- Docente: Alberto Martini
- Credits: 6
- SSD: ING-IND/13
- Language: English
- Moduli: Alberto Martini (Modulo 1) Marco Ezio Pezzola (Modulo 2) Alberto Martini (Modulo 3)
- Teaching Mode: Traditional lectures (Modulo 1) Traditional lectures (Modulo 2) Traditional lectures (Modulo 3)
- Campus: Bologna
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Corso:
Second cycle degree programme (LM) in
Mechanical Engineering (cod. 5724)
Also valid for Second cycle degree programme (LM) in Advanced Automotive Engineering (cod. 9239)
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from Sep 17, 2024 to Nov 07, 2024
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from Nov 26, 2024 to Dec 17, 2024
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from Nov 12, 2024 to Nov 21, 2024
Learning outcomes
Students are introduced to procedures and methods for modelling, identification, design, analysis of dynamical models of motorcycle systems. Tools: - analytical tools, to understand the basic system mechanical behaviour; - numerical tools, in order to simulate complex mechanical systems; - experimental tools, to make it possible critical parameters to be identified.
Course contents
- Motorcycle kinematics
- geometry and kinematic parameters
- steering angle and trim
- tire cross section and trajectory in a turn
- Suspensions
- architecture and kinematics of front and rear suspensions
- stiffness and damping characteristics
- determination of the reduced parameters
- Tire modelling
- analytical models
- semi-empirical models
- tire-road contact forces
- Motorcycle dynamics
- steady state rectilinear motion
- in-plane vibration modes
- road excitation models
- analysis of the effects of the motorcycle response on grip/handling and rider’s comfort
- transient rectilinear motion: acceleration and braking
- steady turning
- transient phases of cornering
- gyroscopic effects
- stability and motorcycle vibration modes
- influence of the main design parameters on stability
- techniques for experimental identification of the motorcycle modal parameters
- rider-motorcycle interaction (brief introduction)
- Numerical modelling of the motorcycle dynamics
- Lagrangian approach: stability in rectilinear motion; sensitivity analysis of the main parameters; stability in cornering; effects of structural stiffness on stability
- modelling with commercial software: simulating maneuvers characterized by high non-linearity; simulating critical events and scenarios; simplified models for traction-control/anti-wheelie and/or anti-lock braking systems
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Experimental tests and model validation
- experimental identification of physical parameters (mass, inertia tensor, tire characteristics, suspension characteristics, steering torque)
- estimation of kinematic quantities
- estimation of dynamic quantities
- virtual tests for implementing strategies to optimize the motorcycle performance: case studies
Readings/Bibliography
The slides shown during the course will be made available for download.
Suggested books (not mandatory):
- Cossalter V. Motorcycle Dynamics. 2nd ed. LULU, 2006.
- Pacejka HB. Tire and Vehicle Dynamics. 3rd ed. Oxford, Butterworth-Heinemann. 2012.
Teaching methods
The course comprises:
- theoretical lectures with blackboard, PowerPoint slides and the support of multimedia tools;
- lectures and seminars held by experts from Academia and Industry;
- classroom exercises with numerical tools and simulation software.
All the contents are taught in English.
Assessment methods
Final examination on the program of the entire course. Three oral questions, about 10-15 minutes for each question. The candidate may be required to draw schematics and/or to write expressions/equations with pen and paper. The candidate must achieve a sufficient score (18 out of 30) for each question in order to pass the exam. The score is assigned on the basis of:
- Knowledge of the specific topic (40 %)
- Ability to analyze and discuss different scenarios and possible interactions with other topics (30 %)
- Clarity in exposition and proper use of technical terminology (30 %)
The final grade is computed as the simple average of the scores of the three questions.
To be admitted to the exam, students must work on a group project (2 or 3 people), consisting in the analysis (and discussion) of a scenario with the numerical simulation tool illustrated during the course, and submit a report on the performed activity to the Examining Committee, at least 3 days prior to the selected exam date.
In compliance with the Art. 16 of the University Didactic Regulations, after a positive final grade has been assigned, the student can decide to retake the exam only once.
Teaching tools
Classroom exercises with commercial software for simulating maneuvers, events, scenarios and control models.
Office hours
See the website of Alberto Martini
See the website of Marco Ezio Pezzola
SDGs


This teaching activity contributes to the achievement of the Sustainable Development Goals of the UN 2030 Agenda.