Service, United Nations,
International Criminal Court and the National Crime Agency.
Scott Hickie is a senior analyst at Open Briefing. He is also a senior policy
officer for the New South Wales government. He is a former political
adviser and lawyer.
Open Briefing is the world’s first civil society intelligence agency.
Founded in 2011, its mission is to keep those striving to make the world
a better place safe and informed. It provides groundbreaking intelligence
and security services to aid agencies, human rights groups, peacebuilding
organisations and concerned citizens. It does this so that a stronger civil
society can promote alternatives to armed conflict, protect human rights
and safeguard the environment. Open Briefing is a bold and ambitious
nonprofit social enterprise. It is a unique international collaboration of
intelligence, military, law enforcement and government professionals
working tirelessly behind the scenes to make a difference.
www.openbriefing.org
Published by the Remote Control project, January 2016
Remote Control Project
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Cover image: Pieces of a Hezbollah UAV (Unmanned aerial vehicle) that
was taken down by the Israeli Air Force. Wikimedia Commons, Flickr/
Israel Defense Forces
This report is made available under a Creative Commons license. All
citations must be credited to The Remote Control Project and Open
Briefing.

Contents

Executive Summary									 1
Introduction											 2
Assessment of commercially-available unmanned vehicles 		

4

Unmanned aerial vehicles 						

4

Unmanned ground vehicles			
Unmanned marine vehicles

			
				

6
8

Assessment of known drone use by non-state actors			

10

Lone wolf										

10

Terrorist organisations

				

11

Insurgent groups 									

12

Organised crime groups 								

12

Corporations										

12

Activist groups 									

13

Drone countermeasures 								

14

Regulatory countermeasures 						

15

Passive countermeasures 								

16

Active countermeasures						

		

17

Conclusions and policy recommendations 					

19

			

Executive Summary

Ever-more advanced drones capable of carrying sophisticated imaging
equipment and significant payloads are readily available to the civilian
market. Unmanned aerial vehicles (UAVs) currently present the greatest
risk because of their capabilities and widespread availability, but
developments in unmanned ground (UGVs) and marine vehicles (UMVs)
are opening up new avenues for hostile groups to exploit.
A range of terrorist, insurgent, criminal, corporate and activist threat
groups have already demonstrated the ability to use civilian drones
for attacks and intelligence gathering. The best defence against the
hostile use of drones is to employ a hierarchy of countermeasures
encompassing regulatory countermeasures, passive countermeasures
and active countermeasures.
Regulatory countermeasures can restrict the capabilities of commercially
available drones and limit the ability of hostile groups and individuals to
procure and fly drones. Policymakers should pass stricter regulations
limiting the capabilities of commercially available drones in the key
specifications affecting hostile drone operations, particularly payload
capacity. Particular attention should be paid to limiting the attack and
ISR capabilities of UAVs and the attack capabilities of surface UMVs.
Manufacturers should be required to install firmware that includes the
GPS coordinates of no-fly zones around sensitive fixed locations. Finally,
civilian operators of drones capable of carrying payloads should be
licenced and the serial numbers of purchased drones registered.
Passive countermeasures alert security to the presence of any drone
within a no-fly zone or defensive perimeter around a static or mobile
target. They limit the ability of hostile groups and individuals to guide a
drone onto a mobile target or target of opportunity or take evasive action
against any kinetic defences. The British government should support the
research and development of commercial multi-sensor systems capable
of detecting and tracking drones within a target area. The government
should also make funding available to police forces and specialist units
for the purchase of early warning systems and other passive drone
countermeasures, including radio frequency jammers and GPS jammers.
The government should also relax the regulations restricting the use of
radio frequency jammers for protection against hostile drone use around
defined key sites.
Active countermeasures can be deployed against drones that still
represent a threat despite passive systems being employed. However,
the active countermeasures currently available for use in non-military
settings are limited. The British government should support the research
and development of innovative less-lethal anti-drone systems, such as
directional radio frequency jammers, lasers and malware, and set out
clear guidelines for the police and military use of kinetic weapons against
hostile drones as a last line of defence.
However, such countermeasures are not foolproof. Furthermore,
there is also the very real chance that, as with drones themselves,
countermeasures will be deployed in turn by some threat groups against
British police or military drones. The technology of remote-control warfare
is impossible to control; the ultimate defence is to address the root drivers
of the threat in the first place.

1

Hostile drones: The use of civilian drones by non-state actors against British targets

Introduction

After long and frequently controversial use by the military, unmanned
vehicle technology is now being widely employed in numerous civilian
settings. There are unmanned vehicles (or drones) for use in the air
(UAVs), on land (UGVs) and on or under the sea (UMVs). Drones are
used for leisure and to monitor crops, take aerial photographs, track
hurricanes, protect wildlife, monitor traffic, deliver parcels, undertake
search and rescue operations and monitor disaster zones. As with many
preceding technologies, civilian drones are also used for less benign
purposes, including snooping and harassment, drug trafficking and
smuggling contraband into prisons.
Ongoing large-scale commercial investment has led to civilian drones
becoming cheaper, able to operate over longer ranges and capable of
carrying ever-larger payloads. The pace of development has accelerated
in recent years, with a vast range of models now available to the civilian
customer. There are hundreds of models available, ranging in size from
that of an AA battery to prototypes capable of carrying a person.
The legislation governing the civilian use of drones is still evolving. It is
struggling to keep up with the speed at which innovative uses are being
identified and new drones developed. There are growing concerns over
the use of drones by private individuals with little knowledge of aviation
rules. In July 2015, the US Department of Homeland Security distributed
an intelligence assessment to law enforcement agencies warning of the
possibility of criminal or terrorist groups using unmanned aerial vehicles.
In February 2015, the House of Lords EU Select Committee called for
the mandatory registration of all civilian drones in the United Kingdom.
As legislation stands, anyone can buy a drone and immediately operate
it without any training or a license, as long as the drone weighs less than
20 kilograms and it is not being used for commercial purposes. While
there are minimal regulations specifically governing the use of ground
and marine drones, aerial versions must not be flown within 150 metres of
any populated area or 50 metres of any other person, vehicle or structure.
The operator is also required to keep the drone in sight, within 500 metres
and below 400 feet in altitude. While these simple rules will be followed
by the majority of leisure users, those with more nefarious motivations
will be less inclined to adhere to them. Even if followed, the regulations
cannot account for operator error or technical drone failures. The
regulations surrounding UGVs and UMVs are less clear, though existing
maritime navigation rules and motor vehicle regulations will likely apply
and combat vehicles will likely be covered by existing import/export arms
control regimes.
This report details the findings of our study into the hostile use of
drones by non-state actors against British targets. While the focus
is on unmanned aerial vehicles, we have examined the designs and
capabilities of over 200 current and upcoming unmanned aerial, ground
and marine systems in order to understand the threat these platforms
pose to potential targets. The previous hostile use of drones by non-state
actors is also examined. A range of terrorist, insurgent, criminal, corporate
and activist threat groups using drones for attacks and intelligence
gathering are identified. The report outlines specific recommendations on

Remote Control Project

2

the strategies available to mitigate the threat of
the hostile use of drones by non-state actors in
the short to medium term.
There is no doubt that unmanned vehicles
are here to stay and will have a considerable
impact on society, both beneficial and
detrimental. Although there is still a large gap
between the capabilities of military and civilian
drones, commercially available drones are
giving hobbyists, companies and hostile groups
access to capabilities previously only available
to the military. Law enforcement agencies
and policymakers are struggling to respond
appropriately to this development. This report is
a contribution to countering that threat.

3

Hostile drones: The use of civilian drones by non-state actors against British targets

Assessment of commercially-available
unmanned vehicles
Unmanned aerial vehicles
The civil and commercial market for unmanned aerial vehicles has
grown significantly over the last five years. The increasing uptake by the
commercial sector is clearly evidenced in the growing numbers of US
Federal Aviation Administration (FAA) exemptions for drone operators to
fly UAVs in the National Airspace System (NAS),1 with the exemptions
list showing a broad range of UAV technologies, uses and capabilities.2
The UK Civil Aviation Authority (CAA) also has a similar licensing regime
for operators using UAVs for commercial aerial work and equipped for
data acquisition. As of 11 September 2015, the CAA has issued 1,036
current UAV licences, with an estimated 37% of licences for models in the
7-20 kilogram weight class.3 The civil or hobbyist market is also showing
significant growth. Some estimates have the global civil and commercial
UAV sector valued at €563.7 million (£418 million).4
UAVs are commercially available as off-the-shelf Ready to Fly (RTF), Bind
and Fly (BNF – with customisable transmitter) and Plug and Fly (PNF
– with customisable transmitter, receiver, battery and charger). Users
with no prior UAV flying experience can procure RTF models, and more
experienced and knowledgeable users can purchase fully-customisable
PNF models. Most commercially available models are rotary multicopter
UAVs coming in quadcopter (four propellers), hexacopter (six propellers)
and octocopter (eight propellers) variants. Fixed-wing UAVs are more
frequently used for commercial deployments in agriculture, public safety,
emergency response and ISR. Many UAV manufactures sell individual
components, enabling customers to build fully-customised drones. This
allows users to achieve specific capabilities, such as flight time, payload
capacity, programmable flight, maximum speed and weather hardening.
Table 1 lists the most popular and readily-available commercial UAVs
across three price points (low end, mid level and high end) and provides
basic specification information.
Our analysis of the 202 commercially-available drones listed on the
product comparison site SpecOut.com reveals that the listed drones
have an average flight time of 18 minutes, an average range of 1,400
metres and median price of $600 (£390).5 Our analysis of FAA Section
333 exemptions indicates that in the United States the agricultural and
film sector are using UAVs with the largest capacity for heavier payloads,
most likely a result of needing to carry larger sensor and imagery
equipment. The public safety, emergency response and infrastructure
inspection sectors appear to be relying upon UAVs with greater capacity
for all-weather conditions.

1
Section 333 FAA Modernization and Reform Act of 2012 (FMRA).
2
https://www.faa.gov/uas/legislative_programs/section_333/333_authorizations/
and http://auvsilink.org/advocacy/Section333.html.
3
https://www.caa.co.uk/docs/1995/SUA%20Operators%2011Sep15.pdf.
4
INEA Consulting (2014), Global Commercial and Civil UAV Market Guide 20142015.
5
http://drones.specout.com.

Remote Control Project

4

Specifications affecting hostile UAV
operations

such as LiDAR or infrared camera, or other
environmental sensors. Despite some highprofile interest, such as Amazon’s nascent
Prime Air service, logistics and transport
companies have not embraced the use of
UAVs because many commercially available
platforms have insufficient carrying capacity for
goods.

A number of specifications are critical to the
capabilities and uses of aerial drones. Users
seeking greater payload capacity, flight time
and range will most likely build customised
drones from individual components to
specification, requiring some basic technical
knowledge. The specifications most relevant to
UAV operations include:

Range
Commercially available UAVs are generally
limited in range by signal transmission and
image relay distance and battery power (flight
time). This means a pilot must be within a
particular proximity of the UAV and that flights
cannot span a significant distance. Flight
time due to power constraints can be partially
managed by interrupting flights for battery
changes.

Payload
Most RTF and BNF UAVs have a limited
payload capacity beyond that required for a
gimbal, camera and battery. Those with larger
capacity payloads are UAVs aimed at carrying
a broader range of imagery capture hardware,

Table 1. Select list of commercially available UAVs

5

Model

Weight

Payload

Flight
time

Range

Max
speed

Camera

Operating
conditions

Price

Parrot BeeBop

0.4 kg

0 kg

12 mins

250 m
(extendable)

29 mph

Yes
(14MP)

Dry
conditions
only

£700-900
(RTF)

Blade 350 QX2

1 kg

0.2 kg

10 mins

1,000 m

32 mph

Yes

Dry
conditions
only

£200-300
(RTF)

3DR IRIS+

0.9 kg

0.2 kg

16 mins

800-1,000 m

40 mph

Yes

Dry
conditions
only

£500-600
(RTF)

DJI Phantom 2 Vision +

1.2 kg

0.2 kg

25 mins

600 m

33 mph

Yes
(14MP)

Dry
conditions
only

£800-1,200

DJI Phantom 3
Professional

1.2 kg

0.3 kg

28 mins

1,900 m

35 mph

Yes
(12MP)

Dry
conditions
only

£1,000-1,200

Walkera Scout X4

1.7 kg

0.5-1.0 kg

25 mins

1,200 m

40-50
mph

Yes

Dry
conditions
only

£700-900

Yuneec Q500 Typhoon

1.1 kg

0.5 kg

25 mins

600 m

54 mph

Yes
(12MP)

Dry
conditions
only

£900-1,100
(RTF)

SkyJib-X4 XL Ti-QR

15 kg

7.5 kg

15 mins

3,000-25,000
m

24 mph

Yes

Wind

£7,500-8,000

Altura Zenith ATX8

3.1 kg

2.9 kg

45 mins

1,000 m

44 mph

Yes

Light rain/
snow

£15,00020,000

MicroDrones MD4-1000

2.65 kg

1.2 kg

88 mins

5,000 m

26 mph

Yes

Light rain/
snow

£20,00030,000

Hostile drones: The use of civilian drones by non-state actors against British targets

Weather proofing
Most low-end and mid-level commercial
UAVs have limited operating conditions.
The ability to operate in a broader range of
weather conditions, such as high winds, rain
and snow, is generally found in the more
expensive commercially available drones, as
weather hardening adds weight, which has
cost implications. Compared to military-grade
UAVs, such as AeroVironment’s Puma AE (All
Environment) model, commercial UAVs have a
limited ability to operate in harsh, unpredictable
and extreme climatic environments.
Commercial UAV users could retrofit weather
hardening to drones, though the extra weight
would likely reduce flight time and payload
capacity unless power or the number of rotors
was also increased.
Imaging
Most UAVs have medium- to high-resolution
cameras (at least 12 megapixels) and the
ability to capture both stills and video. The use
of a gimbal can allow manual and electronic
camera rotation, providing greater situational
awareness. Civilian UAV operators can install
LiDAR and infrared cameras on UAVs.
Automated and programmable piloting and
Follow Me settings
Most commercially available drones can be set
to fly a predetermined flight path based on GPS
coordinates (fly-by-wire). Newer models also
have Follow Me autopilot settings that enable
the UAV to automatically follow the operator.

Unmanned ground vehicles
Unmanned ground vehicles have been
available for several decades. The simplest
example, as reportedly used by Islamic State
(IS) in Iraq, is the familiar remote controlled car.
At the other end of the spectrum, the first fullyautonomous road vehicles for the commercial
market and advanced military robotics are
being developed.
There are two categories of UGVs. The first
are remote controlled vehicles piloted by
humans who are in full control of the vehicle
but driving it but from a distance. These include
the Modular Advanced Armed Robotic System
(MAARS) used by the US Army. The second
are autonomous drones that drive themselves

Remote Control Project

using algorithms, sensor inputs and pre-set
waypoints. These include the Mobile Detection
Assessment and Response System (MDARS)
used by the US Army and Navy, and the
Google Self-Driving Car Project.
UGVs have a large range of applications – from
hobbyists using remote controlled cars for
entertainment and leisure to the military using
vehicles capable of operating in dangerous
regions and environments, including for
disarming explosives.
For the hobbyist, commercially available small
remote controlled cars can travel up to 35 mph
over rough ground, cost between £40 and
£1,200, and can drive for 15 to 90 minutes over
relatively short distances. They tend to have
very limited payloads but could be customised
to include cameras. In contrast, the military and
defence sector use of UGVs is well established
and increasing. This includes vehicles such as
the RipSaw, a commercially available UGV the
US Army equipped with weapons and used in
Iraq. The Ripsaw is priced at approximately
$250,000 (£165,000) and is capable of driving
at up to 95 mph, carrying a 900 kilogram
payload. The US Army used over 6,000 UGVs
in Iraq and Afghanistan for ISR missions
and counter-IED tasks.6 South Korea is also
reportedly using stationary armed surveillance
‘robots’ in the demilitarised zone along the
border with North Korea. While there is limited
commercial availability of military-grade UGVs,
variants of models such as the I-Robot 110
and Mil-Sim A5 Robotic Weapon may enter a
broader commercial market in the future.
Due to the wide range of variations and
capabilities, it would be possible to customise
or purchase a UGV capable of carrying either
explosive payloads or cameras for relatively
modest prices and logistical difficulty. However,
it is worth noting that a comparable manned
vehicle would be significantly cheaper.
Specifications affecting hostile UGV
operations
There are only a limited number of UGV
specifications affecting operations that are
applicable to all classes of UGV. The diversity
in technological capabilities makes pinpointing
operational limitations challenging.

6
http://www.isn.ethz.ch/Digital-Library/Articles/
Detail/?id=186583.

6

Mobility and speed

thorough understanding of on-the-ground
environments.

UGVs can move across ground terrain in a
range of modes and vehicle configurations.
There is an important relationship between
the ability of a UGV to move across diverse
all-terrain environments, such as hills,
obstructions, semiaquatic or flooded areas and
uneven surfaces, and the speed with which a
vehicle can move. For example, the average
remote controlled car may have a reasonably
high top speed but be unable to traverse
uneven terrain very well. On the other hand,
counter-IED UGVs with caterpillar tracks have
a far greater capacity to negotiate diverse
terrains but at much lower speeds.

Payload
The payload capacity of UGVs varies widely.
As with most types of unmanned vehicles,
there are obvious speed and mobility to
payload weight trade-offs. In most instances, a
commercial UGV or remote controlled car will
have a higher payload capacity than hobbyist
UAVs, but the UAV operator has greater visual
awareness and manoeuvrability.
Range
Most remote controlled UGVs have limited
range, though higher end models used by
special operation forces are likely to be tailored
for specific missions. Ranges for counter-IED
and bomb disposal operations are likely to be
based on average blast radius. For models
used in hazardous material inspection or site
contamination, a range of one kilometre should
be sufficient to protect the operator. The range
a hostile operator will require is dependent
on the level of risk they are willing to expose
themselves to depending on the target. In
reality, the effective range is also dependent on
the type of terrain the vehicle has to travel over
to reach its target.

Imaging
UGVs, particularly smaller vehicles that
operate low to the ground, provide only limited
situational awareness to operators, particularly
in contrast to UAVs. Without telemetry systems,
navigation based solely on video stream is
likely to significantly limit the effectiveness of
some UGVs. While UAVs provide superior
visual situational awareness from a distance,
UGVs fitted with more advanced environmental
sensors, such as thermal imagers and chembio sensors, may offer operators a more

Table 2: Select list of UGVs

7

Model

Weight

Operating
environment

Range

Max
speed

Camera

Components

Price

Happy Cow 777-270
i-Spy

166 g

Limited

30 m

n/a

HD video/still
camera

None

£30

Jumpshot MT

n/a

All terrain

100-200 m

27 mph

No

n/a

£175

Savage XL Octane
RTR

7 kg

All terrain

100-200 m

36 mph

No

n/a

£775

Mil-Sim A5 Robotic
Weapon

90 kg

All terrain All
weather

215-500 m

50 mph

IR/low lux with
night vision

Armed with lethal or nonlethal munitions

£2,5006,500

I-Robot 110 First
Look

2.5 kg

All terrain
All weather
Waterproof

200 m

3 mph

4 built-in
cameras
(front, rear
and sidefacing)

Can add specialised
cameras, thermal imagers,
chem-bio sensors and
charge deployment
accessories

£13,000£15,000

MATILDA (Mesa
Associates’ Tactical
Integrated LightForce Deployment
Assembly)

28 kg

All terrain All
weather

1,200 m

2 mph

Pan-tilt zoom
camera

68 kg payload capacity with
adaptable configurations:
sensor, attack and
manipulate

£15,000

Modular Advanced
Armed Robotic
System (MAARS)

136 kg

All terrain All
weather

800-1,000
m

7 mph

Drive and
gunnery
cameras
with thermal
imaging

Armed with lethal or nonlethal munitions

n/a

Hostile drones: The use of civilian drones by non-state actors against British targets

Unmanned marine vehicles
Unmanned marine vehicles are available in
two main classes: underwater and surface
platforms. The majority of UMVs fall into the
first category. These underwater vehicles
are designed for two principal commercial
applications: marine research and offshore oil
and gas sector activities. The 2014-15 search
for missing Malaysia Airlines flight MH370
demonstrated a further novel application
of UMVs for search and recovery. The
Association for Unmanned Vehicle Systems
International (AMVSI) has identified over
745 UMV platforms, with an estimated 75%
in some stage of development, manufacture
or deployment.7 In 2013, there were 115
active UMV platforms available in the United
Kingdom.8
The market for UMVs is smaller than the UAV
market, as it lacks the high levels of hobbyist
uptake and is far more reliant on commercial
usage. The civilian market is restricted by the
very limited capabilities of lower priced entrylevel models. However, expensive drones with
broader capabilities are becoming more readily
available. The cost of an advanced underwater
UMV can reach more than £1 million. UMVs in
this price range have the ability to travel at a
depth of 4,500-6,000 metres for up to 28 hours
and over a distance of 100 miles.9 Market
research from March 2014 estimated that
the global market for remotely-operated and
autonomous UMVs would be £1.08 billion that
year, growing to £3.15 billion by 2019.10
The two key operational attributes of
underwater UMVs are range and dive depth,
with cheaper models requiring a cable
connection in order dive below the surface.
Most underwater drones have a limited payload
(less than 10 kilograms) because of the need
to remain buoyant, and are used for visual
or sonar imaging and collection of scientific
7
https://higherlogicdownload.s3.amazonaws.
com/AUVSI/b657da80-1a58-4f8f-9971-7877b707e5c8/
UploadedFiles/AUVSIUMVCoreCapabilities08-08-13.pdf.
Note, the remaining 25% of platforms are either inactive
(10%) or insufficient information is available to determine
production or operational development (15%).
8
https://higherlogicdownload.s3.amazonaws.
com/AUVSI/b657da80-1a58-4f8f-9971-7877b707e5c8/
UploadedFiles/AUVSIUMVCoreCapabilities08-08-13.pdf (p.
5).
9
http://www.ths.org.uk/documents/ths.org.uk/
downloads/shallowwater_auv_and_usv.pdf.
10
http://www.prnewswire.com/news-releases/
unmanned-underwater-vehicles-market-worth-484-billionby-2019-252903011.html.

Remote Control Project

data. Surface UMVs are dependent on
speed, payload and range (a ‘control triangle’
comparable to the naval architects’ ‘iron
triangle’ of speed, payload and endurance).11
They are capable of carrying up to 1,000
kilograms of explosives, such as was used
in the non-drone attack on the USS Cole in
October 2000 in Yemen.
Cheaper drones and those operating nearer
to the surface are controllable by Wi-Fi up to a
range of 300 metres, giving a pilot direct control
over the drone. However, the majority of highend submersible models move using a GPSbased system of waypoints. It is still possible
for a pilot to maintain some level of control
by changing the drive-to GPS coordinates
or depth levels via acoustic messages and
satellite communication; however, this form of
control is limited at best, and the pilot could
not, for example, navigate a submersible drone
through a confined space. Due to the high
cost and variable commercial use, underwater
marine drones tend to be highly customisable.
Features such as the basic outer shell,
navigation, energy and propulsion components,
and payloads, such as cameras or sonar
equipment, are customisable.
Specifications affecting hostile UMV
operations
There are several factors that affect UMV
operations. Typically, higher-cost drones
feature significantly greater payload capacity,
imaging capability, range and depth than lowercost drones.
Payload
Payload capacity is affected by two factors:
internal space and the buoyancy of the
drone. A payload that is above the buoyancy
weight will cause the drone to sink at a rate
proportional to the weight variance. A payload
below the buoyancy can be offset by the
drone’s navigation facilities, including filling
the buoyancy tanks to achieve a neutral
level. Any space left in the payload chamber
of underwater UMVs can be filled with high
buoyancy foam to increase the potential
payload weight. Higher-end UMVs will have
more space for packages as well as higher
natural buoyancy levels. The entry level drones
may lack any payload capacity.
11
http://www.rand.org/content/dam/rand/pubs/
research_reports/RR300/RR384/RAND_RR384.pdf.

8

Speed

Range

Speed is determined by the engine output and
the shape and weight of the craft. The engine
output of underwater models is very low, with
top speeds in the region of 3-6 mph (similar to
jogging speed). The higher end of the market is
more focussed on delivering endurance rather
than speed. In contrast, speed is key factor for
surface drones, which can reach speeds of up
to 30 mph.

The range of a drone is not determined by
controller range if the UMV is capable of
satellite or GPS communication. If this is the
case, provided the drone remains in contact
with the GPS network, the range is determined
by the fuel capacity (generally electric batteries)
and optimal speed. A drone able to travel at 3
knots (3.45 mph) for 25 hours has an effective
range of 86.25 miles. If GPS communication
is not possible, the drone is typically limited to
either Wi-Fi controller ranges (typically up to
300 metres) or a physical cable connecting it to
a pilot (typically less than 100 metres long).

Imaging
Imaging technology tends to be placed into
the payload chamber in UMVs. This can range
from scientific instruments measuring changes
in pressure or water quality, to sonar equipment
and visual capabilities. The latter allows drones
to be used for surveillance or reconnaissance
of critical infrastructure, such as oil rigs or
offshore military equipment, including naval
vessels.

Depth
Due to the pressure placed on a vehicle that
descends under the water and the hazards
of water damage on electrical components,
the shell of a drone determines the depth to
which it can travel. Drones with shells made
of higher strength metals, such as titanium,
are able to travel deeper than those made of
cheaper metals or plastics. Depth is not a factor
when UMVs are deployed against surface
targets, but some critical infrastructure targets
have significant depth, such as oil lines and
platforms or communications cables.

Table 3: Select list of surface UMVs
Model

Weight

Payload

Fuel capacity

Max speed

Camera/ sonar

Price

C-Target 3

325 kg

0 kg

40 litres

28.7 mph

Yes

£POA

AutoNaut 3.5

120 kg

40 kg

20 litres (plus
solar panels)

3.45 mph

Yes

£POA

AutoNaut 5

230 kg

130 kg

20 litres (plus
solar panels)

4.6 mph

Yes

£POA

Table 4: Select list of sumbersible UMVs
Model

Weight

Buoyancy

Operation
time

Range

Depth

Max speed

Camera/
sonar

Estimate
price

HydroView
Pro 5M

6.4 kg

0.9 kg

180 mins

0.046 miles

100 m
(attached
to cable)

4.6 mph

Yes

$10,00015,000
(£6,5009,700)

Remus-100

37 kg

1 kg

600 mins

51.8 miles

100 m

5.18 mph

Yes

$250,000
(£163,000)

Bluefin-21

750 kg

7.3 kg

1,500 mins

86.25 miles

4,500 m

3.45 mph

Yes

$2.5 million
(£1.63
million)

A review of the known use of drones by various

9

Hostile drones: The use of civilian drones by non-state actors against British targets

Assessment of known drone use
by non-state actors
terrorist, insurgent, criminal, corporate and activist threat groups around
the world has identified two principal categories of hostile use: attack and
intelligence gathering. There are particular concerns that that drones will
be used as simple, affordable and effective airborne Improvised Explosive
Devices (IEDs). Governments are also concerned by the decentralisation
and democratisation of intelligence, surveillance and reconnaissance
(ISR) capabilities made possible by the widespread availability of drones.
In contrast, this is a development that is welcomed by activists working
to hold governments and corporations to account. A brief summary of the
review is presented in the following pages. The majority of drones used
are unmanned aerial vehicles, as they are more readily commercially
available and offer more options than land- or sea-based platforms.

Lone wolf
There are many examples of individuals using drones for purposes
beyond authorised and accepted use, and these suggest scenarios for
future lone wolf attacks.
In September 2011, a 26-year-old American man was arrested by
undercover FBI agents planning to fly explosives-laden model aeroplanes
into the Pentagon and US Capitol and rig mobile phones to detonate
improvised explosive devices (IEDs). In January 2015, an off-duty
employee of the US National Geospatial-Intelligence Agency lost control
of a friend’s DJI Phantom quadcopter, which then crashed onto the White
House lawn. The incident raised concerns about the extent to which
the Secret Service is prepared for drone activity. Four months later, a
man was arrested for trying to fly a Parrot Bebop drone over the White
House fence. In France, unidentified drones have been flown over the US
embassy, the Eiffel Tower, the Invalides military museum, the submarine
communications base at Sainte-Assise, the Place de la Concorde, the
Elysee Palace and multiple nuclear power stations. In June 2014, an
unidentified drone was used to monitor the French national football team
during a closed training session at the 2014 World Cup in Brazil. In July
2014, an unidentified drone came within six metres of an Airbus A320
as it landed at London’s Heathrow Airport, prompting the Civil Aviation
Authority to issue new safety guidelines, known as the ‘dronecode’. In
October 2015, an unidentified drone crashed into the Sydney Opera
House.
Fortunately, there has so far been very few instances of individual
terrorists using drones to undertake attacks. What could be was
demonstrated in April 2015 when a man landed a drone on the Japanese
prime minister’s office in Tokyo. The drone was carrying a bottle
containing radioactive sand from Fukushima, which was emanating up to
1.0 microsievert per hour.
In a response to a freedom of information request by Open Briefing, the
Metropolitan Police Service revealed that between January 2013 and
August 2015, 20 suspicious drone related incidents had been recorded
in and around London.12 Sixty per cent of the disclosed incidents
related to air navigation orders where civil aviation requirements had
12
https://www.whatdotheyknow.com/request/counter_drone_
measures#incoming-702249.

Remote Control Project

10

been breached; the rest related to criminal or
illegal activity. In one case, a UAV was used
to smuggle drugs into a prison and in another
case a drone was flown over 200,000 people
on 20 December 2014.

Terrorist organisations
The Lebanon-based militant group Hezbollah
has the longest history of drone use by a nonstate group. Hezbollah reportedly maintains
a small fleet of UAVs, including Iranian Ababil
and Mirsad platforms and their Hezbollah
derivatives.13 Some reports estimate that the
fleet includes upwards of 200 platforms for ISR
and combat missions.14 In November 2004,
Hezbollah allegedly flew an Iranian UAV over
parts of northern Israel before returning to
Lebanese territory. In August 2006, Hezbollah
launched three small Ababil drones, some
allegedly carrying explosive payloads, with the
intention of attacking Israeli military targets.
The drones were shot down by Israeli F-16s. In
October 2012, Hezbollah allegedly flew a small
Ayub drone 35 miles into Israeli airspace with
the intention of undertaking reconnaissance
on a nuclear reactor. An Israeli aircraft shot the
drone down before it returned to Lebanon.
More recently, it is possible that Hezbollah
has more consistent access to Iranian UAVs,
including the Ababil-3, and are using UAVs
against al-Nusra Front fighters in Lebanon.
In September 2014, the Fars News Agency
reported that Hezbollah had achieved its first
successful drone strike, killing an estimated
23 ‘Syrian rebels’.15 In April 2015, IHS Jane’s
published evidence of a Hezbollah UAV airfield
in the northern Bekaa Valley, Lebanon, that
included a UAV ground command station.16
The group is thought to be continuing to use
UAVs for ISR in the border region between
Syria and Lebanon.
Al-Qassam Brigades, the military wing of the
Palestinian organisation Hamas, is suspected
of having a small fleet of UAVs and a crude
production workshop. During Operation
Protective Edge in 2014, Israeli forces shot
13
https://medium.com/war-is-boring/thisnew-airstrip-could-be-home-to-hezbollah-s-dronesbdec97ff36a8.
14
http://www.ynetnews.com/
articles/0,7340,L-4457653,00.html.
15
https://www.youtube.com/
watch?v=gUSGNApl9XQ.
16
http://www.janes.com/article/50922/hizbullahairstrip-revealed.

11

down a potentially armed Hamas-controlled
Arbabil-1 UAV with a Patriot surface-to-air
missile. Al-Qassam Brigades advised that the
drone was only one of three that breached
Israeli airspace, though the Israeli military deny
this claim. In December 2014, a drone flyover
of a Hamas military parade resulted in Israel
scrambling fighters that returned to base after
the drone did not enter Israeli airspace.
More recently, Al-Qassam Brigades announced
that it had captured an Israeli Skylark 1 that
came down in Gaza in July 2015. The group
claimed that the drone had been repaired
and was operational. Al-Qassam Brigades
also claims to have developed three UAV
platforms, two with combat payloads and one
for surveillance.
The extremist militant group Islamic State were
shown to be using DJI Phantom UAV platforms
in Fallujah, Iraq, from early 2014. While the
early demonstrations of commercially available
drones appeared to be for propaganda
purposes only, there is emerging evidence that
these platforms are now providing actionable
ISR and target acquisition capabilities to
Islamic State.17 There are some indications
that IS used hobbyist drones to gain situational
awareness ahead of the campaign to capture
the Tabqa military airfield in northern Syria in
August 2014. In March 2015, US military forces
launched an airstrike against an IS militant who
had been flying a UAV over Fallujah. In April
2015, Islamic State released a video showing
UAVs being used for reconnaissance and
battlefield coordination during its assault on the
Baiji oil refinery complex in Iraq.18 In May 2015,
the Kurdish Peshmerga shot down an IS drone
that had been filming their positions. In August
2015, there were reports that Kurdish soldiers
had captured a remote controlled car carrying
explosives that had failed to detonate. In the
same month, US Central Command released
a list of airstrike targets around the world,
including ‘an ISIL drone’ near Ramadi in Iraq.19
There are significant barriers to planning and
carrying out a major terrorist attack of any
sort. The intelligence work carried out by the
17
https://medium.com/war-is-boring/islamic-statehas-drones-7827987c1755.
18
http://www.longwarjournal.org/archives/2015/04/
islamic-state-uses-drones-to-coordinate-fighting-in-baiji.
php.
19
http://www.centcom.mil/en/news/articles/august3-military-airstrikes-continue-against-isil-terrorists-in-syriaand.

Hostile drones: The use of civilian drones by non-state actors against British targets

British security services provides a robust
line of defence against terrorist groups. There
have been no known examples in the United
Kingdom, Europe or the United States of
terrorist organisations using drones for either
attack or intelligence gathering. However,
Islamic State is reportedly obsessed with
launching a synchronised multi-drone attack on
large numbers of people in order to recreate
the horrors of 9/11.

Insurgent groups
Insurgent groups have many of the same
capabilities and intentions as terrorist
organisations, but do not face the same
regulatory and law enforcement barriers
to attacks on British interests as groups
attempting to use drones to launch attacks
within the United Kingdom. Drones therefore
have the potential to become significant
components of insurgents’ armouries.
Obtaining aerial, ground and marine
reconnaissance and attack capabilities would
mark a step change for many insurgent groups.
Donetsk People’s Republic (DPR) militias
in eastern Ukraine reportedly possess and
deploy sophisticated Russian-made Eleron3SV drones for ISR campaigns. In contrast, the
Ukrainian military has been using a range of
modified and tailor-made hobbyist UAVs for ISR
support. There are reports that the DPR militias
are using signal jamming and GPS spoofing
countermeasures against some Ukrainian
drones; however, more advanced autopilot
software in the tailor-made models is more
resilient against these countermeasures. The
Ukrainians have requested US military drones,
such as Reapers, and jamming equipment and
radar to better intercept the Russian-made
drones.
In August 2002, a Colombian Army unit
allegedly discovered remote-controlled
aeroplanes during a raid on a Revolutionary
Armed Forces of Colombia (FARC) camp. The
intended use of the aircraft remains unclear.

Organised crime groups
Mexican drug trafficking organisations (DTOs)
have been documented using drones to
smuggle illicit drugs across the US-Mexican
border since 2010. The US Drug Enforcement
Administration (DEA) has recorded around
150 drone trips across the border since 2012.

Remote Control Project

Nearly two tonnes of cocaine and other drugs
are estimated to have been trafficked into the
United States in this way, with an average
of 13 kilograms of drugs per shipment.20 In
January 2015, a drone that crashed in Tijuana,
Mexico, was carrying over three kilograms of
methamphetamine. In August 2015, two men
pleaded guilty to trafficking 12 kilograms of
heroin across the US-Mexican border in the
first cross-border seizure involving a drone.
In the face of increasingly successful military
and law enforcement operations against illicit
drug smuggling in the early 1990s, Colombian
drug cartels began to invest in producing narcosubmarines as an alternate to small planes and
go-fast boats. In August 2005, US authorities
captured an unmanned semi-submersible in the
Pacific Ocean. This was a torpedo-style cargo
container, rather than a self-propelled vessel,
which was towed underwater behind a boat
and released if a patrol ship was spotted. The
narco-torpedo would then release a buoy with
a location transmitter system so that it could
be retrieved later. In July 2010, the Ecuadorian
police and navy found a jungle shipyard
containing a 22.5-metre long narco-submarine.
The advanced ‘supersub’ had a camouflaged
hull made of Kevlar and carbon fibre and a
cargo bay capable of holding over eight tonnes
of cocaine. The high level of sophistication
apparent in the various captured nacrosubmarines and the huge resources available
to the DTOs means that it is highly likely that
they are now investing in remotely-piloted
submersible vessels in addition to custommade UAVs.

Corporations
There have been isolated examples of drones
being used to obtain commercially sensitive
information, such as drones flying over the
filming of Game of Thrones in Ireland, Apple’s
new campus site being built in Cupertino
in the United States and the BAE Systems
facility in northern England that builds
submarines for the Royal Navy. However,
there have been no documented examples
of corporations using drones for commercial
advantage or espionage. However, there is
a broad range of threat scenarios whereby
drones are integrated into corporate espionage
operations alongside cyber offensives and
20
http://www.insightcrime.org/news-briefs/mexicos-cartels-building-custom-made-narco-drones-dea.

12

spear phishing campaigns. A likely scenario
involves using drones as a means to deploy a
malware payload over specific Wi-Fi networks.
The leaked emails of Italian spyware vendor
Hacking Team suggest that early concept plans
for using drones for airborne malware delivery
over Wi-Fi networks were being discussed with
Insitu, a division of Boeing.21
One offensive scenario is the use of crowd
control drones by British companies against
strikers or demonstrators threatening foreign
operations. An example of such a drone is the
Desert Wolf Skunk, which is equipped with four
high-capacity paint ball barrels that can fire a
variety of ammunition, including pepper spray
balls and plastic balls. The drones can be flown
in formation by a single operator. In what the
South African company calls a ‘life threatening
situation’, each drone can fire 80 balls per
second, allowing for ‘real stopping power’.22
Desert Wolf reportedly sold 25 Skunks to an
international mining company after a photo
of the drone was featured on a military news
website in May 2014.

groups have used UAVs to remotely capture
farming, animal husbandry and animal
testing practices in the United States. In April
2015, a man protesting over the Japanese
government’s nuclear energy policy landed a
drone containing radioactive sand on the roof of
the Japanese prime minister’s office in Tokyo.
Although the use of drones by activists is
still uncommon, the most likely way in which
drones will be used by such groups in future
is in undertaking publicity-seeking exercises
in front of the media or filmed using onboard
cameras. Activists could also use drones
to assist existing campaign efforts through
reconnaissance and surveillance.

Activist groups
Although clearly not presenting a threat of the
same type or magnitude as the other threat
groups discussed in this briefing, activists
have employed drones to support their political
campaigns on a number of occasions. In
September 2013, the German political party the
Pirate Party flew a Parrot quadcopter towards
the German chancellor, Angela Merkel, during
a campaign rally in Dresden.23 The stunt was
in protest against the German government’s
surveillance policies. In October 2014, Greater
Albania activists flew a drone carrying the
Greater Albania flag over an Albania-Serbia
football match.24 Greater Albanian’s claim
territory from Albania’s neighbours, including
Serbia. In July 2015, Women on Waves
delivered pregnancy termination pills by drone
from Germany to Poland to highlight restrictive
abortion laws in Poland. Animal rights activist
21
https://theintercept.com/2015/07/18/hackingteam-wanted-infect-computers-drone/.
22
http://www.desert-wolf.com/dw/products/
unmanned-aerial-systems/skunk-riot-control-copter.html.
23
https://www.youtube.com/
watch?v=WcFiMCMbUHo.
24
https://www.youtube.com/
watch?v=hJSQf737Agw.

13

Hostile drones: The use of civilian drones by non-state actors against British targets

Drone countermeasures

There are two theatres in which non-state actors could use drones as
either an offensive weapon against the United Kingdom and its interests
or as an intelligence gathering tool:
1. The international theatre, consisting of all British military operations,
embassies and commercial sites and operations abroad. These
are vulnerable to attack by terrorist or insurgent groups or to being
targeted by activist groups protesting against government policy or
the actions of British corporations.
2. The domestic theatre, consisting of critical national infrastructure,
military sites, government buildings and tourist sites within the United
Kingdom. These are vulnerable to terrorist attacks, disruption by
activist groups or corporate espionage.
There are three key defence scenarios, which range from easier to target/
easier to defend to harder to target/harder to defend:
1. The long-term static target, such as a foreign embassy or nuclear
power station.
2. The temporary static target, such as a G7 summit or a speech by a
politician.
3. The mobile target, such a military supply convoy or the prime
minister’s car.
The UK government, police, military and security services will need to
introduce countermeasures to reduce or mitigate the risk of commercially
available drones being used for attack or ISR operations. These
countermeasures need to be proportionate to the risk, economically
and operational sustainable and balance interests relating to privacy,
individual freedoms, safety and commercial interest.
Drones are a unique technology providing users with significant
capabilities. Defence system against illegal or harmful use of unmanned

Figure 1: The hierarchy of countermeasures

Remote Control Project

14

vehicles should provide for ‘all hazard’
scenarios and multiple threat environments.
However, time and resource investments
should be prioritised for countermeasures that
respond to the scenarios with highest risk (high
likelihood/high impact).
No single countermeasure is completely
effective at limiting the hostile use of drones by
non-state actors. The best strategy is therefore
to employ a hierarchy of countermeasures
encompassing regulatory countermeasures,
passive countermeasures and active
countermeasures. A high-level evaluation of
the various countermeasures that are available
is provided in the following pages. The focus
is on unmanned aerial vehicles, as they
present the greatest threat, but many of the
countermeasures can be applied to unmanned
ground and marine vehicles too, and where
applicable countermeasures specific to these
vehicles have also been considered.

Regulatory countermeasures
Domestic regulations can put in place a range
of measures targeting the full supply chain
and life cycle use of drones. Regulations
would need to proportionate and balance a
range of competing safety and commercial
demands, including establishing procurement
barriers for threat actors while at the same
time encouraging innovative commercial
use and maintaining easy access to suitable
platforms for hobbyists. Specific regulatory
countermeasures may include:

15

•

Point of sale regulations, including
identification requirements for the purchase
and sale of drones above a certain level of
capability.

•

Civil aviation rules and licensing regimes
to regulate the use of drones, with harsh
penalty regimes for flying near critical
national infrastructure and sites of national
security importance.

•

Manufacturing standards and restrictions
for UAVs, including no-fly zones built in to
firmware and limits on carrying capacity
and controller range.

34 members, and the UK government is a
founding member. The MTCR aims ‘to restrict
the proliferation of missiles, complete rocket
systems, unmanned air vehicles, and related
technology for those systems.’ It is a voluntary
association of countries that share the goal
of ‘non-proliferation of unmanned delivery
systems capable of delivering weapons of
mass destruction.’25
Regulations to stop the procurement and import
of drones to the United Kingdom only cover
those weighing more than 20 kilograms or are
equipped to undertake any form of surveillance
or data acquisition at time of purchase.
Heavier drones require airworthiness approval
and those capable of surveillance are more
stringently regulated. This limited regulation
means that drones weighing less than 20
kilograms can be imported without license,
despite many drones weighing 5-20 kilograms
being capable of carrying explosives or camera
equipment; for example, the SkyJib-X4 XL
Ti-QR weighs 15 kilograms and can carry a
payload of 7.5 kilograms.
Civil aviation regulations on UAV licensing
and use
There are currently 32 countries using
regulations to control the use of drones
domestically, particularly unmanned aerial
vehicles. The scope and scale of the
regulations range from altitude or weight limits
to a complete ban on all unmanned aerial
vehicles. Regulation in the United Kingdom
is limited. Drones of any size or weight are
permitted, though they must be used within the
visual sight line of the pilot. In general, UAVs
cannot be flown above 400 feet in altitude
without special permission and must remain
clear of controlled airspace without Air Traffic
Control permission. Commercial operation
requires a license, which is given to an operator
for a particular class of UAV (small fixed wing
or small multirotor).26

Procurement and import regulations

In contrast, some countries maintain a
complete ban, while others have stringent
rules similar to those in effect in South Africa.
South Africa has a well-developed series of
regulations on UAVs, with some of the strictest
rules in the world short of an outright ban. The
operators of drones must have a valid remote

The main international regulation relating to
drones is the 1987 Missile Technology Control
Regime (MTCR). The regime currently has

25
http://www.mtcr.info/english/.
26
https://www.caa.co.uk/default.
aspx?catid=1995&pageid=16012.

Hostile drones: The use of civilian drones by non-state actors against British targets

pilot license and drones cannot be operated
without a letter of approval from the director
of the South African Civil Aviation Authority,
which is valid for 12 months. Drones must not
be flown near nuclear power plants, prisons,
police stations, crime scenes, law courts,
critical national infrastructure or strategic
installations. Regulations also prohibit drones
from being flown in formation or swarm, flown
directly overhead or within a lateral distance of
50 metres of a person or crowd, or within 50
metres laterally of any structure or building.27
There is a vigorous debate between the
innovators, users and regulators. The former
argue for a more laissez faire approach to
allow the rapid development of the civilian
drone market. They argue that if the rules of
use become restrictive now, this could smother
the sector before it properly established.
Conversely, others argue that if the rules are
too relaxed there is a high probability of misuse
with potentially disastrous consequences. As
usual, a compromise needs to be found.
Firmware limitations
The Chinese UAV producer DJI has built safety
features into the firmware (the permanent
software programmed into read-only memory)
used by its drones. The firmware maintains
several No Fly Zones based on the GPS
coordinates of the pilot’s location. There are
around 350 No Fly Zones worldwide.28 These
zones are primarily designed to keep drones
away from airports. Furthermore, within eight
kilometres of a no-fly zone, the pilot is unable to
set an automatic fly-to waypoint, forcing them
to remain in manual control of the drone near
these zones.
The No Fly Zone is currently a limited-use
tool implemented to protect airports; however,
legislation could be implemented to extend the
measure to protect other key sites. In January
2015, DJI reported that it is considering
implementing such a zone over Washington DC
after one of their drones crashed onto the lawn
of the White House. In theory, the firmware
updates to protect these sites could be hacked
and bypassed, but this would require specialist
knowledge not likely to be held by most solo
attackers at least. The company is also working
27
http://www.thedroneinfo.com/south-africa-droneregulations/.
28
http://theuavdigest.com/uav036-no-fly-zones-foruavs/

Remote Control Project

to prevent criminals from using workarounds to
circumvent such security features.
This would make it very difficult for individuals
without the technical knowledge of computer
programming and the criminal links to illegally
import drones to be able to acquire and fly
drones near sites that have been marked as
needing protecting. In effect, this limits the lone
wolf terrorist, and sends a clear message to
activists and businesses of what the legal and
illegal uses of drones are.

Passive countermeasures
Early warning systems
There are several early warning systems that
can identify a drone within a defined area.
Traditional technology such as radar and
CCTV can be effective, but new commercial
systems are being developed that specifically
alert operators to the presence of drones. Such
commercial systems include:
DroneShield is developing a system that
contains a database of common acoustic
signatures unique to drones. If a drone
is detected, DroneShield instantly alerts
security officers via text message, email
or through an existing alarm system. The
system was deployed at the 2015 Boston
Marathon. DroneShield technology is
also available for cars and vans, allowing
a VIP convoy to implement such a
detection system.
Domestic Drone Countermeasures
is developing personal and commercial
detection systems that can detect radio
frequency transmitters and triangulate
moving transmitters. The system
consists of a primary command and
control module that can communicate
with radio frequency sensor nodes up to
60 metres away, with each node typically
able to detect drones within 15 metres in
all directions.
Dedrone has developed the
DroneTracker multi-sensor detection
system, which uses an array of sensors
to detect civilian drones in real time. The
system uses microphones, a daylight
camera and an infrared camera to track
drones within a 100 metre radius, which
can be extended by deploying the units
in series.

16

Although commercial systems have the
potential to be very effective against civilian
drones, military-grade systems include
electronic warfare and radar capabilities that
make them far more effective against advanced
drones. As the counter-drone market grows,
defence companies may begin offering scaled
down versions of their military systems for use
by businesses and high-net-worth individuals.
A comprehensive early warning system would
use a combination of acoustic detectors,
thermal imaging sensors, cameras and radar.
This would allow a drone to be detected,
tracked and identified by target sites. However,
many sites lack sophisticated detection
capabilities, such as radar, and it would be
costly to install them. Companies such as a
Dedrone are developing cost-effective and
drone-specific alternatives. In some high-value
targets, such as military bases or Whitehall,
radar could be installed, but investing in
commercial systems alone would be sufficient
for most sites.
Signal jamming
Once an early warning system detects a
drone, popular drone control frequencies can
be blocked around the target using a radio
frequency jammer, such as the RCJ40-D or
PRO45 High Power (civilian) or JAM201 or
GM20 (military). It is also possible to block
these frequencies at all times, though this
would make mobile phone communications
in and around the site difficult. However,
a drone user can use a wireless intrusion
prevention system to alert them to attempted
jamming. Advanced radio receivers can use a
multi-spectrum frequency set that alternates
through little used frequencies meaning
that the receiver is harder to block. Militarygrade jammers can block a wider spectrum
of frequencies. However, frequency jamming
is illegal in the United Kingdom without
permission.
By implementing no-fly zones around critical
infrastructure, any drone detected can be
assumed to be malicious and the controller
frequencies could be blocked. However, if a
threat actor is able to hack the firmware to
override the inbuilt no-fly zones, they could
place GPS waypoints within the defensive
perimeter. If the drone was detected and
controller frequencies were blocked, the

17

drone operator would be unable to change
the coordinates or have any control over the
aircraft; however, the drone would continue
along its pre-determined route and still be
able to strike a static target. What controller
frequency blocking does is remove the threat
actor’s ability to guide the drone onto a mobile
target or target of opportunity or to take evasive
action against any active defence systems.
GPS jamming is also needed in order to
interfere with the GPS radio signal or undertake
a spoofing attack to change the drone’s
perceived coordinates and either take control of
the vehicle or cause it to crash land.
A possible alternative method for taking control
of a drone was revealed in January 2015
when a security researcher claimed to have
developed the world’s first drone malware:
Maldrone. The Python script is loaded to the
drone over a local Wi-Fi network and can
turn off the drone’s autopilot system and take
control remotely.29 However, drone malware is
currently very limited, and requires the specific
model of the targeted drone to be known. The
Maldrone demonstration does offer an idea of
what might one day be possible though.

Active countermeasures
Kinetic defence systems
For those drones that remain a threat after
the controller frequency and GPS have been
blocked, the last barrier of defence in the
hierarchy of countermeasures are systems
capable of destroying hostile drones. This
includes kinetic weapons, such as missiles,
rockets and bullets.
Israel’s Iron Dome air-defence system has
been tested for its counter-UAV capabilities,
and according to some sources can destroy
armed drones before they are in attack range.
Less-advanced kinetic defences use rockets
or bullets and require line of sight, meaning
a drone can get much closer to the target.
All kinetic systems present a risk of collateral
damage if deployed in a populated area.
Missiles and rockets fired at UAVs could cause
catastrophic damage if they miss their target. If
the drone is hit, shrapnel and wreckage could
still cause casualties on the ground. The blast
radius from a missile or rocket fired at a UGV
could include civilians near the targeted drone,
and bullets fired at UGVs could easily strike
29

http://garage4hackers.com/entry.php?b=3105.

Hostile drones: The use of civilian drones by non-state actors against British targets

passersby.
Less risky commercial options include nonlethal projectile weapons that fire blunt force
rounds, such as bean bags or rubber bullets,
or small portable net guns that can ensnare
drones. A consortium of British companies
called Liteye has developed the Anti-UAV
Defence System (AUDS) system that can
detect and track drones using electronic
scanning and radar then disrupt its operation
with a brief, focused broadcast of directional
radio frequency jamming.
Laser defence systems
Laser defence systems are being developed
that have less chance of causing causing
collateral damage than kinetic systems. For
example, a Chinese consortium of companies,
led by the China Academy of Engineering
Physics, has developed a weapon system that
can shoot down light drones at low altitude
using a 10 kilowatt high energy laser. It has a
1.2-mile range and is effective against aircraft
travelling at up to 112 mph and at a maximum
altitude of 500 metres. It can destroy the drone
within five seconds of locating its target. Boeing
is developing the truck-mounted High Energy
Laser Mobile Demonstrator for the US Army
and the Compact Laser Weapons System,
which can be assembled in 15 minutes and
destroy a drone in 15 seconds.
Laser defence systems are still in development.
However, once deployed and combined with
an early-warning system, directed energy
weapons could provide a useful counter to a
hostile drone, particularly if radio frequency
jammers and GPS jammers have also been
deployed to remove the pilot’s ability to
operate the drone. In this situation, the laser
defence system would be working against an
autonomous vehicle, making it easier to lockon to and destroy. However, such systems
might be of limited use in built-up areas, as
they can only engage drones during times of
line of sight, which may not be enough time to
destroy the drone before it reaches its target.
The fastest commercially available drones can
travel at around 50 mph, meaning a drone
could travel 112 metres in the five seconds a
laser would take to destroy it. In a domestic,
urban setting, this makes such systems most
suited to the defence of static targets with clear
lines of sight.

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18

Conclusions and policy
recommendations

It is estimated that around 200,000 civilian-use drones are being sold
worldwide every month.30 Although they are currently expensive, evermore advanced drones capable of carrying sophisticated imaging
equipment and significant payloads are readily available to the civilian
market. Unmanned aerial vehicles currently present the greatest
risk because of their capabilities and widespread availability, but
developments in unmanned ground and marine vehicles are opening up
new avenues for hostile groups to exploit.
A range of terrorist, insurgent, criminal, corporate and activist threat
groups have already demonstrated the ability to use civilian drones for
attacks and intelligence gathering. The best defence against the hostile
use of drones is to employ a hierarchy of countermeasures encompassing
regulatory countermeasures, passive countermeasures and active
countermeasures.
Regulatory countermeasures can restrict the capabilities of commercially
available drones and limit the ability of hostile groups and individuals to
procure and fly drones. However, any new regulations controlling drones
should be targeted and proportionate to the threat. The key specifications
affecting drone operations are payload capacity, range, speed, depth (for
UMVs), weather proofing, imaging and autopilot settings. Policymakers
should pass stricter regulations limiting the capabilities of commercially
available drones in the key specifications affecting hostile drone
operations, particularly payload capacity. Particular attention should be
paid to limiting the attack and ISR capabilities of UAVs and the attack
capabilities of surface UMVs. Manufacturers should be required to install
firmware that includes the GPS coordinates of no-fly zones around
sensitive fixed locations. This would automatically shut down drones
approaching these sites, thereby restricting malicious use. Finally, civilian
operators of drones capable of carrying payloads should be licenced and
the serial numbers of purchased drones registered.
Passive countermeasures alert security to the presence of any drone
within a no-fly zone or defensive perimeter around a static or mobile
target. They limit the ability of hostile groups and individuals to guide a
drone onto a mobile target or target of opportunity or take evasive action
against any kinetic defences. The military has advanced systems that
can track and destroy drones using radar, lasers and electronic warfare;
however, the market for commercial and civilian early warning systems
is at a nascent stage of development. The British government should
support the research and development of commercial multi-sensor
systems capable of detecting and tracking drones within a target area.
The government should also make funding available to police forces
and specialist units for the purchase of early warning systems and other
passive drone countermeasures, including radio frequency jammers
and GPS jammers. Radio frequency jammers are heavily restricted in
the United Kingdom; however, such equipment could provide additional
protection and security to vulnerable locations and individuals by blocking
command signals to drones. Therefore, the government should relax the
regulations restricting the use of radio frequency jammers for protection
against hostile drone use around defined key sites.
30

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http://dronelife.com/2015/01/24/drone-sales-figures-2014-hard-navigate/.

Hostile drones: The use of civilian drones by non-state actors against British targets

Active countermeasures can be deployed
against drones that still represent a threat
despite passive systems being employed.
However, the active countermeasures currently
available for use in non-military settings are
limited. Kinetic weapons – missiles, rockets
or bullets – can be very effective, but present
considerable risks of collateral damage if used
in urban civilian areas. Less risky defences
include laser systems or non-lethal projectile
weapons and net guns, but these may not
successfully destroy a hostile drone and require
line of sight, which may be difficult in heavily
built-up areas. Despite these limitations, the
British government should support the research
and development of innovative less-lethal
anti-drone systems, such as directional radio
frequency jammers, lasers and malware, and
set out clear guidelines for the police and
military use of kinetic weapons against hostile
drones as a last line of defence.
With active countermeasures still under
development or presenting a high risk of
collateral damage, the focus should be on
the swift adoption of appropriate regulatory
and passive countermeasures and increased
funding for the research and development of
effective active countermeasures. The most
effective and cost efficient measures should
be prioritised. The implementation of more
expensive countermeasures for low likelihood/
high impact events involving drones will depend
on the government’s risk appetite with regards
to specific potential civilian, government or
military targets. Combined with high-quality
intelligence on the present threat of the hostile
use of drones by various threat groups, the
recommendations outlined in this report
represent the best chance of countering the
new and evolving threat from the hostile use of
drones by non-state actors.
However, such countermeasures are not
foolproof. Furthermore, there is also the very
real chance that, as with drones themselves,
countermeasures will be deployed in turn by
some threat groups against British police or
military drones. The technology of remotecontrol warfare is impossible to control; the
ultimate defence is to address the root drivers
of the threat in the first place.

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20

Remote Control Project
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Hostile drones: The use of civilian drones by non-state actors against British targets