Monday, October 28, 2013

History of UAS (1.6)

The Evolution of UAS Design
Militarily speaking, mission requirements for Unmanned Aerial Systems (UAS) have not changed much over the past 60 years. Unmanned Aerial Vehicles (UAV) of the 1950s were tasked to perform reconnaissance and deliver some form of weaponry much like they do today. The differences lie only in how the technological advancements of the past 60 years have set the systems and the payloads apart. It would be a fair assessment that not one particular program has evolved over all these years to become the stand alone system that it is today. Advancements in technology have been applied to UAS programs as operating parameters dictated, only for another program to find a use to implement that newer technology within its own UAS program.

In brief, a comparison of two systems, one from the mid-1950s and the other currently in use, shall be presented in this paper.
1950s
The Army began experimenting with UAVs to perform reconnaissance missions. The RP-71 could ascend to over 3,000 feet per minute and reach a top cruising speed of between 185-224 mph (Blom, 2010). It operated between several hundred feet and four miles and could stay aloft for approximately 30 minutes (Blom, 2010). The UAV could be launched with only five minutes of preparation and used a catapult as its launch platform so that it could operate from the front lines, under the direct control of a ground commander (Blom, 2010). An operator on the ground used a stick box and an on-board camera to control the UAV. (Blom, 2010) When the mission was completed the UAV was flown back over friendly territory, the engine was shut down and a parachute was deployed (Blom, 2010). During a mission, the controller sat in the mobile radar and tracking cabin to guide the RP-71 to its target, while in the cabin, the radar tracked the flight on a map overlay (Blom, 2010). Other instruments in the cabin provided the operator with the altitude, speed and distance from the cabin. Once the drone reached the target, the controller activated the camera. (Blom, 2010)
Current
The Insitu ScanEagle is also a catapult launched UAV based system. However, instead of using the parachute recovery system, ScanEagle has incorporated the technologies of high-quality differential GPS units to catch a rope hanging from a 30-to-50-foot pole (Insitu). This unique launch and recovery system has enabled the ScanEagle to also operate from a marine environment restricted only by the size of the ship operating the equipment. It is capable of operating for up to 20 hours, with speeds up 92 mph with an average cruise speed of 55 mph at a service ceiling of up to 16,000 ft. (Insitu). Its payload is far more advanced than that of the RP-71, in that it operates a stabilized electro-optical and/or infrared camera on a lightweight inertial stabilized turret system, and an integrated communications system having a range of over 62 miles. (Insitu) Modified versions are equipped with a higher resolution camera/video system, all capable of real time viewing and recording in the GCS for mission archives/review/training purposes. ScanEagle’s air-to-ground communications systems deliver stable communications up to 55 nm from a ground control station. (Insitu) Encrypted digital video and command and control datalinks offer increased Intelligence, Surveillance, and Reconnaissance (ISR) security. (Insitu)
Comparisons
It would appear, the operating characteristics are quite different. But then the original designs of the UAV as a Target/Drone have changed. The need for speed is no longer an issue. The capabilities of radar defenses and electronic countermeasures have enabled a UAV capable of flying at much slower speeds without the need of ancient escape and evade mind set. Both systems have cameras but modern technological advances have greatly improved the capabilities of those used in the ScanEagle. Cameras capable of Infrared/night vision, real time digital video, all within a stabilized turret system have greatly improved the mission capabilities of the ScanEagle compared to that of the RP-71. How the UAVs were navigated is probably the greatest technological advancement over the past 60+ years. From radar tracking of an object on a mapped overlay to Satellite GPS, with real time UAV flight critical feedback and proximity of surroundings by video feed to the GCS controller. This newer technology allows for a UAV to be flown on opposite sides of the world without having to have a line-of site link.
New Technologies
As the increased development into solar energy continues, it is possible that more power plants will evolve into solar based energy. Eliminating the need of a depleted fuel source as the mission is conducted and thereby allowing for increased payload of another kind. The issue remains however in developing a battery source that is light/small enough to sustain enough energy to power an engine while operating in non-solar recharging conditions. However, if the engine could provide its own sustainable power source, but then…...
References
Blom, J. D. (2010) Unmanned aerial systems: A historical perspective (Occasional paper; 37) Fort Leavenworth, KS: US Army Combined Arms Center, Combat Studies Institute Press. Retrieved from http://usacac.army.mil/cac2/cgsc/carl/download/csipubs/OP37.pdf

Insitu. (n.d.). ScanEagle capabilities. Retrieved from
http://www.insitu.com/systems/scaneagle/capabilities

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