SI4000 SUMMER 2004 UAV Brief UAV Development and History at Northrop Grumman Corporation
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SI4000 SUMMER 2004 UAV Brief UAV Development and History at Northrop Grumman Corporation Ryan Aeronautical Center Norman S. Sakamoto [email protected] 619.203.5726 File Name.1 As of (date) UAV Family Tree Historically, no single, universally accepted definition has adequately categorize the Unmanned Air Vehicle. Vehicle Ballistic Powered Guided Unguided Smart Bomb Free Fall ICBM Bomb Bullet Shell Simple Rocket Unmanned Expendable Remote Control Automatic Control Guided Missile Cruise Missile File Name.2 As of (date) Unguided Guided Manned Recoverable Remote Control Automatic Control RPV Drone Expendable Recoverable Kamikaze Conventional Aircraft Current Definition of a UAV Unmanned Air Vehicle Origins Necessity, the “mother of invention” produced flying bomb concepts during the First World War. The armistice halted experiments on all but targets. • 1917: French artillery officer, Rene`Lorin proposed flying bombs using gyroscopic and barometric stabilization and control. • 1918: Germany halts development of guided weapons. • 1918: Charles Kettering (USA) flies Liberty Eagle “Kettering Bug” and Army Air Corps orders 75 copies. • 1920: Elmer Sperry perfects the gyroscope and the first enabling technology makes flight control feasible • 1932: RAE “Fairey Queen” crashes, technology is still in its infancy. File Name.3 As of (date) Fairey Queen IIIF Mark IIIB, 1932 USA - Targets Become Successful 1935 - Reginald Denny develops the RP-1 and launches the Radio Plane Company, later to become the Northrop Ventura Division. File Name.4 As of (date) V-1 Debuts in 1943 Advanced technologies of the Forties provided control, guidance and targeting. Azimuth Control by gyroscope governed by magnetic compass Speed was determined by engine performance at max. power Aneroid barometer altitude control Propeller driven “airlog” governed range File Name.5 As of (date) Launch Systems A wide variety of launch systems have been developed for UAV applications Pneumatic Catapult Air Launch JATO/RATO Launch Runway Launch File Name.6 As of (date) UAV Recovery Techniques Recovery schemes are determined by application and UAV size, the trend is toward autoland capability Parachute ABIAS Mid Air Retrieval System (MARS) Net File Name.7 As of (date) Conventional SI4000 SUMMER 2004 UAV Brief Ryan Aeronautical UAV History Norman S. Sakamoto [email protected] 619.203.5726 File Name.8 As of (date) Ryan XAAM-A-1 Firebird Firebird ushers in the missile age at Ryan in 1949 Speed was determined by engine performance at max. power 7.5’ without booster Aneroid barometer altitude control Early radar guidance was a forerunner to Sparrow missiles File Name.9 As of (date) BQM-34 Firebee Subsonic Aerial Target High Performance, Jet-powered UAV designed to simulate hostile aircraft or missile threats • Primary Missions – Air defense weapons development, test & evaluation – Air defense weapons training • Secondary Missions – Aerial reconnaissance – Experimental aerial platform • System Capabilities – – – – Ground launch Air launch from C-130 Recovery by parachute on land or at sea 8-12 flights per vehicle • Flight Control and Navigation – Remotely piloted from airborne or ground control station – Preprogrammable Microprocessor Flight Control System ( MFCS) for autonomous flight File Name.10 As of (date) BQ-34 Firebee evolved from the Ryan KD-A BQM-34E Firebee II Supersonic Aerial Target Turbojet Powered UAV designed to simulate high speed hostile aircraft and anti-ship missiles • Primary Missions – Air defense training – Aerial combat training – Weapons systems development • Secondary Missions – Test vehicle for advanced aerodynamic technology research (NASA) • System Capabilities – Ground Launch – Air launch from C-130 – Recovery by parachute on land or at sea – 8-12 flights per vehicle File Name.11 As of (date) Firebee II with external fuel tank in subsonic flight AQM-91A Compass Arrow Twenty plus vehicles built in the late ‘60’s, still holds the unmanned turbine powered altitude record, 80,000 ft. • First large UAV specifically designed to survive by stealth. • Compass Arrow operated at altitudes in excess of 80,000 ft. while traveling at subsonic speeds. • Incorporated several low observable features. • Significant reduction in the RCS features of the aircraft as seen from the ground. • Vertical tails and fuselage sides canted toward centerline to eliminate the specular reflections from the side aspect at or below the horizontal plane. • The engine inlet, located on top of the fuselage was lined with RAM, to conceal it from angles below the horizontal plane. • Exhaust nozzle was cooled to reduce IR signature, and like the inlet, was placed so as to be hidden by other airframe features at many aspects of observation. RAM was applied to the leading edges of the wing and to some portions of the fuselage. File Name.12 As of (date) AQM-81A/N Firebolt Rocket-powered target missile designed to replicate high altitude and high speed threats. • Primary Mission –Provide a realistic threat simulation of advanced enemy threats that fly in the upper reaches of earth’s airspace for… – Air defense training – Aerial combat training – Weapons systems development • Reusable Hybrid Rocket Powered Target Missile –Air Launch –Recovery by MARS over land or sea –20 Flights per vehicle • Flight Control and Navigation –Pre-programmable Mission Logic Control Unit (MLCU) –Remotely piloted from Ground Control Station File Name.13 As of (date) YQM-98A Compass Cope Two units built and flight tested in 1976, held the unmanned turbine engine endurance record of 28 hr. 11 min. until surpassed by Global Hawk on March 21, 2001 • Primary Mission –High altitude endurance reconnaissance and surveillance • Minimum 24 hours of endurance • 750 lbs. payload capability • Triple redundant autoland system • Dual redundant avionics system • Quadruple redundant Command & Control System • First major Use of GOTS/COTS hardware File Name.14 As of (date) Model 410 Long Endurance UAV Economical aerial reconnaissance and surveillance system for civilian or military customers • Primary Mission – Provide a long-range or longendurance aerial platform for: – Military reconnaissance – Electronic communications relay – Electronic warfare countermeasure – Law enforcement, drug interdiction – Border surveillance – Disaster area observation – Natural resources monitoring File Name.15 As of (date) Model 410 Long Endurance UAV (continued) Economical aerial reconnaissance and surveillance system for civilian or military customers • System Components – Long Endurance Aerial Vehicle – – – – Composite construction Modular design Two-man assembly / disassembly Short, unimproved runway capability – Ground Control Station – Self contained, transportable, fully integrated – Autonomous flight control & mission programming – Remote manual flight & sensor control – Real-time datalink – Image data processing – Onboard Flight Control & Navigation – Central Flight Control Computer (CFCC) – Global Positioning System (GPS) – Auto takeoff and landing File Name.16 As of (date) – Payload – 300 pound capacity – 24 cubic foot volume – Stabilized retractable sensor platform Model 324 Medium Range Mobile and transportable advanced technology unmanned aerial reconnaissance system • Primary Mission – Conduct autonomous tactical aerial reconnaissance and surveillance • System Components – Unmanned Aerial Vehicle (UAV) – Composite airframe – Ground launch from mobile transport trailer – Recovery by parachute with air-bag attenuation system – Onboard Flight Control & Navigation – Mission Logic Control Unit (MLCU) – Inertial Navigation System (INS) – Global Positioning System (GPS) File Name.17 As of (date) Model 324 Medium Range (continued) Mobile, and transportable advanced technology unmanned aerial reconnaissance system • System Components (con’t) – Mobile Launch & Recovery Vehicle (LRV) – – – – 8 wheel all-terrain tractor 6 wheel trailer transport/launcher Self-contained command 7 control shelter Autonomous flight control & mission programming – Remote manual flight control – Command tracking & telemetry system – Payload – CAI/Recon Optical KS-153A camera – Loral IRLS D-500 Infrared line scanner File Name.18 As of (date) SI4000 SUMMER 2004 UAV Brief Ryan Aeronautical Modern UAV Design & Technology Norman S. Sakamoto [email protected] 619.203.5726 File Name.19 As of (date) Model 350 Medium Range UAV Advanced technology tactical unmanned aerial reconnaissance system • Mission – Provide near real-time optical and/or infrared images of heavily defended areas – Target detection – Target identification – Battle damage assessment • System Components – Onboard Flight Control & Navigation – Mission Logic Control Unit (MLCU) – Inertial Navigation System (INS) – Global Positioning System (GPS) – Payload – Advanced Tactical Aerial Reconnaissance System (ATARS) File Name.20 As of (date) Model 350 Medium Range UAV Advanced technology tactical unmanned aerial reconnaissance system • System Components – Unmanned Aerial Vehicle (UAV) – Ground launch – Air launch ( from F/A-18 and F-16R) – Soft landing recovery by parachute or by Mid-Air Recovery System (MARS) – Local Control & Monitoring Station (LCMS) – Self-contained, transportable – Autonomous flight control & mission programming – Remote manual flight control – Command, tracking, telemetry & image data link systems – Image data processing system File Name.21 As of (date) Global Hawk HAE UAV High Altitude Endurance Unmanned Aerial Reconnaissance System • Mission – Provide continuous day / night, high altitude, all weather surveillance and reconnaissance in direct support of allied ground and air forces across the spectrum of conflict – Increase the reach of existing and future surveillance systems – Extraordinary range and endurance – Fewer number of systems required to maintain global ISR coverage File Name.22 As of (date) Global Hawk HAE UAV The Global Hawk is an Integrated System Speed (n.miles/hour) File Name.23 As of (date) Global Hawk System Overview INMARSAT C2 COMMUNICATIONS UHF-Band: C2 LOS C2 SATCOM UHFSATCOM Ku SATCOM INMARSAT or Equivalent C2 and Sensor SATCOM X-Band CDL: C2 and Sensor LOS ATC Voice Ku-Band: MISSION CONTROL ELEMENT (C2 & SENSOR) C2 & SENSOR C2 & SENSOR C2 CDL SENSOR CDL C2 & SENSOR C2 C2 C2 LOS LAUNCH AND RECOVERY ELEMENT (C2 ONLY) SENSOR ATC VOICE TACTICAL USERS (SENSOR ONLY) File Name.24 As of (date) Global Hawk Vehicle Size U-2 Length: 63.1 feet Wingspan: 104.8 feet Height: 16.7 feet (at tail) Max Takeoff Wt: 40,000 lb. Maximum Speed: 410 kts. TAS Operational Ceiling: over 70,000 feet Max Unrefueled Range: over 3,000 NM File Name.25 As of (date) B-737 Length: 97 feet Wingspan: 94 feet Max Takeoff Wt: 130,000 lb. 573 kts. TAS Loiter Speed: Operational Ceiling: 40,000 feet Max Unrefueled Range: 2,700 NM Global Hawk Length: 44.4 feet Wingspan: 116 feet Height: 15.2 feet (at tail) Max.Takeoff Wt: 25,600 lb. 343 kts. TAS Loiter Speed: Operational Ceiling: 65,000 feet Max Unrefueled Range:over 12,000 NM Global Hawk Integrated Sensor Suite File Name.26 As of (date) SI4000 SUMMER 2004 UAV Brief Ryan Aeronautical Future UAV Technology Norman S. Sakamoto [email protected] 619.203.5726 File Name.27 As of (date) Telepresence Telepresence, also called virtual presences, is participation in an environment from a remote location • A subset of virtual reality, telepresence uses external mechanics to view the environment, • Lethal UAV weapons delivery systems of the 1970’s put the shooter out of harms way. • Ryan developed systems to launch a variety of guided standoff weapons from BGM-34C UAV’s. • Virtual Reality software today contains the following features: – Object database - descriptions of virtual objects or environments – Attribute database - color, texture, orientation – Sensor driver- monitors tracking devices to know actual position – display driver- reality engine updates object for display – Simulation manager - coordinates entire system maintaing proper perspective between objects File Name.28 As of (date) Virtual Reality Web sites Commercial VR packages are available from many houses on the web. • • • • • World Tool Kit Sense8 www.sense8.com VR Development Systems VREAM www.vream.com Walk Through Virtus www.virtus.com Virtual Reality Studio Danmark Software WWW.domark.com Cyberspace Development Kit Autodesk www.autodesk.com • File Name.29 As of (date) Recent check of the links, Red are no longer pertinent or active. Fuzzy Logic / Neural Nets The development of an adaptive control system to enhance engine performance is on the horizon • Fuzzy logic algorithms and hardware have enjoyed a recent development frenzy • The technology is ready for transition to UAV class engine controllers when the need is great enough • Current F/A-18 Fuzzy logic engine control work is funded and ongoing File Name.30 As of (date) Voice Directed UAV Speech recognition could replace some navigation logic allowing mixed use of UAV’s and manned aircraft • Neural Network computing methods could be applied to artificial speech recognition and UAV command language • This will increase asset interoperability for a force commander or commercial air traffic controller • Minimizes ground control station assets File Name.31 As of (date) Damage Detection / Failure Prediction UAV Mission Failure rate can improve airframe monitoring and failure prediction. • In high threat areas, damage may occur due to hostile action. • With proper sensors, a UAV could “decide” to return to base if damage or failures were detected prior to catastrophic failure. • Smart structure technologies will detect damage, predict useful life, continue operation at optimal flight conditions. • The UAV will react by reducing speed, flying minimum G profile or dumping fuel and returning to base File Name.32 As of (date) SI4000 SUMMER 2004 UAV Brief UAV’s Where We’ve Been and Where We’re Going Norman S. Sakamoto [email protected] 619.203.5726 File Name.33 As of (date) Customers • USAF • USA • USN • USCG • RCAF • JDF • GOI • GOE File Name.34 As of (date) • NATO • DEA • DNA • DOT • CIA • FBI • NSA • INS • Sandia • Los Alamos • LLL • NASA • DARPA • DARO • MDA Performance • Altitude 7 Ft to 100,000 Ft • Velocity 60 Kts to Mach 4 • Endurance 7 Minutes to 40 hours • Range 25 NMi to 14,000 Nmi • Take-Off Gross Weight 200 Lb to 34,500 Lb • Payload Weight 25 Lb to 3,000 Lb File Name.35 As of (date) Missions • IMINT • SIGINT • GPS Pseudolite • Air Sampling • Strike • EW/ESM File Name.36 As of (date) • • • • • Decoy BPI/BPLI Target Cargo / Logistics ACN Aerodynamics • Conventional Airfoil • Rogallo Wing • Laminar Flow • SuperCritical • Ailerons, Elevators, Rudders, Ruddervators, Spoilers, Speed Brakes, Flaps, Elevons • BLC File Name.37 As of (date) • Twin Verticals • V - Tails • Canards • V/STOL • Non Atmospheric • Hypersonic Airframe • Metallic – – – – • Aluminum Steel Titanium Magnesium Composite – Fiberglass – Graphite • Molded – Sheet Molded Compound File Name.38 As of (date) Low Observables • Radar • Acoustic • Visual • IR File Name.39 As of (date) Propulsion • Reciprocating ( Aircraft) • 2 Cylinder 2 Cycle • Turbo Prop • Turbo Jet • Turbo Fan • Ramjet • Pulse Jet • Rocket • Electric Motors File Name.40 As of (date) Payload Sensors • Cameras – Still – Motion – Panoramic • • • • • • Electro-Optical FLIR IRLS SAR ISAR IFSAR File Name.41 As of (date) • • • • • • • Chaff Active EW Jammers COMINT ELINT ESM Ordnance Leaflets/Propaganda Navigation • Dead Reckoning • Doppler • LORAN / Omega • INS • GPS/DGPS • INMARSAT File Name.42 As of (date) Flight Controls • Analog • Digital • Hybrid • Duplex • Triplex • Electrostatic File Name.43 As of (date) • AHRS (Gyros) • Inertial • Formation Flight • Autonomous Flight – Active Real-Time – Re-Planning – Re-Tasking Secondary Power • Batteries • Auxiliary Power Unit (APU) • Solar • Generator File Name.44 As of (date) Actuation System • Hydraulic • Pnuematic • Electro-Mechanical – Linear/Rotary – Push/Pull – Cables/Pulleys File Name.45 As of (date) UAVs - Current Development and Emerging Uses File Name.46 As of (date) The Networked Vision of the Future File Name.47 As of (date) UAVs Are A Major Part of the Vision Warfighter’s Challenge ~ Future Combat • Regional & Global Asymmetric Warfare – Proliferation of Ballistic Missile/Cruise Missile Threats – Proliferation of WMD Capabilities /Systems ~ and the Will To Use Them • Uncertainty In Situational Awareness/Decisions • Non-Traditional Roles & Missions ~ With Force Structure Pressures • Acquisition of Advanced Technology Force Structures – Technologies, Applications, Systems & Insertion Sequencing – Force Mix, Postures, Basing, CONOPS & Employment Concepts – Sustaining Capability in the Transition/Transformation – Establishing & Sustaining Affordability - No Immunity To Budget Constraints File Name.48 As of (date) Understanding & Integrating UAVs Is A Significant Part of the Challenge Some of the Emerging Concepts & Requirements That UAVs Can Meet Military BM/C4ISR BPLI - Theater Ballistic Missile Defense These Lists Are Cruise Missile Defense - BM/C4ISR & Intercept By No Means Battlespace ~ Infosphere Comms & Reach-Back Comprehensive Kinetic & Non-Kinetic Combat Operations PSYOPs & SOF Operations SBIRS Low Adjunct & Tactical Surrogate Satellite / Sensor Test Bed Civil Authority & Commercial Applications Space Sensing Communications Space Surveillance Law Enforcement Space Tracking Drug Interdiction Space Comms/Data Relay Disaster Preparedness & Management Military Science Global Meteorological (NOAA) Military R&D Forest Fire Surveillance Augmentation of GPS Environmental Monitoring, Management & Enforcement File Name.49 As of (date) Agricultural Resource Surveillance & Management Natural Resource Surveillance & Management Scientific Research Questions? File Name.50 As of (date)