History of Autopilot Development

The first autopilot systems were developed in the 1920s to assist pilots with long, monotonous flights. Early systems like Sperry's "Automatic Pilot" helped maintain altitude and heading but required frequent manual corrections. Through the 1930s and 40s, autopilots gained capabilities like automatic take-offs and landings. GYROS computers provided more robust altitude and heading holds. By the 1950s, autopilots could fly a complete instrument approach procedure. The jet age and new fly-by-wire technology further enabled automation.

Current Autopilot Components and Functions

Modern Autopilot Systems integrate complex sensors, computers and actuators. Gyroscopic systems still provide vital attitude and heading reference using laser or fiber optic gyroscopes. Advanced flight computers receive inputs from these gyros plus air data systems, GPS, terrain databases and other sources. Auto-Throttle functions manage engine power under computer command. Hydraulic or electric "servo" actuators manipulate primary and secondary flight controls following autopilot commands. Together these components can fly and navigate the aircraft automatically.

Altitude Hold maintains a selected cruising altitude by subtly adjusting pitch and power. Vertical Speed Hold controls climb and descent rates. Heading or Course Hold steers the aircraft to and along a selected compass radial or GPS waypoint. Most autopilots now include coupled VOR, LOC, ILS and GPS approaches with "fly-to" navigation. Advanced systems support "Managed" or "Required Navigation Performance" procedures down to Cat 1 minimums. Automatic Take-off and Landing functions assist in all phases from pushback to taxi and final approach.

Pilot Intervention and Monitoring

While autopilots handle routine flight duties, the trained crew must continually oversee automated functions. Pilots select and verify routes, set modes and parameters, and monitor the flight path against navigation sources. They intervene in non-normal or uncertain conditions. Autopilot disconnect buttons allow immediate manual recovery. Flight directors, in some aircraft separable from the autopilot, provide guidance symbology on the flight displays. This aids when hand-flying or to transition between auto and manual operation. Robust monitoring against failure is important, reinforcing the human role in aviation safety.

Future Autonomous Developments

Future autopilot systems advances aim to simplify flight while enhancing safety margins. "Glass Cockpit" flight decks integrate traditional instrumentation onto multi-function electronic displays. "Fly-by-wire" replaces mechanical controls with computerized flight control laws, enabling new modes. " Automatic " operations supplement the autopilot systems by handling taxi, takeoff and landing with limited crew input. Some functions edge close to "autonomous" aircraft operation. Researchers suggest vehicles that can fly predetermined schedules between gate and gate with no pilots aboard - though regulatory and liability issues remain barriers. For now and foreseeably, aviation oversight requires maintaining appropriate human supervision of automation. As technology progresses further, this optimized balance of automatic and crew functions will keep flight safer, greener and more accessible for all.

Get More Insights On Autopilot Systems