|Role||Unmanned Combat Air Vehicle|
|Manufacturer||Boeing Integrated Defense Systems|
|First flight||22 May 2002|
|Primary user||United States Air Force|
The Boeing X-45 unmanned combat air vehicle is a concept demonstrator for a next generation of completely autonomous military aircraft, developed by Boeing's Phantom Works. Manufactured by Boeing Integrated Defense Systems, the X-45 was a part of DARPA's J-UCAS project.
Boeing developed the X-45 from research gathered during the development of the Bird of Prey. The X-45 features an extremely low-profile dorsal intake placed near the leading edge of the aircraft. The center fuselage is blended into a swept lambda wing, with a small exhaust outlet. It has no vertical control surfaces — split ailerons near each wingtip function as asymmetric air brakes, providing rudder control, much as in Northrop's flying wings.
Removing the pilot and its associated facilities from the aircraft dramatically reduces the aircraft's cost. Ground-based pilots execute the higher level decisions, but the mechanical flying of the aircraft is autonomous.
Boeing built two of the model X-45A; both were scaled-down proof-of-concept aircraft. The first was completed by Boeing's Phantom Works in September 2000. The goal of the X-45A technology demonstrator program was to develop the technologies needed to "conduct suppression of enemy air defense missions with unmanned combat air vehicles." The first generation of unmanned combat air vehicles are primarily planned for air-to-ground roles with defensive air-to-air capabilities coupled with significant remote piloting.
The X-45A had its first flight on May 22, 2002, and the second vehicle followed in November of that year. On April 18, 2004, the X-45A's first bombing run test at Edwards Air Force Base was successful; it hit a ground target with a 250-pound inert precision-guided munition. On August 1, 2004, for the first time, two X-45As were controlled in flight simultaneously by one ground-based pilot.
On February 4, 2005, on their 50th flight, the two X-45As took off into a patrol pattern and were then alerted to the presence of a target. The X-45As then autonomously determined which vehicle held the optimum position, weapons (notional), and fuel load to properly attack the target. After making that decision, one of the X-45As changed course and the ground-based pilot authorized the consent to attack the simulated antiaircraft emplacement. Following a successful strike, another simulated threat, this time disguised, emerged and was subsequently destroyed by the second X-45A. This demonstrated the ability of these vehicles to work autonomously as a team and manage their resources, as well as to engage previously-undetected targets, which is significantly harder than following a predetermined attack path.
After the completion of the flight test program, both X-45As were sent to museums, one to the National Air and Space Museum, and the other to the National Museum of the United States Air Force at Wright-Patterson Air Force Base, where it was inducted on November 13, 2006.
The larger X-45B design was modified to have even more fuel capacity and three times greater combat range, becoming the X-45C. Each wing's leading edge spans from the nose to the wingtip, giving the aircraft more wing area, and a planform very similar to the B-2 Spirits'. The first of the three planned X-45C aircraft was originally scheduled to be completed in 2006, with capability demonstrations scheduled for early 2007. By 2010, Boeing hoped to complete an autonomous aerial refueling of the X-45C by a KC-135 Stratotanker. Boeing has displayed a mock-up of the X-45C on static displays at many airshows.
The X-45C portion of the program received $767 million from DARPA in October 2004, to construct and test three aircraft, along with several supplemental goals. The X-45C included an F404 engine. In July 2005, DARPA awarded an additional $175 million to continue the program, as well as implement autonomous Aerial refueling technology.
On March 2, 2006, the US Air Force decided not to continue with the X-45 project. However, Boeing submitted a proposal to the Navy for a carrier based demonstrator version of the X-45, designated the X-45N.
The X-45N was Boeing's proposal to the Navy's Unmanned Combat Air Systems demonstration project. When it became known that the US Air Force would end funding to the Joint Unmanned Combat Air System program (which included the X-45 and X-47), the US Navy started its own UCAS program. Requirements were defined over the summer of 2006, and proposals were submitted in April 2007.
The first flight of the X-45N was planned for November 2008, had Boeing won the contract. The contract was eventually awarded to Northrop Grumman's proposed naval X-47, thus ending the X-45 program.
The software Boeing developed to allow the X-45N to land and takeoff autonomously on aircraft carriers has recently been installed on the first F/A-18F, which has used it to perform autonomous approaches. All autonomous approaches ended with a wave-off by design. This Super Hornet is expected to be able to hook the carrier's arrester cables autonomously by the 2009 timeframe, setting the stage for carrier-borne UAV operations.
Boeing planned to develop and demonstrate an unmanned flying test bed for advanced air system technologies. The internally funded program, called Phantom Ray, uses the X-45C prototype vehicle that Boeing originally developed for the Defense Advanced Research Projects Agency (DARPA)/U.S. Air Force/U.S. Navy Joint-Unmanned Combat Air System (J-UCAS) program. The UAV was not aimed at any particular program or competition. However, Boeing may plan to use a design based on the Phantom Ray for the Navy's unmanned carrier-launched surveillance and strike (UCLASS) program.
- Crew: 0
- Length: 26 ft 6 in (8.08 m)
- Wingspan: 33 ft 10 in (10.3 m)
- Height: 6 ft 8 in (2.14 m)
- Empty weight: 8,000 lb (3,630 kg)
- Powerplant: 1 × Honeywell F124-GA-100 turbofan
- Maximum speed: Mach 0.75 (571 mph, 919 km/h)
- Range: 1,300 nmi (2,405 km)
- Combat radius: 375 miles (600 km)
- Service ceiling: 40,000 ft (13,200 m)
- Hardpoints: 8 - 2 weapon bays with 4 in each - and provisions to carry combinations of:
Aircraft of comparable role, configuration and era
- Swan, Sarah (2006-11-17). "X-45A Unmanned Combat Vehicle on Display". Aerotech News and Review.
- The 50th flight: Two X-45s work autonomously as a group and successfully attack previously undetected targets Archived August 29, 2005, at the Wayback Machine.
- Boeing news release Archived November 10, 2006, at the Wayback Machine.
- "Boeing Receives First Engines for X-45C UCAV" Archived December 5, 2005, at the Wayback Machine.. Boeing, November 18, 2004.
- "Boeing Awarded Additional $175 Million for Joint Unmanned Combat Air Systems Capability Demonstration Program" Archived November 25, 2005, at the Wayback Machine.. Boeing, July 11, 2005.
- "J-UCAS ending", Aviation Week and Space Technology.
- "Navy's UCAS program", Aviation Week and Space Technology.
- article; Navy UCAS proposals", Aviation Week and Space Technology
- "Winner to be selected in late 2007 or early 2008". Aviation Week and Space Technology.
- "Navy awards UCAS-D contract to Northrop Grumman X-47 team
- "F/A-18F approaches carrier autonomously, will soon land autonomously". Aviation Week and Space Technology
- "Boeing's Phantom Ray - the 'Phoenix' of UCAVs". Aviation Week.
- "Breaking: Boeing resurrects X-45C as 'Phantom Ray' testbed". Flight Global.
- US Navy delays UCLASS RFP - Flightglobal.com, December 11, 2012
- X-45 J-UCAV Joint Unmanned Combat Air System, specifications. airforce-technology.com[unreliable source?]
- X-45 Joint Unmanned Combat Air System Archived March 23, 2008, at the Wayback Machine.. Boeing.
|Wikimedia Commons has media related to Boeing X-45.|
- Boeing X-45 Site
- X-45 Video Collection
- NASA Dryden X-45A UCAV Photo Collection
- First bombing run test is a success
- Composites combat ready in UCAVs
- Boeing X-45 / X-46 page on designation-systems.net
- Photograph; X-45C unfinished prototype
- X-45C/N computer-rendered images
- Boeing 'Phantom Eye' Hydrogen Powered Vehicle Takes Shape