Ingegneria Gestionale | MEASUREMENT SYSTEMS FOR INDUSTRY 4.0

cod. 0612600047

MEASUREMENT SYSTEMS FOR INDUSTRY 4.0

	0612600047
	DIPARTIMENTO DI INGEGNERIA INDUSTRIALE
	EQF6
	INDUSTRIAL ENGINEERING AND MANAGEMENT
	2019/2020

PERCORSO COMUNE

	YEAR OF COURSE
	YEAR OF DIDACTIC SYSTEM 2018
	SECONDO SEMESTRE

TEACHING UNITS

	SSD	CFU	HOURS	ACTIVITY	TYPE OF ACTIVITY
	ING-INF/07	6	60	LESSONS	OPTIONAL SUBJECTS

	Objectives
	KNOWLEDGE AND UNDERSTANDING THE TEACHING HAS AMONG ITS MAIN OBJECTIVES, THE STUDY OF THE ARCHITECTURES OF SENSOR NETWORKS AND DISTRIBUTED MEASUREMENT SYSTEMS THAT CAN BE USED IN THE FIELD OF MODERN INDUSTRY FOR AUTOMATION (OPERATIONAL AND MANAGEMENT) OF PROCESSES. IN PARTICULAR, WE WILL STUDY THE MAIN IOT TECHNOLOGIES FOR THE INTEGRATION OF SENSOR NETWORKS IN INDUSTRIAL NETWORKS FOR AUTOMATION AND PROCESS MANAGEMENT, WE WILL LEARN METHODS AND PROGRAMMING SKILLS IN GRAPHIC ENVIRONMENTS FOR THE IMPLEMENTATION OF DISTRIBUTED MEASUREMENT SYSTEMS AND FOR THE AUTOMATION AND REMOTE MANAGEMENT OF DATA (ALSO VIA MOBILE DEVICES SUCH AS TABLET OR SMARTPHONE). FINALLY, WE WILL LEARN THE MAIN DIAGNOSTIC TECHNIQUES FOR IMPROVING THE RELIABILITY OF THE DATA MEASURED BY THE SENSOR NETWORKS. KNOWLEDGE AND UNDERSTANDING OF UNDERSTANDING - ENGINEERING ANALYSIS: UNDERSTANDING OF THE TERMINOLOGY USED IN THE DEVELOPMENT OF MEASUREMENT AND CONTROL SYSTEMS FOR AUTOMATION WITH PARTICULAR ATTENTION TO THE COMMUNICATION INFRASTRUCTURES NECESSARY FOR THE AUTOMATION AND DIAGNOSTICS OF MODERN INDUSTRIAL PROCESSES. KNOWLEDGE AND UNDERSTANDING APPLIED CAPACITY - ENGINEERING DESIGN GENERAL CAPABILITIES FOR THE DESIGN, CONSTRUCTION AND USE OF A DISTRIBUTED MEASUREMENT SYSTEM FOR MODERN INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION APPLICATIONS. PROGRAMMING SKILLS WITH GRAPHIC ENVIRONMENTS FOR THE REALIZATION OF DISTRIBUTED MEASUREMENT SYSTEMS FOR INDUSTRIAL APPLICATIONS; LEARNING OF PROGRAMMING TECHNIQUES FOR THE AUTOMATION AND REMOTE MANAGEMENT OF DATA (ALSO VIA MOBILE DEVICES SUCH AS TABLET OR SMARTPHONE). JUDGMENT AUTONOMY - ENGINEERING PRACTICE: KNOWING HOW TO IDENTIFY THE MOST APPROPRIATE METHODS FOR EFFICIENTLY DESIGNING AND IMPLEMENTING A MEASUREMENT AND CONTROL SYSTEM FOR INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION. TRANSVERSAL CAPACITIES - COMMUNICATION SKILLS: KNOWING HOW TO EXPLAIN ORALLY A TOPIC RELATED TO THE DESIGN AND DEVELOPMENT OF MEASUREMENT SYSTEMS FOR INDUSTRIAL AUTOMATION (OPERATIONAL AND MANAGEMENT). TRANSVERSAL CAPACITY - LEARNING ABILITIES: KNOWING HOW TO APPLY THE ACQUIRED KNOWLEDGE TO CONTEXTS DIFFERENT FROM THOSE PRESENTED DURING THE COURSE. KNOW HOW TO DEEPEN THE TOPICS COVERED USING MATERIALS OTHER THAN THOSE PROPOSED. KNOWING HOW TO WORK IN A GROUP TO DESIGN AND BUILD A MEASUREMENT SYSTEM FOR INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION.

KNOWLEDGE AND UNDERSTANDING
THE TEACHING HAS AMONG ITS MAIN OBJECTIVES, THE STUDY OF THE ARCHITECTURES OF SENSOR NETWORKS AND DISTRIBUTED MEASUREMENT SYSTEMS THAT CAN BE USED IN THE FIELD OF MODERN INDUSTRY FOR AUTOMATION (OPERATIONAL AND MANAGEMENT) OF PROCESSES. IN PARTICULAR, WE WILL STUDY THE MAIN IOT TECHNOLOGIES FOR THE INTEGRATION OF SENSOR NETWORKS IN INDUSTRIAL NETWORKS FOR AUTOMATION AND PROCESS MANAGEMENT, WE WILL LEARN METHODS AND PROGRAMMING SKILLS IN GRAPHIC ENVIRONMENTS FOR THE IMPLEMENTATION OF DISTRIBUTED MEASUREMENT SYSTEMS AND FOR THE AUTOMATION AND REMOTE MANAGEMENT OF DATA (ALSO VIA MOBILE DEVICES SUCH AS TABLET OR SMARTPHONE). FINALLY, WE WILL LEARN THE MAIN DIAGNOSTIC TECHNIQUES FOR IMPROVING THE RELIABILITY OF THE DATA MEASURED BY THE SENSOR NETWORKS.

KNOWLEDGE AND UNDERSTANDING OF UNDERSTANDING - ENGINEERING ANALYSIS:
UNDERSTANDING OF THE TERMINOLOGY USED IN THE DEVELOPMENT OF MEASUREMENT AND CONTROL SYSTEMS FOR AUTOMATION WITH PARTICULAR ATTENTION TO THE COMMUNICATION INFRASTRUCTURES NECESSARY FOR THE AUTOMATION AND DIAGNOSTICS OF MODERN INDUSTRIAL PROCESSES.

KNOWLEDGE AND UNDERSTANDING APPLIED CAPACITY - ENGINEERING DESIGN
GENERAL CAPABILITIES FOR THE DESIGN, CONSTRUCTION AND USE OF A DISTRIBUTED MEASUREMENT SYSTEM FOR MODERN INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION APPLICATIONS. PROGRAMMING SKILLS WITH GRAPHIC ENVIRONMENTS FOR THE REALIZATION OF DISTRIBUTED MEASUREMENT SYSTEMS FOR INDUSTRIAL APPLICATIONS; LEARNING OF PROGRAMMING TECHNIQUES FOR THE AUTOMATION AND REMOTE MANAGEMENT OF DATA (ALSO VIA MOBILE DEVICES SUCH AS TABLET OR SMARTPHONE).

JUDGMENT AUTONOMY - ENGINEERING PRACTICE:
KNOWING HOW TO IDENTIFY THE MOST APPROPRIATE METHODS FOR EFFICIENTLY DESIGNING AND IMPLEMENTING A MEASUREMENT AND CONTROL SYSTEM FOR INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION.

TRANSVERSAL CAPACITIES - COMMUNICATION SKILLS:
KNOWING HOW TO EXPLAIN ORALLY A TOPIC RELATED TO THE DESIGN AND DEVELOPMENT OF MEASUREMENT SYSTEMS FOR INDUSTRIAL AUTOMATION (OPERATIONAL AND MANAGEMENT).

TRANSVERSAL CAPACITY - LEARNING ABILITIES:
KNOWING HOW TO APPLY THE ACQUIRED KNOWLEDGE TO CONTEXTS DIFFERENT FROM THOSE PRESENTED DURING THE COURSE. KNOW HOW TO DEEPEN THE TOPICS COVERED USING MATERIALS OTHER THAN THOSE PROPOSED. KNOWING HOW TO WORK IN A GROUP TO DESIGN AND BUILD A MEASUREMENT SYSTEM FOR INDUSTRIAL (OPERATIONAL AND MANAGEMENT) AUTOMATION.

	Prerequisites
	COMPULSORY PRE-REQUISITES ARE NOT REQUIRED BUT THE STUDENT SHOULD HAVE PREVIOUSLY ACQUIRED THE BASICS ON ELECTRICAL ENGINEERING, ON THE USE OF MEASURING INSTRUMENTS AND ON BASIC INFORMATICS.

	Contents
	1. ANALYSIS OF THE GENERAL REQUIREMENTS OF MODERN INDUSTRY WITH REFERENCE ALSO TO THE "NATIONAL INDUSTRY 4.0 PLAN". (4 HOURS OF THEORY) 2. ANALYSIS OF NETWORK INFRASTRUCTURES AND ENABLING TECHNOLOGIES FOR MULTI-DIRECTIONAL COMMUNICATION BETWEEN PRODUCTION PROCESSES AND PRODUCTS. (4 HOURS OF THEORY) 3. ARCHITECTURES OF DISTRIBUTED SYSTEMS FOR THE INTERNET OF THINGS (IOT): MAIN ELEMENTS OF A SENSOR NETWORK, CENTRALIZED AND DISTRIBUTED MEASURING SYSTEMS FOR PROCESS AUTOMATION. (6 HOURS OF THEORY) 4. WIRED AND WIRELESS COMMUNICATION TECHNOLOGIES FOR INDUSTRIAL SENSOR NETWORKS AND FOR SUPERVISORY CONTROL AND DATA ACQUISITION SYSTEMS (SCADA), GENERAL OVERVIEW AND CHOICE BASED ON THE CHARACTERISTICS OF APPLICATION CONTEXTS. (6 HOURS OF THEORY) 5. SELF-DIAGNOSIS TECHNIQUES FOR AUTOMATIC MEASUREMENT SYSTEMS TO INCREASE THE RELIABILITY OF THE MEASUREMENT DATA AND OF THE ENTIRE PROCESS. (6 HOURS OF THEORY) 6. FUNDAMENTALS OF LABVIEW PROGRAMMING FOR INDUSTRIAL AUTOMATION (CONTROLS, INDICATORS, CONTROL STRUCTURES, ITERATIVE CYCLES, INSTRUMENTATION MANAGEMENT THROUGH A COMMUNICATION BUS, REMOTE ACCESS OF DATA VIA LAN AND INTERNET). (16 HOURS OF LABORATORY) 7. DEVELOPMENT IN A LABVIEW ENVIRONMENT OF A GROUP PROJECT CONCERNING A MEASUREMENT APPLICATION FOR THE AUTOMATION AND MANAGEMENT OF PROCESS AND REMOTE MANAGEMENT THROUGH MOBILE DEVICES (TABLET AND / OR SMARTPHONE). (18 HOURS OF LABORATORY)

Contents

1. ANALYSIS OF THE GENERAL REQUIREMENTS OF MODERN INDUSTRY WITH REFERENCE ALSO TO THE "NATIONAL INDUSTRY 4.0 PLAN". (4 HOURS OF THEORY)
2. ANALYSIS OF NETWORK INFRASTRUCTURES AND ENABLING TECHNOLOGIES FOR MULTI-DIRECTIONAL COMMUNICATION BETWEEN PRODUCTION PROCESSES AND PRODUCTS. (4 HOURS OF THEORY)
3. ARCHITECTURES OF DISTRIBUTED SYSTEMS FOR THE INTERNET OF THINGS (IOT): MAIN ELEMENTS OF A SENSOR NETWORK, CENTRALIZED AND DISTRIBUTED MEASURING SYSTEMS FOR PROCESS AUTOMATION. (6 HOURS OF THEORY)
4. WIRED AND WIRELESS COMMUNICATION TECHNOLOGIES FOR INDUSTRIAL SENSOR NETWORKS AND FOR SUPERVISORY CONTROL AND DATA ACQUISITION SYSTEMS (SCADA), GENERAL OVERVIEW AND CHOICE BASED ON THE CHARACTERISTICS OF APPLICATION CONTEXTS. (6 HOURS OF THEORY)
5. SELF-DIAGNOSIS TECHNIQUES FOR AUTOMATIC MEASUREMENT SYSTEMS TO INCREASE THE RELIABILITY OF THE MEASUREMENT DATA AND OF THE ENTIRE PROCESS. (6 HOURS OF THEORY)
6. FUNDAMENTALS OF LABVIEW PROGRAMMING FOR INDUSTRIAL AUTOMATION (CONTROLS, INDICATORS, CONTROL STRUCTURES, ITERATIVE CYCLES, INSTRUMENTATION MANAGEMENT THROUGH A COMMUNICATION BUS, REMOTE ACCESS OF DATA VIA LAN AND INTERNET). (16 HOURS OF LABORATORY)
7. DEVELOPMENT IN A LABVIEW ENVIRONMENT OF A GROUP PROJECT CONCERNING A MEASUREMENT APPLICATION FOR THE AUTOMATION AND MANAGEMENT OF PROCESS AND REMOTE MANAGEMENT THROUGH MOBILE DEVICES (TABLET AND / OR SMARTPHONE). (18 HOURS OF LABORATORY)

	Teaching Methods
	THE COURSE INCLUDES FRONTAL LECTURES (26 HOURS), LABORATORY EXERCISES ON THE GRAPHIC ENVIRONMENT FOR THE DEVELOPMENT OF MEASUREMENT SYSTEMS FOR AUTOMATION (16 HOURS), AND DEVELOPMENT OF A GROUP PROJECT (REALIZATION OF A MEASUREMENT SYSTEM) FOR AUTOMATION AND PROCESS MANAGEMENT) IN THE LABORATORY ON A TOPIC ASSIGNED BY THE TEACHER (18 HOURS). DURING THE COURSE OF THE PROJECT EACH GROUP WILL BE FORMED BY A MAXIMUM OF 4 STUDENTS.

Teaching Methods

THE COURSE INCLUDES FRONTAL LECTURES (26 HOURS), LABORATORY EXERCISES ON THE GRAPHIC ENVIRONMENT FOR THE DEVELOPMENT OF MEASUREMENT SYSTEMS FOR AUTOMATION (16 HOURS), AND DEVELOPMENT OF A GROUP PROJECT (REALIZATION OF A MEASUREMENT SYSTEM) FOR AUTOMATION AND PROCESS MANAGEMENT) IN THE LABORATORY ON A TOPIC ASSIGNED BY THE TEACHER (18 HOURS). DURING THE COURSE OF THE PROJECT EACH GROUP WILL BE FORMED BY A MAXIMUM OF 4 STUDENTS.

	Verification of learning
	THE ACHIEVEMENT OF THE OBJECTIVES OF THE TEACHING IS CERTIFIED BY PASSING AN EXAM WITH EVALUATION IN THIRTIETHS (THE MINIMUM LEVEL OF EXCEEDING CORRESPONDS TO "18" AND THE MAXIMUM TO "30 CUM LAUDE"), WHICH PROVIDES FOR A SINGLE ORAL EXAM, LASTING INDICATIVE AVERAGE OF 40 MINUTES, AND AIMED AT: 1) VERIFY THE LEARNING OF THE TOPICS COVERED IN THE HOURS OF FRONTAL TEACHING; 2) VERIFY THE GROUP PROJECT CARRIED OUT ON A TOPIC ASSIGNED BY THE TEACHER; 3) THE ABILITY TO DISPLAY THE TOPICS ADDRESSED; 4) AUTONOMY OF JUDGMENT IN PROPOSING THE MOST APPROPRIATE APPROACH TO ARGUE AS REQUIRED. TO PASS THE EXAM, IT IS NECESSARY TO REACH SUFFICIENCY BOTH IN THE VERIFICATION OF THE LEARNING OF THE TOPICS COVERED IN THE THEORY HOURS AND IN THE INDIVIDUAL VERIFICATION (REALIZATION AND DESCRIPTION SKILLS) OF THE ASSIGNED LABORATORY PROJECT. IN ADDITION, THE STUDENT REACHES THE LEVEL OF EXCELLENCE IF HE DEMONSTRATES THE ABILITY TO MAKE CONNECTIONS BETWEEN THE THEORETICAL TOPICS COVERED AND DEMONSTRATES FULL MASTERY OF THE ACTIVITIES CARRIED OUT DURING THE LABORATORY PROJECT CARRIED OUT.

Verification of learning

THE ACHIEVEMENT OF THE OBJECTIVES OF THE TEACHING IS CERTIFIED BY PASSING AN EXAM WITH EVALUATION IN THIRTIETHS (THE MINIMUM LEVEL OF EXCEEDING CORRESPONDS TO "18" AND THE MAXIMUM TO "30 CUM LAUDE"), WHICH PROVIDES FOR A SINGLE ORAL EXAM, LASTING INDICATIVE AVERAGE OF 40 MINUTES, AND AIMED AT: 1) VERIFY THE LEARNING OF THE TOPICS COVERED IN THE HOURS OF FRONTAL TEACHING; 2) VERIFY THE GROUP PROJECT CARRIED OUT ON A TOPIC ASSIGNED BY THE TEACHER; 3) THE ABILITY TO DISPLAY THE TOPICS ADDRESSED; 4) AUTONOMY OF JUDGMENT IN PROPOSING THE MOST APPROPRIATE APPROACH TO ARGUE AS REQUIRED.
TO PASS THE EXAM, IT IS NECESSARY TO REACH SUFFICIENCY BOTH IN THE VERIFICATION OF THE LEARNING OF THE TOPICS COVERED IN THE THEORY HOURS AND IN THE INDIVIDUAL VERIFICATION (REALIZATION AND DESCRIPTION SKILLS) OF THE ASSIGNED LABORATORY PROJECT. IN ADDITION, THE STUDENT REACHES THE LEVEL OF EXCELLENCE IF HE DEMONSTRATES THE ABILITY TO MAKE CONNECTIONS BETWEEN THE THEORETICAL TOPICS COVERED AND DEMONSTRATES FULL MASTERY OF THE ACTIVITIES CARRIED OUT DURING THE LABORATORY PROJECT CARRIED OUT.

	Texts
	- Clyde f. Coombs, jr “Electronic Instrument Handbook”, second edition McGrawHill, inc. - Supplementary notes prepared by the teacher and available on the site indicated by the teacher.

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