B2-13c: Autoflight PDF

Summary

This document is training material for a subject on Autoflight. It covers fundamentals, command signal processing, and different modes of operation in aircraft control systems. Topics include roll, pitch, yaw control, and various types of autopilot systems.

Full Transcript

Student Resource

Subject B2‐13c:
Autoflight
 Copyright © 2020 Aviation Australia
All rights reserved. No part of this document may be reproduced, transferred, sold, or otherwise
disposed of, without the written permission of Aviation Australia
CONTROLLED DOCUMENT

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 CONTENTS
Contents 3
Study Resources 4
Definitions 5
Introduction 6

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 STUDY RESOURCES
E. H. J. Pallett, & Shawn Coyle (1993). Automatic Flight Control, (fourth edition): Blackwell Science,
London.
Jeppesen Sanderson, (1974). Avionics Fundamentals, United Airlines.

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 DEFINITIONS
Define
 To describe the nature or basic qualities of.
 To state the precise meaning of (a word or sense of a word).

State
 Specify in words or writing.
 To set forth in words; declare.

Identify
 To establish the identity of.

List
 Itemise.

Describe
 Represent in words enabling hearer or reader to form an idea of an object or process.
 To tell the facts, details, or particulars of something verbally or in writing.

Explain
 Make known in detail.
 Offer reason for cause and effect.

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 INTRODUCTION
The purpose of this subject is to familiarise you with general engineering drawings, parts and
tooling typically used in aircraft maintenance engineering..
On completion of the following topics you will be able to:
Topic 13.3.1 Autoflight ‐Fundamentals
Explain the fundamentals of automatic flight control including working principle and define
current terminology.
Topic 13.3.2 Autoflight ‐ Command Signal Processing
Explain command signal processing.
Topic 13.3.3 Autoflight ‐ Modes of Operation
Explain the modes of operation in the following control channels:
 Roll
 Pitch
 Yaw
Topic 13.3.4 Autoflight Systems ‐ Yaw Damping
State the purpose of Yaw Dampers and explain their operation.
Topic 13.3.5 Helicopter Autoflight Systems
State the purpose of Stability Augmentation System (SAS) in helicopters and explain its operation.
Topic 13.3.6 Autoflight Systems ‐ Trim Control
State the function of Automatic trim control and explain its operation.
Topic 13.3.7 Autopilot Navigation Aids Interface
Explain the operation of Autopilot Navigation Aids interface.
Topic 13.3.8 Flight Management System Interface
Explain the operation of Flight Management Systems (FMS) including the navigation database.
Topic 13.3.9 Autoflight Systems‐ Autothrottle
State the purpose of Autothrottle systems and explain their operation.
Topic 13.3.10 Autoflight Systems‐ Autoland
Explain the principles and categories of Automatic Landing Systems:
 Modes of operation;
 Approach,
 Glideslope,
 Land and
 Go‐Around.
 System Monitors and Failure Conditions and
 Downgrade and Upgrade Procedures.

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TOPIC 13.3.1: FUNDAMENTALS
Table of Contents
List of Figures................................................................................................................................ 3
TOPIC 13.3.1: FUNDAMENTALS.................................................................................................... 5
Auto Pilot Purpose......................................................................................................................... 5
Inner Loop (Roll)........................................................................................................................ 7
Outer Loop (Altitude or Heading).............................................................................................. 8
Modes of Operation................................................................................................................... 9
Single Axis Autopilot................................................................................................................ 10
Two Axis Autopilot................................................................................................................... 10
Three axis Autopilot................................................................................................................. 10
Multi axis Autopilot.................................................................................................................. 10
Authority.................................................................................................................................. 10
Capture.................................................................................................................................... 11
Autopilot Principle of Operation.............................................................................................. 11
Selecting a New Heading......................................................................................................... 12
Engagement................................................................................................................................ 15
Autopilot Engagement............................................................................................................. 15
Synchronisation....................................................................................................................... 15
Amplification............................................................................................................................ 16
Turbulence............................................................................................................................... 16
Adaptive Gain Control.............................................................................................................. 16
Semi‐adaptive Gain Control..................................................................................................... 17
Self‐adaptive Gain Control....................................................................................................... 17
Wash Out................................................................................................................................. 17
Artificial Feel............................................................................................................................ 17
Control Surface Actuation........................................................................................................ 18
Controls................................................................................................................................... 18
Servomotors and Servo Actuators........................................................................................... 18
Actuators and Servos............................................................................................................... 19
Electro‐Pneumatic Servo.......................................................................................................... 22
Electro‐Mechanical Servo........................................................................................................ 23
Electrohydraulic Servo‐Actuators Power Assisted....................................................................... 24
Powered Flight Controls........................................................................................................... 24

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 Power Assisted Control............................................................................................................ 24
Power Operated Control.......................................................................................................... 25
Electro‐Hydraulic Actuators..................................................................................................... 26
Manual Operation.................................................................................................................... 27
A Summary of Actuator Operation to this Point...................................................................... 28
ON/OFF Solenoid..................................................................................................................... 30
ON/OFF Solenoid Operation.................................................................................................... 31
Transfer Valve.......................................................................................................................... 32
Transfer Valve Operation......................................................................................................... 33
Autopilot Actuator Operation.................................................................................................. 34
Artificial Feel............................................................................................................................ 35
Electrohydraulic Servomotors.................................................................................................. 36
Duplex Servomotors................................................................................................................ 37
Quadruple Redundant Duplex Hydraulic Actuator................................................................... 38
Quadruple Redundant Duplex Hydraulic Servo Actuator Schematic........................................ 40
Interlocks................................................................................................................................. 43

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List of Figures
Figure 1: Autopilot basic principles................................................................................................... 5
Figure 2: Basic autopilot (yaw control).............................................................................................. 6
Figure 3: Basic autopilot (pitch mode).............................................................................................. 6
Figure 4: Inner loop roll control........................................................................................................ 7
Figure 5: Outer loop.......................................................................................................................... 8
Figure 6: Outer loop control.............................................................................................................. 8
Figure 7: Basic 3‐axis autopilot.......................................................................................................... 9
Figure 8: Autopilot capture............................................................................................................. 11
Figure 9: Selecting a new heading................................................................................................... 12
Figure 10: Autopilot coupling.......................................................................................................... 13
Figure 11: Couple related to mode of operation............................................................................. 13
Figure 12: Auto land runway........................................................................................................... 14
Figure 13: Autopilot gain................................................................................................................. 16
Figure 14: Self‐adaptive gain control............................................................................................... 17
Figure 15: Electronic flight control system...................................................................................... 19
Figure 16: Actuators and servos...................................................................................................... 20
Figure 17: Pneumatic and electric servos........................................................................................ 21
Figure 18: Electro‐pneumatic servo................................................................................................ 22
Figure 19: Electro‐mechanical servo............................................................................................... 23
Figure 20: Electrohydraulic servo‐actuators ‐ power assisted......................................................... 24
Figure 21: Electrohydraulic servo‐actuators ‐ power operated....................................................... 25
Figure 22: Electrohydraulic actuator No. 1...................................................................................... 26
Figure 23: Electrohydraulic actuator No. 2...................................................................................... 27
Figure 24: Electrohydraulic actuator No. 3...................................................................................... 28
Figure 25: Electrohydraulic actuator No. 4...................................................................................... 29
Figure 26: Electrohydraulic actuator No. 5...................................................................................... 29
Figure 27: ON/OFF solenoid............................................................................................................ 30
Figure 28: On / off solenoid operation No. 1................................................................................... 31
Figure 29: On / off solenoid operation No. 2................................................................................... 31
Figure 30: Transfer valve................................................................................................................. 32
Figure 31: Transfer valve operation No. 1....................................................................................... 33
Figure 32: Transfer valve operation No. 2....................................................................................... 33
Figure 33: Autopilot actuator operation No. 1................................................................................ 34

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Figure 34: Autopilot actuator operation No. 2................................................................................ 35
Figure 35: Artificial feel unit............................................................................................................ 35
Figure 36: Electrohydraulic servomotor.......................................................................................... 36
Figure 37: Duplex servomotor......................................................................................................... 37
Figure 38: Quadruple redundant duplex hydraulic actuator........................................................... 38
Figure 39: Servomotors duplex with no command input................................................................ 39
Figure 40: Command input and transfer valves respond correctly................................................. 39
Figure 41: Duplex actuator remaining non‐failed half operates normally....................................... 40
Figure 42: Quadruple redundant duplex hydraulic servo actuator................................................. 41
Figure 43: Hydraulic duplex servo actuator with control and monitor circuitry.............................. 42
Figure 44: Hydraulic duplex servo actuator with analogue interface.............................................. 42
Figure 45: Interlocks........................................................................................................................ 43
Figure 46: Troubleshooting schematic No. 1................................................................................... 44
Figure 47: Troubleshooting schematic No. 2................................................................................... 44

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TOPIC 13.3.1: FUNDAMENTALS
Auto Pilot Purpose
The aircraft autopilot controls the aircraft in vertical speed, attitude and heading to reduce
workload and fatigue on the flight crew and to provide improved flight comfort and stability.
The basic principles of an autopilot are:
 Error sensing
 Correction
 Follow‐up
 Command

Figure 1: Autopilot basic principles

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 Figure 2: Basic autopilot (yaw control)

Figure 2 shows an aircraft which is on‐course and encounters a crosswind. The gyro senses the
heading change and the amplifier provides a signal to the servo to move the control surface.
A position sensor on the control surface provides a signal back to the amplifier to either null the
system or to give negative feedback to dampen the system.

Figure 3: Basic autopilot (pitch mode)

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All autopilots follow the basic principles of error sensing, correction, follow‐up and command,
although different types of sensors and servos are used.
The auto‐flight system, as with any control system, has an “inner loop” and an “outer loop”
The inner loop typically handles internal conditions such as:
 Attitude sensing
 Attitude changes in terms of error signals
 Processing of error signals
 Conversion of error signals into movement of flight control surfaces

Inner Loop (Roll)

Figure 4: Inner loop roll control

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Outer Loop (Altitude or Heading)
Raw data inputs such as air speed, altitude, magnetic heading and interception of ground‐based
radio aids for instance, can also constitute “outer loop” control.

Figure 5: Outer loop

Figure 6: Outer loop control

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Modes of Operation
Aircraft operating in automatic flight mode are capable of maintaining set operating parameters
depending on the stage of the flight.
These can include:
 attitude hold
 heading hold
 turbulence
 vertical speed hold
 airspeed hold
 altitude hold
 control wheel steering
 navigation:
o VOR
o ILS
o Aux
or several other modes as selected by the pilots to suit the stage of the flight.
A flight director system provides cues for the pilot to navigate and fly the aircraft, but a flight
director cannot control the aircraft. Only the pilot or the autopilot system can fly the aircraft.

Figure 7: Basic 3‐axis autopilot

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Single Axis Autopilot
A Single axis Autopilot is:
 Normally only roll axis and is the most basic concept
 Is used in small light aircraft for heading hold and basic radio coupling
 Originally known as a wing levelling device
Two Axis Autopilot
A Two axis Autopilot is:
 Typically roll and pitch
 Allows heading hold and radio coupling
 Has altitude and attitude hold capabilities.
Three axis Autopilot
A Three axis Autopilot provides attitude control about all three axes and is typically a fully
Automatic Flight Control (AFCS) System.
Multi axis Autopilot
Multi axis Autopilot is a system which controls an aircraft about the roll and pitch axis (two axis) or
roll, pitch and yaw axis (three axis). Sometimes the rudder has a yaw damper incorporated but this
is not considered a three axis system.
Authority
Limits may be placed on control signals that are demanded to prevent excessive attitude changes
or harsh manoeuvring.
It is necessary to monitor what is known as the authority of the AFCS. This means that limits must
be placed on any control signals that are demanded to prevent excessive changes to the attitude
of the aircraft, or to cause any harsh manoeuvring. For example, a typical roll channel incorporates
a bank angle limiter and a roll rate limiter.
The bank angle limiter limits any input signal to a value which is required by a particular mode of
operation. The maximum bank angle limit is 25 degrees to 30 degrees but can be changed
automatically depending which mode is selected. For example, 20 degrees for VOR on course
mode.
The roll rate limiter limits the rate at which the aircraft changes its bank angle by limiting the rate
at which the servo motor turns. Typical roll rate limit outputs are 1 1/2 degrees per second to 7
degrees per second.

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Capture
Radio deviation signals are sensed by the AFCS but are not used until capture occurs. The term
capture means the point at which the radio deviation is used by the AFCS as a reference to fly the
aircraft.

Figure 8: Autopilot capture

In the case of the ILS the capture point is determined by the vertical beam sensor in the pitch
channel and the lateral beam sensor in the roll channel. The beam sensors are voltage level
sensing circuits that satisfy certain switching functions and apply radio deviation to the signal
chain.
Autopilot Principle of Operation
To control autopilot steering the flight control computer can utilise many references. Heading,
attitude and instrument landing system commands.
The basis of operation to maintain a selected reference is typically conducted by selecting a
reference and then having the flight control system generate corrective attitude changes
whenever a deviation from the selected parameter is selected.
For example, the pilot flies onto a heading and engages heading hold. The actual heading and
desired heading signals are compared in an operational amplifier and any variation from the
desired heading will produce a differential between the two signals (phase or amplitude), which
will be applied to a servo amplifier to correct for the deviation.
Similarly, a parameter can be selected on an autopilot control box, e.g. rate of climb. When auto
pilot is selected the difference between the actual rate of climb and the selected rate of climb will
produce an error signal (from an Op Amp), which will only be nulled when the aircraft is climbing
at the same rate as selected.
This principle is the basis of all automated flight management. Aircraft actual parameters are
applied to Op Amps (or something similar) and are compared with desired parameters whenever
automatic pilot is engaged. Whenever a differential between selected parameter and actual
parameter is detected the aircraft attitude will be corrected to re‐align.

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In a fully computerised system heading changes can be programmed in advance.
Assume an aircraft is programmed to fly from Dubai to Sydney (Australia). The parameters are
typed into a Flight Management Computer (FMC). The aircraft takes off and heads for Singapore.
When the Inertial Reference System (IRS) determines the aircraft is over Singapore a signal will
trigger the change of heading required and the aircraft flight control system will respond and turn
onto the new selected heading for Sydney.
The maximum rate of turn permissible is typically programmed into the flight control computer so
as not to throw the aircraft into violent manoeuvres.
Selecting a New Heading
With heading hold engaged, when the pilot decides to select a new heading, he selects a new
heading by turning the heading marker on the HSI dial.
The aircraft is in position “A” flying on the original heading. The pilot selects a new heading by
turning the heading marker on the HSI. The new heading is compared to the aircraft’s actual
heading. The AFCS will immediately notice the difference and send an error signal through to the
aileron servo actuator to deflect the ailerons and the aircraft rolls and turns onto the new heading.
Once the aircraft has reached the new heading, the error signal is nulled, and the aircraft returns
to its straight and level attitude.

Figure 9: Selecting a new heading

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 Figure 10: Autopilot coupling

Couple – Related to the mode of operation – it is the provision of raw data input to the AFCS
relevant to a particular flight path.

Figure 11: Couple related to mode of operation

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Runway Visual Range (RVR). The range over which the pilot of an aircraft on the line of a runway
can see the runway surface markings or the lights delineating the runway or identifying its centre
line.
Decision Height (DH). A specified altitude or height in the precision approach at which a missed
approach must be initiated if the required visual reference to continue the approach has not been
established.
Categories of precision approach and landing operations:
Category I DH 200 feet and RVR 550 metres
Category II DH 100 feet and RVR 300 metres
Category IIIa No DH or DH below 100 feet and RVR not less than 175 metres
Category IIIb No DH or DH below 50 feet and RVR less than 75 metres
Category IIIc No DH and no RVR limitation.
NOTE: Special authorization and equipment required for Categories II and III.

Figure 12: Auto land runway

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Engagement
Autopilot Engagement
The basic principle of autopilots is to hold the aircraft in basic heading, pitch and roll channel
attitude at the time of engagement. An autopilot system is designed so there will be a gradual
transition when it is engaged, therefore if heading hold is engaged when aircraft is 90° from
selected heading, the aircraft will not immediately throw itself into a violent bank to capture the
commanded heading. The aircraft will be limited in its rate of heading change to perhaps 3° per
second, thereby taking 30 seconds or more to align to the commanded heading. Typically, the rate
of change of heading can also be selected by the pilot. The same gradual engagement is replicated
for any autopilot function.
The Autopilot Control Panel provides for engagement for the range of autopilot options, e.g.
Heading hold, Roll stabilisation and Vertical speed hold all engaged simultaneously to control a
climb to assigned altitude. Often autopilot cannot be engaged until pre‐set conditions are met, e.g.
roll stabilisation cannot be engaged until bank angle less than 10°, Autoland can only be engaged if
Radar Altimeter system functioning, Radar altitude hold, and barometric altitude hold cannot be
engaged simultaneously.
The Autopilot is engaged by selecting the appropriate switches and buttons to select the autopilot
functions desired.
Autopilot will not engage if:
 Interlock circuit not complete
 Circuit breakers not engaged
 Switches in incorrect positions
Synchronisation
The Synchronisation of signals is normally performed as a pre‐engage function. This is to remove
any standing signals that may cause snatching of the controls when initially engaged and allows
the autopilot to take control in a smooth manner. The attitude sensing elements, such as the
vertical gyro are continuously monitoring the aircraft’s attitude and supplying signals to the servo
motors. If the aircraft has been placed, for example, in a nose down attitude prior to engagement,
on engaging the autopilot would immediately receive an error signal from the vertical gyro. The
computer would then signal the servo motors to move the control surfaces to provide a nose up
attitude. It is therefore necessary to oppose the vertical gyro error signal and reduce it to zero
before engaging the autopilot. This ensures that the system is synchronised with the attitude of
the aircraft.

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Amplification
Any error signal derived from a detection device or command signal must be amplified, as they do
not have the magnitude to operate a servo actuator.
The type of aircraft and its handling characteristics will have a great bearing on the way it
responds to control surface movement. For example, an empty aircraft will respond quite
differently from the same one that has a full load of fuel and passengers on board. It is therefore
necessary for the AFCS to have a system which will adjust the ratio of the output signal to the
input signal to achieve the desired rate of response. The response of an aircraft to a command or
detection signal will therefore be determined by the gain of the amplifier circuits in the flight
control computer.
The gain or transfer ratio of an amplifier is the ratio of the output to the input. To put it another
way, the gain is equal to the transfer ratio, which is equal to output divided by the input.

Figure 13: Autopilot gain

Turbulence
An aircraft experiencing turbulent air conditions in flight will have varying degrees of load applied
to its structure. In these circumstances, the pilot will adjust speed, power and use of controls to
suit the prevailing conditions.
If the aircraft encounters turbulent conditions while the AFCS is engaged, the AFCS will correct for
any movement that takes place. However, this correction, in these conditions, could possibly lead
to additional loads being applied to the structure due to the rate at which the AFCS responds. This
can cause the AFCS response rate to get out of phase with the disturbance rate. The pilot would
normally disengage the AFCS in these conditions, but in some AFCS there is a mode selection
which reduces the gain of the pitch and roll channels thereby softening the response of the AFCS
to the disturbance (Turbulence Penetration).
Adaptive Gain Control
This term refers to the way in which the sensing of the handling characteristics in flight is carried
out by a system which is classified as either:
 Semi‐adaptive gain control
 Self‐adaptive gain control

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Semi‐adaptive Gain Control
This is a system of adjusting the gain of the amplifier using external signals. It is called gain
programming or gain scheduling.
As an example, a radio deviation signal could be used to control the gain within the computer.
Self‐adaptive Gain Control
This is a system whereby it monitors its own operation and automatically adjusts its own gain for
the best aircraft performance.
The system is controlled by a model reference which will adjust the system to give the best
response regardless of the flight conditions. Command signals are fed through the model to the
system, and as the gain is increased, the error signal is amplified and fed to the control servo. The
overall system is known as high loop gain because maximum gain is needed to get the best
response.

Figure 14: Self‐adaptive gain control

Wash Out
Wash out is the automatic sensing and opposition of any standing signals existing from attitude
signal transmitters.
This enables engagement of the Autopilot system without any sudden control surface position
change or ‘snatching’ of control surfaces.
Artificial Feel
Artificial feel is used to provide an artificial mechanical feedback between the control surfaces and
the pilot.
This feel is provided by a variety of methods depending on aircraft complexity and sophistication.
The feedback is provided so the pilot can determine what aerodynamic loads are on the control
surfaces.
This is necessary in some situations, as without this feedback, the pilot could demand a control
surface movement that exceeds the allowable aerodynamic loading.

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Control Surface Actuation
On small light aircraft the power to move the control surfaces is provided by the pilot. The control
column is physically connected to the control surfaces by cables and the pilot moves the control
surfaces by repositioning the control column or rudder pedals. As the control column or rudder
pedals are displaced, the movement is mechanically transferred to the control surface, the aircraft
attitude changes and the pilot re‐centres the control column or rudder pedals when the desired
attitude or heading is achieved. Any autopilot function in this simple system is nothing more than
the use of trim tabs to trim the aircraft to eliminate excessive drift and to relieve the pilot of the
necessity to continually maintain a force on the control column or rudder pedals in order to
maintain straight and level flight.
Controls
When the control column is moved backwards, the elevators are raised thereby decreasing the lift
of the horizontal stab so that the aircraft is displaced by a pitching moment about the lateral axis
into a nose up or climbing attitude.
Forward movement of the control column lowers the elevators to increase the lift of the
horizontal stabiliser and so the pitching moment causes the aircraft to assume a nose‐down or
descending attitude. Pitch displacements are opposed by aerodynamic damping in pitch and by
the longitudinal stability and as the response to elevator deflections is a steady change of attitude.
Elevators are essentially displacement control devices. Control column and control wheel
movements are independent of each other so that lateral and longitudinal displacements can be
obtained separately or in combination. This concept of having separate control movements for
each axis goes right through to the most complex automatic flight control systems with multi axis
control.
Servomotors and Servo Actuators
On larger aircraft it is physically impossible to move the control surfaces by muscles alone. All
aircraft, with the exception of light aircraft or very old aircraft, will incorporate some form of
power assistance (like power steering in a car) to move control surfaces. The power assistance is
provided by actuators or servos and these devices can operate from either mechanical input (like
your cars power steering) or electrical input. Once a flight control system is capable of
repositioning control surfaces by use of electrical signals, these signals can be provided by a
number of sensors to control the aircraft’s flight path. Instead of the pilot detecting an
uncommanded roll or heading change and moving the stick or pedals to counteract it, gyros,
accelerometers and other sensor equipment can detect the uncommanded attitude changes far
more accurately and then provide an electrical output to an actuator or servo. This is the basis of a
fly‐by‐wire or automatic flight control system.
The sensors detect uncommanded attitude changes and counter them. When the pilot moves the
control column or rudder pedals (a commanded attitude change) an electrical signal from the stick
or pedal transducers is transmitted to the electrically operated actuator and the control surface is
deflected by pilot input to achieve an attitude change. In this electrically operated system, it is
electrical signals not mechanical inputs which control the actuator or servo operation.

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Going one step further, the electrically operated flight control system can be programmed to fly a
specific route, at a specific altitude and then the pilot is simply along for the ride. The avionic
systems of the aircraft provides the flight control computer with inputs of heading, altitude,
waypoints, etc. and the flight control computer repositions the actuators with electrical signals to
maintain the aircraft on the programmed flight path. This attribute in an automatic flight control
system is called an autopilot.

Figure 15: Electronic flight control system

Actuators and Servos
The components used in an automatic flight control system (AFCS) to move the aircraft’s control
surfaces are called servomotors, servo actuators, or by the name of the control surface or channel
that it controls, for example rudder servo or pitch actuator.
The signals received from the AFCS computer are electrical. Therefore, the control of the actuators
is electrical. The servo actuators convert these electrical signals into control surface movement by
converting the electrical signal into mechanical motion which is usually done by torque motors or
solenoid controlled valves (electro‐hydraulic valves).
The three main types of servomotors are:
 electromechanical
 electro‐pneumatic
 electro‐hydraulic
Electromechanical and electro‐pneumatic actuators or servos are more suited to smaller aircraft,
and the typical installation in a modern commercial aircraft is an electro‐hydraulic system. Even
though some of the surface actuators may be electro‐hydraulic, it is not uncommon for others to
be electromechanical or electro‐pneumatic, e.g. flap motors may be electrically driven and throttle
boost actuators may be pneumatically driven when the remaining actuators may all be
hydraulically driven (aileron, rudder, elevators).

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Servomotors may be connected in series or parallel with the AFCS. A series servomotor is one that
moves the control surfaces without moving the pilot’s controls, whilst a parallel servomotor
moves the control surfaces and the pilot’s controls.
The most common actuator used on commercial aircraft flight control systems is the electro‐
hydraulic actuator.

Figure 16: Actuators and servos

Pneumatic and Electric Servos1
Simple servos found on light aircraft use vacuum sources like those which operate the gyroscopic
instruments. Pneumatic pressure is obtained from either an engine driven pump or from a tapping
at one of the engine compressor stages. The vacuum is directed to pneumatic servos that are
mechanically connected to the normal mechanical flight control linkages. The pneumatic servo is
an airtight housing which contains a moveable diaphragm. When vacuum is applied to the servo
the diaphragm is displaced pulling on the cable to reposition the flight control surface. Two of
these servos would be needed for each control surface, a “pull” and a “push” actuator.
Another method of driving the control surface of light aircraft is by use of an electric motor. These
servomotors may be powered by either AC or DC depending on the type of automatic flight
control system used. An electric motor servo can use a reversible DC motor and reduction gearing
to supply the force to move the flight control surface in both directions. Alternatively, a constant
direction motor can be used with magnetically switched clutches to engage a mechanism to apply
force to a control cable. The servomotor consists of an electromagnetic clutch, gearbox and drive
mechanism. It may also include an amplifier to amplify the command signal and a feedback system
such as a potentiometer or tachogenerator. The constant drive type has the advantage that the
inertia forces in starting and stopping the motor are eliminated so it can be engaged and
disengaged more rapidly and precisely.
When the AFCS computer sends a signal to the motor of the electric servomotor, it will drive the
gear train and subsequently the control surface in the desired direction. At the same time, it drives
a tacho generator to provide feedback to the computer for speed limiting and smoothing. A
follow‐up synchro is also driven by the motor which will send a signal back to the computer
indicating the actual position of the control surface. The synchro signal is of a phase opposite, but
in proportion to the control surface displacement and will null the output signal of the computer
when both signals are equal. Thus, control surface movement will cease.

1
(Pallett Automatic Flight Control pg. 200 and 201)

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Both the pneumatic and electric servos are only power assisting servos, with the flight control
system still fundamentally powered by the pilot’s muscles. The pneumatic and electric flight
control servos are limited to use in only light and simple aircraft. Neither of these examples are a
fly‐by‐wire system.
The actuators used in larger and more modern aircraft are typically electro‐hydraulic.

Figure 17: Pneumatic and electric servos

Pneumatic Servo – when vacuum is applied the diaphragm pulls the cable repositioning the flight
control surface.
Electric Motor Servo – can use a reversible DC motor or a constant direction motor with
magnetically switched clutches.
Electric Motor and Pneumatic (vacuum) powered servos are normally only incorporated in light
aircraft.
Neither of these are fly‐by‐wire systems – large modern aircraft typically use electro‐hydraulic
actuators which are entirely electrically controlled

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Electro‐Pneumatic Servo
An electro‐pneumatic servo consists of an electro‐magnetic valve with dual poppet ports
connected via pressure ports and orifices to two cylinders containing pistons sealed against
pressure loss. The valves are controlled by electrical command signals from the auto pilot and with
no signal present both valves are open.

Figure 18: Electro‐pneumatic servo

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Electro‐Mechanical Servo
This mechanism consists of an AC or DC motor and gear train, coupled to the flight control system
via an electro‐magnetic clutch, gear train and a sprocket and chain drive.
Feedback is provided by a potentiometer in a DC motor, and a CX synchro and a tachogenerator to
provide position and rate feedback signals for AC motors.

Figure 19: Electro‐mechanical servo

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Electrohydraulic Servo‐Actuators Power Assisted
Powered Flight Controls
These are used in high performance aircraft and consist of two main types:
 Power assisted
 Power operated
The main difference in the two systems is the way in which the actuators are connected to the
control surfaces.
Power Assisted Control
In the power assisted system, the pilot’s control stick is connected to the control surface via a
control lever. When the pilot pulls back on the stick to begin a climb, the control lever pivots about
point X and commences moving the control surface up. At the same time, the control valve pistons
are displaced allowing hydraulic fluid to flow to the left hand side of the actuating jack, which is
secured to the structure of the aircraft. The pressure exerted on the piston causes the whole servo
unit and control lever to move to the left and, because of the greater control effort produced, the
pilot is assisted in moving the control surface further.

Figure 20: Electrohydraulic servo‐actuators ‐ power assisted

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Power Operated Control
In this system, the control column is connected to the control lever only, whilst the servo unit is
directly connected to the control surface. The effort required by the pilot to move the control
column is that needed to move the control lever and control valve piston. The power required to
move the control surface is supplied solely by the servo unit’s hydraulic power. As there are no
forces transmitted back to the control column, the pilot has no feel of the loads acting on the
control surfaces and a means of artificial feel must be introduced at a point between the control
column and the connection to the servo unit control lever.

Figure 21: Electrohydraulic servo‐actuators ‐ power operated

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Electro‐Hydraulic Actuators
The transfer valve is an electrically controlled hydraulic valve which operates a piston assembly
called the autopilot actuator, which in turn operates the main control valve for the actuating
cylinder. The movement of the actuator is monitored by the output of a Linear Variable
Differential Transducer (LVDT). This will provide the follow up signal back to the computer. Direct
operation of the hydraulic power unit has two main advantages; one is the very low computer
power output required and the other is that it is more sensitive and accurate, due to the absence
of cable slack, stretch and drag.

Figure 22: Electrohydraulic actuator No. 1

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Manual Operation
In manual operation, the control column moves the control quadrant and we will assume this
relates to a back stick input to move the elevators. The pilot pulls the stick backwards to start a
climb (moves the cockpit control to the left on the slide), the control cables will turn the control
input quadrant which will move the upper end of the control valve actuator (long green arm) to
the left. At this point before the surface begins to move the control surface actuator is
hydraulically locked in position (shown still centred on the diagram, because this is before it begins
to move) so the control valve actuator (long green arm) is anchored at the bottom. The end result
of the top of the arm moving left is that the control valve will be displaced left. When the control
valve moves left hydraulic supply pressure is ported to the left hand side of the control surface
actuator, which will force the piston to the right.

Figure 23: Electrohydraulic actuator No. 2

The pressure applied to the left of the control surface actuator will force the piston to the right
moving the control surface. This will move the bottom anchor point of the control valve actuator
(long green arm) to the right and this time the top of the arm is held stationary (pilot still has
control column pulled back). The control valve spool will be moved to the right, thus
synchronising again and causing a hydraulic lock on either side of the control surface actuator
piston, locking the control surface in the commanded position (whilst ever the pilot maintains the
back stick input).

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A Summary of Actuator Operation to this Point
When the pilot applies back stick, the control valve ported hydraulic pressure through to the
control surface actuator, thus hydraulically driving the control surface to the commanded
position. The pilot input is only moving the control valve; it is the hydraulic pressure which drives
the control surface actuator. While the pilot retains the stick input the control surface will remain
in the position it has been driven to (just like a pilot holding back stick on a cable system – the
control surface will remain in the back stick position until the stick is re‐centred).
If no hydraulic pressure were applied, you can move the stick all you want, but the only effect it
has is to move the control valve. The control surface will not move without hydraulic pressure
applied.

Figure 24: Electrohydraulic actuator No. 3

The control surface will remain in the back stick position until the stick is re‐centred. When the
back stick is released, the same process as previously described occurs again. The bottom of the
control valve actuator (long green arm) is locked in place because the control surface is initially
still hydraulically locked in the extended position. With the bottom of the control valve actuator
(long green arm) locked, the control valve will be displaced to the right, porting hydraulic pressure
to the right side of the control surface actuator.

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 Figure 25: Electrohydraulic actuator No. 4

With the bottom of the control valve actuator (long green arm) locked, the control valve will be
displaced to the right, porting hydraulic pressure to the right side of the control surface spool
piston. The hydraulic pressure applied to the control surface spool piston will force the piston to
the left and retract the control surface. This will also reposition the control valve to the left re‐
centring it and again hydraulically locking the control surface in the central position until the
control column is again displaced.
This description of the flight control system operation still refers to a manually operated system.
No electrical inputs have been described yet. As you can see, actuator operation is dependent
upon control valve position. If we can electrically drive the control valve, we can control the
actuator with electrical signals alone.

Figure 26: Electrohydraulic actuator No. 5

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ON/OFF Solenoid
An ON/OFF solenoid is simply a hydraulic relay. With no electrical power applied, hydraulic
pressure is shut‐off because the solenoid spring holds the seat against a seal, preventing pressure
from being felt downstream.
When power is applied, the solenoid coil magnetises and unseats the valve (overpowers spring
pressure) and permits hydraulic oil to flow.
In the hydraulic actuator, the ON/OFF solenoid provides pressure to the transfer valve when
autopilot is activated. Power to the ON/OFF solenoid is typically controlled through a series of
monitors which detect any failures in the autopilot system. In the event that an autopilot failure is
detected, the ON/OFF solenoid is de‐energised, isolating autopilot inputs from the actuator.

Figure 27: ON/OFF solenoid

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ON/OFF Solenoid Operation
When the ON/OFF solenoid is energised, the transfer valve is provided with hydraulic pressure.
Typically, the pressure provided to the transfer valve nozzle will also be provided through the
ON/OFF solenoid, but that is not shown here to reduce the complexity of the diagram.
When the transfer valve is provided with hydraulic pressure, it is primed to convert the electrical
inputs into hydraulic outputs which will drive the autopilot actuator, controlling the control valve
and control surface actuator electrically instead of mechanically as previously described.

Figure 28: On / off solenoid operation No. 1

Figure 29: On / off solenoid operation No. 2

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Transfer Valve
Before looking at the operation of the actuator, we must understand the workings of the transfer
valve, which transforms electrical signals from the computer into hydraulic pressure. A transfer
valve is also often called an Electro‐Hydraulic Valve (EHV), or a hydraulic servo which can be driven
by torque motors directly connected to the Autopilot Actuator spool. As the torque motor style is
a high current application though, so the transfer valve and EHV style of electrical interface to the
hydraulic actuator are more common in modern flight control installations.
In Figure 28, on the right‐hand side, there is a coil of windings around a C shaped core. If a signal is
presented to this coil, it will move the permanent magnet armature up or down about its pivot.
The computer outputs a DC signal and the polarity of the signal determines the direction of
movement. Hydraulic fluid is fed into the unit through the feed pipe, passing through a flexible
tube which then divides across the pointed divider, just under the flexible tube. The feed pipe
provides full hydraulic system pressure to the transfer valve nozzle, but it is supplied through only
very narrow gauge plumbing because the work it has to perform to manipulate the spool valve is
minimal, so a high rate of flow of pressurised hydraulic fluid is unnecessary.
If there is no electrical signal to the coil, the flexible tube remains in the neutral position, due to
spring loading (represented by the two black lines connecting the nozzle point and the spool valve
piston assembly). In this position, the spool valve and feedback springs sense equal hydraulic
pressure at both ends and take up the neutral position, closing off both control ports.

Figure 30: Transfer valve

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Transfer Valve Operation
When the flight control computer sends a signal to the coil windings (either drawing the
permanent magnet attached to the nozzle up or down) the permanent magnet will rotate, moving
the nozzle in a direction dependent upon polarity of the input signal from the computer.
In the first illustration, this will cause a greater pressure to be directed to the top of the spool
valve than at the bottom. This moves the spool valve down. The spool valve will continue to move
down until the force of the feedback springs is sufficient to bring the flexible tube back almost to
the neutral position. With the spool valve moved down, hydraulic supply pressure is ported out
through the upper control port. This pressure is used to control the autopilot actuator spool valve,
which will be explained next slide.
With the spool valve down, hydraulic pressure is ported out the top control port and the bottom
control port is opened to the hydraulic return line.
If the electrical signal is of reversed polarity, the spool valve will move up instead of down, porting
hydraulic pressure through the bottom control port and opening the top control port to the
hydraulic return line.

Figure 31: Transfer valve operation No. 1

Figure 32: Transfer valve operation No. 2

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Autopilot Actuator Operation
On engaging the Automatic Flight Control System (AFCS), the ON/OFF solenoid opens and supplies
hydraulic pressure to the transfer valve. When an AFCS command signal is supplied to the coil
windings in the transfer valve, the spool valve nozzle is displaced. The hydraulic pressure is
applied to the right hand side of the autopilot actuator, causing it to move to the left. The control
valve actuator (long green arm) pivots on the control surface actuator and moves the control
valve to the left. This is the same movement as shown in the manual operation, except that the
input to the control valve actuator is provided by the autopilot actuator, not the cockpit control.
When the command signal is of the opposite polarity, the transfer valve nozzle moves down
forcing the spool valve up, which ports hydraulic pressure to the left side of the autopilot
actuator. When the autopilot actuator moves right, the control valve is forced to the right
providing pressure to the control surface actuator to drive the control surface.
On the actuator illustrated below, the electrical inputs driving the transfer valve and the autopilot
actuator reposition the control surface and also reposition the control column in the cockpit. Any
corrections made by the flight control computer will be felt at the control column.
Other actuators are designed so that electrical inputs only move the control surface and have no
effect on the cockpit controls. Damper signals are typical of this method of operation. When
aircraft oscillations are detected by a gyro, it outputs a signal through the flight control computer
to the actuator to counter the oscillations, but the rudder pedals or control column will not be
moved. This design of the actuator is not that different from the type described here, but the
differences will not be covered in this lesson.
As the autopilot actuator moves to the left, the autopilot LVDT produces an electrical output
which is sent back to the computer to null the command signal input.

Figure 33: Autopilot actuator operation No. 1

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 Figure 34: Autopilot actuator operation No. 2

Artificial Feel
Because the pilot has no feel of the aerodynamic loads acting on the control surfaces, it is
necessary to incorporate an “artificial feel” device at a point between the pilot’s controls and their
connection to the servo‐unit control lever.

Figure 35: Artificial feel unit

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This is commonly known as a “q” feel unit in which the feel force varies with the dynamic pressure
of the air sensed by the Pitot‐static system.
Q=1/2ΡV2
A “q” feel unit monitors hydraulic pressure and produces control forces dependent on the amount
of control movement and forward speed of the aircraft.
An artificial feel unit is connected at a point between the pilot’s controls and their connection to
the servo‐unit control lever – it restricts movement of the control column.
Electrohydraulic Servomotors

Figure 36: Electrohydraulic servomotor

 When the autopilot is engaged the A/P SOLENOID ACTUATOR energises and allows fluid
through to the A/P ENGAGE MECHANISM and up to the A/P SELECT VALVE.
 The SELECT VALVE compresses under fluid pressure and allows fluid to flow to the SPOOL
and TRANSFER VALVES
 The PCU receives signals from the A/P COMPUTER moving the TRANSFER VALVE thus
sending fluid to the MAIN ACTUATOR to move the AILERONS.

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Duplex Servomotors
In some aircraft the possibility of a hard over or runaway condition resulting from automatic flight
control malfunctions is prevented by utilising two independent control systems which displace
control surfaces via duplex servomotors and differential gearing.
The pitch and roll servo motors are of equal authority and torque and their outputs are summed
by their respective differential gearing. The yaw servomotor is of a single type with torque limiting.
When the commands from AFCS computer 1 and 2 to a servomotor are identical (normal
operation), the motions of both motors within the servo are identical, so providing doubled
authority to operate the appropriate control surface.
If, however, a malfunction in one system occurs such that a hard over roll is commanded by that
system, then it will turn the differential gear in the direction commanded. The other system
however, will, at the outset, detect the undesired attitude change and will command its motor to
rotate the differential in the opposite direction with the net result that the deflection is prevented.
Each motor is coupled electrically to a sensor known as a speed monitor, which in turn is
connected to braking units. The purpose of the monitor is to identify a runaway motor, which it
does within about 2 milliseconds, and then to apply a signal to the respective brake thus locking
out half of the differential gear and enabling the good motor to drive the control surface through
its half of the gearing. Since the servo power is halved, then any hard over risk in the remaining
control system is reduced. Additional redundancy typically incorporated is for 3 or 4 computer
channels.

Figure 37: Duplex servomotor

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Quadruple Redundant Duplex Hydraulic Actuator

Figure 38: Quadruple redundant duplex hydraulic actuator

Common command is applied to all EHVs from all 4 channels and all signals are identical and
complimentary. The DP (Differential Pressure) Sensors monitor the EHV outputs and when all
pressures are balanced (normal operation), no failure signal is generated.
If any detected computer fails (in a single channel), it turns off the command signal and the
remaining signals still command the actuator with no loss of efficiency: e.g. LVDT fail, cross
channel mismatch, wiring short or open circuit.
If a DP sensor detects EHV failure, the SOV controlling the EHV is turned off removing hydraulic
pressure from EHV. Pressure is still provided to the MCV and the main ram actuator continues to
function on the remaining good EHV with no efficiency loss. The bypass damper ports return
pressure to MCV to prevent hydraulic lock with the EHV de‐energised.
If the second EHV fails, the second SOV turns off and the actuator reverts to mechanical operation
for input directly to MCV.

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If there is no command input, the transfer valves are in the neutral position and the
pressures/flow rates P1 + P4 = P2 + P3. The Failure Sensor is centred and LVDT O/P (output) is
normal

Figure 39: Servomotors duplex with no command input

With the command inputs equal and the transfer valves response equal, P1 + P4 still equals P2 +
P3, the Failure Sensor is centred and the LVDT O/P is normal.

Figure 40: Command input and transfer valves respond correctly

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If a transfer valve is blocked or misaligned, P1 + P4 > P2 + P3 for example, the Failure Sensor piston
is driven from neutral – LVDT O/P to FCC indicates failure and the SOV is de‐energised. The
primary function of the failure sensor is to detect faults and disengage the EHV before any
uncommanded flight control input is made. In a duplex actuator, the remaining non‐failed half of
actuator continues to function normally driving the control surface.

Figure 41: Duplex actuator remaining non‐failed half operates normally

Quadruple Redundant Duplex Hydraulic Servo Actuator Schematic
The Schematic diagram Figure 42 is a hydraulic duplex servo‐actuator. Its components are:
 SOVs
 EHVs (Transfer Valves)
 DPs (Failure Sensors)
 System Selector valve
 Mechanical input – mode selector valve
 MCV
 Bypass Damper
 CAS LVDT – Rate feedback
 RAM LVDT – position feedback

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 Figure 42: Quadruple redundant duplex hydraulic servo actuator

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 Figure 43: Hydraulic duplex servo actuator with control and monitor circuitry

Figure 44: Hydraulic duplex servo actuator with analogue interface

Gain scheduling, interface with sensors and input devices is performed by the FCC processor. The
circuitry illustrated represents analogue interface with the actuator (just 1 channel is shown).

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Interlocks
Before an automatic control system can be engaged with an aircraft’s flight controls, certain
preliminary operating requirements must be fulfilled to ensure that the system is in a condition
whereby it may safely take control of the aircraft.
The principal requirements are that the connections between system power supplies, the
elements comprising the system, and the appropriate signal and engage circuits are electrically
complete.
It is the practice, therefore, to incorporate within any automatic control system a series of
switches and/or relays, known as interlocks, which operate in a specific sequence to ensure
satisfactory engagement and the coupling of input signals from outer loop control elements.

Figure 45: Interlocks

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 Figure 46: Troubleshooting schematic No. 1

Figure 47: Troubleshooting schematic No. 2

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TOPIC 13.3.2: COMMAND SIGNAL PROCESSING
Table of Contents
List of Figures................................................................................................................................ 4
TOPIC 13.3.2: COMMAND SIGNAL PROCESSING........................................................................... 7
Introduction.................................................................................................................................. 7
Autopilot Control Panels............................................................................................................... 7
Command Signal Processing.......................................................................................................... 8
Autopilot Sensors.......................................................................................................................... 9
E and I Bar Sensors..................................................................................................................... 9
Moving Vane Sensors............................................................................................................... 10
Dynamic Vertical Sensor.......................................................................................................... 11
Displacement Gyroscopes........................................................................................................ 12
Rate Gyro................................................................................................................................. 12
Accelerometers........................................................................................................................ 14
Torque Balanced Accelerometer.............................................................................................. 15
Modern Accelerometers.......................................................................................................... 16
Air Data Sensor........................................................................................................................ 17
Force Transducers....................................................................................................................... 18
Control Wheel Steering............................................................................................................ 18
CWS Transducer....................................................................................................................... 19
Linear Variable Differential Transformer (LVDT)......................................................................... 23
LVDT Operation........................................................................................................................ 23
Trim Tabs..................................................................................................................................... 25
Operation of Trim Tabs............................................................................................................ 25
Fixed Trim Tabs........................................................................................................................ 25
Controllable Trim Tabs............................................................................................................. 26
Trim Indicators............................................................................................................................ 27
Automatic Trim Control Devices.................................................................................................. 28
Cable Tension Trim Sensor....................................................................................................... 28
Servomotor Sensor.................................................................................................................. 29
Electro‐Hydraulic Servo Actuator................................................................................................ 30
Transfer Valve.......................................................................................................................... 30
AFCS Principles............................................................................................................................ 32
Fly–By–Wire Control System....................................................................................................... 33

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 Fly–By–Wire Benefits............................................................................................................... 33
Sidesticks................................................................................................................................. 33
Servomotors and Servo Actuators........................................................................................... 33
Closed Loop Feedback............................................................................................................. 35
Position Feedback.................................................................................................................... 36
Rate Feedback......................................................................................................................... 36
Feedback and Damping............................................................................................................ 37
Automatic Flight Control System (AFCS) Elements.................................................................. 38
Inner Loop................................................................................................................................ 38
Synchronising........................................................................................................................... 39
Gain and Adaptive Control....................................................................................................... 41
Limiting.................................................................................................................................... 44
Damping Systems..................................................................................................................... 45
Turbulence Penetration............................................................................................................... 46
Flight Control Surfaces............................................................................................................. 46
AFCS Operation........................................................................................................................... 48
Autopilot Principle of Operation.............................................................................................. 48
Autopilot Engagement............................................................................................................. 48
Autopilot Override................................................................................................................... 49
AFCS Failure Monitoring.......................................................................................................... 50
AFCS Failure Monitoring Circuits and Servo Amplifier............................................................. 51
Single Axis Auto Pilot............................................................................................................... 52
Single Axis Autopilot Components........................................................................................... 52
Three Axis Autopilot................................................................................................................ 54
Basic Autopilot System................................................................................................................ 56
Typical Autoflight Components................................................................................................ 56
Roll Channel............................................................................................................................. 58
Pitch Channel........................................................................................................................... 59
Turn Coordination....................................................................................................................... 60
Versine..................................................................................................................................... 61
Pitch Computer Versine Processing............................................................................................. 62
Roll Computer in Attitude Hold Mode..................................................................................... 63
Selecting a New Heading......................................................................................................... 63
Control Wheel Steering (CWS) Mode....................................................................................... 64

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 Autopilot Coupling....................................................................................................................... 65
ILS Localiser Element............................................................................................................... 65
Glide Path Element.................................................................................................................. 66
Autoland.................................................................................................................................. 67

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List of Figures
Figure 1: Autopilot controller – Beech King Air................................................................................. 7
Figure 2: Autopilot control panel – Boeing 777................................................................................. 7
Figure 3: Autopilot control panel – Airbus A330............................................................................... 8
Figure 4: E and I bar sensor operation.............................................................................................. 9
Figure 5: Moving vane transducer with two square wave inputs.................................................... 10
Figure 6: Moving vane transducer with offset vane........................................................................ 10
Figure 7: Dynamic vertical sensor................................................................................................... 11
Figure 8: A laser ring gyro schematic diagram................................................................................. 12
Figure 9: Rate gyro.......................................................................................................................... 13
Figure 10: Rate gyro response......................................................................................................... 13
Figure 11: Different types of accelerometers.................................................................................. 14
Figure 12: Accelerometer operation............................................................................................... 15
Figure 13: Torque balanced accelerometer.................................................................................... 16
Figure 14: Modern day accelerometers.......................................................................................... 16
Figure 15: Air Data Computer (ADC)............................................................................................... 17
Figure 16: Practical use of a force transducer................................................................................. 18
Figure 17: CWS selector switches.................................................................................................... 18
Figure 18: Mode select panel with CWS option.............................................................................. 19
Figure 19: Roll CWS location........................................................................................................... 19
Figure 20: CWS installation............................................................................................................. 20
Figure 21: CWS transducer.............................................................................................................. 20
Figure 22: Pitch CWS operation...................................................................................................... 21
Figure 23: Pitch CWS circuit operation............................................................................................ 22
Figure 24: LVDT principles of operation.......................................................................................... 23
Figure 25: LVDT signal generation................................................................................................... 24
Figure 26: Fixed trim tab................................................................................................................. 25
Figure 27: Controllable trim tabs.................................................................................................... 26
Figure 28: Trim indicator................................................................................................................. 27
Figure 29: ECAM trim indicator....................................................................................................... 27
Figure 30: Pitch trim control schematic.......................................................................................... 28
Figure 31: Electrically sensed pitch trim control circuit................................................................... 29
Figure 32: Electro‐hydraulic servo actuator.................................................................................... 30
Figure 33: Transfer valve................................................................................................................. 31

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Figure 34: Simplified AFCS principle of operation........................................................................... 32
Figure 35: Powered flight control.................................................................................................... 33
Figure 36: Using electrical and hydro‐mechanical power for flight controls................................... 34
Figure 37: Input applied to closed loop system............................................................................... 35
Figure 38: Response to closed loop input....................................................................................... 35
Figure 39: Simplified position feedback schematic......................................................................... 36
Figure 40: Simplified rate feedback schematic................................................................................ 37
Figure 41: Position and rate feedback comparison......................................................................... 37
Figure 42: AFCS elements................................................................................................................ 38
Figure 43: AFCS inner loop.............................................................................................................. 39
Figure 44: AFCS synchronising prior to engagement....................................................................... 39
Figure 45: Gain control.................................................................................................................... 41
Figure 46: Model referencing gain control...................................................................................... 42
Figure 47: Radio altitude control of GS and LOC signals.................................................................. 43
Figure 48: Gain programming with invalid radio altimeter signal................................................... 43
Figure 49: Bank angle and bank rate limiting.................................................................................. 44
Figure 50: Damping systems........................................................................................................... 45
Figure 51: Primary control surface operation................................................................................. 47
Figure 52: Autopilot mode control panel........................................................................................ 49
Figure 53: Shut Off Valve (SOV) interlock circuit............................................................................. 50
Figure 54: Servo amplifier failure monitoring circuits..................................................................... 51
Figure 55: Single axis autopilot....................................................................................................... 52
Figure 56: Autopilot components.................................................................................................... 52
Figure 57: Basic single axis autopilot schematic.............................................................................. 53
Figure 58: ’Mechanical Mike’ (the evolution of the modern airplane autopilot)............................ 54
Figure 59: Sperry automatic pilot diagram...................................................................................... 54
Figure 60: 3‐axis autopilot components.......................................................................................... 57
Figure 61: Roll channel circuit......................................................................................................... 58
Figure 62: Pitch channel circuit....................................................................................................... 59
Figure 63: Yaw channel sensor inputs and processing required for turn coordination................... 60
Figure 64: Rudder displacement command processing................................................................... 60
Figure 65: Versine command signal processing – level flight.......................................................... 61
Figure 66: Versine command signal processing – bank angle of 30 degrees................................... 61
Figure 67: Pitch computer versine processing................................................................................. 62

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Figure 68: Roll computer attitude hold mode................................................................................. 62
Figure 69: Heading hold function.................................................................................................... 63
Figure 70: LOC signal schematic...................................................................................................... 65
Figure 71: G/S signal schematic...................................................................................................... 66
Figure 72: Autoland configuration.................................................................................................. 67

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TOPIC 13.3.2: COMMAND SIGNAL PROCESSING
Introduction
Autopilot systems have various modes of operation that can be selected depending on the
function (e.g. maintain altitude, follow ILS glideslope, climb, descend etc.) that the pilot requires
the system to perform. Each different function may require input signals from different sensors.
The selected mode also determines how these outputs will be processed to produce the command
signals that will perform the selected autopilot function.
Autopilot Control Panels
Most autopilots have a mode control panel where the pilots can select the various functions
available to operate the aircraft. Terminology varies as does the number of functions,both of
which are dependent on the type of autopilot fitted and the complexity and requirements of the
aircaft in which it is installed.

Figure 1: Autopilot controller – Beech King Air

Figure 2: Autopilot control panel – Boeing 777

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 Figure 3: Autopilot control panel – Airbus A330

Command Signal Processing
The signals produced by error signal sensors, in whatever form the sensors may take, cannot be
applied directly to their associated servo‐actuators for 2 principal reasons:
 Further computation of signals is necessary particularly when outer loop control is
adopted, and
 the power of the signals is very low. They do not have sufficient power to control the
servomotors, solenoids, relays or the actuators that are designed to cope with the
aerodynamic loads acting on the flight control surfaces.
Therefore, in any one flight control system it is necessary to incorporate within the corresponding
servo control loops a signal processing system having some, or all, of the following functions:
1. Differentiation, e.g. deriving simulated rate information from a vertical‐axis gyroscope
signal sensor.
2. Demodulation, i.e. converting AC error signals into DC control signals where polarity
represents phase relationship.
3. Integration, e.g. to obtain simulated attitude information or to correct any sustained
attitude errors.
4. Amplification, e.g. to increase sensor signals to a level high enough to operate the
servomotors.
5. Limiting, e.g. to ensure that certain parameter changes are kept within prescribed limits.
6. Gain adjustments, e.g. to allow pre‐setting and/or automatic programming to adapt system
response to suit the handling qualities or flight path of an aircraft.
7. Programming, e.g. to produce a precise manoeuvre, e.g. when selecting a particular outer
loop control mode.
8. Applying feedback, e.g. signal processing to ensure that corrective control is proportional
to command signal inputs.

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Autopilot Sensors
E and I Bar Sensors
The E and I bar sensor requires an AC signal for excitation of the primary winding. They operate
using the same principles as an AC transformer. The primary differences are:
 An adjustable component that can vary the output signal, and
 Two ‘counter wound’ secondary windings that counteract each other in the null position.
In the right image of Figure 4 the movement of the I bar relative to the E section varies the air gap
resulting in the output signals illustrated.

Figure 4: E and I bar sensor operation

Another application of the E and I bar is illustrated in the left image of Figure 4 showing the ‘I’ bar
as have a lateral motion as would be used in an accelerator and side slip sensor.
When an aircraft maintains an attitude change which is cannot be sensed by the gyros, an
acceleration sensor can provide an output in a direct relationship to the attitude change. An I bar,
suspended between calibrated springs with the sensing axis aligned to sense acceleration in that
plane.

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Moving Vane Sensors
Moving vane transducers differ from E and I bar sensors in that they use two square wave signals
as excitation inputs. Two square wave A.C. signals that are 180 degrees out of phase are applied to
coils 1 and 3. In the null position there is no output to the computer/amplifierError! Reference
source not found..

Figure 5: Moving vane transducer with two square wave inputs

If two moving vane transducers were mounted on the inner and outer gimbal rings of a vertical
gyro to sense pitch and roll attitude changes, then during level flight there is no output. If there
was an attitude change detected by the gyros the transducer vane would have relative movement
to the coil assembly with the resultant output used as a command signal to the computer or
amplifierError! Reference source not found..

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 Figure 6: Moving vane transducer with offset vane

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Dynamic Vertical Sensor
The dynamic vertical sensor is a pendulum actuated synchro transmitter the axis of which is
aligned with the fore and aft axis of the aircraft.
The unit is oil damped and in a coordinated turn the pendulum aligns with the resultant of
centrifugal and gravitational forces. At the dynamic vertical there is no signal output but if the
aircraft is slipping or skidding, the pendulum will be displaced from the vertical with a signal
output.

Figure 7: Dynamic vertical sensor

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Displacement Gyroscopes
Aircraft attitude information is provided by sensors mounted to a stabilised or referenced
platform. Gyroscopes are commonly used to provide the stable reference and provide the primary
element of inner loop stabilisation.
The outputs of a gyroscope are used to provide attitude information to autopilot systems in a
similar manner to the way gyro outputs are displayed on gyro instruments. They detect aircraft
pitch, roll, and yaw movement and deviations in attitude or in the rate of change from a selected
attitude are converted into electrical error signals and sent to the autopilot computer.
On small aircraft, the autopilot sensors are commonly part of the attitude and heading gyro
display instruments.
Larger modern aircraft and autopilot systems use sensors that employ laser beams instead of a
spinning gyro rotor. These laser sensors are called Ring Laser Gyros (RLGs) or Fibre Optic Gyros
(FOGs). These devices are more expensive than mechanical gyros, but they do not precess, and
they eliminate the moving parts that generate errors and cause a conventional gyro to gradually
wear out.

Figure 8: A laser ring gyro schematic diagram

Rate Gyro
Where a displacement gyro utilises a gyros property of rigidity in space and measure displacement
around it, a rate gyro relies on a gyro being subjected to precessive forces against spring pressure
to determine rate of movement. The higher the rate of movement the greater the inertial force
applied to the gyro resulting in precession. The higher the rate of turn, the greater the precessive
force, the greater the movement against spring pressure.

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 Figure 9: Rate gyro

These units are used to measure the aircraft’s rate of turn. If the nose of the aircraft is deflected,
the gyro will sense this, and signals will be sent to the rudder to move the aircraft back to the
correct heading.
The rate gyro output shown below the aircraft represents the 400 Hz synchro signal developed
during an