DYNAMICS AND COMPLIANT DESIGN OF ROAD VEHICLES (MODULE 2)
cod. 1010710

Academic year 2024/25
1° year of course - Second semester
Professor
Carlo CONCARI
Academic discipline
Convertitori, macchine e azionamenti elettrici (ING-IND/32)
Field
A scelta dello studente
Type of training activity
Related/supplementary
30 hours
of face-to-face activities
3 credits
hub: UNIBO
course unit
in ENGLISH

Integrated course unit module: DYNAMICS AND COMPLIANT DESIGN OF ROAD VEHICLES

Learning objectives


The aim of the second module is to provide the theoretical basis and the practical skills required to design embedded hardware and firmware compliant with industrial standards (safety, interoperability, maintainability). In addition, model-based design and automatic code generation using Matlab/Simulink will be considered.

Prerequisites


Electronics fundamentals, coding fundamentals.

Course unit content


Embedded hardware and firmware design in compliance with industrial and safety standards, model-based design.

Full programme

Embedded hardware for compliant systems (1 hr)
Sensing, control, actuation, redundancy, power supply, insulation.

Structured approach to firmware design (2 hr)
V-model, levels of abstraction, validation, verification, documentation.

Real-time computing (3 hr)
Numerical approximation of functions and differential calculus, optimization.

Fixed-point ALUs (6 hr)
Fixed-point numeric formats, fixed-point arithmetic, normalized fractional format, computations with normalized quantities, examples (Ohm's law, magnetic flux observer for IMs), TDL structures, µC vs. DSP, fixed point numeric saturation.

Implementation: the building system (4 hr)
Source code, preprocessor, compiler, assembly language, machine code, internal operation of the CPU, registers, stack, assembler, linker, optimization.

Software testing and documentation (2 hr)
Unit testing, static and dynamic code analysis, code coverage, process documentation, inline documentation, Doxygen, authoring tools.

Version control systems (2 hr)
Concurrent development, centralized vs. distributed VCSs, SVN, GIT, repositories, update, commit, branching, tagging, merging.

Standards (1 hr)
Standardization organizations, operation, stage codes.

Safety standards (1 hr)
Introduction to safety standards, safety integrity levels, good programming practices.

Coding standards (2 hr)
Motivation, MISRA C, CERT C, Barr Group, rule examples.

Communication protocols (2 hr)
CAN, CANopen, J1939, introduction to industrial communication protocols.

Watchdogs (1 hr)
Timeout watchdog, windowed watchdog, hardware watchdog, independence, best practices.

Bootloaders (1 hr)
MCU vs. FPGA and SoC, MCU booting sequence, interrupt vector table relocation, OpenBLT.

Model-based design (2 hr)
Automatic code generation, model-in-the-loop, software-in-the-loop, processor-in-the-loop, rapid control prototyping.

Bibliography


Lecture notes, standards, and documentation of the software used.

Teaching methods


Lectures.

Assessment methods and criteria


Oral exam.

Other information

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2030 agenda goals for sustainable development

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