글래스 콕핏 (Glass Cockpit) (Glass Cockpit)
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Definition
전통적인 아날로그 원형 계기 배열을 대체하는 대형 다기능 전자 디스플레이가 장착된 비행갑판.
What Is a Glass Cockpit?
A glass cockpit is a flight deck in which traditional electromechanical analog flight instruments — the altimeter, airspeed indicator, attitude indicator, vertical speed indicator, heading indicator, and navigation displays — are replaced by large multifunction liquid crystal or OLED screens. These displays can reconfigure to show any combination of flight data, system synoptics, moving maps, weather radar overlays, and traffic information, dramatically reducing cockpit clutter and pilot workload.
How It Works
The core of a glass cockpit is the Primary Flight Display (PFD) and Navigation Display (ND) — or a combined Electronic Flight Instrument System (EFIS). Data flows from:
- Air Data Computers (ADC): Airspeed, altitude, vertical speed, Mach number from pitot-static system
- Inertial Reference Systems (IRS): Attitude, heading, acceleration, ground speed
- GPS/FMS: Position and flight plan data overlaid on the moving map ND
- Engine/systems data: Displayed on Engine Indicating and Crew Alerting System (EICAS) or Electronic Centralized Aircraft Monitoring (ECAM) displays
The PFD integrates what once required six separate instruments into a single intuitive display. The ND overlays flight plan route, weather radar returns, TCAS traffic, and terrain. Pilots interact with display modes through dedicated control panels. Integration with the FMS and autopilot provides a fully coupled flight management environment, and a HUD can mirror PFD data into the pilot's forward view.
Evolution and Modern Systems
The Boeing 767 (1982) and Airbus A310 introduced early EFIS displays. The Airbus A320 (1988) introduced a full glass cockpit with sidestick and fly-by-wire. The Boeing 777 (1995) brought the world's first fully digital, triple-redundant glass cockpit. Today's A350 and 787 feature large-format displays (up to 15 inches), touchscreen CDUs, and synthetic vision systems that display terrain and runway in 3D even in zero-visibility conditions. General aviation glass cockpits — Garmin G1000, Avidyne Entegra — have become standard in new training and personal aircraft.
Regulatory Requirements
Display systems must meet RTCA DO-178C (software) and DO-254 (hardware) standards. Minimum display performance standards are specified in FAA TSO-C113b and EASA ETSO-C113b. Redundancy is required: at least one standby attitude indicator (often an ISIS — Integrated Standby Instrument System) must remain operational on battery power if all electronic displays fail. Type certification requires demonstration of readability under all lighting conditions including direct sunlight.
Related Terms
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.