Autopilot Control Systems

An autopilot is an example of a control system. Control systems apply an action based on a measurement and almost always have an impact on the value they are measuring. A classic example of a control system is the negative feedback loop that controls the thermostat in your home. Such a loop works like this:

  1. It's summertime, and a homeowner sets his thermostat to a desired room temperature -- say 78°F.
  2. The thermostat measures the air temperature and compares it to the preset value.
  3. Over time, the hot air outside the house will elevate the temperature inside the house. When the temperature inside exceeds 78°F, the thermostat sends a signal to the air conditioning unit.
  4. The air conditioning unit clicks on and cools the room.
  5. When the temperature in the room returns to 78°F, another signal is sent to the air conditioner, which shuts off.

It's called a negative feedback loop because the result of a certain action (the air conditioning unit clicking on) inhibits further performance of that action. All negative feedback loops require a receptor, a control center and an effector. In the example above, the receptor is the thermometer that measures air temperature. The control center is the processor inside the thermostat. And the effector is the air conditioning unit.

autopilot feedback loop
Image courtesy Bill Harris

Automated flight control systems work the same way. Let's consider the example of a pilot who has activated a single-axis autopilot -- the so-called wing leveler we mentioned earlier.

  1. The pilot sets a control mode to maintain the wings in a level position.
  2. However, even in the smoothest air, a wing will eventually dip.
  3. Position sensors on the wing detect this deflection and send a signal to the autopilot computer.
  4. The autopilot computer processes the input data and determines that the wings are no longer level.
  5. The autopilot computer sends a signal to the servos that control the aircraft's ailerons. The signal is a very specific command telling the servo to make a precise adjustment.
  6. Each servo has a small electric motor fitted with a slip clutch that, through a bridle cable, grips the aileron cable. When the cable moves, the control surfaces move accordingly.
  7. As the ailerons are adjusted based on the input data, the wings move back toward level.
  8. The autopilot computer removes the command when the position sensor on the wing detects that the wings are once again level.
  9. The servos cease to apply pressure on the aileron cables.

This loop, shown above in the block diagram, works continuously, many times a second, much more quickly and smoothly than a human pilot could. Two- and three-axis autopilots obey the same principles, employing multiple processors that control multiple surfaces. Some airplanes even have autothrust computers to control engine thrust. Autopilot and autothrust systems can work together to perform very complex maneuvers.

Autopilot Failure

Autopilots can and do fail. A common problem is some kind of servo failure, either because of a bad motor or a bad connection. A position sensor can also fail, resulting in a loss of input data to the autopilot computer. Fortunately, autopilots for manned aircraft are designed as a failsafe -- that is, no failure in the automatic pilot can prevent effective employment of manual override. To override the autopilot, a crew member simply has to disengage the system, either by flipping a power switch or, if that doesn't work, by pulling the autopilot circuit breaker.

Some airplane crashes have been blamed on situations where pilots have failed to disengage the automatic flight control system. The pilots end up fighting the settings that the autopilot is administering, unable to figure out why the plane won't do what they're asking it to do. This is why flight instruction programs stress practicing for just such a scenario. Pilots must know how to use every feature of an AFCS, but they must also know how to turn it off and fly without it. They also have to adhere to a rigorous maintenance schedule to make sure all sensors and servos are in good working order. Any adjustments or fixes in key systems may require that the autopilot be tweaked. For example, a change made to gyro instruments will require realignment of the settings in the autopilot's computer.

The John F. Kennedy Jr. Crash
There has been much speculation about what caused the plane crash that killed John F. Kennedy Jr., along with his wife, Carolyn Bessette Kennedy, and her sister, Lauren Bessette, on July 16, 1999. Although the National Transportation Safety Board (NTSB) determined the probable cause of the accident to be pilot error due to spatial disorientation, some insist that a mechanical failure -- perhaps even a failure related to the autopilot -- contributed to the wreck.­

The plane, a Piper PA-32R-301, Saratoga II, N9253N, was equipped with a Bendix/King 150 Series Automatic Flight Control System, a two-axis autopilot that controlled pitch and roll. The investigation by the NTSB revealed that the autopilot had malfunctioned once or twice before the accident, turning the airplane to a new heading. The problem required that the autopilot be disengaged and then reengaged.

While such a problem with the autopilot could have contributed to the events leading to the wreck, it seems unlikely. In fact, some reports indicate that the autopilot had already been disengaged before the plane encountered problems.

Modern Autopilot Systems

Many modern autopilots can receive data from a Global Positioning System (GPS) receiver installed on the aircraft. A GPS receiver can determine a plane's position in space by calculating its distance from three or more satellites in the GPS network. Armed with such positioning information, an autopilot can do more than keep a plane straight and level -- it can execute a flight plan.

plane landing
Digital Vision/Getty Images
The newest autopilots can execute an entire flight plan.

Most commercial jets have had such capabilities for a while, but even ­smaller planes are incorporating sophisticated autopilot systems. New Cessna 182s and 206s are leaving the factory with the Garmin G1000 integrated cockpit, which includes a digital electronic autopilot combined with a flight director. The Garmin G1000 delivers essentially all the capabilities and modes of a jet avionics system, bringing true automatic flight control to a new generation of general aviation planes.

Wiley Post could have only dreamed of such technology back in 1933.

For more information about autopilots, check out the links on the next page.

Cruise Control -- Autopilot for Your Car
Autopilots aren't found only on airplanes. Ships have them, too, although they are often known by different names. Some captains refer to their ship's autopilot as "Metal Mike," a playful name that arose soon after Elmer Sperry invented the gyrocompass.

Others refer to the device as an "autohelmsman" because it assumes the role of helmsman, steering the ship efficiently with no human intervention. Even your car, if it's a later model, has an autopilot system. It's called cruise control, and it's another classic example of a control system. Cruise control automatically regulates the speed of your car using a feedback loop that involves a speed sensor and the car's accelerator.