design of uav systems

Design of UAV Systems

Control stationsc 2003 LM Corporation 10-1

Lesson objective - to discuss

Control stationsincluding …

• Functions• Approaches• Sizing• Example problem

Expectations - You will understand the fundamentals of UAV control stations and the overall size, weight and complexity of the associated systems


Control stationsc 2003 LM Corporation 10-2

Importance

• UAV systems cannot operate without control stations

- Even if they are autonomous

• A good understanding of control station design issues and requirements are among the most important issues addressed during UAV pre-concept design

10-3


Control stationsc 2003 LM Corporation

Control Functions

Mission Planning

Mission and Payload Management Information Processing and Dissemination

Launch and Recovery

http://www.fas.org/irp/program/collect/pioneer.htm

http://www.fas.org/irp/program/disseminate/uav_tcs.htmhttp://www.fas.org/irp/program/collect/pioneer.htm

http://www.fas.org/man/dod-101/sys/ac/equip/afmss.htm

10-4



levels of control l

Level 1 -Receipt and transmission of secondary imagery or data.

Level 2 -Receipt of imagery or data directly from the UAV.

Level 3 -Control of the UAV payload.

Level 4 -Control of the UAV, less takeoff and landing.

Level 5 -Full function and control of the UAV to include takeoff and landing.

Source -http://www.fas.org/irp/program/disseminate/uav_tcs.htm

UAV Tactical Control System (TCS) Definitions

10-5



Levels of autonomy

Direct control Flight path controlhttp://www.fas.org/irp/program/collect/eagle-eye.htm

Supervised controlFully autonomous

http://www.fas.org/irp/program/collect/uav_gcs.htm

UAV Annual Report FY 1997 DarkStar

Control stick

d/dt,dh/dt and dV/dt

Attack return etc.

…or Navigation Control

10-6



Span of control

System Unique Multi-System

http://www.fas.org/irp/program/disseminate/uav_tcs.htmhttp://www.fas.org/irp/program/collect/eagle-eye.htm

10-7



Control Location

http://www.fas.org/irp/program/disseminate/uav_tcs.htm

Ground

Rear Area

ForwardArea

Sea

Air

http://www.fas.org/irp/program/disseminate/uav_tcs.htm

http://www.army.mil/armyimages.htm

http://www.fas.org/irp/program/collect/pioneer.htm

Lockheed Martin Aeronautics Company

10-8



Global Hawk example

10-9



Global Hawk MCE

10-10



Global Hawk LRE

10-11



Pioneer GCS

10-12



Predator GCS

The GCS consists of (1) a pilot position and (2) a payload operator position (interchangeable), (3) a Data Exploitation, Mission Planning and Communications position where imagery is annotated and initially exploited, and a (4) SAR workstation

Source http://www.fas.org/irp/agency/daro/predator/toc.html

30 ft x 8 ft x 8 ft commercial van

Trojan Spirit GDT

10-13



Pointer GCS

10-14



UCAV control (status)

10-15



Another common GCS

10-16



And another

10-17



Mission control issues

Manpower requirements

Weapon control concept (for UCAV)

Overall size

Estimated cost

Vehicle control concept

Payload control concept

Site requirements

Product exploitation concept

Mission planning concept

10-18



Selection considerations

• Mission planning concept - For military users, manned and unmanned aircraft will almost certainly use common mission planning tools. Example

- USAF Mission Support System (AFMSS) has individual data modules that tailor it for each aircraft in the fleet. Global Hawk and Predator missions are planned like any other aircraft

- Civilian users will probably do the same - the selection of UAV mission planning tools may be driven by what exists

• Vehicle control concept will be driven by near vs. long term cost considerations and mission needs

- Autonomy costs a lot to develop, direct control doesn’t- Autonomy will cut long term operations and support costs

10-19



Considerations - cont’d

• Payload control concept will be driven by the ConOps- If the ConOps is to bring data back for analysis,

automated payload control will be cost effective- If the ConOps requires real time data analysis and

sensor retasking, direct control will probably be required- Automation can be used to reduce operator work load

• Payload product exploitation concept will also be driven by Conops- If data is to be sent elsewhere for analysis, no on-site

processing will be required- Otherwise, significant on-site processing will be required

- Efficient data processing tools will be required to keep the task work load down and the crew size small

10-20




• The weapon control concept (for UCAV) will be driven by ConOps and weapon type

- It is highly unlikely that machines will be allowed to attack without human authorization unless a target is preplanned and fixed (like a cruise missile)

- Otherwise operator intervention and authorization to attack will be required

- The amount of information required to support a decision to attack may be substantial

- Fire and forget weapons can also be highly automated- On board guided weapons by definition require high

levels of operator involvement

10-21



• Site requirements - At a minimum, a control station will be required at the launch and recovery area- Depending on the ConOps, other control stations may

be required - Mission control is often collocated with the user of the

system or its product (Global Hawk example)- Sometimes, multiple users are involved


10-22



• Manpower requirements - With enough automation, a single operator should be able to handle multiple UAVs and their payloads- To date, however, multiple operators are required

for one UAV with the typical assignments being(1) Launch and recovery(2) Vehicle control(3) Payload control(4) Payload information processing

- Predator example (for 4 air vehicle squadron)- 6 air vehicle operators- 9 payload operators- 9 data exploitation and mission planners- 3 SAR imagery analysts


10-23



Sizing

Little public control station information is available• What information does exist is mostly from

marketing brochures- Lots of pictures, little substance

• Janes UAVs and Targets has some data that we can parameterize for sizing purposes

The available data falls into two broad categories

• Short range, portable systems

• Van or trailer mounted long range control stations with environmental enclosures

10-24



Size and cost

Control station sizing(including supprt equip)

10

100

1000

10000

100000

1 10 100 1000 10000

Volume (cuft)

Control station only

0

500

1000

1500

2000

1 2 3 4

Seats

GH MCEGH LREPredator GCSCamcopterBristol UTCSJavelin

No enclosures

• Nominally each operator station in an enclosure requires about 350 - 400 cuft at about 12 lbs/ft^3

• There is very little publicly available control station cost information; Global Hawk CGS @ $45M (including comms), Predator @ $6.8M (excluding comms)

10-25



Lesson objective - to discuss

Control stationsincluding …

• Functions• Approaches• Sizing• Example problem

Next subject

10-26



Example problem

• Five medium UAVs, four provide wide area search, a fifth provides positive target identification- WAS range required (95km) not a challenge

• Only one UAV responds to target ID requests• No need to switch roles, simplifies ConOps• No need for frequent climbs and descents

• Communications distances reasonable (158nm & 212 nm)

• Speed requirement = 280 kts • Air vehicle operating altitude differences reasonable• We will study other

options as trades• Where should the control

station(s) be located?• How big are they?

100 nm

200 nm x 200 nm

158 nm

27.4 Kft

10 Kft27.4 Kft 27.4 Kft

212 nm

10-27



• Command and control approach• How to control the UAVs, where to locate control

stations and how many operators to employ• Control options

• Direct control (remotely piloted)• Inexpensive but high operations and support risk

• Navigation (waypoint and flight path) control• Slightly more complicated but low risk operations

• Supervised control (high level mission management)• Operational benefits but complicated development

• Autonomous• Minimizes operators but very complicated to develop

• Control locations will be driven by our threshold requirement approach • Minimum requirement is for one control station

• Located at the launch and recovery base• Navigation control approach will minimize risk

Considerations

10-28



Number of operators

• Assume one air vehicle operator can control all wide area search operations • Low work load activity – basically a monitoring task

• Another air vehicle operator handles ID operations• Controls both air vehicle and payload

• Wide area search/moving target payload operations require one operator (at a

minimum)• Fourth operator processes data and disseminates intelligence to users• Fifth operator for launch and recovery and backup• Sixth operator to control air and ground computer and communications systems

100 nm

200 nm x 200 nm

158 nm

27.4 Kft

10 Kft27.4 Kft 27.4 Kft

212 nm

10-29



• Control Station element• Waypoint/flight path control• 6 control consoles [air vehicle/EO/IR (2), SAR (1), C3I (1),

product process/dissemination(1), launch and recovery(1)]

Updated requirements

C3I = C2I + Communications

10-30



Homework

Assess control station requirements for your project and develop a approach that you think will work(1) Determine control station locations(2) Estimate number of operators and seats(3) Estimate weight(s) and volume(s)(4) Document your derived requirements

Submit your homework via Email to Egbert by COB next Thursday. Document all calculations.

10-31



Intermission

design of uav systems

Documents

levels of control

control location10

direct control

control functions10

automated payload control

ucav control status10

data exploitation

uav payload