1 / 35

ELEC4504/4906G AVIONICS SYSTEMS ENGINEERING

ELEC4504/4906G AVIONICS SYSTEMS ENGINEERING. INTRODUCTION. OBJECTIVES SOME HISTORY FACTORS AFFECTING AVIONICS DEVELOPMENT. COURSE OBJECTIVES. To provide the aeronautical engineering student with knowledge of: The basic principles behind the avionics systems used in civil aircraft

zanthe
Download Presentation

ELEC4504/4906G AVIONICS SYSTEMS ENGINEERING

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. ELEC4504/4906GAVIONICS SYSTEMS ENGINEERING

  2. INTRODUCTION • OBJECTIVES • SOME HISTORY • FACTORS AFFECTING AVIONICS DEVELOPMENT

  3. COURSE OBJECTIVES • To provide the aeronautical engineering student with knowledge of: • The basic principles behind the avionics systems used in civil aircraft • The factors which should be taken into account when installing avionics in aircraft and • How the avionics systems are used in the operation of a commercial aircraft

  4. COURSE OUTLINE • Organizational Framework • Air Traffic Control CNS – Communications/ Navigation /Surveillance • The Electromagnetic Spectrum • Navigation • Precision Approach Systems • Communications Systems • Radar and Surveillance Systems

  5. COURSE OUTLINE(CONTINUED) • Control Systems • Flight Management Systems • Display Systems • Electrical Systems • System Design • System Testing • Future Developments

  6. Factors Affecting Avionics Development Sometimes it appears to take a long time to introduce new systems into service. There are several reasons for this • Cost: • Number of systems in service • Benefits • Reliability

  7. ORGANIZATIONAL FRAMEWORK • ICAO (International Civil Aviation Organization) • National Civil Aviation Organizations (FAA, CAA, Transport Canada). • RTCA • SAE • ARINC • EUROCAE

  8. ORGANIZATIONAL FRAMEWORK • ICAO (International Civil Aviation Organization) • Part of the United Nations • Headquarters in Montreal • Since civil aviation is an international activity, it is beneficial for all nations to use the same standards for most aspects of their aviation operations.

  9. ICAO • ICAO provides this service through documents called SARPS (standards and recommended practices) • Examples of activities covered by SARPS are: • Aircrew licensing • Weather reports • Flight plan forms • Registration Markings • Navigation Systems

  10. ICAO • ICAO (Continued) • For example the SARPs on Navigation defines the characteristics of the Instrument Landing System (ILS) and includes: • Signal strength • Signal format • Accuracy • Coverage (distances at which usable signal can be detected)

  11. ICAO • ICAO (Continued) • Note that all of these documents are recommendations only. Each country (or state) makes its own laws and rules • It is advantageous, however, for a country to follow these SARPS since non-standard practices discourage other countries from operating into such states.

  12. ORGANIZATIONAL FRAMEWORK 2. RTCA (Requirements and Technical Concepts for Aviation) • Formerly known as the Radio Technical Committee for Aeronautics • and Radio Technical Commission for Aeronautics • An example of the FAA’s practice of contracting out much of its technical work • To understand the role of RTCA it is necessary to understand the FAA’s TSO (Technical Standard Order)

  13. RTCA • A given TSO is a minimum performance standard for a given piece of aircraft equipment (not restricted to avionics equipment) • A TSO authorization is the FAA’s recognition that a given design meets the TSO and also authorizes the manufacturer to produce it. • While the TSO authorization is not an approval to install the equipment it gives the equipment a very great advantage in obtaining certification for its installation One of the first questions you are asked, if you want to install some equipment in an aircraft is “is it TSO’d? Thus a TSO is very important

  14. RTCA • Q: Where do TSO’s come from? • A: RTCA When the FAA determines the need for a new piece of equipment e.g. a GPS receiver, it contacts the RTCA. RTCA then establishes a committee (called a special committee) and invites anyone with any interest in the subject to join the committee. (airlines, equipment manufacturers, FAA officials, aircraft associations and international representatives) GPS committee is SC-159 The committee produces a document called a MOPS (minimum operational performance standard) This is given a number preceded by DO e.g. the MOPS for the GPS receiver is DO-208

  15. RTCA • The RTCA MOPS is then submitted to the FAA which uses it as the basis for the TSO • The GPS receiver TSO is TSO-C129a • Thus the RTCA is a very powerful organization in the development of aircraft equipment (not just avionics)

  16. ORGANIZATIONAL FRAMEWORK • ARINC (Aeronautical Radio Inc) • Started in the 1930’s by a group of airlines to provide communications between their aircraft and their bases. • It still provides this service through the ATN (Aeronautical Telecommunications Network) and ACARS (Aircraft Communications and Addressing System) • For avionics, however it is important for standardizing aircraft electronics boxes, trays and connectors. • Later it developed standards for aircraft digital data busses.

  17. ARINC • ARINC (Aeronautical Radio Inc) • Started in the 1930’s by a group of airlines to provide communications between their aircraft and their bases. • It still provides this service through the ATN (Aeronautical Telecommunications Network) and ACARS (Aircraft Communications and Addressing System) • For avionics, however it is important for standardizing aircraft electronics boxes, trays and connectors.

  18. ARINC • ARINC (Aeronautical Radio Inc) • Started in the 1930’s by a group of airlines to provide communications between their aircraft and their bases. • It still provides this service through the ATN (Aeronautical Telecommunications Network) and ACARS (Aircraft Communications and Addressing System) • For avionics, however it is important for standardizing aircraft electronics boxes, trays and connectors.

  19. ARINC • Electronic Equipment in aircraft has to be • Firmly attached to the aircraft structure (by means of racks) • Wired in to the aircraft systems • Power • Signals • Controls

  20. ARINC • Early Electronic Equipment was not standardized and hence the mounting systems and connectors were different not only for each piece of equipment but for the same equipment from different manufacturers • Thus upgrading equipment was expensive and time consuming • ARINC devised a set of standard “black box” sizes and corresponding mounting systems as well as connector designs.

  21. ARINC • With standardized racks, boxes, trays and connectors, airlines could choose among various manufacturers of a particular item (e.g. Communications Transceiver) knowing that all they had to do was pull out the old set and plug in the new one.

  22. ARINC • The original standard was called ARINC 404. • Or ATR (Air Transport Racking) • “Black box” sizes were 1ATR, 3/4ATR, ½ ATR, ¼ ATR etc. • A 1ATR box was about 10” wide, 8”high and 22” deep • The latest racking standard is ARINC 600 series.

  23. ARINC • With the advent of digital communications in aircraft, ARINC developed popular digital data bus communications standards, primarily ARINC 429 and ARINC 629

  24. SAE • SAE (originally Society of Automotive Engineers, now SAE International) • Another organization which develops standards. • For avionics the primary publications are ARP’s (Aerospace Recommended Practices) • ARP5672 - Aircraft Precipitation Static Certification • AS 5672A - ARC Fault Circuit Breaker (AFCB), Aircraft, Trip-Free Single Phase and Three Phase 115 VAC, 400 Hz - Constant Frequency

  25. EUROCAE • EUROCAE is essentially the European version of RTCA • The two organizations work closely together and publish joint standards.

  26. AIR TRAFFIC CONTROL (ATC)AND ITS RELATIONSHIP TO AVIONICS SYSTEMS

  27. OBJECTIVES OF ATC • Maintain separation of aircraft • Expedite the flow of Air Traffic • NOT responsible for the separation of aircraft from the ground (except when in radar contact

  28. RESPONSIBILITES OF THE PILOT (GENERAL) • Maintain aircraft ATTITUDE • Navigate the aircraft from departure to destination • Avoid collision with other aircraft • How these are accomplished depends on the weather • (specifically ceiling and visibility)

  29. VISUAL METEOROLOGICAL CONDITIONS (VMC) • Generally 3 miles visibility and 1000 Ft. ceiling • Visual Flight Rules (VFR) apply • Attitude maintained by visual reference to the horizon • Navigation by reference to the ground (or electronic aids if pilot is able to and aircraft is so equipped • Separation from other aircraft by visual contact (see and be seen) Note: ATC will assist but is not responsible. • Aircraft not allowed to enter cloud

  30. VFR ON TOP • With extra training in radionavigation, pilots can fly in clear air above cloud • Note: Attitude is still with reference to the visible horizon • Climb and descent must not require entry into cloud

  31. INSTRUMENT METEOROLOGICAL CONDITIONS (IMC) • IMC exist whenever VMC do not • Obviously the rules pertaining to IMC are IFR (Instrument Flight Rules) • IFR apply in IMC and also to all flight above 18000 Ft in Canada and the USA (other altitudes are specified in other countries)

  32. INSTRUMENT FLIGHT RULES • Separation from other aircraft is responsibility of ATC • ATC issues “clearances” which are specific routes/altitudes which must be followed. • Attitude (pitch, bank and heading) is maintained with reference to instruments. • Simplest: artificial horizon and compass • More complex: inertial navigation system • Navigation is done using electronic navigation aids • Two way communication is required between pilot and controller • ATC must know where aircraft is • ATC radar requires a transponder on the aircraft

  33. INSTRUMENT FLIGHT RULES • On-board Collision Avoidance Systems supplement ATC • Terrain Avoidance Systems provide protection from CFIT (Controlled Flight Into Terrain) when aircraft is out of radar coverage

  34. Typical IFR Flight Procedure • Pilot plans route (including altitudes) from departure point to destination • Pilot files flight plan • ATC decides if flight plan can be accepted as is or if it needs to be amended • Prior to starting engines, pilot requests ATC clearance. • ATC gives clearance (may be just “flight planned route”) • Pilot contacts ground control for taxi clearance

  35. Typical IFR Flight Procedure • Aircraft taxis to runway • Takeoff clearance is obtained from Tower • After takeoff, pilot contacts Departure Control who gives “vectors” or a series of headings and altitudes to guide aircraft to the start of the route to which it has been cleared • Near destination, Arrival Control provides vectors to the landing approach. • Tower gives clearance to land • Ground Control gives clearance to taxi to arrival gate

More Related