플라이-바이-라이트 (Fly-By-Light) (FBL: Fly-By-Light)
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Definition
전기 배선 대신 광섬유 케이블로 조종 신호를 전송하여 전자기 간섭에 면역성을 갖는 첨단 비행 조종 시스템.
What Is Fly-By-Light?
Fly-By-Light (FBL) is an advanced flight control architecture that uses fiber-optic cables — rather than the copper electrical wiring used in fly-by-wire systems — to transmit pilot control inputs and sensor data between cockpit controls, flight control computers, and actuators. Light pulses traveling through glass fibers are inherently immune to electromagnetic interference (EMI), lightning-induced transients, and high-intensity radiated fields (HIRF) — vulnerabilities that all electrical fly-by-wire systems must address through expensive shielding and redundancy.
FBL represents an extension of the fly-by-wire philosophy pioneered in systems like the fly-by-wire system of the Airbus A320 family. While FBL has been extensively researched and demonstrated, it has not yet entered commercial production due to challenges in high-speed optical signal processing, the cost of ruggedized fiber-optic connectors, and the maturity and reliability of established fly-by-wire systems.
How It Works
In an FBL system, sensors convert physical measurements (stick position, pressure altitude, angle of attack) into light signals using electro-optical converters. These signals travel through single-mode or multimode fiber-optic cables at the speed of light to flight control computers, which then command hydraulic or electro-hydrostatic actuators via optical-to-electrical converters at the actuation end.
- Bandwidth advantage: Fiber-optic cables can carry data at rates exceeding 100 Gbps — orders of magnitude beyond the ARINC 429 (100 kbps) or AFDX (100 Mbps) data buses used in current glass-cockpit aircraft.
- Weight reduction: Fiber-optic cables weigh approximately 70% less than equivalent copper wire bundles. On a large transport aircraft, replacing all signal wiring with fiber could save 200–500 kg (440–1,100 lb).
- EMI immunity: No electromagnetic emission means FBL aircraft would be less detectable by radar — a key driver for military FBL programs, particularly the U.S. Air Force's Advanced Tactical Fighter program in the 1980s.
- Integration with composites: Composite materials used in modern airframes are non-conductive, making it difficult to use the aircraft structure as an electrical ground return — a problem FBL avoids entirely.
Key Examples
The Boeing X-36 (1997) and the NASA F/A-18 Systems Research Aircraft (SRA) were among the first aircraft to fly with fiber-optic flight control signal transmission. The Eurofighter Typhoon uses a partial FBL architecture for its digital flight control system's sensor data buses. Rockwell Collins demonstrated a full FBL architecture on a modified Lockheed C-130 in 2003 as part of an USAF research program, achieving MTBF (Mean Time Between Failures) exceeding 20,000 hours for fiber-optic harness assemblies.
Aircraft Examples
- Eurofighter Typhoon: Partial FBL for sensor data transmission; primary flight control commands remain fly-by-wire electrical.
- Boeing F/A-18E/F Super Hornet: Fiber-optic data buses for MIL-STD-1773 avionics interconnect, separate from primary flight control wiring.
- Future commercial programs: Airbus has explored FBL for the A220 family successor; Boeing's New Mid-Market Airplane (NMA) concepts included FBL architecture studies before the program was suspended.
- Unmanned Aerial Vehicles (UAVs): The General Atomics MQ-9 Reaper and similar MALE UAVs use fiber-optic connections within the aircraft to isolate sensor payloads from flight-critical EMI-sensitive avionics.
Related Terms
복합 재료
탄소 섬유 강화 폴리머(CFRP)와 같이 높은 강도와 가벼운 무게를 결합한 구조 항공기 부품용 첨단 엔지니어링 재료.
플라이 바이 와이어 시스템 (FBW)
조종사 입력과 조종면 사이의 직접적인 기계적 연결을 디지털 컴퓨터 매개 신호로 대체하는 전자 비행 조종 아키텍처.
플라이 바이 와이어 (Fly-by-Wire)
조종사의 조종 장치와 항공기 조종면 사이의 전통적인 기계식 연결을 대체하는 전자식 비행 제어 시스템.
글래스 콕핏 (Glass Cockpit)
전통적인 아날로그 원형 계기 배열을 대체하는 대형 다기능 전자 디스플레이가 장착된 비행갑판.