- Martin Šipoš (guarantor)
- Martin Šipoš (guarantor)
- Department of Measurement
The course Integrated Modular Avionics (IMA) focuses on a modern concept of the approach to the development and design of aircraft electronics (avionics), where the transition from distributed HW systems to SW blocks. They use high-speed connections to exchange data in applications related to paid air transport. The existing regulatory basis and airspace sharing define the requirements for the accuracy, reliability, and functionality of electronic systems even in the event of a failure. In the course, students will learn details about the requirements for so-called safety-critical multi-sensor systems, methods of data processing from predetermined systems, fault detection methods, selection of primary computer and control system in parallel architectures, bus technology, and methods of testing/certification of aircraft instruments.
Processing of laboratory tasks and submission of required reports. Processing of individual work.
- Syllabus of lectures:
1) Integrated modular avionics - its development, standardization, architecture, and use (A380, B787).
2) Aircraft architecture. Aircraft buses ARINC 429, 629, 659. CSDB, ASCB.
3) AFDX aircraft buses, MIL-1553, STANAG 3910.
4) Industrial buses in aviation - CAN, CANaerospace. High speed and secure buses - SpaceWire, TTP, FlexRay, IEEE-1394.
5) Methods of analysis and testing of EMI and EMS aircraft systems. Design rules for aircraft systems from the EMC point of view.
6) The concept of Performance-Based Navigation (PBN), related requirements for sensor equipment, and accuracy of measured quantities.
7) Statistical data processing from redundant systems. Use of parallel / serial architectures and their limits. Use in data captured in aeronautical applications.
8) The concept of Failure Detection Isolation and Recovery (FDIR) in parallel redundant systems. Example of use in electronics of the control and monitoring system of aircraft engines FADEC.
9) Integrated sensor systems, methods of integration, and data sharing. Modeling of sensor systems. Use of models for condition monitoring and error detection (FDIR).
10) Software and its architecture, design of avionic systems - requirements, analysis of performance, reliability, and security. Demonstration of competency and life cycle.
11) Certification process in the design of avionics systems - requirements, analysis of performance, reliability, and safety. ICAO, EASA, aviation law, non-transferred products.
12) TSO standard, requirements, and expected outputs for SW certification according to DO-178 and HW according to DO-160. Examples.
13) Simulation systems and their categories. GPWS Dangerous Approach Warning System.
14) Cybersecurity, data access and security in on-board systems, and data sharing with air traffic control.
- Syllabus of tutorials:
Exercises are focused on the transmission of data from sensors using digital buses used in aviation, then they are focused on the field of electromagnetic compatibility. These are online exercises, which are presented in the form of a video presentation and then individual processing of the data provided.
The next part is focused on data processing from aircraft sensors and systems - error detection algorithms (FDIR) and algorithms for data fusion from various sources.
- Study Objective:
The goal of the study is to gain a practical view of data processing in aviation and its use for flight control.
- Study materials:
1) Cary R. Spitzer: Digital Avionics Handbook, Second Edition, Avionics: Development and Implementation, CRC Press, 2007, ISBN: 978-0-8493-8441-7.
2) Advanced Avionics Handbook, U.S. Department Transportation, Federal Aviation Administration, 2009.
3) Moir, Seabridge: Military Avionics Systems, John Wiley & Sons, 2006, ISBN: 2006.
4) Cary R. Spitzer: Digital Avionics Systems: Principles and Practice, Second Edition, 1993, 978-1-930665-12-5.
5) Moir, Seabridge, Jukes: Civil Avionics Systems, Second Edition, John Wiley & Sons, 2003.
6) Moir, Seabridge: Aircraft Systems Mechanical, electrical, and avionics subsystems integration, Third Edition, John Wiley & Sons Ltd, 2008.
Recommended literature is available at the lecturer.
- Further information:
- Time-table for winter semester 2021/2022:
- Time-table is not available yet
- Time-table for summer semester 2021/2022:
Wed Thu Fri
- The course is a part of the following study plans:
- Cybernetics and Robotics - Systems and Control (compulsory elective course)
- Cybernetics and Robotics - Robotics (compulsory elective course)
- Cybernetics and Robotics - Senzors and Instrumention (compulsory elective course)
- Cybernetics and Robotics - Aerospace Systems (compulsory course of the specialization, compulsory elective course)
- Cybernetics and Robotics - Cybernetics and Robotics (compulsory elective course)