Caricamento in corso...
System health Management
01TAKRO
A.A. 2022/23
Lingua dell'insegnamento
Italiano
Corsi di studio
Dottorato di ricerca in Ingegneria Meccanica - Torino
Organizzazione dell'insegnamento
| Didattica | Ore |
|---|---|
| Lezioni | 20 |
Docenti
| Docente | Qualifica | Settore | h.Lez | h.Es | h.Lab | h.Tut | Anni incarico |
|---|---|---|---|---|---|---|---|
| Sorli Massimo | Professore Ordinario | IIND-02/A | 9 | 0 | 0 | 0 | 3 |
Collaboratori
Didattica
| SSD | CFU | Attivita' formative | Ambiti disciplinari | *** N/A *** |
|---|
The course intends to present the scope, the architecture, the enabling technologies, the design process and the performance metrics used in System Health Management, highlighting the relationship between traditional safety and reliability engineering methods and more recent approaches in detecting, diagnosing and predicting failures of complex engineering systems.
The course intends to present the scope, the architecture, the enabling technologies, the design process and the performance metrics used in System Health Management, highlighting the relationship between traditional safety and reliability engineering methods and more recent approaches in detecting, diagnosing and predicting failures of complex engineering systems.
ingegneria dei sistemi, sistemi controllati, attuatori, sensori, servosistemi
servosystems, actuators, sensors, systems engineering, controlled systems
1) FUNDAMENTALS
1.1: Background and objectives
1.2: Definitions
1.3: Functions and requirements
1.4: Reference architecture
1.5: Summary of enabling technologies
2) SENSING AND DATA PROCESSING
2.1: Transducing principles
2.2: Sensors placement
2.3: Virtual sensors
2.4: Smart sensors
2.5: Data processing
2.6: Use cases of signals analysis for health assessment: gears, bearings, lubricants
3) PROGNOSTICS AND HEALTH MANAGEMENT (PHM)
3.1: Faults monitoring, diagnosis and prognosis framework
3.2: Methodologies for fault diagnosis
3.3: Methodologies for failure prognosis
3.4: Performance metrics
3.5: Data mining
3.6: Use case: PHM applied to aircraft fight control actuators
4) SYSTEMS HEALTH MANAGEMENT APPLIED TO VEHICLES (IVHM)
4.1: IVHM design
4.2: Fleet user requirements
4.3: Operational scenario
4.4: End-to-end system
4.5: Vehicle level reasoning system
4.6: Autonomic logistic support
1) FUNDAMENTALS
1.1: Background and objectives
1.2: Definitions
1.3: Functions and requirements
1.4: Reference architecture
1.5: Summary of enabling technologies
2) SENSING AND DATA PROCESSING
2.1: Transducing principles
2.2: Sensors placement
2.3: Virtual sensors
2.4: Smart sensors
2.5: Data processing
2.6: Use cases of signals analysis for health assessment: gears, bearings, lubricants
3) PROGNOSTICS AND HEALTH MANAGEMENT (PHM)
3.1: Faults monitoring, diagnosis and prognosis framework
3.2: Methodologies for fault diagnosis
3.3: Methodologies for failure prognosis
3.4: Performance metrics
3.5: Data mining
3.6: Use case: PHM applied to aircraft fight control actuators
4) SYSTEMS HEALTH MANAGEMENT APPLIED TO VEHICLES (IVHM)
4.1: IVHM design
4.2: Fleet user requirements
4.3: Operational scenario
4.4: End-to-end system
4.5: Vehicle level reasoning system
4.6: Autonomic logistic support
In presenza
On site
Sviluppo di project work in team
Team project work development
P.D.2-2 - Aprile
P.D.2-2 - April
- 4 aprile ore 14.30-17.30 presso sala riunioni III piano Dimeas
- 5 aprile ore 14.30-17.30 presso sala C. Ferrari II piano Dimeas
Successivamente verranno concordati gli altri incontri
- 4 aprile ore 14.30-17.30 presso sala riunioni III piano Dimeas
- 5 aprile ore 14.30-17.30 presso sala C. Ferrari II piano Dimeas
Successivamente verranno concordati gli altri incontri