ASCI 530, Assignment 7.4, Request for Proposal

Mission

The purpose of this project is to field an unmanned aerial vehicle (UAV) to provide aerial surveillance, observation, and reconnaissance of disaster areas.  The UAV will aid in disaster relief and search and rescue (SAR) efforts.  The UAV system will have a relatively small logistical footprint and provide useful time periods of overhead coverage.  The estimated time of development to fielding will be six years.

Base requirements

1.     Transportability – Entire system (all elements) shall be transportable by a vehicle not to exceed the 2.5 ton range.

1.1  – Vehicle shall provide stowage space for disassembled unmanned aerial vehicle (UAV).

1.2  – Vehicle shall provide stowage space for UAV catapult launcher.

1.3  - Vehicle shall provide stowage space for recovery net system.

1.4  – Vehicle shall provide stowage space for command and control (C2) communications equipment.

1.5   – Vehicle shall provide exterior mounting points for C2 equipment.

1.6  – Vehicle shall provide stowage space for UAV operator control terminal.

1.7  – Vehicle shall provide stowage space for UAV system support tools, equipment, and spare parts.

1.8  – Vehicle shall provide necessary electrical power to support UAV system operations.

1.9  – Vehicle shall provide stowage space for crew’s personal gear and provisions.

1.10              – Vehicle shall transport up to 4 personnel.

1.11              – Vehicle shall not expose UAV system components to damaging and excessive g-forces due to transit.

1.12              – Vehicle shall traverse light to moderate uneven terrain.

2.    Payload

2.1  – Shall not exceed 33% of the gross weight of the air vehicle.

2.2   - Shall be capable of color, daylight, video imagery from an altitude of 1,000 feet AGL.

2.3  – Shall be capable of infrared (IR) imagery from an altitude of 1,000 feet AGL.

2.4  – Shall provide a range of view of at least 90 degrees on either side of centerline axis.

2.5  – Shall be interoperable with C2 system and equipment.

2.6  – Shall use power provided by the UAV.

2.7  – Shall be easily accessible for maintenance purposes.

3.    Support Equipment – Equipment that shall provide support to UAV system operations.

3.1  – Shall include a portable, collapsible catapult launch mechanism.

3.2  – Shall include a portable, collapsible net recovery mechanism.

3.3  – Shall include UAV system support tools, equipment, and spare parts.

3.4  – Shall include personal protective equipment (PPE) for crewmember safety.

3.5  – Shall include appropriate fire suppression equipment.

3.6  – Shall include appropriate environmental impact preventative equipment.

10. Testing Requirements

      10.1 Transportability

               10.1.1 Item Storage

10.1.1.1      Test fit space for disassembled UAV.

10.1.1.2      Test fit space for UAV catapult launcher.

10.1.1.3      Test fit space for recovery net system.

10.1.1.4      Test fit space for C2 communications equipment.

10.1.1.5      Test fit space for UAV operator control terminal.

10.1.1.6      Test fit space for UAV system support tools, equipment, and spare parts.

10.1.1.7      Test fit space for crew’s personal gear and provisions.

                10.1.2 Durability

10       

10.1.1       

10.1.2       

10.1.2.1      Test transit g-forces.

10.1.2.2      Test transit over light to moderate uneven terrain.

                10.1.3 Electrical Power

10       

10.1.1       

10.1.2       

10.1.3       

10.1.3.1      Test electrical power output.

10.1.3.2      Test compatibility of power connections with UAV operations support system equipment.

                10.1.4 Other Items

10       

10.1.1       

10.1.2       

10.1.3       

10.1.4       

10.1.4.1      Test transportability of up to 4 crewmembers.

10.1.4.2      Test exterior mounting points for C2 equipment.

      10.2 Payload

                    10.2.1 Weight

10       

10.1       

10.2       

10.2.1       

10.2.1.1      Test that payload weight does not exceed 33% of gross weight of air vehicle.

               10.2.2 Capabilities

10       

10.1       

10.2       

10.2.1       

10.2.2       

10.2.2.1      Test color, daylight, video imagery from an altitude of 1,000 feet AGL.

10.2.2.2      Test infrared (IR) imagery from an altitude of 1,000 feet AGL.

10.2.2.3      Test range of view of at least 90 degrees on either side of centerline axis.

              10.2.3 Other Items

10       

10.1       

10.2       

10.2.1       

10.2.2       

10.2.3       

10.2.3.1      Test interoperability with C2 system and equipment.

10.2.3.2      Test power output provided by the UAV.

10.2.3.3      Test accessibility for maintenance purposes.

     10.3 Support Equipment

                   10.3.1 Operations Support

10       

10.1       

10.2       

10.3       

10.3.1       

10.3.1.1      Test portable, collapsible catapult launch mechanism.

10.3.1.2      Test portable, collapsible net recovery mechanism.

10.3.1.3      Test UAV system support tools, equipment, and spare parts.

              10.3.2 Safety

10       

10.1       

10.2       

10.3       

10.3.1       

10.3.2       

10.3.2.1      Test personal protective equipment (PPE).

10.3.2.2      Test fire suppression equipment.

10.3.2.3      Test environmental impact preventative equipment.

10.3.2.4      Ensure safety equipment complies with federal and state regulations (“Selecting PPE for the Workplace”, n.d.).

Development

The type development process most suited to this project will be Rapid Application Development (RAD).  The short development time to fielding (Six years) makes RAD an appropriate choice.  The goal is to produce a working system to support critical, time-sensitive disaster relief missions.  Another factor is the use of commercial-off-the-shelf (COTS) components when possible to aid in rapid development and conservation of resources.  Since this UAV system is intended to be highly mobile and present a small logistical footprint, scalability to a larger aerial vehicle is not a concern (“Selecting a Development Approach”, 2008).

Testing

COTS components will be utilized where possible and appropriate to expedite the testing process.  The primary components where COTS solutions will be most important will be the sensor suite (payload), powerplant, launching and recovery systems, communications antennae, transport vehicle, computer hardware, and safety equipment.  These components will have already been tested and proven individually.   Testing may proceed to the integration stage to test all components of the complete UAV system.

Testing of the UAV airframe will be a relatively simple process compared to other aircraft due to the relatively low speed and service ceiling intended of the UAV.  Initial flight tests may be performed before integration of the payload.  A ballast to simulate the weight of the actual payload can be used in the initial flight tests.  Initial test locations will be on clear, unobstructed fields and progress to locations simulating disaster areas.

Testing of the transport vehicle will consist mainly of modifications to ensure the vehicle will not transmit damaging g-forces to any system components during transit (“Vibration and Mechanical Shock Test”, 2014).  Sensors will be used to monitor compliance with the requirements.

Overview

Natural disasters do not adhere to a schedule and often occur with little to no warning.  In the aftermath of any event, time is a critical factor to saving lives.  As such, the development to fielding process for a system to provide critical enhancement for disaster relief personnel must be rapid.  This is the primary factor driving the goal set for the development to fielding schedule.

The requirements of the UAV system was driven by the concept of keeping the entire system highly mobile and easily deployable.  The aerial vehicle needed to be compact yet capable of providing useful capabilities over the area of operations.  The performance of the UAV needed to be high enough to reach destinations in a timely manner and provide a useful loiter time as well.  The service ceiling needed to be high enough to allow the sensor payload to provide wide imagery coverage while remaining within the sensors’ parameters to provide the best quality image.

The requirements of the payload were selected to provide the best aerial observation and surveillance capabilities possible.  The wide field of view and quality of imagery will provide the best possible vantage point aloft for disaster relief personnel, particularly search and rescue teams.  The IR imagery provides observation capability in low light or dusk conditions, extending the window of operations.  Limited visibility and low light conditions present significant challenges to manned aerial search and rescue platforms (Tripp, 2011, p. 7).  A UAV could be deployed in conditions deemed too hazardous to flight crews.  The IR capability would also be useful in seeing through light cover (“CHP Helicopter”, 2014).   The weight requirement was selected to ensure enough space was reserved on the air vehicle for an appropriate powerplant and a sufficient fuel supply.  These two components are critical to the performance factors mentioned previously.

The number of required crewmembers was to be kept to a minimum to keep the logistical footprint small.  Two person carry will most likely be necessary with the heavier pieces of equipment, such as the air vehicle.  A crew of four would be sufficient to carry out sustained operations. 

The size of the transport vehicle was selected to ensure the entire UAV system could be transported by a single vehicle.  Separating the components into multiple vehicles would increase the logistical footprint since each vehicle would require the same amount of maintenance as a single one.  Multiple vehicles also mean that each one requires a driver and may increase the number of personnel required for the crew.  Uneven terrain capability was also levied as a requirement since a disaster area may have damaged roads, debris, or require detours onto off paved surfaces.  Staging locations may also be on unpaved surfaces.  The requirement for the vehicle design to limit g-forces on the UAV system was levied to extend the lifespan of the components.  Prolonged exposure to damaging g-forces and vibration during transit will shorten the life of the components of the UAV system.  Response to a disaster area will almost certainly require significant ground transit, potentially reducing the useful operational life of the UAV system before it is even deployed.

References:

El Dorado County Search and Rescue.  (2014).  CHP Helicopter.  Retrieved from http://www.comspark.com/esarc/articles/h20.htm

United States Department of Health and Human Services.  (2008, March 27).  Selecting a Development Approach.  Retrieved from http://www.cms.gov/Research-Statistics-Data-and-Systems/CMS-Information-Technology/XLC/Downloads/SelectingDevelopmentApproach.pdf

United States Department of Labor – Occupational Safety and Health Administration.  (n.d.).  Selecting PPE for the Workplace.  Retrieved from https://www.osha.gov/SLTC/etools/eyeandface/ppe/selection.html

 

Vibration and Mechanical Shock Test.  (2014).  Retrieved from http://www.istgroup.com/english/3_service/03_01_detail.php?MID=2&SID=10&ID=98

Tripp, D.  (2011).  Working with Search & Rescue Helicopters.  London: Crown Copyright.