CATALOGUE OF COURSE UNITS HELD IN ENGLISH · and both space-time block and trellis codes will be...
Transcript of CATALOGUE OF COURSE UNITS HELD IN ENGLISH · and both space-time block and trellis codes will be...
University of Padova
FOR ERASMUS, FOREIGN AND ITALIAN STUDENTS
academic year 2014 > 2015
CATALOGUE OF COURSEUNITS HELD IN ENGLISH
School of Engineering
FIRST-CYCLE DEGREES WITH COURSE UNITS HELD IN ENGLISHAerospace EngineeringMechanical Engineering
SECOND-CYCLE DEGREES ENTIRELY HELD IN ENGLISHEnviromental Engineeringhttp://en.didattica.unipd.it/offerta/2014/IN/IN1825/2010
SECOND-CYCLE DEGREES WITH COURSE UNITS HELD IN ENGLISHAerospace EngineeringAutomation EngineeringBioengineeringChemical and Process EngineeringCivil EngineeringComputer EngineeringElectrical Energy EngineeringElectronic EngineeringEnergy EngineeringEngineering and Management (Vicenza campus)Materials EngineeringMechanical EngineeringProduct Innovation Engineering (Vicenza campus)Telecommunications Engineering
FOR COURSES BASED ON A SEMESTER ORGANIZATIONFirst semester: October 1st, 2014 to January 24th, 2015
Winter exams session: January 26th, 2015 to February 28th, 2015Second semester: March 2nd, 2015 to June 12th, 2015
Summer exams session: June 15th, 2015 to July 25th, 2015Extra exams session: August 24th, 2015 to September 23th 2015
First-cycle degree = Bachelor degreeSecond-cycle degree = Master degree
INDEX
ADVANCED COMMUNICATION TECHNIQUES
AIR POLLUTION CONTROL
APPLIED ACOUSTICS
ASEISMIC DESIGN OF BUILDING STRUCTURESBIOFUELS AND SUSTAINABLE INDUSTRIAL PROCESSES
BUSINESS STRATEGY
CHANNEL CODING
COASTAL MANAGEMENT AND PROTECTION
COMPUTATIONAL ELECTRICAL ENGINEERING
COMPUTER NETWORK MANAGEMENT
COMPUTER NETWORKS >>TELECOMMUNICATION NETWORKS
COMPUTER VISION AND 3D GRAPHICS
DESIGN OF STRUCTURES FOR ENVIRONMENTAL PROTECTION
DESIGN WITH COMPOSITE MATERIALS
DIGITAL TRANSMISSION
ECOTOXICOLOGY
ELECTRICAL ACTUATORS FOR AEROSPACE SYSTEMSELECTRICAL AND ELECTROMAGNETIC MICRO/NANODEVICES
ELECTRICAL MACHINE DESIGN
ELECTRICITY MARKET ECONOMICS
ELECTROMAGNETIC PROCESSING OF MATERIALS
ENERGY AND BUILDINGS
ENVIRONMENTAL ELECTRICAL SCIENCE
ENVIRONMENTAL FLUID MECHANICS
ENVIRONMENTAL GEOTECHNICS
ENVIRONMENTAL HYDRAULICS
First-cycle degree = Bachelor degreeSecond-cycle degree = Master degree
ENVIRONMENTAL IMPACT AND LIFE CYCLE ASSESSMENT
ENVIRONMENTAL PROJECT WORK
FLUID DYNAMICS SIMULATION
FUNDAMENTALS OF ASTRONOMY AND ASTROPHYSICS
GAME THEORY
GEOGRAPHICAL INFORMATION SYSTEMS
GEOLOGY AND GEOCHEMISTRY
GEOLOGY AND GEOPHYSICS
GLASS SCIENCE AND TECHNOLOGY
GROUNDWATER HYDROLOGY
IMAGE AND VIDEO ANALYSIS
INDUSTRIAL PLASMA TECHNOLOGIES
INNOVATION AND PROJECT MANAGEMENT
INNOVATION IN PROCESSES FOR METALLIC PRODUCTSINTEGRATED DESIGN OF PRODUCT, PROCESS AND PRODUCTION SYSTEM
INTERNATIONAL ENVIRONMENTAL LAW
IRONMAKING AND STEELMAKING
MATERIALS FOR ENERGETICS
MATHEMATICAL PROGRAMMING
MODELING AND CONTROL OF BIOLOGICAL SYSTEMSMODELING AND SIMULATION OF MECHANICAL SYSTEMSMODELLING AND CONTROL OF ENVIRONMENTAL SYSTEMSMULTIPHASE THERMODYNAMICS AND TRANSPORT PHENOMENA
NANOSTRUCTURED MATERIALS
NEARSHORE HYDRODYNAMICS AND COASTAL PROTECTION
NETWORK ANALYSIS AND SIMULATION
NETWORK MODELING
NETWORK SECURITY
NON LINEAR SOLID AND STRUCTURAL MECHANICS
OPERATIONS RESEARCH APPLICATIONS
OPTICAL AND QUANTUM COMMUNICATIONS
PHOTONICS DEVICES
POWER ELECTRONICS 1
POWER ELECTRONICS 2
PRECAST AND TIMBER STRUCTURES
PRODUCT AND PROCESS DESIGN
PRODUCT VARIETY MANAGEMENT
QUALITY AND METROLOGY IN MANUFACTURING
QUALITY OF INDUSTRIAL PRODUCTION
REAL AND COMPLEX ANALYSIS
REMEDIATION OF CONTAMINATED SITES
RIVER ENGINEERING
ROBOTICS, VISION AND CONTROL
SATELLITE NAVIGATION
SEPARATION UNIT OPERATIONS AND PROCESS SIMULATION
SERVICE OPERATIONS MANAGEMENT
SOIL PROTECTION PROJECT WORK
SOLID WASTE MANAGEMENT
SOURCE CODING
SPACE OPTICS INSTRUMENTATION
SPORTS ENGINEERINGS AND REHABILITATION DEVICES
STATISTICAL METHODS AND APPLICATIONS
SUSTAINABLE AND RENEWABLE RESOURCES
TELECOMMUNICATION NETWORKS
THERMONUCLEAR FUSION
UNIT OPERATIONS FOR THE FOOD AND PHARMACEUTICAL INDUSTRIESWASTE MANAGEMENT IN DEVELOPING COUNTRIES
WASTEWATER TREATMENT
WATER DISTRIBUTION AND DRAINAGE SYSTEMS
WATER RESOURCES MANAGEMENT
WATER SUPPLY TREATMENT
WIRELESS SYSTEMS AND NETWORKS
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
1
ADVANCED COMMUNICATION TECHNIQUES
ProgrammeThe course will focus on the two most important technologies for nowadays communication networks: orthogonal frequency division multiplexing (OFDM) and multiple input multiple output (MIMO) systems. Constant reference to standards, including 3G and 4G cellular communications, wireless LAN/MAN and digital video broadcasting will be provided to show application of the techniques. Various issues will be addressed, including design of OFDM systems, synchronization, channel estimation, peak to average power ratio (PAPR) reduction. About MIMO, transmission and reception with multiple antennas will be considered (as a part of already deployed communication systems) and both space-time block and trellis codes will be introduced. Concepts of diversity and multiplexing will be investigated. Decoding techniques for MIMO systems will be discussed, including the sphere decoder and interference cancellation decoder. Channel models currently used in standard development for MIMO systems will also be presented. Lastly, multiuser MIMO in cellular system will be studied. Detailed planned teaching activity:- Introduction, dispersive channel model, filterbank modulation.- Orthogonal Frequency Division Multiplexing (OFDM): scheme and orthogonality, guard interval.- Zero padding OFDM. Choice of symbol size. Waterfilling.- Synchronization for OFDM – Exercises.- Effects of Symbol time offset (STO), carrier
frequency offset (CFO) – Time synchronization methods.- CFO Synchronization methods – Exercises.- CFO estimation – Channel estimation for OFDM.- LS and MMSE – Exercises.- Expectation-minimization blind channel estimation.- Peak to average power reduction (PAPR): the problem – Exercises.- Clipping for PAPR. Tone reservation and tone injection.- Single carrier-frequency division multiple access (SC-FDMA) – Exercises.- Multiple input multiple output (MIMO) channel model and examples – MIMO capacity.- MIMO capacity, examples.- MISO capacity – Exercises.- Single input multiple output (SIMO) capacity- Pairwise error prob. Space-time block codes (STBC).- Space time coding (STC) design – Exercises.- Alamouti STBC – Maximum likelihood (ML) decoding of Alamouti.- Extension of Alamouti code – Exercises.- Space-time trellis codes – spatial multiplexing.- Spatial multiplexing (SM) minimum mean square error receiver – Exercises.- ML detection for SM.- Sphere decoder – Exercises.- Sphere decoder – final remarks.ExaminationWriting of a short report on an assigned topic. Discussion of the report and questions on the contents of the course.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INN1037839/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: tbdCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
AIR POLLUTION CONTROL
2
PrerequisitesNone.ProgrammeThe objective of this course is to deepen and apply the following main topics: 1 ) Air Pollution - The composition and structure of the atmosphere - Regulatory limits of regulated pollutants and air quality objectives. - Critical Exposure and chronic and protection of ecosystems. Costs related to air pollution, with reference to individual primary and secondary pollutants. - Chemical reaction kinetics / photochemical atmosphere. Persistence of pollutants. The role of OH radicals. Kinetics of pseudo-1st order. - Particulate matter: characteristics, mechanisms of formation and abatement techniques. Fine particulates: PM10 and PM2,5. Hazardous particulates.
2) Emissions and control (abatement) techniques: - Statement of EU, national and regional levels. Protocols and international guidelines (UN, Osparcom , Montreal , Kyoto) and the Regional Plan for the Protection and Rehabilitation of the atmosphere. - Concentration of pollutants (ppm ,%, mass/m3 , ...). Corrections of measured concentrations: normalization, conversion on a dry basis and % O2 reference. Comparison between units of measurement of emissions and air quality. Mass flows of pollutants emitted. Time mediation of
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Antonio MantovaniCredits: 6 CFU/ECTS
the concentration values (half-hourly, hourly, 6-8 hours, daily, monthly, yearly). - Macro emissions sources in the EU and in Italy. Directive NEC (National Emission Ceilings).- The role of prevention and the integrated approach: the European directive 2010/75/EU - so-called IPPC (Integrated Pollution Prevention and Control) - Conveyed, diffuse and fugitive emissions . - Models of dispersion of pollutants emitted into the atmosphere . Deposition of the pollutants. Technical factors (temperature, stack height and speed output ) that affect the concentration of depositions. The relationship between deposition and environmental impact. - Techniques for treatment of gaseous streams:• dust collectors ( baghouse filters , cyclones, electrostatic precipitators )• absorption in the liquid phase ( wet-scrubbers): neutralization of acid gases. Absorption Vs. stripping (eg. NH3)• desulfurization of flue gas.• treatment and thermal DeNOx catalytic NOx: stationary sources and motor vehicles.• activated carbon adsorption: fixed filters and in-duct injection• condensation of the vapors (VOCs)• Catalytic and Thermal oxydation• biofiltration. - Deepening the chain of flue gas cleaning from waste incineration plants.
3) Application of the European directive 2010/75/EU - IPPC : - list of affected industrial activities - Criteria IPPC and BAT (Best Available Techniques) - The role of resource-saving and energy efficiency. Requirement of minimum energy performance. - EU definitions: TWG, IEF, BAT-AEL, BREF. Decisions and Directives in European legislation. - The BREF - the mandatory guidelines in the release of the AIA (IPPC) - Illustration of examples of AIA issued at the state level, relating to thermal power plants and chemical industries.
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
ExaminationWritten. During the course is offered the opportunity to take the exam by two class assignments: a mid-course test, and the other just finished. About 90% of the students passed the exam with the mode of homework. Participation to the 2nd test is subjected to a minimum mark of 15/30 on the first one. You are given the possibility to repeat the 2nd session in Summer and Autumn; Alternatively, the student can redo the written examination test of the whole program.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01123478/N0
First-cycle degree in Mechanical EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Antonino Di BellaCredits: 6 CFU/ECTS
3
APPLIED ACOUSTICS
PrerequisitesNone.ProgrammeFundamentals of acoustic waves.Psychoacoustics and theories of hearing.Environmental and building acoustics.Measurement methods and common instrumentation.Noise control methods.Machinery noise.Community reaction.Legal aspects.ExaminationWritten testMore informationhttp://en.didattica.unipd.it/didattica/2014/IN0506/2011/002PD/INN1036256/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
ASEISMIC DESIGN OF BUILDING STRUCTURES
4
PrerequisitesStructural Desing I and IIProgrammeSeismic action and buildings performance related to code prescribed limit states. General criteria for aseismic design and modelling of structures. Methods for analysis and verification of RC and load-bearing masonry buildings and buildings with base isolation systems. Example of design for RC buildings: comparison between modal analyses and nonlinear static analyses (push-over); comparison between frame and wall-system structures. Example of design for load-bearing masonry buildings: comparison between static linear analyses and static non-linear analyses; comparison between un-reinforced and reinforced masonry buildings. Basics of base-isolation systems. Example of design for buildings with base isolation. Numerical methods for static and dynamic analysis of structures and application with software codes. Experimental methods in earthquake engineering.ExaminationPractical test: aseismic design and verification of buildings.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0517/2010/000ZZ/INO2043578/N0
Second-cycle degree in Civil EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Francesca Da PortoCredits: 9 CFU/ECTS
BIOFUELS AND SUSTAINABLE INDUSTRIAL PROCESSES
ProgrammeENERGY FOR SUSTAINABLE TRANSPORT: General issues and possible solutions. Introduction to life cycle analysis (LCA) techniques for sustainability process assessment.BIOFUEL PRODUCTION: Technologies for biofuel production from sugar/starch materials (I generation) or lignocellulose (II generation). Technologies for biodiesel production from vegetable oils (fundamental concepts concerning the usage of microalgae for oil production). Technologies for biogas production.PROCESS INTEGRATION: Scheduling and design of batch processes. Energy integration for sustainable production. Pinch analysis in process design: distillation columns, evaporation systems, integration between process and cogeneration systems. Usage of software for pinch analysis. Design of water networks in industrial processes: pinch analysis techniques for maximum water reuse and minimum wastewater treatment.ExaminationWritten exam (35% of final marks) and team work (65%). The team work focuses on the strategic analysis of an energy issue to be discussed through an oral presentation.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INP3050553/N0
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Fabrizio BezzoCredits: 6 CFU/ECTS
5
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
BUSINESS STRATEGY
6
PrerequisitesNone.ProgrammeStrategy concept: What is a strategy? What factors make a strategy successful? The different levels of Strategy: Functions, Business, Corporate, Network, Value, Vision, Mission.Analysis of the external environment: Industry Analysis, Demand and Supply Analysis, Strategic Groups.Analysis of the internal environment: Value chain analysis, Analysis of the firm resources and distinctive competences, Organizational structures.Strategy identification & selection: Generic Competitive Strategies, Cost Leadership, Differentiation and Focus, Strategic Positioning.Strategy implementation: Internal vs. External Growth: M&A.Business plan.ExaminationThe grade is calculated based on students’ participation, project work (business plan writing) and oral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0018843/N0
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: second semesterLecturer: Anna NosellaCredits: 6 CFU/ECTS
7
CHANNEL CODING
PrerequisitesAny introductory course on digital communications covering the basic concepts of digital transmission, and MAP and ML decision criteria (e.g., the ”Telecomunicazioni” course at the ”Laurea in Ingegneria dell’Informazione”).Programme- Hard versus soft decoding of block codes.- Introduction to linear codes.- Comparing codes performance via bit error rate and spectral efficiency.- Convolutional codes: properties, performance, and efficient decoding using the Viterbi algorithm.- Codes on graphs: convolutional, turbo, LDPC, repeat-accumulate, BICM, and trellis codes.- Decoding via message passing algorithms.- Analytical study of message passing performance for LDPCs.- Shannon’s capacity theorem: proof of direct and converse theorems.- Capacity for Gaussian, waveform, and parallel channels.- Capacity and coding for MIMO and multiple-antenna systems.ExaminationHomework, oral presentation of a project, Oral examination on theoretical aspects.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INP3060357/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Tomaso ErsegheCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
COASTAL MANAGEMENT AND PROTECTION
8
PrerequisitesHydraulicsProgrammeCoastal climate: wind, currents, sea level oscillations.Short waves: theoretical approach. Wave generation, forecasting and hindcasting. Wave regimes and extreme conditions evaluation. Wave propagation from offshore to shallow waters and associates phenomena. Wave-structures interactions.Hydrodynamics of coastal regions.Beach regimes, sediment characteristics.Coastal morphodynamics, coastal processes.Cross-shore and long-shore sediment transport.River deltas and inlets dynamics.Shore protection interventions: hard interventions (groins, detached breakwaters, etc.), soft interventions and mixed solutions. Beach nourishment. Innovative structures for coastal defence. Dune systems.Coastal management and environmental impact assessment of different policies.Wave energy converters.Mathematical and physical models for coastal studies.ExaminationOralMore informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043833/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Piero RuolCredits: 6 CFU/ECTS
COMPUTATIONAL ELECTRICAL ENGINEERING
PrerequisitesNone.ProgrammeElettromagnetism: Maxwell’s partial differential equations in terms of potentials, constitutive equations, boundary and interface conditions in terms of potentials, symmetries.Finite differences: Regular and irregular grids, curved boundaries, Theta method.Finite elements: Triangular and quadrilateral elements, shape functions, weighted residual and variational formulations, applications to 2D, axisymmetric and 3D problems, pre- and post-processing, applications and critical review.Electrical networks: Matrix description of topology, matrix representation of one-port and two-port components, linear networks in DC and steady-state AC, tableau analysis and nodal analysis, transient analysis of linear networks.Finite difference time domain method.Automatic optimization of electromagnetic devices: Main classes of methods, sensitivity, Pareto optimality.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2013/000ZZ/INL1001599/N0
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Piergiorgio AlottoCredits: 9 CFU/ECTS
9
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
COMPUTER NETWORK MANAGEMENT
10
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0521/2009/000ZZ/INL1001835/N0
Second-cycle degree in Computer EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Alexandru SoceanuCredits: 9 CFU/ECTS
11
COMPUTER VISION AND 3D GRAPHICS
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INO2043950/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
DESIGN OF STRUCTURES FOR ENVIRONMENTAL PROTECTION
12
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01122777/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Paolo FranchettiCredits: 9 CFU/ECTS
DESIGN WITH COMPOSITE MATERIALS
PrerequisitesThe preliminary requirements for the course are those for admission to the Master’s Programme in Product Innovation Engineering.ProgrammeGeneral characteristics of polymer composites, outline of the main production processes and comparison with other structural materials. Theory of elasticity for anisotropic bodies. Micromechanical analysis, elastic properties and strength of unidirectional lamina. Classical lamination theory. Criteria of static failure. Resistance and stiffness oriented design of composite structures. Notch and edge effects in composite structure. Thermal stresses. Sandwich Structures. Experimental characterization of composite laminates and NDT. Strategies for numerical analysis of composite structures. Examples of applications.ExaminationThe exam, in written form, consists in 5-6 open questions on the subjects illustrated during the course. For the higher marks there is the possibility of an oral integration for a deeper discussion on the questions answered in written form.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0531/2008/000ZZ/INP3059720/N0
Second-cycle degree in Product Innovation EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Marino QuaresiminCredits: 6 CFU/ECTS
13
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
DIGITAL TRANSMISSION
14
PrerequisitesBasic knowledge of signals, systems and transmission.ProgrammeSignal and system analysis: baseband and passband (baseband equivalent model) digital transmission systems, Wiener filter and linear prediction, spectral estimation methods.Adaptive transversal filters: LMS and RLS algorithms.Radio link: baseband and discrete time equivalent models, random models, simulation models.Transmission over dispersive channels: intersymbol interference (ISI), Nyquist criterion for the absence of ISI, performance evaluation in the presence of ISI.Equalization: linear and non linear (cancelation based).Optimum data detection in dispersive channels: Viterbi and forward-backward algorithms.Synchronization: timing and carrier phase recovery, many practical methods.Multicarrier systems (OFDM): architecture, orthogonality conditions, performance and efficient implementation.ExaminationFour homeworks will be assigned, which need the use of Matlab, and a final exam at the end of the course.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INP3050608/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Nevio BenvenutoCredits: 9 CFU/ECTS
15
ECOTOXICOLOGY
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1000954/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Alberto PivatoCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
ELECTRICAL ACTUATORS FOR AEROSPACE SYSTEMS
16
PrerequisitesIt is necessary to know basis of Electrotechnique and Electrical Machines theory.ProgrammeBasic concepts of electromechanical energy conversion.Main electrical machinery: DC motor, induction motor, synchronous machine.Classification, design criteria, problems. Engines with very high dynamics.Power electronics: electronic components, static converters, rectifiers uncontrolled and controlled, chopper, inverter, PWM modulation techniques.Criteria for choosing motors and drives: load characteristics, identification of the mechanical characteristics of the machines most appropriate choice of the type of drive and control.Sizing criteria, calculating magnetic loss calculations, thermal calculation and thermal network.Outline of project drive with speed control and position for certain types of electric motor, the block diagram of the system, the choice of the regulator.Solutions of electric motors and electric converters redundant likely to present a high fault tolerance to temporary or permanent (fault-tolerant).PRACTICAL ACTIVITY IN LABORATORY: development of low power electromechanical systems (e.g., robots, controlled actuators).
Second-cycle degree in Aerospace EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Nicola BianchiCredits: 9 CFU/ECTS
ExaminationTraditionalMore informationhttp://en.didattica.unipd.it/didattica/2014/IN0526/2008/000ZZ/INN1027640/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
ELECTRICAL MACHINE DESIGNELECTRICAL AND ELECTROMAGNETIC MICRO/NANODEVICES
18
PrerequisitesBasics of Electrotechnique and Electrical Machines theory.ProgrammeDesign and analysis of electric machines.Design of electrical machines for standard applications. Design of single- and three-phase reactors and transformers, with air and oil cooling system. Synchronous machines. Induction motors. DC motors.Design of electrical machines for electrical drives. DC motors with wound rotor and permanent magnet rotor. Brushless motors. Induction motors. Synchronous reluctance motors. Switched reluctance motors. Additional losses and stress due to the electronic converter supply.Innovative tools and techniques for the electrical machine design. Optimization techniques as design tools. Applications of electromagnetic field computation tools (Laboratory of finite element analysis of electrical machines).ExaminationTraditional method with lectures (24), exercises (30), computation laboratory (18).More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2013/000ZZ/INL1000688/N0
PrerequisitesNone.ProgrammeIntroduction.Elements of electromagnetic fields.Electromagnetic shielding.Elements of crystal structure.Ferroelectric and piezoelectric materials.Energy harvesting.Applications.Realization and characterization of thin films.“Magnetron sputtering” technique. Measurement techniques on thin films.ExaminationThe examination is oral and regards the matter of the lectures.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2013/000ZZ/INP3051534/N0
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Daniele DesideriCredits: 9 CFU/ECTS
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Nicola BianchiCredits: 9 CFU/ECTS
17
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
ELECTROMAGNETIC PROCESSING OF MATERIALS
2019
ELECTRICITY MARKET ECONOMICS
PrerequisitesNone.ProgrammeThe course is focused on induction heating systems, where ‘the classical theory’ is studied for the design of an inductor. Information about arc furnaces, resistors ovens, heating by direct current, radiofrequency and microwaves heating are also provided. Students following the “9 ECTS - 6 hours per week” version of the course will have the chance to verify the theory with practical tests in the laboratory or computer models.ExaminationTraditional frontal lecture, Numerical laboratory.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0523/2011/000ZZ/INP3050934/N0
PrerequisitesA basic knowledge of economics of the operation of energy markets is suggested.ProgrammePrice regulation; organisation of the electricity industry.Plant despatch and merit order: generation in a competitive market.Contracts.The operation of the power exchange and the capacity market.The transmission line: benefits of the interconnection and optimal transmission capacity.Congestion management.Markets for the environment: green certificates, carbon credits, energy efficiency.Financial products for the power market.Electricity prices: comparing different contracts.Principles of finance for hedging electricity contracts.Examination2 Written classworks during the course (First classwork: Mid Course; Second classwork: End of the Course). Session of exams (orals): June, July, September, December, February, March. After the classworks, you can register your vote only if their average is > or = 23/30. If not, or if you want to improve the vote, you have to give an oral exam on all or just one half of the programme, if the other is above 23/30, keeping good only that half.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2014/000ZZ/INO2044788/N0
Second-cycle degree in Materials EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Michele ForzanCredits: 9 CFU/ECTS
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Arturo LorenzoniCredits: 6 CFU/ECTS
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
ENERGY AND BUILDINGS
PrerequisitesIt is not mandatory, but it is recommended to have a basic knowledge on heating and cooling plants and components, i.e. for Italian students “Impianti termici e frigoriferi/Impianti termotecnici”.ProgrammeIndoor environmental quality (comfort, ventilation and lighting). Determination of weather conditions for the energy calculation of a building. Determination of main characteristics and problems related to building envelope: insulation, thermal bridges, condensation. Determination of main characteristics and problems related to glazing surfaces: lighting transmission, solar energy transmisison, shading, daylighting and glare. Thermal balance of a room (steady state and dynamic). Determination of heating, domestic hot water, cooling and electrical consumptions of a building. Energy and environmental certification and labelling. The concept of multi-energy systems and ZEB (Zero Energy Buildings).Examination Students have to deliver one week before the examination a detailed report of their house showing: - the electric and heating consumptions based on bills - a thermal bridge of their house: define the heat loss and the possible condensation problem - determination of the energy demand for
Second-cycle degree in Energy EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Michele De CarliCredits: 6 CFU/ECTS
21
heating and domestic hot water, including energy labelling, with a quasi steady state model (EN 13790) - determination of the net energy demand for heating/cooling the building by means of a commercial dynamic simulation tool (TRNSYS) - dynamic simulation with cooling plant switched off and evaluation of the indoor temperatures drift - Comparison between results of calculations and energy bills
The examination will be based on the result of the report (including discussion) and on two questions: one written common question (half an hour) and immediately after an oral question.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0528/2011/000ZZ/INN1032119/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
ENVIRONMENTAL FLUID MECHANICS
2322
ENVIRONMENTAL ELECTRICAL SCIENCE
PrerequisitesBASIC KNOWLEDGE REQUIRED: Mathematical Analysis 1,2; Physics 1; Hydraulics, Transport PhenomenaProgrammeGeneral principles: mass and energy balances; molecular diffusion; ensemble and temporal averages; ensemble mean concentration; ensemble mean cloud and ensemble mean of clouds; turbulent diffusion; laminar and turbulent dispersion.Outline of chemical reaction kinetics and of equilibrium chemical modeling.Transport and mixing in rivers: mass balance equation; Streeter-Phelps equation and its improvements; waste load allocation; Dissolved Oxygen dynamics in wide rivers and estuaries; outline of numerical modeling of the convection-diffusion equation.Transport and mixing in lakes: characteristics of water circulation in lakes; horizontal and vertical mixing in the Epilimnion and in the Hypolimnion; phosphorous as a limiting nutrient; mass balance of total phosphorous in lakes, nutrient loading criteria; dynamic ecosystem models for eutrophication assessments.ExaminationWrittenMore informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INN1028643/N0
PrerequisitesElectromagnetism, Electrical ScienceProgrammeThe course deals with the analysis of the environmental impact of electromagnetic fields. The different effects due to the values of the frequency of the fields are analyzed and biological effects are analyzed and compared with the present regulations; possible policies of prevention and protections are introduced.ExaminationI° alternative: oral examination. II° alternative: written development and discussion on one subject related to the course programme.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01123479/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Stefano LanzoniCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Alvise MaschioCredits: 6 CFU/ECTS
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
ENVIRONMENTAL HYDRAULICSENVIRONMENTAL GEOTECHNICS
25
PrerequisitesHydraulics’ or ‘Fluid Mechanics’ProgrammeThe course offers a view of modern advances in environmental hydraulics, moving forward from classical theories of advection, dispersion and sediment transport treated in basic courses. It describes state-of-the- art scientific knowledge as well as practical engineering tools (such as tracer tests) for water quality mathematical and physical modelling including surface and hyporheic transport of solutes and sediments. It describes the procedures required to perform Environmental Assessment Studies on the design of hydraulic structures for irrigation, renewable energy production and river and wetland restoration. It offers an insight of risk analysis and vulnerability assessment of environmental damages caused by hydro-geological extreme events, including collapse of hydraulic structures, sewer overflow, overaggradation and flooding.ExaminationOral examination and topic presentation.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1001807/N0
PrerequisitesGeotechnics, HydraulicsProgrammeSLOPE STABILITY: Peak and residual shear strength. Infinite and limited height slopes. Classification of landslides. Landslides monitoring (inclinometers, piezometers, etc.). Static and dynamics conditions, Safety factors according to limit equilibrium methods.COMPACTION: theory, geotechnical properties and structure of compacted soils, field compaction equipment. In situ and laboratory permeability and shear tests on compacted samples.LANDFILL: Design concepts and construction layout. Top and bottom natural and syntetic barriers. Shear strength and compressibility of municipal and industrial solid waste. Slurry walls.GEOSYNTHETICS: designing with geotextiles, geogrids, geonets, geomembranes, geosynthetic clay liners etc.SOLID WASTE.ExaminationWritten test containing exercises and theory questions. For a grade higher than 26/30 an oral exam must be passed.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1000752/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Marco FavarettiCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Andrea MarionCredits: 6 CFU/ECTS
24
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
ENVIRONMENTAL PROJECT WORK
2726
ENVIRONMENTAL IMPACT AND LIFE CYCLE ASSESSMENT
ProgrammeAnalysis of the composition and production of solid waste in a given basin, calculation of the flows of the different fractions after separate collection, choice and dimensioning of pre-treatment systems of the non-separated fraction.Dimensioning of a landfill according to current legislation.Graphical representation of all parts of a system, in particular the bottom barrier, leachate drainage system and extraction, biogas collection and final cover.Writing of a Technical report, including the economical evaluation metric calculation.A real-scale wastewater treatment aimed at complying with legal limitations established for discharges, including civil engineering works and plants, with a view to optimization of the process and operational and maintenance costs. Preparation of graphs illustrating the general plan, block scheme, hydraulic profile, project data, current legislation, discharge limits, depuration guarantees.Industrial discharges: problems, project data, specific pollutants, treatment schemes. Dimensioning of the process. Hydraulic profile, load loss, hydraulic calculations.Problems connected to civil engineering works.The different sections of a treatment plant (water and sludge streams). The main machines used, the different hydraulic components (pipes, valves, special parts, materials, etc.) instruments. Problems in start-up, management, and maintenance. Major problematic issues in the process, design and management
ProgrammeThe course is centred on the environmental impact assessment procedure. In particular the following topics are addressed: legislation (European and national), the administrative practice, the environmental impact study document writing and the tools for the evaluation of impacts. Several other closely related topics are discussed too: the strategic environmental evaluation, incidence evaluation and the integrated pollution prevention and control. After an introduction to the general theory of decision making and of decision support systems, the principal evaluation tools are presented, e.g. multi-criteria analysis, risk analysis and life cycle assessment. Applications to real case studies are foreseen along the entire duration of the course in order to clarify the theoretical subjects presented.ExaminationOral examinationMore informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043821/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Raffaello CossuCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Luca PalmeriCredits: 6 CFU/ECTS
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
FLUID DYNAMICS SIMULATION
28
ProgrammeINTRODUCTION TO COMPUTATIONAL FLUID DYNAMICS: Navier-Stokes equations. Statistical description of turbulent flows. Models for turbulent flow description in computational fluid dynamics: two-equation models. Some mention to large eddy simulation (LES).SOLVING FLUID DYNAMICS MODELS: The finite volume method: steady and transient flows. Availability and selection of numerical methods in commercial software. A brief introduction to meshing criteria.MULTIPHASE FLOWS: Phase coupling analysis (using dimensionless numbers). Eulerian-Lagrangian and Eulerian-Eulerian modeling approaches; some mention to population balance modeling.REACTIVE FLOWS: Multiscale approach to mixing in turbulent systems. Interaction between mixing and reactive phenomena. Reactive flow modeling in computational fluid dynamics: reaction rate models, equilibrium models, flamelet models.USAGE OF COMMERCIAL SOFTWARE FOR EQUIPMENT SIMULATION AND DESIGN: hands-on tutorials for analyzing homogeneous, multiphase, and reactive systems.MIXING EQUIPMENT DESIGN: Equipment details in mixing tanks. Mixing in homogeneous systems: criteria for equipment design and scale-up. Multiphase systems: liquid-solid and liquid-gas mixing. Design criteria for interphase mass transfer. Equipment design in reactive systems. Mixing in pipelines: criteria for equipment selection and design.
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Fabrizio BezzoCredits: 6 CFU/ECTS
countermeasures.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043822/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
FUNDAMENTALS OF ASTRONOMY AND ASTROPHYSICS
29
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0511/2011/000ZZ/INO2043561/N0
First-cycle degree in Aerospace Engineeringlanguage: EnglishTeaching period: second semesterLecturer: Cesare BarbieriCredits: 6 CFU/ECTS
ExaminationWritten examination (85% of final marks) and homework (15%).More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INO2043210/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
GAME THEORY
PrerequisitesA course, even a basic one, on statistics.ProgrammeBasic concepts of game theory Utility, market, discount factor Static games in normal form Dominance, Nash equilibrium Efficiency, price of anarchy Zero-sum games, minmax games Mixed strategies, mixed equilibria Nash theorem, minmax theorem Pure and mixed strategies The tragedy of the commons
Dynamic games Strategy and subgames Backward utility Stackelberg equilibria Repeated games and cooperation Dynamic duopolies, collusion Cooperation, pricing Imperfect/incomplete information Bayesian games, signaling, beliefs Revelation principle
Axiomatic game theory Fictitious play Best response dynamics Distributed optimization Algorithmic game theory Computation, complexity, and completeness of equilibria Auctions, bargaining First-price and second-price auctions VCG principle
Second-cycle degree in Computer EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Leonardo BadiaCredits: 6 CFU/ECTS
30
Cooperative games: the core, the Shapley value
Duopolies and competition Resource allocation Utilities, choices, and paradoxes Potential games, coordination Bio-inspired algorithms Evolutionary games Cognitive networks Selfish routing Game-theory enabled multiple-input systems Wireless spectrum auctionsExaminationPreliminary written exam (general exercises on the course). Development of a project in 1-3 person groups, on course-related topics but applied to ICT, and discussion of it (by appointment).More informationhttp://en.didattica.unipd.it/didattica/2014/IN0521/2009/000ZZ/INP4064059/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
GEOLOGY AND GEOCHEMISTRY
3231
GEOGRAPHICAL INFORMATION SYSTEMS
ProgrammePropedeutical concepts. Earth internal structure and outline on plate tectonics. Mineralogy. Mineral properties. Outline on silicate structures and classification. Clay minerals. Diagnostic methods. Petrology and petrography. Magmatic, sedimentary and metamorphic processes and related rocks. Structural geology. Folds; faults; overthrusting and tectonic nappes. Outline on mechanichs of rock materials. Geomorphology. Landscapes forms and their evolution in the glacial, eolic, coastal, fluvial, carsic environment. Mass movement and slope stability. Laboratory. Identification and classification of rocks on hand specimens. Geologic maps and sections: practical examples. Chemical differentiation of the Earth. Geospheres. Geochemical classification of the elements. Chemical fractionation. Geochemistry of the petrogenic process. Weathering. Dissolution, hydrolysis and oxidation. Silicate, carbonate and sulphide weathering. Soils Geochemistry. Clay minerals. Soils mineralogy. Soil composition and classification. Geochemistry of surface water. Geochemical survey. Geochemical anomalies. Sampling. Organizing a report on Environmental geochemistry. Analytical methods. Sample preparation. Introduction to SEM, XRPD, XRF, EMP analytic techniques.
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01123483/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Raffaele SassiCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Giuseppe SalemiCredits: 6 CFU/ECTS
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
GEOLOGY AND GEOPHYSICS
33
PrerequisitesBasic knowledge of physics and chemistry.ProgrammeElements of cartography.Geographic, UTM and Gauss Boaga coordinates, topographic maps, stratimetry analysis, geological profiles.Properties of the rocks and sediments. Review of stratigraphy, rock and sediment classification.Elements of structural geology and geomorphology, erosion process and sediment production, geomorphological implications.Geological maps of the Veneto, Garda area, Padua, Trentino, Euganean hills, Apennines, Italy.Elements of geothermics.Seismic refraction and reflection survey.Electrical survey, resistivity profiles.Stress and strain, rock reology, fault mechanics, elements of seismotectonic and seismic hazard.Elements of geodynamics, mantle and core physics, geothermal setting and gravity.Field laboratories: Structural and geomechanical measures: Euganean hills. Geophysics (geoelectrical and seismical survey): Fenice Parc. Radon measures: Euganean hills.Examination2 written tests and a final oral examination. Each test is 60 minutes long.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043832/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Silvana MartinCredits: 6 CFU/ECTS
ExaminationOral test. During the examination students are required to classify 2 rock specimens and interpret a geological section.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INN1028178/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
GROUNDWATER HYDROLOGYGLASS SCIENCE AND TECHNOLOGY
35
PrerequisitesMathematical analysis, statistics, fluid mechanics.Programme1. Introduction: Hydrologic Cycle, Water Balance.2. Aquifer Properties and Types: Hydraulic Conductivity, Darcy’s Law, Hydraulic Head, Elastic Storage, Homogeneity and Isotropy, Compressibility and Effective Stress.3. Groundwater Flow in Saturated Media: Analytical Solutions, Flow Nets.4. Unsaturated Porous Media, Groundwater Flow in Unsaturated Media.5. Confined Aquifers: Well Hydraulics, Analytical Solutions, Aquifer Testing.6. Leaky Aquifers: Well Hydraulics, Analytical Solutions, Aquifer Testing.7. Unconfined Aquifers: Well Hydraulics, Analytical Solutions, Aquifer Testing.8. Stream Aquifer Interaction: Semi-analytical and Numerical Models.9. Introduction to Groundwater Solute Transport.10. Groundwater Flow and Transport Analytical Solutions.ExaminationOral examination and discussion of problem assignment.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INN1030535/N0
PrerequisitesNone.ProgrammeGlass Structure: definition of glass. Glass transition range. Vetrification conditions: structural and kinetic theories. Phase separation. Structure of inorganic glasses and proposed models. Brief introduction to non-oxide glasses.Properties: rheological properties (viscosity); thermal properties (specific heat, thermal conductivity, thermal expansion); chemical properties (glass surface, acid and alkaline attack, water attack and weathering); electrical properties (ionic and electronic conductivity, semiconductor glasses); optical properties (refraction, reflection, absorption, transmission, colored glasses, photochromic glasses, photosensitive glasses, electrochromic glasses, optical fibers).Glass technology: raw materials and calculation of batch composition. Types of industrial furnaces. Melting, homogeneizing, fining and conditioning. Annealing. Flat glass: sheet glass, plate glass, float glass. Fusion process. Container glass: blow-blow and press-blow. Main characteristics of glass containers.ExaminationTraditional (written examination). The examination can be taken in Italian or in English.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0523/2014/000ZZ/INP3050685/N0
Second-cycle degree in Materials EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Paolo ColomboCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Matteo CamporeseCredits: 6 CFU/ECTS
34
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
INDUSTRIAL PLASMA TECHNOLOGIES
3736
IMAGE AND VIDEO ANALYSIS
PrerequisitesThorough knowledge of electrical science.ProgrammeDischarges in the plasma: dark discharge, breakdown, corona discharge, glow discharge, arc, capacitive and inductive discharges.Fundamentals of plasma physics, main plasma parameters, interaction between particles, diffusion and mobility, fluid motion of charged particles, Townsend theory on the ionization, Paschen curve.Plasma diagnostics, electrostatic probes.Plasma torches: welding and cutting torches, metallurgy and waste treatment torches.Surface modifications and coatings by plasma, physical vapour deposition, chemical vapour deposition, plasma enhanced vapour deposition, magnetron sputtering, plasma sterilization.Plasma processes in the semiconductor technology, plasma etchng., plasma display panels, plasma lighting systems.MHD conversion. Spatial propulsion.Laboratories: vacuum technology, DC discharges: electrical parameters and plasma parameters, magnetron sputtering: Paschen curve measurement, visit to the space propulsion laboratory.ExaminationFace to face examination based on: presentation and discussion of an in depth-examination of a topic selected by the student and discussion on laboratory measurements.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2013/000ZZ/INP3051533/N0
Prerequisites“Elaborazione numerica dei segnali” (Digital signal processing), recommended but not mandatory.ProgrammeIntroduction: Radiometry, image formation, colorimetry.Image processing: Intensity transformations, histogram-based transformations, linear and non-linear filters.Image analysis: Edge detection , corner detection, image segmentation, feature extraction (Hough transform, SIFT), scale space analysis.Video processing: Motion detection and analysis, motion-compensated filtering, tracking.Image and video coding: Information theory, lossless and lossy coding, predictive methods, transform coding (DCT), applications (PNG, JPEG and MPEG standards).ExaminationWritten examination, homework and final project.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INP4064217/N0
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Piergiorgio SonatoCredits: 6 CFU/ECTS
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Pietro ZanuttighCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INNOVATION AND PROJECT MANAGEMENT
PrerequisitesThe course can be followed by students with different backgrounds. Having attended a course like “Strategic Management of Organizations” can facilitate the learning of the contents of this course.ProgrammeCharacteristics of a project.The basic parameters of the project (scope, resources, time, cost, quality).The phases of the project life cycle Stakeholders and their influence on the project.The areas of knowledge in the management of a project (scope, time, cost, quality, risk, human resources, communication, procurement, integration).Project planning Project Quality Management.Project Risk Management.The organizational dimension in project management.Creation and management of the project team.The relationship aspects in project management (communication, team building, leadership).The economic and financial dimension of the project (evaluation criteria, the economic control of the project).Monitoring and control of the project.Project closure and lessons learned.Types of innovation projects.The sources of innovation.The process of developing a new product (phases and methodologies).The creativity dimension in the development of a new product / service.The protection of intellectual property (patents,
Second-cycle degree in Computer EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Moreno MuffattoCredits: 6 CFU/ECTS
38
trademarks, etc.).Organizational and management development team Innovative processes and relationships between companies.Communication and marketing of innovation Innovation projects and new business creation.The entrepreneurial dimension of a project.The recognition of a business opportunity.The identification and development of a business model.Business development.ExaminationAt the end of the course a written examination is planned on the entire programme.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0521/2009/000ZZ/INP3049981/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
39
INNOVATION IN PROCESSES FOR METALLIC PRODUCTS
PrerequisitesChemistry and metallurgy (or Material Science). Metallurgical processes.ProgrammeGeneral introduction of the course. The concept of Innovation and Product Development. Historical evolution of materials: development of metallic materials. The impact of innovation in the iron and steel industries, in the blast furnaces and electric furnaces. Innovative thin rolled metal products for automotive applications (High Strength Steels, Advanced High Strength Steels, Ultra High Strength Steels). Material and process selection: theory and application of the “Ashby method” for industrial components. Practice with the use of the Cambridge Engineering Selector software. Diamond inserts in the production of cutting tools. The selection of the matrix and diamond types. The wearing phenomena of cutting tools. Innovative processes in light alloy foundry: vacuum die casting, thixocasting, rheocasting, squeeze casting, lost foam. Numerical simulation of metallurgical processes (analytical and numerical methods, operative numerical simulation of iron and steel process, foundry processes and welding). Metal Matrix Composites (MMC): characteristics and methods for the production of metallic matrix and reinforcements, industrial processes for MMC production, technical and economical criteria for MMC selection. Industrial applications.
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: first semesterLecturer: Giulio TimelliCredits: 6 CFU/ECTS
Life Cycle Assessment and Life Cycle Costs. Assessment of costs in metallurgical processes. Industrial visits.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0018841/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INTERNATIONAL ENVIRONMENTAL LAW
INTEGRATED DESIGN OF PRODUCT, PROCESS AND PRODUCTION SYSTEM
41
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1000513/N0
ProgrammeEarly estimate of manufacturing cost and main design for injection moulding guidelines.Numerical simulation of the injection moulding process to evaluate moulding problems and the effect of engineering changes.Main methods for process set up and control: Design of Experiments, ANOVA, Response Surface, Multiobjective optimization, Statistical Process Control.ExaminationOral examination and evaluation of the assigned project.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0518/2011/000ZZ/INN1034753/N0
Second-cycle degree in Mechanical EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Giovanni LucchettaCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Luciano ButtiCredits: 6 CFU/ECTS
40
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
MATERIALS FOR ENERGETICS
4342
IRONMAKING AND STEELMAKING
PrerequisitesPhysics, General and Inorganic Chemistry, Physical Chemistry, Solid State Chemistry, Materials Science.ProgrammePart I. Primary and secondary batteries: materials, methods and devices • Solid Electrolytes: Synthesis and properties. • Conventional and innovative electrode materials: synthesis and properties. • Structural and morphological characterization techniques • Electrochemical characterization. • Devices and figures of merit. • Primary batteries: materials, devices and electrochemical processes. • Secondary batteries: materials, devices and electrochemical processes.
Part II. Fuel cells and electrolysers • Fuel cells: types and characteristics. • Electrolysers: types and characteristics. • Devices and figures of merit. 1. Electrolytes. 2. Electrocatalysts. 3. Structural and morphological characterization of materials. 4. Electrochemical and electrical characterization. 5. Membrane-electrode assembly (MEA). 6. Single cells and stacks.
Part III. Supercapacitors: Materials, methods and devices • Electrolytes: Synthesis and properties. • Conventional and innovative electrode
PrerequisitesNone.ProgrammeRaw material for iron and steel production: an overwiev on iron ore extraction and enrichment processes; coals, limestone.Process physicochemical fundamentals. Physicochemicals of blast furnace process: the reduction of iron ores.Overview of Blast Furnace Process. Balances of Blast Furnace.Physicochemicals of oxygen steelmaking process. Overview of oxygen steelmaking process.Balances of BOF converter.Electric Steelmaking: the Electric Arc Furnace.Secondary steelmaking.Vacuum processes.High alloyed steelmaking: Stainless steel production, AOD process.Continuous Casting: overview and controls of microstructure.Remelting processes.Foundry: Overview and processes for moulding.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0523/2014/000ZZ/INP3050693/N0
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Vito Di NotoCredits: 6 CFU/ECTS
Second-cycle degree in Materials EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Manuele Dabala’Credits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
MATHEMATICAL PROGRAMMING
44
PrerequisitesFunction analysis, vector spaces, basic operations on matrices.ProgrammeModelling an optimization problem.Algorithms for the solution of linear programming, integer linear programming, and optimization problems on graphs.Algorithms for convex problems and for general non-linear programming problems.Introduction to computational complexity analysis.Case study on some relevant problems in real-world applications.ExaminationWritten examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0527/2008/000ZZ/INP4063827/N0
Second-cycle degree in Automation EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Michele MonaciCredits: 9 CFU/ECTS
materials: synthesis and properties. • Techniques for electrochemical characterization. • Devices and figures of merit.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2014/000ZZ/INP4065843/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
MODELING AND SIMULATION OF MECHANICAL SYSTEMS
4645
MODELING AND CONTROL OF BIOLOGICAL SYSTEMS
PrerequisitesNone.ProgrammeTheory of multibody systems: kinematic and dynamic analysis, algorithmic and numerical implications.Elements of 3D geometrical modelling (with CATIA).Multibody modelling bricks: kinematic joints, contact models, shock models, friction models, tire models.Modelling of complex mechanical systems, hierarchy, sub-modelling.Development and discussion of many cases study (with LMS Virtual Lab Motion).ExaminationRealization of a project agreed with the lecturer.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0518/2011/000ZZ/INO2044864/N0
PrerequisitesThe content of the course “Systems and Models”, 3-year degree Information Engineering (L-INF).ProgrammeRecap of modeling, a priori identifiability, least squares & maximum likelihood parameter estimation, deconvolution fundamentals.Bayes estimation.Design of optimal experiment.Deconvolution of physiological systems.Nonlinear mixed effect modeling (population modeling).Models to understand/measure the glucose-insulin control system, both at whole-body and organ level.Models to simulate the glucose system in diabetes. Diabetes control: the artificial pancreas.ExaminationThe examination consists of: - a written examination on both lessons and laboratory session arguments; - an oral examination. Two optional homeworks will be offered which, if positive, can contribute to the final score. Two optional written tests will be offered during the course, each related to a portion of lessons and laboratory sessions. The two tests can substitute the final examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0532/2011/000ZZ/INP4062795/N0
Second-cycle degree in Mechanical EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
Second-cycle degree in BioengineeringLanguage: EnglishTeaching period: second semesterLecturer: Claudio CobelliCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
MULTIPHASE THERMODYNAMICS AND TRANSPORT PHENOMENA
MODELLING AND CONTROL OF ENVIRONMENTAL SYSTEMS
48
PrerequisitesNone.ProgrammePrinciples of statistical mechanics.Techniques of molecular simulations: Monte Carlo and molecular dynamics.Thermodynamic models of intermolecular potentials and equations of state for pure fluid and multi-component systems: cubic equations of state and perturbation theory.Computational methods for equations of state.Phase equilibrium calculations: vapor-liquid, liquid-liquid and solid-liquid.Thermodynamics of systems containing associating fluids, polymers, membrane and hydrogel. Thermodynamics of colloidal systems. Osmotic pressure and thermodynamic of biological systems.Thermodynamic properties and model parameters. Non-equilibrium thermodynamics.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INN1036258/N0
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1000693/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Luca PalmeriCredits: 6 CFU/ECTS
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Nicola ElvassoreCredits: 9 CFU/ECTS
47
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
NEARSHORE HYDRODYNAMICS AND COASTAL PROTECTION
5049
NANOSTRUCTURED MATERIALS
PrerequisitesNone.ProgrammeWAVE THEORY: elementary theory of waves, the dispersion relation, diffraction, refraction, shoaling, wave breaking process, radiation stress, wave set-up, Piling up. Longitudinal coastal currents (longshore), cross (rip) and return (undertow) currents. Distribution of the longshore currents induced by wave breaking. Sea level rise. Astronomical tide. Storm surge. Subsidence.SEDIMENT TRANSPORT: Average wave climate concept. Sediment transport mechanisms, depth of closure. Equilibrium profile. Dean profile. Longitudinal and cross-shore transport. CERC formula, Equation of the shore line (diffusion model). Distribution of the longshore sediment transport, Bijker formula. Sediment balance. Elements of coastal morphology. The beaches: the size of the sediment. Physiographic unit.COASTAL PROTECTION Selection of the design wave. Return period, probability distribution and cumulative frequency. Frequency factor. Materials, mechanical properties. Beach nourishment. Techniques, fill factor concept. Initial volumes and reintegration. Long-term effectiveness of the nourishments. Dunes. Detached breakwaters, emerged and submerged, innovative works, geotextiles, bypass systems of the sands. Dredging near shore and offshore, Flooding risk. Global Change: sea level rise and coastal erosion, coastal flooding and risk assessment.TECHNOLOGIES: pontoons, boats, tugs.
PrerequisitesSolid state physics.ProgrammePhysical chemistry of solid surface: surface energy, electrostatic and steric stabilization.Chemical synthesis of nanoparticles (metals, semiconductors, oxides), physical properties, applications.Chemical synthesis of nanorods, nanowires and nanotubes, physical properties and applications.Thin films depositions.Nanostructures fabricated by physical techniques: lithography and microfabbrication.Nanocomposites: synthesis and properties.Part of the lectures will be held in the lab where the students will synthesize and characterize different kind of nanomaterials. Visits to nanotechnology research labs will be organized.ExaminationOral, laboratory reports. Standard classes and laboratory classes.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0523/2011/000ZZ/INL1001815/N0
Second-cycle degree in Civil EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Luca MartinelliCredits: 9 CFU/ECTS
Second-cycle degree in Materials EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Alessandro MartucciCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
NETWORK ANALYSIS AND SIMULATION
51
PrerequisitesBasics of probability theory; basic networking courseProgrammeTheoretical foundations of simulation, confidence interval; simulation tools; analytical tools for network analysis; simulation lab; study of innovative schemes as published in recent scientific papers; course project.ExaminationCourse project; written test; oral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INP3049930/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Michele ZorziCredits: 6 CFU/ECTS
Hydraulic excavators, mechanical, buckets for excavations in water. Geotextiles, laying methods. Analysis of the costs and timings. Planning areas. Impact assessment of the work, the authorization process.PHYSICAL AND NUMERICAL MODELING Models for wave propagation, circulation, morphological, morpho-dynamic models. One line, 2D, 3D models. Froude scale, theory of wave generation, laboratory instruments, calibration procedures.WAVE ENERGY CONVERTERS Seminar by: Prof. P. Frigaard, Aalborg University (DK), Director of the Civil Engineering Department, which assesses possible interest to carry out one/two thesis in Aalborg.EXERCICES: LABORATORY Exercises: 1) Calibration of wave gauges; 2) Generation of a regular wave 3) Generation of an irregular wave 4) Data acquisition 5) Optional: Perform a simple experiment (based on availability of the laboratory) MATLAB OR OCTAVE EXERCISES 1) Introduction; Operations between vectors; Functions; Charts; Solution dispersion relation of the waves, if/for cycles, load data from laboratory 2) Design of a nourishment, analysis of wave climate; 3) Design of nourishment, 4) design of groin system (assessment annual longitudinal transport distribution) 5) Analysis of Laboratory data: Identification of incident and reflected waves, Evaluation of transmission coefficient, of loads.ExaminationThe evaluation will be based on the basis of: - numerical exercises (a collection of exercises must be presented by each group, formed by 3-4 people) - short experimental exercise - oral discussion on theoretical arguments (a list of questions will be available).More informationhttp://en.didattica.unipd.it/didattica/2014/IN0517/2010/000ZZ/INO2043803/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
NETWORK SECURITY
5352
NETWORK MODELING
PrerequisitesA basic class on communication or computer networks.ProgrammeBasic security notions and definitions.Unconditional vs computational security.Cryptographic and non cryptographic security mechanisms.Network security protocols at different layers.Further security issues for wireless, ad hoc and mobile networks.ExaminationThe student must first either undertake a team lab exercise or submit an individual literature review essay. Then, he/she will have to take an oral examination to obtain his/her final grade.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INN1027837/N0
PrerequisitesProbability theory; basic networking.ProgrammeProbability theory review; Markov chains, their limiting behavior; Poisson processes; renewal processes; applications and examples.ExaminationWritten test and oral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INP3049939/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Nicola LaurentiCredits: 6 CFU/ECTS
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Michele ZorziCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
OPERATIONS RESEARCH APPLICATIONS
NON LINEAR SOLID AND STRUCTURAL MECHANICS
55
PrerequisitesCourse of Operations Research, or equivalent education about:- Linear, Linear Integer and Linear Mixed Integer Programming, slution at the computer by means of a specific software and manual solution of small dimension models by means of primal and dual symplex algorithm. - Network flow models, manual solution by means of Ford and Fulkerson algorithm.ProgrammeDiscrete simulation models building and coding techniques.Queueing models theory and solution techniques.Network Programming with limited resources models solution techniques.Location models theory and solution techniques.Routing models theory and exact and heuristic solution techniques.ExaminationTest on discrete simulation model building and computer coding.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0018839/N0
PrerequisitesStructural Dynamics.ProgrammeTheory: Mathematical preliminaries: vector and tensor algebra, linearization and directional derivative, tensor analysis. Finite rotations: the vector and tensor representation of rotations in 3D space, quaternion representation. Formulation of a beam undergoing finite deformation: kinematic, balance laws and constitutive relationships. Formulation of shell undergoing finite displacements, rotations and deformations: kinematic and balance laws. Numerical methods for solving non-linear equations: Newton-Raphson, Orthogonal Residual and Arc-Length. Introduction to non linear dynamic analysis: Newmark algorithm and energy-conserving methods. Classes of problems and solutions: problems of solid and structures undergoing with finite displacements and rotations, problems involving beams in finite deformations, problems dealing with shells in finite deformations.Exercises: Introduction to MatLab and FEAP code; analyses using non-linear truss elements; analyses with non-linear beam elements; analyses with non-linear brick element; implementation of elasto-plastic constitutive laws; implementation of different solution techniques; non linear dynamic analyses.ExaminationPractical applications.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0517/2010/000ZZ/INO2043807/N0
Second-cycle degree in Civil EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Carmelo MaioranaCredits: 9 CFU/ECTS
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: first semesterLecturer: Giorgio Romanin JacurCredits: 6 CFU/ECTS
54
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
PHOTONICS DEVICES
5756
OPTICAL AND QUANTUM COMMUNICATIONS
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INO2043947/N0
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INO2043946/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Marco SantagiustinaCredits: 6 CFU/ECTS
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Roberto CorvajaCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
POWER ELECTRONICS 1
PrerequisitesIn addition to a basic knowledge of mathematics and physics, the course will make use of concepts developed in the courses of Circuit Theory (properties of electrical networks and fundamental theorems of network theory), Electronics (electronic devices, operational amplifiers), and Signals & Systems (feedback, stability, frequency response, Bode plots).ProgrammeGeneral concepts on Power Electronics.Static and dynamic characterization of electronic devices employed as switches: diodes, MOSFET, IGBT.Basic dc-dc converter topologies: steady-state analysis (Continuous Conduction Mode - CCM and Discontinuous Conduction Mode - DCM).Isolated converters: forward (reset R-C-D, active clamp and auxiliary winding), push-pull, half-bridge, full-bridge, flyback.Average models in CCM and DCM and their linearization around a given operating point.Direct duty-cycle control: design of PI and PID controllers.Double loop current controls: peak current mode, average current mode.Analysis of high-frequency transformers: skin and proximity effects, approximated derivation of the low-frequency transformer leakage inductance, Dowell curves and high-frequency winding losses.Snubber for switch overvoltage limitation at turn off (clamping circuits).Input filters: design criteria.Laboratory activity: static and dynamic
Second-cycle degree in Electronic EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Giorgio SpiazziCredits: 9 CFU/ECTS
58
measurements of a boost dc-dc converter.Description of MATLAB/Simulink and PLECS software and their use in the simulation of switching power supplies.ExaminationThe final examination will be divided into two parts: written test and oral test. Reports of the laboratory activity will have to be presented before the examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0520/2008/000ZZ/INP3054110/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
PRECAST AND TIMBER STRUCTURES
6059
POWER ELECTRONICS 2
PrerequisitesFundamentals of Structural Design 1 and 2.ProgrammeR.C. Precast Structures - Construction industrialization concept. General design principles. Design tolerances. Frame and Shear Walls Structures Construction typologies and concepts. Single and Multi-storey buildings: plane and spatial static schemes; horizontal and vertical joints. Industrial buildings: bearings and scheme problems. Particular schemes. Precast r.c. and beams: typologies, design requirements, structural details. Slabs: hollow core, double-tee, ribbed and special roofing elements. Structural elements: corbels, diffusion zones, foundation elements. Deep and shallow foundations. Connections: typology, preliminary design and final check. Mechanical devices for fixing, lifting and bearing. Pre-tensioning and post-tensioning technologies and concepts, . Facade panels: typology and computation. Bracing calculation (shear walls or plane trusses). Lateral stability of precast r.c. and p.c. large depth beams and columns, instability in precast structures, lateral action effects. Beam stability in temporary and final conditions. Design examples and reinforcement details. Numerical models for static and seismic design. Performance in recent seismic events. Seismic retrofitting of existing structures. Timber Structures - Properties of timber: anisotropy, moisture and long duration effects. Consequence of timber properties on structural analysis and detailing. Design standards for timber structures. Overview of glulam and manufactured wood
PrerequisitesIt is highly recommended that students have already taken or attended Power Electronics 1.ProgrammeFourth order dc-dc converters Cuk and SEPIC.State-space models of switched-mode power converters and state-space averaging techniques.Fundamentals of digital control of switched-mode power converters.Single-phase and three-phase inverters: overview and main modulation techniques.High-quality power factor correctors (PFC).Use of MATLAB/Simulink for system-level simulation and design of converters.ExaminationOral examination. As a prerequisite for admission to the exam, students will have to turn in a homework assignment concerning the design and Matlab/Simulink verification of a power converter.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0520/2008/000ZZ/INP3054121/N0
Second-cycle degree in Civil EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Roberto ScottaCredits: 9 CFU/ECTS
Second-cycle degree in Electronic EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Luca CorradiniCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
PRODUCT AND PROCESS DESIGN
61
ProgrammeINTRODUCTION TO PROCESS AND PRODUCT DESIGN: Products in the chemical industry: commodities, fine chemicals, specialty chemicals. Process analysis, synthesis and design. Hierarchical flowsheet decomposition. An introduction to product design. Interaction between product and process design. Turning qualitative product properties into quantitative data for process design.HIERARCHICAL APPROACH TO PROCESS DESIGN: Input data. Production operation: batch vs. continuous. Inputs/outputs structure. Reactor design and recycle structure. Separation system structure. Rules of thumb for discriminating alternative design configurations. Process simulation for process design.ECONOMICAL ASSESSMENT OF CHEMICAL PROCESSES: Estimation of capital costs. Estimation of manufacturing costs. Time value of money. Profitability analysis.DESIGN REPORTS: Oral and written communication of design results. A mention to process troubleshooting and debottlenecking.ExaminationWritten examination (50% of final marks) and team project (50%). The objective of the team project is the solution of a process design problem, the writing-up of a technical report, and the oral communication of the results.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INP3050933/N0
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Fabrizio BezzoCredits: 6 CFU/ECTS
products. Static and seismic design concepts within the limit design approach. Introduction to main timber construction technologies: frame structures and shear-wall platform frame of crossLam structures. Review of loading formulation: static and seismic loading. Design of structural members: beam, columns, floor diaphragms, shear-wall, trusses. Traditional and modern connections: typologies and design. Analytical and numerical models for timber structures. Design, detailing and structural analysis of timber roof structures, buildings and bridges. Discussion of design examples. Common aspects - Approach to fire design of precast/prestressed RC and Timber Structures.ExaminationDesign of a specific task assigned to a group of 2-4 students; Final oral discussion.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0517/2010/000ZZ/INO2043809/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
62
PRODUCT VARIETY MANAGEMENT
PrerequisitesNone.ProgrammeMass customization. Drivers of product variety and customization. Mass customization definition. Overview of mass customization enablers.The product configuration process. Total and partial configurability. Traditional approaches to configuration. Configuration system architecture. Commercial product modeling. How to evaluate a sales configurator. Technical product modeling. Generic bills of materials. Models to determine product cost, price and code, graphic representation of customized products. Choosing the optimal degree of automation of a product configuration system. Selecting and implementing a product configurator. Organizational impacts of implementing a product configurator.Form postponement types and market contingencies. Organizational changes for form postponement.Modularization of a product family. Relationships between product configuration, component standardization, product modularization and form postponement.The information systems support to Mass Customization. How to integrate PDM, CRM and product configurator.The information-processing view (IPV) of organization design. Analyzing product configurator introduction and form postponement application through the lens of IPV.
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: first semesterLecturer: Cipriano ForzaCredits: 9 CFU/ECTS
ExaminationWritten and oral examination and laboratory assignments.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INO2044723/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
QUALITY OF INDUSTRIAL PRODUCTION
QUALITY AND METROLOGY IN MANUFACTURING
64
PrerequisitesFundamentals of manufacturing processes, geometrical product specifications (GPS), basics of measuring processes, measuring uncertainty evaluation procedure, geometrical product data exchange, integrated CAD/CAM systems.ProgrammeIntroduction to quality systems. Quality assurance of manufacturing processes: testing of machine tools, statistical process control, evaluation of process capabilities.Surface metrology. Verification of roughness in industrial practice. Advanced mapping of surface geometry, nanometrology of surfaces and microparts.Dimensional and form metrology. Coordinate measuring machines (CMMs) and systems. Non-contact metrology. Computed tomography for dimensional metrology.Product conformity assessment: tolerance verification, decision rules in acceptance testing, procedures for the quantification of measurement uncertainty. Quality assurance of measuring systems.ExaminationWritten examination, continuous assessment during lab experiments and final colloquium. The written test includes 4-5 open questions on course contents and an exercise. Lab experiments will generate data to be analysed by the student as homework and discussed at the final colloquium. The final colloquium will include discussion of an individual assignment,
PrerequisitesPreparatory courses are not compulsory.ProgrammeRole of metrology in modern manufacturing; Simple dimensional measuring instruments; Measuring uncertainty and traceability; Geometrical Product Specifications; Coordinate metrology; Non contact scanning metrology and Reverse Engineering; Surface metrology; Form metrology.ExaminationWritten examMore informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0019390/N0
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: second semesterLecturer: Simone CarmignatoCredits: 6 CFU/ECTS
Second-cycle degree in Mechanical EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Enrico SavioCredits: 6 CFU/ECTS
63
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
REAL AND COMPLEX ANALYSIS
65
PrerequisitesAll the concepts and definitions of differential and integral calculus covered in the courses of Analysis 1 and 2.ProgrammeSequences and series of functions. Banach and Hilbert spaces. Lebesgue integral and L^p spaces. Fourier series and Fourier transform. Elements of complex analysis. Distributions.ExaminationThe examination will consist of a written test made with some exercises and also theoretical questions. During the semester two partial examinations will be given. The final grade will be the average of the grades of the two partial examinations, in the case that these are both sufficient.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0527/2008/000ZZ/INP4063746/N0
Second-cycle degree in Automation EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Caterina SartoriCredits: 9 CFU/ECTS
consisting on the design of a dimensional testing procedure for a mechanical part proposed by the student.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0518/2011/000ZZ/INN1034751/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
RIVER ENGINEERINGREMEDIATION OF CONTAMINATED SITES
67
PrerequisitesHydraulics, Basic Hydrology, Solid Mechanics, Geotechnical Engineering, Water Supply and Drainage Systems.ProgrammeAims and design of hydraulic structures; notes on regulations.Elements of hydrology: hydrological cycle; collection and analysis of data; geometrical representation of hydrological basins and of rivers; rainfall data analysis; flood models.Hydraulic of canals, rivers and mountain streams. Bed-load transport; check dams; riverbank stabilization and protection; stream junctions; levee design and other river improvements; scouring; diversion works; bridges and culverts.Hydroelectric plants: dam regulation, weir and barrages; energy dissipation and stilling basins; provisional works; canals and hydraulic tunnels.Elements of inland waterways.ExaminationWritten and oral final examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043834/N0
PrerequisitesBasic concepts of environmental sanitary engineering (biodegradation processes) and organic chemistry.ProgrammeSources to soil and groundwater pollution.Characteristics of the contaminants and their interactions with soil and groundwater.Sampling and analysis for site characterization according to the current legislation.Attenuation and degradation of pollutants.In situ and ex-situ techniques for remediation of contaminated soil and groundwater (Biological, Chemical-physical and Thermal treatment): Soil vapor extraction; Air sparging; Soil washing; Chemical oxidation; Thermal desorption and incineration; Bioremediation, Groundwater Remediation (pump and treat, reactive barriers).Landfill Remediation.Case studies.ExaminationWritten exam comprising exercises and open questions.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01123477/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Roberto RagaCredits: 9 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Paolo SalandinCredits: 9 CFU/ECTS
66
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
SATELLITE NAVIGATION
6968
ROBOTICS, VISION AND CONTROL
PrerequisitesAstrodynamics, Basic programming, Numerical analysis.ProgrammeSatellite Navigation’ is a course for second year students of the degree Programme. The course includes theoretical background and practice in developing simple applications in data processing.ExaminationTraditional.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0526/2014/000ZZ/INM0018399/N0
PrerequisitesCalculus, Physics, Linear Algebra, Automatic Control, System Theory.ProgrammeMobile robots vehicles: navigation (in particular Map-Based Planning) and localization (in particular Monte-Carlo localization).Arm-type Robots: Robot arm kinematics (inverse Kinematics and computation of trajectories), velocity relationships, dynamics and control.Computer-vision: light and color, image formation, image processing, image feature extraction, analysis of multiple Images.Robotics, vision and control: vision-based control, advanced visual serving.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0527/2008/000ZZ/INP4063809/N0
Second-cycle degree in Aerospace EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Alessandro CaporaliCredits: 9 CFU/ECTS
Second-cycle degree in Automation EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Ruggero CarliCredits: 9 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
SERVICE OPERATIONS MANAGEMENT
SEPARATION UNIT OPERATIONS AND PROCESS SIMULATION
71
PrerequisitesNone.ProgrammeService Operations Management: different types of service processes and challenges within service management. The service concept. Focused and unfocused service operations. Customer and supplier relationship. Customer segmentation and retention. Service quality: defining expectations and service quality factors. Customer satisfaction. Engineering service processes and the customer experience. Service people: managing and motivating service providers. Resource utilization: capacity management. How network technology and information are transforming services. Special seminars on specific industries: for example, health care, banking, insurance.ExaminationWritten examinations and oral examinations (elective).More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0018838/N0
PrerequisitesKnowledge of pieces of equipment such as pumps, fans, compressors, heat exchangers, used in chemical plants. Applied thermodynamics for both monocomponent and multicomponent systems.ProgrammeFluid phase equilibrium thermodynamics.Material balances on separation unit operations.Energy balances on separation unit operations.Distillation processes.Stripping processes.Absorption processes.Solvent extraction processes.Sizing and rating of sieve tray columns.Sizing and rating of packed columns.Process simulation and process simulators fundamentals.Process simulator applications.ExaminationBoth written and oral examinations. The oral examination can be taken only after passing the written examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INN1032227/N0
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Alberto BertuccoCredits: 12 CFU/ECTS
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: first semesterLecturer: Andrea VinelliCredits: 6 CFU/ECTS
70
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
SOLID WASTE MANAGEMENT
7372
SOIL PROTECTION PROJECT WORK
ProgrammeWaste production and quality. Current legislations about waste management, resource recovery and disposal of residues.Waste management systems and strategies.Waste collection and transport. Separate collection and material recovery. Mechanical selection schemes and processes. Separation of single fractions.Recycling and recovery processes of material (paper, plastics, glass, etc.). RDF production. Biostabilization processes for the biodegradable fraction. Energy recovery from waste: biological and thermal processes. Management and disposal of residues.Landfill technologies. Processes in landfill. Barriers, drainage and leachate collection. Mathematical models for evaluation of leachate and biogas production. Landfill long term emissions. Landfill aftercare. Top cover systems and closure of landfills.Biogas collection and treatment. Leachate treatment.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01123480/N0
PrerequisitesGeotechnicsProgrammeThe following topics will be discussed: Summary of geotechnical notes Static and dynamic soil compaction In-situ tests for soil characterization Embankment and levee construction and soil consolidation Vertical drains Vacuum assisted consolidation Construction stage stability Monitoring and prediction of settlements Forms and function of levees Levee stability and seepage Failures of levees, remediations and restorations Retaining walls in static and dynamic conditions Bases of rock mechanics Stabilty of rock slopes Rockfall protective systemsExaminationSome brief preliminary homework, executive geotechnical project and oral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INO2043844/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Raffaello CossuCredits: 9 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Fabio GabrieliCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
SPACE OPTICS INSTRUMENTATIONSOURCE CODING
75
ProgrammeElectromagnetic waves. Maxwell’s equations, wave equation, electromagnetic spectrum. Geometrical optics. Concept of ray, reflection and refraction laws. Object and image, ideal lens, paraxial optics. Thin lenses, imaging, ocular, astronomical and terrestrial telescopes. Flat and aspheric mirrors, conic function, spherical mirrors, image formation with mirrors. Aberrations.Astronomical telescopes: Gregorian, Newtonian, Cassegrain, Dall-Kirkham, Ritchie-Chretien, Schmidt, Maksutov, Wolter. in Telescopes and diffraction, Airy function, angular resolution. PSF, reflectivity, obscuration, diffused light, materials.Elements of interference theory of between waves and applications. Interference between light waves (principles). Interferometers. Principles of stellar interferometry. Interferometry N elements, the “long baseline interferometry, the “null-interferometry”.Elements of diffraction and spectroscopy. Diffraction by a rectangular slit. Dispersing elements. Spectroscopic systems. Czerny-Turner configuration. Concave grating: Rowland mount, Offner and Wadsworth. Variable line spacing grating: Harada configuration. Echelle mounting. Iperspectrum.Introduction to photoemission detectors. Photoelectric effect. Quantum efficiency. Photocathode, photomultiplier, channeltron, MCP. MCP detectors, readout anode single and multianode.Introduction to semiconductor detectors. Atomic theory, semiconductors. Photodiodes and HCT. CCD operation and configurations. Passive and
More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INN1029415/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
Second-cycle degree in Aerospace EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Giampiero NalettoCredits: 9 CFU/ECTS
74
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
SPORTS ENGINEERINGS AND REHABILITATION DEVICES
76
PrerequisitesThe knowledge of elements of applied mechanics and mechanics of materials is recommended, as well as the knowledge of differential mathematics and vectorial algebra.ProgrammeFundamentals: 1. Basic knowledge of anatomy and physiology of the musculoskeletal system. 2. Quantitative anthropometry. 3. Modelling equilibrium and motion of the segments of the human body. 4. Analysis of gait and running. Methodologies: 5. Sensors and systems for the evaluation of kinematic, kinetic and physiological parameters during the sport exercise: motion capture systems, force platforms, pressure insoles, electromyography. 6. Design and calibration of strain gauge multi-component load cells for the collection of functional loads at the human body – equipment interfaces. 7. Musculoskeletal simulation codes. 8. Design of a research project for the statistical evaluation of sport and rehabilitation devices. Applications: 9. Classification of sport equipments and rehabilitation devices. 10. Identification of perfomance, comfort and safety parameters of sport – rehabilitation equipments. 11. Knowledge of safety standards, implementation of standard tests methods. 12. Functional evaluation of sport equipments,
Second-cycle degree in Mechanical EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Nicola PetroneCredits: 6 CFU/ECTS
active CMOS (APS). Hybrid detectors.The weather satellite Meteosat. Meteosat imaging mode, the payload, the telescope and the focal plane; MTP and MSG, SEVIRI. MTG; MTG instrumentation.The remote sensing SPOT satellite. SPOT orbit spectral bands; HRG telescope and focal plane, push-broom mode, the “super mode” HRG, HRS, stereoscopic vision.Wide Angle Camera for the Rosetta space mission. The WAC Rosetta, optical design, features, mirrors, theoretical optical performance, filters, shutter, tolerance analysis, thermal analysis, alignment set-up and calibration, measurement of the PSF, distortion, thermal-vacuum measurements, temperature depending focusing, integration. Flight performance.The Hubble Space Telescope. Telescope, focal plane instruments, FOS, HRS, HSP, WF/PC1, FOC, COSTAR; WF/PC2, optical design, STIS, optical design, detector; NICMOS, optical design, dewars, optical quality; ACS, optical design, mechanical scheme, detectors. Servicing Mission 4 and present instruments. The XMM Newton satellite. The multi-mirror telescopes. Instruments: the RGS spectrometer, EPIC cameras, the Optical Monitor.The Herschel satellite. Description of the satellite. Focal plane instruments: the systems of imaging and spectroscopy PACS and SPIRE, the HIFI spectrometer.The Fermi satellite. The Large Area Telescope and the GLAST Burst Monitor.The SAR technique. Operation of radar applications, Doppler effect, the polarization of the radar beam; SAR technique, parameters, resolution in range and azimuth, basic configuration, data processing, synthetic aperture, image distortion, SAR stereoscopic topography, interferometric SAR. Applications.The coronography solar satellite. The coronagraphs LASCO and UVCS on SOHO.The study for the SIM Lite mission.ExaminationSlide projection. Lecture notes available before lectures.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0526/2014/000ZZ/INO2043274/N0
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
STATISTICAL METHODS AND APPLICATIONS
77
PrerequisitesNone.ProgrammeElements of univariate and multivariate statistical methods: Elements of descriptive statistics: frequency, indices of synthesis (position, variability and shape) and graphical representations (histogram, boxplot, scatterplot). Elements of probability theory: discrete and continuous probability distributions. Elements of statistical inference: sampling distributions, point and interval estimation, hypothesis testing, simple and multiple linear regression.Design and analysis of experiments and Conjoint Analysis: One-way ANOVA, Multi-Way ANOVA, Factorial Designs and Optimal Designs. Response Surface Methodology. Full profile and choice based conjoint analysis.Nonparametric statistics: Resampling methods: univariate and multivariate permutation tests.ExaminationOral examination.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0522/2008/000ZZ/INM0018840/N0
Second-cycle degree in Engineering and ManagementLanguage: EnglishTeaching period: first semesterLecturer: Luigi SalmasoCredits: 6 CFU/ECTS
orthoses, assistive technologies, prostheses and training or rehabilitation machines.ExaminationThe exam will consist of a written assessement, covering all the topics of the lectures and the laboratory esperiences. An oral discussion will follow the written assessement in order to integrate its results with questions regarding the anathomy and physiology of the muscoloskeletal system. The final mark will take also into account the evaluation of the group project conduction and presentation and of the weekly assigned homeworks.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0518/2011/000ZZ/INN1032097/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
TELECOMMUNICATION NETWORKS
7978
SUSTAINABLE AND RENEWABLE RESOURCES
PrerequisitesStudents are expected to have confidence with the most basic networking and communication concepts and terms (ISO/OSI model, packet-based networks, routing), and a good mathematical and probability theory background (probability measure, first and second order statistics, expectation and Bayes theorem, elementary queueing theory). Basic programming and computer skills are required in the lab experiences. An introductory course on Linux fundamentals is offered on a volunteer basis by lab technicians before the beginning of the course (see https://moodle.dei.unipd.it/course/view.php?id=1537 for further details). Basic programming skills in Matlab and Java are also required for homework.ProgrammeThe beginning of the course is devoted to a quick review of basic networking and performance analysis concepts, such as terminology, standards, protocols structure, communication devices, and queueing theory. The major part of the course is devoted to the study of the most prominent networking protocols and algorithms, with reference to state of the art technologies. In particular, the course will be introductory to the architecture and the protocols of Internet, and to the performance analysis of the most common medium access control, link layer and transport protocols. The theoretical lessons will be completed by practical lab experiences, which will cover the following topics: Static routing, Cisco router operating system (IOS), RIP (with Quagga & router), Socket programming,
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01122726/N0
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Andrea ZanellaCredits: 9 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
THERMONUCLEAR FUSION
80
PrerequisitesNone.ProgrammeWorld Energy and the Role for Fusion: the existing energy options.Introduction to Plasma Physics and Controlled Fusion.Electromagnetic fields and forces, charged particle trajectories, fluid equations, ideal MHD.Plasma confinement: magnetic confinement, axisymmetric toroidal equilibrium.Cylindrical configurations: Z-pinch, theta-pinch, screw-pinch. Toroidal configurations: Tokamaks, RFPs.Magnetic field calculations, magnet design and optimization, coil forces, superconducting coils.Power supplies, energy storage and transfer systems.Plasma Heating: Ohmic Heating (OH), Neutral Beam Injection (NBI), Radio Frequency (RF) heating.Plasma facing components: Blanket, Divertor.Diagnostics: Magnetic measurements, active wave diagnostics.Fusion Power plants: DEMO.ExaminationOral examination and report on numerical labs.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1979/2013/000ZZ/INN1027624/N0
Second-cycle degree in Electrical Energy EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Paolo BettiniCredits: 6 CFU/ECTS
TCP & UDP (flow control, congestion control, IP fragmentation), Firewall. A more detailed programme of the course can be found at the following URL: http://www.dei.unipd.it/corsi/RTLC/calendar.htmlExaminationThe final grade consists of: 1) a lab test that requires the student to apply the practical knowledge acquired in lab 2) a written test with a few multi-choice questions and a couple of problems related to network planning and performance analysis. Homework assigned during the course may also be evaluated to increase the final grade. Oral examination is generally not provided, but can be requested at the lecturer’s discretion, or by students who have passed the written test.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INN1027895/N0
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
WASTE MANAGEMENT IN DEVELOPING COUNTRIES
8281
UNIT OPERATIONS FOR THE FOOD AND PHARMACEUTICAL INDUSTRIES
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01122554/N0
PrerequisitesNone.ProgrammeMaterials of food and pharmaceutical industry: granular materials and powders, slurries. Properties and characterization of solid materials. Solid-solid and solid-fluid interactions. Distributed properties.Static analysis of stresses in solids: design of silos and hoppers; flow function and flow factors; kinematics and dynamic analysis: rheology of granular materials and powders. Mixing and segregation of solids; industrial mixers. Sampling.Granulation: agglomeration mechanisms; industrial granulators.Comminution: physical principles of size reduction and choice of milling devices.Crystallization: principles and design criteria.Separation operations; fluid dynamics of suspension and packed beds: filtration and sedimentation. Solid-solid separation: screening.ExaminationThe written examination includes both numerical exercises and theoretical questions.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0530/2012/000ZZ/INO2043201/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
Second-cycle degree in Chemical and Process EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Andrea Claudio SantomasoCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
WATER DISTRIBUTION AND DRAINAGE SYSTEMS
WASTEWATER TREATMENT
84
PrerequisitesApplied hydraulics, hydrology.ProgrammeSustainable water management.Water crisis.Numerical and conceptual modelling water distribution and drainage systems.Water quantity and water quality issues.Water treatment.Land and water use change: man-soil-vegetation-atmosphere interaction and feedbacks.Reliability of water drainage and water distribution systems.ExaminationPractical activity (following lectures on special topics, aimed to fix major issues, to be delivered on MOODLE).More informationhttp://en.didattica.unipd.it/didattica/2014/IN0517/2010/000ZZ/INO2043805/N0
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01122796/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 9 CFU/ECTS
Second-cycle degree in Civil EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Nadia UrsinoCredits: 9 CFU/ECTS
83
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
WATER SUPPLY TREATMENT
8685
WATER RESOURCES MANAGEMENT
More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/IN01122795/N0
PrerequisitesBasic principles of hydrology (hydrologic response, Darcy’s law), basic concepts of statistics and mathematics.Programme1. Water resources and the hydrologic cycle: recalling basic concepts from probability and hydrology2. Water resources and the hydrologic cycle: recalling basic concepts from probability and hydrology.3. Modelling and forecasting of rainfall processes: i) Zero-dimensional rainfall models: poissoninan models; Cluster models (Bartlett Lewis, Neymann-Scott); ii) Rainfall forecasting (outline): global circulation models, limited area models, downscaling, meteorologic forecasting and flood protection.4. Soil moisture dynamics: i) soil moisture dynamics and runoff production; ii) stochastic modelling of soil moisture; iii) soil moisture and plant nutrition.5. Streamflow characteristics: i) floods and droughts; ii) continuous models of the hydrologic response; iii) stochastic analysis of streamflows series (duration curves, distributions of extremes).6. Water resources management models: i) reservoirs: floods mitigation, industrial and agricultural supply; ii) Reservoirs regulation; iii) flood retention plains.7. Irrigation systems and schemes.ExaminationOral examination, and discussion on homework.More informationhttp://en.didattica.unipd.it/didattica/2014/IN1825/2010/000ZZ/INL1001294/N0
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: tbdCredits: 6 CFU/ECTS
Second-cycle degree in Environmental EngineeringLanguage: EnglishTeaching period: second semesterLecturer: Gianluca BotterCredits: 6 CFU/ECTS
INDEXSCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
WIRELESS SYSTEMS AND NETWORKS
PrerequisitesThe student should have a good knowledge of basic probability theory, including random processes, random variables, their expectations, etc. No previous courses are required as mandatory as the instructor will go through the needed preliminary theory at the beginning of each topic. Nevertheless, for some of the mathematical analyses that will be presented in the course, additional knowledge on stochastic processes and in particular on Markov processed is helpful. Hence, a perspective student may also wish to attend: Course no. IN0521 NETWORK MODELING - MODELLI PER LE RETI, Code INP3049939. In addition, some basic knowledge on computer networks, including their basic tools for performance analysis (queueing theory) and some knowledge on networking protocols (in particular link layer and transport) is also beneficial. Hence, a perspective student may also wish to attend: Course no. IN0521 TELECOMMUNICATION NETWORKS - RETI DI TELECOMUNICAZIONI, Code: INP3050962.ProgrammeThe course aims at providing some advanced knowledge on protocol stacks for wireless communications, including the analysis of distributed wireless networks, state of the art wireless technologies and current trends. The topics that will be covered will range from link layer technology to routing over ad hoc wireless networks and application layer coding. Selected topics will be presented using recent research papers from the literature as a source of reference.
Second-cycle degree in Telecommunication EngineeringLanguage: EnglishTeaching period: first semesterLecturer: Michele RossiCredits: 9 CFU/ECTS
87
In the first part of the course, the student will be introduced to the technology used in modern ISO/OSI stacks, characterizing the performance of the single layers and then of the protocol stack as a whole. In the second half of the course, the focus will be on distributed ad hoc network architectures, with particular emphasis on distributed Wi-Fi networks (IEEE802.11 a/g/h/n) and wireless sensor networks (IEEE 802.15.4). The corresponding technologies (IEEE 802.11 and 802.15.4) will be introduced in detail (PHY/MAC/routing), characterizing their performance through suitable mathematical tools. The course will be research oriented and, at the end of it, the student will have a clear view on modern protocol technology, and will be able to carry out its performance evaluation through tractable mathematical tools. The main topics that will be discussed in the course are:- Wireless channel: Simulation-based introduction to wireless channel models: path loss, shadowing, fading and frequency selectivity- Link layer: Link layer algorithms based on FEC: applications; Hybrid ARQ systems: mathematical analysis and performance evaluation; Fountain codes: theoretical foundations, optimal and suboptimal (practical) decoders.- Protocol stack analysis: Performance evaluation of protocol stacks over correlated fading channels. This analysis will cover all layers from the physical layer up to the transport, accounting for Markov channel models, ARQ system models and transpor protocol performance.- IEEE 802.11 a/g/h/n: Physical layer technology. Introduction to the OFDM technology, diversity and MIMO techniques; Channel access technology (Medium Access Control, MAC); Mathematical analysis and performance evaluation of dynamic rate control algorithms (adaptive modulation and coding).- Routing over “ad hoc” multi-hop wireless networks: Performance analysis of data dissemination in multi-hop mobile wireless networks; Description and performance evaluation of selected routing algorithms for ad hoc wireless networks.- Wireless sensor networks (WSN): Relevant channel access and routing algorithms, analytical models and their performance analysis; Study
SCHOOL OF ENGINEERING # COURSE UNITS HELD IN ENGLISH
INDEX
of WSN systems powered by energy harvesting sources.ExaminationTo pass the examination, a student needs to pass a written examination and to provide the instructor with a written technical project (a teamwork carried out with other students of the course). In each of them, the student needs to attain at least 18 points (i.e., the lowest passing grade). An additional oral test is optional and decided on a case-by-case basis, depending on the performance attained for the written exam and the project and on whether the student aims at obtaining extra-credit, so as to improve his/her final grade. FINAL GRADE: the final grade will be attained as the weighted sum of the grade assigned to the written examination and of that of the technical project. Additionally an oral examination will also be taken into account and handled on a case-by-case basis. WRITTEN EXAM: the written examination usually contains one exercise and two theory questions. The exercise is about dimensioning a wireless networking system, involving the transmission of some data flow through a network of terminals, where some of the links are wireless. Different exercises and their solution will be amply discussed by the instructor throughout the course. The two theory questions are either about deriving equations to characterize the performance of a certain protocol that has been presented in the course or discussing the advantages or disadvantages of a certain technology or protocol. Past examinations can be found in the course website, some of them include the solution to the technical exercise: http://www.dei.unipd.it/~rossi/courses/SRW/Results.html TECHNICAL PROJECT: technical projects can be of three types: T1) technical project (involving computer simulation or selected theoretical developments), T2) technical review (involving a review of relevant techniques from the scientific and technical literature), T3) experimental project (involving the design and implementation of a network protocol in real software). Proposals and possibilities for the technical projects will be amply discussed by the instructor throughout the course. WHEN TAKING A NEW WRITTEN EXAMINATION. If a student has been assigned a
sufficient grade from a past written examination, he/she has the right of taking a new written exam to improve his/her grade. In the case he/she decides to do so, the student will have 15 minutes to check the exercises and questions of the new written exam and decide as to whether he wants to continue with this new exam or maintain the old grade (from the last written examination he/she has passed). In the former case, the grade from the new written exam will replace that of the last written exam he/she has passed.More informationhttp://en.didattica.unipd.it/didattica/2014/IN0524/2008/000ZZ/INO2043955/N0
University of PadovaSchool of Engineering
CATALOGUE OF COURSE UNITS HELD IN ENGLISHFOR ERASMUS, FOREIGN AND ITALIAN STUDENTS2014 > 2015
Graphic design: Servizio Relazioni pubbliche