플라이 바이 와이어 (Fly-by-Wire) (Fly-by-Wire)
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Definition
조종사의 조종 장치와 항공기 조종면 사이의 전통적인 기계식 연결을 대체하는 전자식 비행 제어 시스템.
What Is Fly-by-Wire?
Fly-by-wire (FBW) is a flight control architecture in which the physical connection between the pilot's sidestick or yoke and the aircraft's control surfaces — ailerons, elevators, and rudder — is replaced by electronic signals processed through flight control computers. The pilot's inputs become digital commands that computers interpret and translate into surface deflections, often with built-in envelope protection that prevents the aircraft from exceeding its structural or aerodynamic limits.
How It Works
When a pilot moves the sidestick on an Airbus A320, sensors measure the deflection and send electrical signals to the Flight Control Primary Computers (FCPCs). These computers calculate the appropriate control surface positions based on the pilot's intent, current flight conditions (speed, angle of attack, load factor), and programmed flight envelope limits. Servo actuators then physically move the surfaces. The system operates with triple or quadruple redundancy — if one computer fails, others take over seamlessly.
- Normal law: Full envelope protection active (bank angle limit, pitch protection, overspeed protection)
- Alternate law: Partial protection, activated when sensors degrade
- Direct law: Pilot inputs command surfaces directly, no protection — last resort
FBW integrates tightly with autopilot and the glass cockpit, sharing sensor data and computer infrastructure.
Evolution and Modern Systems
The Concorde used an early analog FBW system in the 1970s. The Airbus A320, entering service in 1988, was the first commercial airliner with a fully digital FBW system and sidestick controllers. Boeing adopted FBW on the 777 (1995) and later the 787, but retained the conventional yoke rather than Airbus's sidestick. The Airbus A380 and A350 use FBW with force-feedback sidesticks. Military aircraft like the F-16 were pioneering FBW in the 1970s, as their inherently unstable aerodynamic designs are only flyable via computer-mediated controls.
Regulatory Requirements
FBW systems must satisfy FAA AC 25.1309 and EASA AMC 25.1309 design assurance requirements, demonstrating catastrophic failure probability below 10⁻⁹ per flight hour. Software is developed to DO-178C Level A (highest integrity). Hardware follows DO-254. Certification requires extensive iron-bird rig testing, simulator validation, and flight test demonstration of all degraded modes before revenue operations begin.
Related Terms
자동 비행 시스템 (Auto-Flight System)
이륙 직후부터 착륙까지 항공기의 비행 경로와 에너지 상태를 관리하여 승무원의 업무 부담을 줄이고 정밀도를 향상시키는 자동 조종장치·자동 추력 장치·비행 지시기의 통합 자동화 장치.
조종실 (Cockpit)
비행 계기와 조종 장치가 있는, 조종사가 항공기를 조작하는 구역.
전기 버스 (Electrical Bus)
중요 장비에 우선적으로 전원이 공급되도록 우선순위 계층으로 구성되어 발전기·APU·배터리의 전기 에너지를 항전 장비와 시스템으로 분배하는 전력 배전망.
플라이-바이-라이트 (Fly-By-Light)
전기 배선 대신 광섬유 케이블로 조종 신호를 전송하여 전자기 간섭에 면역성을 갖는 첨단 비행 조종 시스템.
플라이-바이-와이어 혁명 (Fly-by-Wire Revolution)
기계적 케이블 및 유압 시스템을 전자 디지털 컴퓨터로 대체한 항공기 조종 시스템의 변혁으로, 1988년 취항한 Airbus A320이 상업적으로 선도했다.
유압 시스템 (Hydraulic System)
가압된 유압 유체를 통해 힘을 전달하여 비행 조종면, 랜딩 기어, 브레이크 등 항공기의 핵심 메커니즘을 작동시키는 고압 유체 동력 시스템.