|
Insegnamento
|
CFU
|
SSD
|
Ore Lezione
|
Ore Eserc.
|
Ore Lab
|
Ore Studio
|
Attività
|
Lingua
|
|
8039881 -
CHARACTERIZATION OF NANO-ENGINEERING SYSTEMS
(obiettivi)
LEARNING OUTCOMES
The course aims to provide students with the fundamental notions of physical and chemical characterizations of nanomaterials and nanostructures. Different analysis techniques are highlighted such as optical microscopèy, electronic and contact microscopies, optical and infrared spectroscopies, XPS, Auger, SIMS, etc. A general overview of the radiation-matter interaction is also given. Students will also acquire practical skills thanks to some laboratories that will be carried out during the course.
KNOWLEDGE AND UNDERSTANDING
It is required to be able to read and understand scientific publications for dissemination or research, usually in English. To be able to connect the different topics (interrelated between them) discussed during the course. To apply theoretically and practically, the concepts acquired during the course.
APPLYING KNOWLEDGE AND UNDERSTANDING
At the end of the course it is required to be able to illustrate the relevant points of the program in a concise and analytical manner with appropriate language. The use of a technical language appropriate to the subject is required. It is necessary to know how to analyze a problem / question and to know how to organize an adequate response justifying it. It is necessary to know how to reorganize and develop the experiments performed in the laboratory.
MAKING JUDGEMENTS
Students will be asked to motivate the tools and methodologies used for certain scientific experiences and be able to describe them and implement them even in different forms with respect to those described during the course. They have to be able to integrate explanations also with references to everyday life and they have to be able to provide links with what described and analyzed during the lessons. They are required to be able to abstract general concepts from particular cases.
COMMUNICATION SKILLS
They are required to be able to describe the topics covered during the course in a professional manner and with adequate language. They are required to be able to extract the important concepts and to illustrate them in a synthetic and punctual way by providing examples.
LEARNING SKILLS
It is required to be able to read scientific texts in English. To understand graphs and scientific figures. To know how to select and correlate topics.
|
|
M-5871 -
FUNDAMENTALS OF CHARACTERIZATION OF NANO SYSTEMS (MODULE 1)
-
MILANI ENRICO
( programma)
1. Relativistic dynamics; Atomic structure and transitions.
2. Radiation properties; Radiation – matter interaction.
3. X-ray photoemission spectroscopy (XPS), Auger electron spectroscopy (AES), Ultraviolet photoemission spectroscopy (UPS), electron energy loss spectroscopy (EELS): Principles and instrumentation.
4. Secondary ion mass spectrometry (SIMS): Principles and instrumentation.
5. Depth profiling and chemical imaging by using XPS, AES and SIMS techniques.
6. Practical applications of surface analysis techniques: examples and experimental tests in the laboratory.
7. Morphological characterization: Optical Microscopy, Atomic Force Microscopy (AFM), Scanning Tunneling Microscopy (STM), Scanning Electron Microscopy (SEM) and Transmission Electron Microscopy (TEM). The instrumentations and the basic working principles of the different techniques will be illustrated.
8. Optical spectroscopy of nanostructures. The main optical techniques such as absorption, reflection and photoluminescence will be explained. The influence of the small dimensions of the nanostructures on the optical properties will be discussed.
9. Some practical applications will be carried on and some laboratory instrumentations will be shown.
 J.F. Watts and J. Wolstenholme, An Introduction to Surface Analysis, Wiley, 2003; Y.-W. Chung, Practical Guide to Surface Science and Spectroscopy, Academic Press, 2001; Fundamentals of light microscopy and electronic imaging D. B. Murphy John Wiley and Sons (2001); Physical Principles of Electron Microscopy R.F. Egerton Springer (2005); Nanostructures and Nanomaterials: Synthesis, Properties and Applications G. Cao and Y. Wang World Scientific Publishing (2011).
Slides of the lessons.
|
2
|
FIS/07
|
16
|
-
|
3
|
-
|
Attività formative affini ed integrative
|
ENG |
M-5870 -
CHARACTERIZATION OF NANO-ENGINEERING SYSTEMS (MODULE 2)
-
KACIULIS SAULIUS
( programma)
1. Relativistic dynamics; Atomic structure and transitions.
2. Radiation properties; Radiation – matter interaction.
3. X-ray photoemission spectroscopy (XPS), Auger electron spectroscopy (AES), Ultraviolet photoemission spectroscopy (UPS), electron energy loss spectroscopy (EELS): Principles and instrumentation.
4. Secondary ion mass spectrometry (SIMS): Principles and instrumentation.
5. Depth profiling and chemical imaging by using XPS, AES and SIMS techniques.
6. Practical applications of surface analysis techniques: examples and experimental tests in the laboratory.
7. Morphological characterization: Optical Microscopy, Atomic Force Microscopy (AFM), Scanning Tunneling Microscopy (STM), Scanning Electron Microscopy (SEM) and Transmission Electron Microscopy (TEM). The instrumentations and the basic working principles of the different techniques will be illustrated.
8. Optical spectroscopy of nanostructures. The main optical techniques such as absorption, reflection and photoluminescence will be explained. The influence of the small dimensions of the nanostructures on the optical properties will be discussed.
9. Some practical applications will be carried on and some laboratory instrumentations will be shown.
J.F. Watts and J. Wolstenholme, An Introduction to Surface Analysis, Wiley, 2003; Y.-W. Chung, Practical Guide to Surface Science and Spectroscopy, Academic Press, 2001; Fundamentals of light microscopy and electronic imaging D. B. Murphy John Wiley and Sons (2001); Physical Principles of Electron Microscopy R.F. Egerton Springer (2005); Nanostructures and Nanomaterials: Synthesis, Properties and Applications G. Cao and Y. Wang World Scientific Publishing (2011).
Slides of the lessons.
-
PROSPOSITO PAOLO
( programma)
1. Relativistic dynamics; Atomic structure and transitions.
2. Radiation properties; Radiation – matter interaction.
3. X-ray photoemission spectroscopy (XPS), Auger electron spectroscopy (AES), Ultraviolet photoemission spectroscopy (UPS), electron energy loss spectroscopy (EELS): Principles and instrumentation.
4. Secondary ion mass spectrometry (SIMS): Principles and instrumentation.
5. Depth profiling and chemical imaging by using XPS, AES and SIMS techniques.
6. Practical applications of surface analysis techniques: examples and experimental tests in the laboratory.
7. Morphological characterization: Optical Microscopy, Atomic Force Microscopy (AFM), Scanning Tunneling Microscopy (STM), Scanning Electron Microscopy (SEM) and Transmission Electron Microscopy (TEM). The instrumentations and the basic working principles of the different techniques will be illustrated.
8. Optical spectroscopy of nanostructures. The main optical techniques such as absorption, reflection and photoluminescence will be explained. The influence of the small dimensions of the nanostructures on the optical properties will be discussed.
9. Some practical applications will be carried on and some laboratory instrumentations will be shown.
J.F. Watts and J. Wolstenholme, An Introduction to Surface Analysis, Wiley, 2003; Y.-W. Chung, Practical Guide to Surface Science and Spectroscopy, Academic Press, 2001; Fundamentals of light microscopy and electronic imaging D. B. Murphy John Wiley and Sons (2001); Physical Principles of Electron Microscopy R.F. Egerton Springer (2005); Nanostructures and Nanomaterials: Synthesis, Properties and Applications G. Cao and Y. Wang World Scientific Publishing (2011).
Slides of the lessons.
|
4
|
ING-IND/23
|
32
|
-
|
6
|
-
|
Attività formative caratterizzanti
|
ENG |
|
8039882 -
NANOSCALE SYNTHESIS METHODS
(obiettivi)
LEARNING OUTCOMES
Knowledge to design the material properties starting from atomic and molecular structures. The main goal of this course is to to provide a comprehensive picture of the synthesis of inorganic and organic nanoparticles.
KNOWLEDGE AND UNDERSTANDING
Ability to design the properties of materials starting from the atomic and molecular structures;
Knowledge of advanced materials (polymeric, metallic, ceramic, composite and nanostructured) in terms of microstructure;
Knowledge and understanding of the most modern methods of organic and inorganic synthesis applied to nano-science;
Knowledge and understanding of the chemical and physical characteristics of the main materials.
APPLYING KNOWLEDGE AND UNDERSTANDING
Structure property correlations for materials.
Ability to select the most appropriate material for a specific application.
Ability to predict the degradation of a material in relation to the environment to which it is exposed.
Choice of the most suitable materials for the realization of a product in relation to its characteristics and the required application.
MAKING JUDGEMENTS
The ability to obtain and describe data resulting from experiments and analysis, in order to arrive at the formulation of an interpretative judgment on the results acquired;
The ability to collect and process technical and safety information, taking into account the chemical and physical properties of the material, including any specific risk.
COMMUNICATION SKILLS
The international environment in which the Master will take place will result in an increase in communication skills. Teaching includes oral exams (in English) and will train students to effectively support scientific discussions by improving their skills.
LEARNING SKILLS
This part of the training will be achieved through lectures supported by laboratory exercises. As part of the Master’s Degree program, the experimental laboratory activity is developed in order to provide a clear knowledge of implementation and application problems.Learning skills will be achieved throughout the course, with particular regard to the planned individual study and the activity carried out for the preparation of the final exam.
-
DI VONA MARIA LUISA
( programma)
1. Nanoscale synthesis and bottom-up techniques
2. Advanced synthetic tools for the covalent assembly of building blocks in the preparation of molecular systems relevant in nanochemistry
3. Carbon-based nanomaterials
4. Sol-gel and colloidal chemistry
5. Applications of sol-gel chemistry
6. Nanoporous materials
7. Healt, safty and environmental issues
Materials for engineers, W.F. Hosford, Cambridge 2008; Nanomaterials: An Introduction to Synthesis, Properties and Applications, D. Vollath, Wiley 2nd Edition, 2013.
Nanoscience and Nanomaterials: Synthesis, Manufacturing and Industry Impacts; Wei-Hong Zhong, Bin Li, Russell G. Maguire, Vivian T. Dang, Jo Anne Shatkin, Gwen M. Gross, Michael C. Richey DEStech Publications, Inc.
Nanomaterials and Nanocomposites. Synthesis, Properties, Characterization Techniques, and Applications; R. Kumar Goyal, Taylor and Francis, 2017.
|
5
|
CHIM/07
|
39
|
-
|
6
|
-
|
Attività formative affini ed integrative
|
ENG |
|
8039951 -
MACROMOLECULAR AND SUPRAMOLECULAR CHEMISTRY
(obiettivi)
LEARNING OUTCOMES
The aim of the course is to provide the general background on polymer and colloidal and “soft” materials needed for the understanding of phenomena and processes that students will encounter during their further studies or their future working actiivty. At the end of the course concepts such as the molecular weight distributions, step and chain polymerizations and the technology aspects, polymer solutions, gels and self assembly, experimental approaches to study polymer and self assembled materials, elastomers and mechanical behaviour of polymers, will be the knowledge background of the student in order to orient himself in future research topics and work issues.
KNOWLEDGE AND UNDERSTANDING
At the end of the course the student should know how to analyze the scientific literature at university level and the information contained in a laboratory report in the field of polymer and self assembly chemistry.
APPLYING KNOWLEDGE AND UNDERSTANDING
At the end of the course the student should be able to understand and discuss in an organized way the logical steps in a problem solving activity in topics covered during the course, on the basis of the received concepts and information. Operative and conceptual aspects of the work and of the research will be managed in a critical and organized way.
MAKING JUDGEMENTS
One of the aims of the course is to raise a critical and independent approach in the reading of a scientific journal of the field or about a laboratory report, being able to work out connections and original logical steps
COMMUNICATION SKILLS
To master concepts worked out in thecourse is at the base of the ability to share such contents also in front of a not-specialized audience without loosing the logic and scientific rigor.
LEARNING SKILLS
At the end of the class, the student is able to handle the studied contents in order to understand actively future issues and therefore to progress toward more specialized knowledge.
-
PARADOSSI GAIO
( programma)
Understanding basic concepts of Polymer Chemistry and self Assembly processes.
Ability to apply the knowledge worked out during the couse to the behaviour of polymeric materials. Ability to perform and understand experiments concernng polymer and self assembling materials and to treat data according to simple theoretical models.
Slides provided by Professor.
P. J. Flory,
Introduction to Polymer Chemistry
Cornell University Press.
R.J. Young and P.A. Lovell
Introduction to polymers
CRC Editors.
Ian W. Hamley
Introduction to Soft Matter
Wiley.
|
5
|
CHIM/02
|
45
|
-
|
-
|
-
|
Attività formative caratterizzanti
|
ENG |
|
8039884 -
NANOSCALE ENERGY TECHNOLOGY, NANO-SENSORS AND MICRO-FLUIDICS
(obiettivi)
LEARNING OUTCOMES
The course provides an introduction to recent application of nanotechnologies to energy and sensors. The selected examples will mainly focus on nanotechnology for solar energy (photovoltaics) and the employment of nanofluidic systems for single molecule sensing and nanoporous membrane for energy harvesting from salinity gradients (blue-energy).
KNOWLEDGE AND UNDERSTANDING
For what concern the energy module, at the end of the course, the student will know the main features of a photovoltaic systems and the most modern technology for new generation photovoltaics. Concerning the nanofluidics module, the student will be able to understand the main phenomena related to the transport of mass and ions in electrolyte solutions.
APPLYING KNOWLEDGE AND UNDERSTANDING
The student will be able to recognize the range of validity of the various models proposed for the description of fluids at nanoscale. The student will be able to design and characterize a new generation solar cells. She/He will also be able to apply the knowledge and understanding developed during the course to study and understand recent literature.
MAKING JUDGEMENTS
The transversal preparation provided by the course implies: 1) the student’s capability to integrate knowledge and manage complexity, 2) the student ability to deal with new and emerging areas in nanotechnology application to energy and sensing and 3) an understanding of the models suited for a given context and their limitations.
COMMUNICATION SKILLS
The student will be able to communicate the contents of the course to specialists in a clear and unambiguous way. It will also be able to communicate the main features of the models used and their limits to specialists in other related disciplines (example: other engineers, physicists, chemists).
LEARNING SKILLS
The structure of the course contents, characterized by various topics apparently separated but connected by a multi-scale and multi-physics vision, will contribute to developing a systemic learning capacity that will allow the student to approach in a self-directed or autonomous way to other frontier problems on nanotechnology application to energy and sensing. Furthermore, the student will be able to read and understand recent scientific literature.
-
AGRESTI ANTONIO
( programma)
Ion transport in nanopores
Ion motion in an electrolytic solution. Conductivity and conductance. Quasi-1D model. Access resistance. Application for nanopore sensing: blockade current.
Micro and nanofluidics
Equation of motion. Conservation of mass and momentum. Boundary conditions. Poiseuille flow. Slip boundary condition. Electrohydrodynamics. Transport equation for ions. Electic double layer. Debye length. Blue energy: from salinity gradient to electric energy.
Diffusion
Lagrangian and Eulerian description. Langevin equation. Fluctuation-dissipation relation.
Molecular dynamics simulations
Equation of motion for classical molecular dynamics. Force fields. Lennard-Jones potential. Simulation of biomolecules. Equilibration. Computational laboratory: system set-up and simulation using VMD and NAMD softwares.
NanoEnergy
General introduction on global energy demand focused on solar energy; Introduction on photovoltaics: the photovoltaic effect, p-n junction, main photovoltaic electrical parameters; solar cell characterization techniques; New generation photovoltaics: organic and hybrid devices; Organic solar cells;
Hybrid solar cells
Dye Sensitized solar Cells (DSCs) and modules; Perovskite Solar Cells (PSCs) and modules; Nanomaterials and bi-dimensional (2D) materials: properties and characterization techniques; Perovskite Photovoltaics and 2D materials: power conversion efficiency (PCE), stability and scalability on module dimensions.
Theoretical Microfluidics, Henrik Bruus, Oxford University Press (2008)
(notes of the course provided by the professors).
-
CHINAPPI MAURO
( programma)
Ion transport in nanopores
Ion motion in an electrolytic solution. Conductivity and conductance. Quasi-1D model. Access resistance. Application for nanopore sensing: blockade current.
Micro and nanofluidics
Equation of motion. Conservation of mass and momentum. Boundary conditions. Poiseuille flow. Slip boundary condition. Electrohydrodynamics. Transport equation for ions. Electic double layer. Debye length. Blue energy: from salinity gradient to electric energy.
Diffusion
Lagrangian and Eulerian description. Langevin equation. Fluctuation-dissipation relation.
Molecular dynamics simulations
Equation of motion for classical molecular dynamics. Force fields. Lennard-Jones potential. Simulation of biomolecules. Equilibration. Computational laboratory: system set-up and simulation using VMD and NAMD softwares.
NanoEnergy
General introduction on global energy demand focused on solar energy; Introduction on photovoltaics: the photovoltaic effect, p-n junction, main photovoltaic electrical parameters; solar cell characterization techniques; New generation photovoltaics: organic and hybrid devices; Organic solar cells;
Hybrid solar cells
Dye Sensitized solar Cells (DSCs) and modules; Perovskite Solar Cells (PSCs) and modules; Nanomaterials and bi-dimensional (2D) materials: properties and characterization techniques; Perovskite Photovoltaics and 2D materials: power conversion efficiency (PCE), stability and scalability on module dimensions.
Theoretical Microfluidics, Henrik Bruus, Oxford University Press (2008)
(notes of the course provided by the professors).
|
5
|
ING-IND/08
|
39
|
-
|
6
|
-
|
Attività formative affini ed integrative
|
ENG |
Gruppo opzionale:
OPTIONAL COURSES: 2 exams (5 CFU). Option A "Chemistry" or option B "Modelling". Option A: STRUCTURAL AND FUNCTIONAL PROPERTIES OF BIOPOLYMERS and NMR OF NANO-SYSTEMS; Option B: NANOSCALE STRUCTURAL TRANSFORMATIONS AND KINETICS and PROBABILITY AND STATISTICAL METHODS FOR MODELLING ENGINEERS. - (visualizza)
 |
5
|
|
|
|
|
|
|
|
|
8039853 -
STRUCTURAL AND FUNCTIONAL PROPERTIES OF BIOPOLYMERS
(obiettivi)
LEARNING OUTCOMES
Ability to include the main structural and functional properties of biopolymer.
KNOWLEDGE AND UNDERSTANDING
Understanding of the chemical and physical principles that underlie structural motifs in biopolymers, as well as important techniques for their study.
APPLYING KNOWLEDGE AND UNDERSTANDING
Ability to apply the different knowledge learned during the lessons, as well as ability to discriminate between the best strategy to follow for a study project.
MAKING JUDGEMENTS
Ability to be independent in a scientific project by acquiring information from other related sectors.
COMMUNICATION SKILLS
Ability in the relationship with sectors of genetics, biochemistry and molecular biology to apply for suitable experiments.
LEARNING SKILLS
Ability to autonomously extend one’s own knowledge by using the suitable literature and to know how to move in sectors related to one’s own.
-
SETTE MARCO
( programma)
Structural features and conformational equilibria of polypeptides, proteins, polysaccharides and nucleic acids.
Biopolymer-ligand interactions: equilibrium and kinetics aspects.
Biopolymers for polymer synthesis.
Self assembled systems of biopolymers: hydrogels and microgels.
Synthetic polymers with applications in biological environments.
Computed aided visualization of biological macromolecules.
Slides provided by Professor.
|
3
|
CHIM/07
|
23
|
-
|
4
|
-
|
Attività formative affini ed integrative
|
ENG |
|
8039854 -
NMR OF NANO-SYSTEMS
(obiettivi)
LEARNING OUTCOMES
Ability to understand the relevant scientific literature and to extract information from spectra of Nuclear Magnetic Resonance.
KNOWLEDGE AND UNDERSTANDING
Understanding of the necessary NMR experiments of utility in the field of nanosystems and of the basic theory behind each of them.
APPLYING KNOWLEDGE AND UNDERSTANDING
Ability to apply the different methodologies used during the lesson, as well as the ability to discriminate between the best strategy to follow.
MAKING JUDGEMENTS
Ability to be independent in a scientific project by acquiring information deriving from other related sectors.
COMMUNICATION SKILLS
Ability to relate to other sectors to establish appropriate experiments
LEARNING SKILLS
Ability to extend their own knowledge for the use of other experiments and to know how to move in sectors related to their own.
-
SETTE MARCO
( programma)
NMR basic theory: the resonance phenomenon, chemical shift, scalar and dipolar coupling, molecular interactions. One- and two-dimensional experiments in solution and in solid phase. Diffusion experiments. Examples from literature.
Edwin Becker
High Resolution NMR. Theory and Chemical Applications
Elsevier. 3rd Edition
|
2
|
BIO/10
|
15
|
-
|
3
|
-
|
Attività formative affini ed integrative
|
ENG |
|
8039855 -
NANOSCALE STRUCTURAL TRANSFORMATIONS AND KINETICS
(obiettivi)
LEARNING OUTCOMES
The course aims to provide the basic knowledge about the diffusion based phase transformation occurring in the solid state with particular attention to thermodynamics and kinetics. The chemical distribution on nano- and micro-scale and the microstructure of materials will be presented.
KNOWLEDGE AND UNDERSTANDING
The students should understand how the microstructure of metallic materials can be modified through heat treatments which induce the formation of different phases.
APPLYING KNOWLEDGE AND UNDERSTANDING
The content of the course is useful for determining the fundamental process parameters (temperature, time, atmosphere) of heat treatments to induce the suitable microstructural transformations in metal alloys and achieve the desired mechanical properties for a given engineering application.
MAKING JUDGEMENTS
The students will be able to understand how to perform the right heat treatments on metal alloys to get the desired mechanical properties.
COMMUNICATION SKILLS
Description of the microstructure of metallic materials in terms of type and fraction of different phases, and their effect on the mechanical properties.
LEARNING SKILLS
Understanding the relations between microstructural features and mechanical properties of the main families of metal alloys for engineering applications.
-
MONTANARI ROBERTO
( programma)
1. Binary and ternary phase diagrams
2. Classification of diffusion based solid state phase transformations.
3. Transformations occurring through nucleation and growth mechanisms.
4. Transformations occurring through spinodal reaction.
5. Identification of unknown compounds by means of X-ray diffraction. The use of the X-ray database. Lab exercices.
D.R. Askeland, The Science and Engineering of Materials, Stanley Thornes Publishers Ltd.
|
2
|
FIS/03
|
15
|
-
|
3
|
-
|
Attività formative affini ed integrative
|
ENG |
|
8039883 -
PROBABILITY AND STATISTICAL METHODS FOR MODELLING ENGINEERS
(obiettivi)
LEARNING OUTCOMES
After a careful study during the course the students should be able to:
1. Identify the role of statistics in engineering problems.
2. Discuss the methods used by engineers to collect data.
3. Explain the differences between mechanistic and empirical models.
4. Understand and describe sample spaces and events of random experiments with graphs, tables, lists or tree diagrams.
5. Interpret and use the probability of the results to calculate the probabilities of the events. Calculate the probability of joint events and interpret / calculate the conditional probabilities of events.
6. Apply the Bayes theorem.
7. Understand the meanings of a random variable.
8. Select an appropriate discrete / continuous probability distribution. Determine probability, mean, and variance for the presented discrete / continuous probability distributions.
9. Calculate and interpret mean, variance, standard deviation, median and sample interval.
10. Build and interpret normal probability diagrams.
11. Know the general concepts of estimating the parameters of a population or a probability distribution.
12. Explain the properties of point estimators (bias, variance, mean square error).
13. Construct point estimators with moments method and maximum likelihood method.
14. Calculate and explain the precision of the estimation of a parameter.
15. Understand the central limit theorem.
16. Explain the role of normal distribution as a sampling distribution.
17. Build confidence intervals, forecast intervals, tolerance intervals.
18. Structure engineering decision problems as hypothesis tests.
19. Check the hypotheses on the average of a normal distribution using a Z-test or t-test procedure.
20. Test the hypotheses on variance or standard deviation of a normal distribution. Check the hypotheses on a population.
21. Use the P value approach to make decisions in hypothesis tests.
22. Select a sample size for tests on averages, variances and proportions.
23. Explain and use the relationship between confidence intervals and hypothesis testing.
24. Use the chi-square test to test hypotheses about the distribution.
25. Use simple linear regression to build empirical models of technical and scientific data.
26. Understand the use of the least squares method to estimate parameters in a linear regression model.
27. Analyze the residuals to determine if the regression model fits the data or to see if there are violations of the initial hypotheses.
28. Test the statistical hypotheses and construct confidence intervals on the parameters of the regression model.
29. Use the regression model for the prediction of a future observation and construct an appropriate prediction interval on future observation.
30. Use simple transformations to obtain a linear regression model.
31. Apply the correlation model.
32. Finally, discuss how probabilities and probability models are used in engineering and science in general.
KNOWLEDGE AND UNDERSTANDING
Students acquire understanding and knowledge of: 1) fundamental statistical techniques (summary statistics, normal distribution, interval estimation, regression analysis, modelling) and how they relate to the baseline discipline; 2) software statistical techniques; 3) process monitoring by control charts; 4) process optimization by response surface methodology; 5) determining important factors by hypothesis testing; 6) process modelling by, e.g., regression analysis; 7) design of experiments and laboratory recommendation.
The teaching approach provides the foundation for this understanding, in such a way that at the end of the course students have assimilated a complete knowledge of the basic themes.
APPLYING KNOWLEDGE AND UNDERSTANDING
The goals of the course are to help the students to: i) model and simulate basic engineering problems, ii) collect, analyze and present numerical data in general and simulation results in particular, iii) interpret simulation results by means of statistical methods, iv) use statistical principles and concepts, v) develop software for reporting and for graphical presentation, vi) be familiar with basic probability theory and perform estimation, hypothesis testing, simple correlation-/regression analysis, vii) identify, formulate, and solve engineering problems. Such applications of statistics are widespread in all branches of engineering.
MAKING JUDGEMENTS
The training provided for students of the course is hallmarked by the acquisition of a flexible mentality that helps them to extend the knowledge learned to new concepts, enabling them to introduce elements of innovation. These activities encourage students to develop: critical thinking and problem solving; critical analysis; independence of judgement. At the end of the course, students are therefore able to pose, refine and evaluate scientific questions, this being a fundamental objective both educational and cognitive.
COMMUNICATION SKILLS
Students develop the ability to present clearly what they have learned during the course and, in the same way, the additional knowledge gained from practical exercises, classroom exercises and textbooks. They are expected to present their knowledge effectively. These skills, which concern both oral and written presentations, are based on the ability to analyze and integrate the knowledge areas acquired during the course. Students are also encouraged to develop a positive attitude towards teamwork.
The evaluation of the achievement of written and oral communication skills is verified during classroom exercises, practical exercises, tutoring and through written and oral exams at the end of the course.
LEARNING SKILLS
Students, through the introduction of a range of fundamental statistical techniques, learn how to: analyse data, apply statistics in engineering contexts, use appropriate statistical sofware. Furthermore they acquire: numeracy skills, effective Information retrieval and research skills, computer literacy. On these bases they will be able to connect and relate knowledge across various scales, concepts, and representations “in” and “across” domains.
-
RICHETTA MARIA
( programma)
– The role of Statistics in Engineering: Mechanistic and Empirical Models, Probability and Probability Models.
– Probability: Discrete Random Variables and Probability Distributions; Continuous Random Variables and Probability Distributions.
– Point Estimation of Parameters.
– Random Sampling and data Description, Statistical Intervals for a Single Sample.
– Tests of Hypotheses for a Single Sample.
– Simple Linear Regression and Correlation: Empirical Models.
– Multiple Linear Regression Model.
– The Analysis of Variance (ANOVA): Residual Analysis and Model Checking; The Random Model.
– Design of Experiments with Several factors.
– Statistical Quality Control.
– Statistics for Engineers and Scientists, W.Navidi, McGraw-Hill Education 2020.
– Fundamentals of Probability and Statistics for Engineers, T.T. Soong, Jhon Wiley & Sons 2004.
– Probability and Statistics for Engineering and the Sciences, J. Devore, Brooks/Cole 2010.
– Probability and Statistics; John J. Schiller, R. Alu Srinivasan, Murray R Spiegel, 4 th Edition 2013.
– Essential Matlab for Engineers and Scientists; Brian Hahn, 5 th Edition 2012.
|
3
|
FIS/01
|
23
|
-
|
4
|
-
|
Attività formative affini ed integrative
|
ENG |
|
|
- -
OPTIONAL COURSES
|
4
|
|
36
|
-
|
-
|
-
|
Attività formative a scelta dello studente (art.10, comma 5, lettera a)
|
ENG |
