True full authority digital engine controls have no form of manual override nor manual controls available, placing full authority over all of the operating parameters of the engine in the hands of the computer. If a total FADEC failure occurs, the engine fails. If the engine is controlled digitally and electronically but allows for manual override, it is considered to be an EEC or
ECU. An EEC, though a component of a FADEC, is not by itself FADEC. When standing alone, the EEC makes all of the decisions until the pilot wishes to intervene. The term FADEC is often misused for partial digital engine controls, such as those only electronically controlling fuel and ignition. A turbocharged piston engine would require digital control over all intake airflow to meet the definition of FADEC. FADEC works by receiving multiple input variables of the current flight condition including
air density, power lever request position, engine temperatures, engine pressures, and many other parameters. The inputs are received by the EEC and analyzed up to 70 times per second. Engine operating parameters such as fuel flow, stator vane position, air bleed valve position, and others are computed from this data and applied as appropriate. FADEC also controls engine starting and restarting. The FADEC's basic purpose is to provide optimum engine efficiency for a given flight condition. FADEC not only provides for efficient engine operation, it also allows the manufacturer to program engine limitations and receive engine health and maintenance reports. For example, to avoid exceeding a certain engine temperature, the FADEC can be programmed to automatically take the necessary measures without pilot intervention.
Safety With the operation of the engines relying on automation, safety is a great concern.
Redundancy is provided in the form of two or more separate but identical digital channels. Each channel may provide all engine functions without restriction. FADEC also monitors a variety of data coming from the engine subsystems and related aircraft systems, providing for
fault tolerant engine control. Engine control problems simultaneously causing loss of thrust on up to three engines have been cited as causal in the
crash of an Airbus A400M aircraft at Seville Spain on 9 May 2015. Airbus Chief Strategy Officer Marwan Lahoud confirmed on 29 May that incorrectly installed engine control software caused the fatal crash. "There are no structural defects [with the aircraft], but we have a serious quality problem in the final assembly."
Applications A typical civilian transport aircraft flight may illustrate the function of a FADEC. The flight crew first enters flight data such as wind conditions,
runway length, or cruise altitude, into the
flight management system (FMS). The FMS uses this data to calculate power settings for different phases of the flight. At take-off, the flight crew advances the power lever to a predetermined setting, or opts for an auto-throttle take-off if available. The FADECs now apply the calculated take-off thrust setting by sending an electronic signal to the engines; there is no direct linkage to open fuel flow. This procedure can be repeated for any other phase of flight. In flight, small changes in operation are constantly made to maintain efficiency. Maximum thrust is available for emergency situations if the power lever is advanced to full, but limitations can not be exceeded; the flight crew has no means of manually overriding the FADEC. == Advantages ==