Aircraft Digital Computer Systems PDF

Summary

This presentation details the architecture and functions of aircraft digital computer systems, particularly the Central Maintenance Computer System (CMCS). It explains how the CMCS facilitates troubleshooting and data transmission in modern aircraft.

Full Transcript

Aircraft Digital
Computer Systems
 CMC SYSTEM ARCHITECTURE

Introduction
When the mechanic receives the
pilot’s complaint, it should be possible
to start trouble shooting to locate the
source of the failure in an economical
way. On old generation aircraft, you
need to know many different methods
of trouble shooting.
 CMC SYSTEM ARCHITECTURE

Introduction
For instance each system test is
performed with an individual switch
either located on a cockpit panel or
on the front side of different
computers and in different locations
with specific methods of test result
presentation.
 CMC SYSTEM ARCHITECTURE

Introduction
Modern aircraft such as the A340,
A320 and 747--400, have a central
Maintenance computer system or
CMCS. The CMCS provides a central
location in the cockpit for trouble
shooting with standardized methods
of testing and fault reporting.
CMC SYSTEM ARCHITECTURE
 CMC SYSTEM ARCHITECTURE

The central maintenance
computer system consists of:
1. One or two central maintenance
computers or CMC located in the
avionic compartment
2. Two or three Multi-purpose
Control and Display Units or
MCDU in the cockpit as the main
interface between the operator
and the system
 CMC SYSTEM ARCHITECTURE

Central Maintenance
Computers or CMC

MCDU
CMC SYSTEM ARCHITECTURE

MCDU
 CMC SYSTEM ARCHITECTURE

The central maintenance
computer system consist of:
3. A printer in the cockpit for
hardcopies of the information.
4. A connection to the datalink
system called ACARS, for
transmission of the information to
the homebase.
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE

ACARS
 CMC SYSTEM ARCHITECTURE

The central maintenance
computer system consist of:
5. A digital computer in each aircraft
system which is connected to the
CMC in order to provide the
trouble shooting information.
 CMC SYSTEM ARCHITECTURE

The aircraft systems that are
connected to the CMC are those
made up of many components.
These systems need a computer to
manage their normal operation and
it is often difficult to locate a failure
source in them.
 CMC SYSTEM ARCHITECTURE

Typical examples of such systems are
the engine control system, all types of
avionic equipment such as
navigation, communication,
instruments and auto flight systems,
the fuel system, the landing gear and
brake system and the flight control
system.
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE
CMC SYSTEM ARCHITECTURE

The total number of complex
systems that are connected to the
CMC varies from aircraft to aircraft
but is between 50 and 100.
 CMC SYSTEM ARCHITECTURE

Simple aircraft systems, such as
the water system, which have a
small number of components, are
not connected to the CMC. Trouble
shooting for these systems must
be performed in the conventional
way.
 CMC SYSTEM ARCHITECTURE

Note that the CMCS and its
components can have different
names in different aircraft. For
instance in the A320 the CMC is
called the centralized fault
display interface unit (CFDIU)
and the CMCS is called the
centralized fault display system
(CFDS). However, the general
function is identical.
CMC SYSTEM ARCHITECTURE

CMC Schematic
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The CMCS has two modes of
operation. The modes are called
reporting mode
interactive mode.
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The first mode is called the
reporting mode. In this mode, the
CMC scans all of the aircraft
systems that are connected to it.
As it does this, the CMC memorizes
the transmitted fault information.
CMC SYSTEM ARCHITECTURE

CMCS Functions
This memorized fault information
can be read at anytime by use of
the MCDU or a printout from the
printer. It can also be sent to the
homebase via the datalink system.
CMC SYSTEM ARCHITECTURE

Reporting Mode
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The second mode is the interactive
mode. This mode can be selected
only on the ground and is mainly
used for system tests. To start the
interactive mode, select one aircraft
system from the MCDU followed by
a test start signal to the selected
system that now performs the test.
CMC SYSTEM ARCHITECTURE

CMCS Functions
Finally, the aircraft system sends
back the test results. These results
can then be read on the MCDU or
on the printout from the printer or
it can be sent via the datalink to
the homebase.
CMC SYSTEM ARCHITECTURE

Interactive Mode
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The CMC communicates with the
computers of the aircraft systems
via a specialized portion of the
computers called the BITE. BITE
stands for built in test
equipment.
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The BITE is located inside each
aircraft system computer but is
completely independent from its
operational part.
CMC SYSTEM ARCHITECTURE

CMCS Functions
The BITE has 2 functions

detect failures
perform tests on the ground.
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The first of these functions to
detect failures occurs during the
normal operation of the system. It
identifies the most probable cause
of the failure and sends this to the
CMC.
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The second function of the BITE, to
perform system tests, only occurs
when the aircraft is on the ground.
 CMC SYSTEM ARCHITECTURE

CMCS Functions
The test happens automatically
when electrical power is switched
on -- this is the power up test. The
same test and sometimes
additional tests can be started
manually from the CMC. The test
result is then sent to the CMC.
CMC SYSTEM ARCHITECTURE

BITE
 CMCS REDUNDANCY

In the reporting mode, information
from the various BITES is stored in
the memory of the CMC. To be
able to read this information after
the flight the CMC must be
operational.
 CMCS REDUNDANCY
However, if the CMC
fails during flight, this
would have a major
influence on the
maintenance activities.
It would not be possible
to read data or perform
tests from the MCDU.
Therefore the CMCS
must have a
 CMCS REDUNDANCY

This is completely fulfilled with a
second standby CMC. This
identical CMC receives the same
input data and the output
becomes active automatically
when the normal CMC fails.
CMCS REDUNDANCY
 CMCS REDUNDANCY

On some aircraft, the standby
CMC can be activated by pressing
a control pushbutton even if the
normal CMC is working.
CMCS REDUNDANCY

CMCS Redundancy
 CMCS REDUNDANCY

Redundancy is also possible via a
backup channel on the CMC but
this is limited to the interactive
mode only.
CMCS REDUNDANCY

CMC Backup Channel
 CMCS REDUNDANCY

MCDU Basics
The MCDU consist of
a control area with many push
buttons and one control knob
a display area which can be
either a color or monochrome
cathode ray tube or CRT
and several annunciator lights
to provide information to the
operator.
CMCS REDUNDANCY
 CMCS REDUNDANCY

MCDU Basics
The MCDU is used mainly during
flight to control the flight
management system. Many of the
control pushbuttons and
annunciators are only used for
that function and will not be
discussed here.
 CMCS REDUNDANCY

MCDU Basics
The only annunciator that is
important for CMC use is the FAIL
annunciator. It shows you that this
MCDU is defective and that you
must use another one.

The MCDU MENU annunciator is
also not used for CMC operation
and its function will therefore not
 CMCS REDUNDANCY

MCDU Basics
The brightness control knob
switches the MCDU on or off.
Normally a flight management
system display page appears
when the display is first
switched on. This knob also
allows adjustment of the display
brightness.
 CMCS REDUNDANCY

MCDU Basics
Note: that on some types of
MCDU it is not possible to switch
the display completely OFF but
only to decrease it in brightness.
CMCS REDUNDANCY
 CMCS REDUNDANCY

MCDU CMCS Data
After pressing the MCDU MENU
pushbutton the MCDU MENU
shows the systems which are
connected to the MCDU. Different
systems can be selected and you
can read their abbreviations on
the display.
 CMCS REDUNDANCY

MCDU CMCS Data
1.FM as we know already, stands
for flight management, which
is the system normally selected
during flight.
2.ACARS stands for aircraft
communication, addressing
and reporting system. This is
the datalink system that can
also be used for the CMCS.
 CMCS REDUNDANCY

MCDU CMCS Data
3.ACMS stands for aircraft
condition monitoring system
and provides information about
the engine, APU and certain
system condition.
4.CMS is the A340 abbreviation
for the CMCS and stands for
central maintenance
 CMCS REDUNDANCY

MCDU CMCS Data
A symbol, called the prompt, is
shown adjacent to a system or
function that can be selected. The
prompt points to a pushbutton
called a line select key.
 CMCS REDUNDANCY

MCDU CMCS Data
The line select key is pressed to
select the required function. There
are a total of 12 line select keys
called 1L to 6L and 1R to 6R. On
the lowest display line is the
SELECT DESIRED SYSTEM
message. This shows that you
have the choice to select the
 CMCS REDUNDANCY

Note: that only
the system
abbreviations are
different on
different MCDU’s.
CMCS REDUNDANCY
 CMCS REDUNDANCY

MCDU CMCS Data
Pressing line select key 4 Left
gives you the CMCS maintenance
menu. As you can see, this allows
the selection of the different CMC
functions.
CMCS REDUNDANCY
 CMCS REDUNDANCY

MCDU Display and Data Entry
The display screen consists 14
lines with a maximum of 24
characters in each. The top line is
called the title line and shows the
title of the selected display. Below
the title line are 12 data lines.
 CMCS REDUNDANCY

MCDU Display and Data Entry
The data lines are arranged in 6
pairs with a label line in small
fonts at the top and a data line in
large fonts below it. Each data line
has a right and left line select key.
 CMCS REDUNDANCY

MCDU Display and Data Entry
The bottom line is called the
scratchpad or message line. In
this line the MCD gives messages
to the operator such as select
desired system which we have
seen already.
CMCS REDUNDANCY
 CMCS REDUNDANCY

MCDU Display and Data Entry
The scratchpad is also used to
enter alpha numeric data into the
data lines. This is always
necessary if boxes appear in the
data line. To enter data, type the
necessary alpha numeric keys.
 CMCS REDUNDANCY

MCDU Display and Data Entry
The typed data appears in the
scratchpad you must then press
the LS key adjacent to the boxes.
The data is then transfered from
the scratchpad to the data field.
 CMCS REDUNDANCY

MCDU Display and Data Entry
Sometimes when you press the
line select key the data entry is
not accepted. This occurs if the
data that you have typed is too
long to fit into the boxed data field
or exceeds an allowed value. In
this case press the CLEAR
pushbutton on the alpha numeric
CMCS REDUNDANCY