Educational objectives GENERAL OBJECTIVES
The course aims to provide the fundamentals of geomatics with respect to positioning and navigation (Global Navigation Satellite Systems - GNSS) and the storage and management of spatial data (Geographic Information Systems - GIS).
The teaching starts from the fundamentals of Geodesy (reference systems and coordinate systems) and then deals with the observables of satellite positioning systems and their treatment aimed at estimating geometric parameters. Finally, modern spatial data management techniques will be analyzed.
The fundamental objective of the course is the process of defining, generating and managing spatial data.
SPECIFIC OBJECTIVES
1. Knowledge of the international geodetic reference system.
2. Knowing how to identify and use the suitable instrumentation to acquire GNSS observations for different types of applications.
3. Making judgement: To understand the most appropriate approach (mathematical and physical) to the processing of observations aimed at estimating geometric parameters
4. Communication skill: To present and defend the acquired knowledge during an oral and/or written exam.
5. Learning skill: To use the management systems of the estimated parameters for applications related to geomatic monitoring and navigation
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Educational objectives General learning outcomes
The course aims to provide knowledge and develop skills related to urban mining and recycling processes of end-of-life products turning them into secondary raw materials, in agreement with the principles of circular economy and the sustainable development goals of UN AGENDA 2030, with particular reference to SDG11 (Sustainable cities and communities), SDG12 (Responsible consumption and production), SDG13 (Climate action). In particular, the course aims to illustrate the main technologies and related equipment at laboratory and / or industrial plant scale in order to carry out the recognition, characterization, selection and treatment of materials to be recycled of different nature and origin (packaging waste such as plastic, glass, paper and aluminum, construction & demolition waste, waste from electrical and electronic equipment, end-of-life vehicles, etc.). Starting from the knowledge of solid particle properties, it will be possible to evaluate and define the most suitable physical-mechanical treatment techniques in order to produce secondary raw materials, taking into account technical, economic, environmental aspects and technological innovations of a rapidly evolving sector. Some of the main recycling chains for the production of secondary raw materials will be then examined, highlighting the critical issues and the key factors of each of them.
Specific learning outcomes
Based on the acquired knowledge, the student will be able to define the fundamental operations, their sequence and logic in order to design a mechanical process to produce secondary raw materials from end-of-life products, choosing the most suitable separation methods, defined from the characterization of solid waste materials also through innovative approaches. The student will also develop the ability to evaluate, select and apply quality control actions for both feed and output streams in a recycling plant, in order to optimize the processes, maximizing waste recovery and secondary raw materials value, in the perspective of circular economy and efficient use of resources.
After passing the exam, students will be able to:
● Understand the fundamental principles for the recycling-oriented characterization of materials
● Apply traditional and innovative analytical techniques for material recycling
● Know the recycling technologies for different waste materials and end of life products
● Understand and evaluate recycling processes considering both technical and economic aspects
● Apply the fundamental principles for the physical separation of materials to be recycled
Students will also acquire the following transversal skills:
● Demonstrate effective communication with specialists and non-specialists
● Team work ability
● Write a technical-scientific report
● Make an oral presentation
● Analyze issues critically
● Access and select appropriate sources of information
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Educational objectives The main outcome of this course is to provide the students with the basics of Environmental Law with a specific focus on the Italian, European and International regulatory Framework.
Special attention is devoted to the practical implications of Environmental Law concerning several topics addressed in the Master’s Degree (Pollution, Land Planning etc.), as well as to the implications affecting the professional activity of the Environmental Engineer.
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Educational objectives General learning outcomes
The course aims to provide the scientific basis and technical knowledge to develop interdisciplinary skills aimed at assessing the sustainability of the use of renewable and exhaustible resources and, in general, of all production activities. Through the knowledge and use of tools and methods for environmental monitoring, for the characterization of the environmental and energy loads of the production cycles (LCA) and the related environmental costs (LCC), the course, in accordance with the principles of circular economy and with the SDGs n. 7, 11, 12 and 13 of the UN AGENDA 2030, aims to analyze the product and/or process impacts, pursuing the control and improvement of environmental performances, also in order to implement voluntary adhesion tools such as Environmental Labeling and Environmental Management Systems.
Specific learning outcomes
Knowledge and understanding
At the end of the course, students will be able to:
● define the elements that identify a sustainable growth; evaluate what use of renewable resources can be considered sustainable and how mining exploitation and the use of exhaustible resources should be analyzed with a view to rationalization and reduction, without neglecting the eco-compatibility of the extraction processes;
● know the Life Cycle Assessment methodology, identifying it as a tool for characterizing the environmental and energy load throughout the life cycle of a product/service and as a useful tool for identifying possible mitigation interventions on induced environmental impacts, also through the reduction of raw materials and energy used in a system;
● know the Life Cycle Costing methodology as a tool for assessing total costs (private and environmental) throughout the life cycle of a product/service; discern the implications of replacing the "price" criterion of an asset with that of "cost", with a view to circular economy;
● know the ecological labelling systems and the management tools that allow economic and non-economic organizations to control the environmental impacts of their activities, pursuing the continuous improvement of environmental performance;
● know image processing techniques in order to characterize the territory and all its components from a qualitative and quantitative point of view, through the study and interpretation of medium and high resolution satellite images.
Applying knowledge and understanding
At the end of the course, students will be able to:
● evaluate the economic feasibility of the exploitation and use of exhaustible and renewable resources;
● develop an LCA by setting the different phases of the methodology: functional unit and system boundaries, inventory analysis (LCI) with the creation of an analog model of the system, identification of process inputs and outputs, analysis and interpretation of data related to the resulting impacts (LCIA);
● set up an hypothetical procedure for ecological product/service labelling, choose the type of labelling according to the objectives and the monitored product/service group; create impact indicators in order to simplify the obtained information and make it accessible even to non-experts;
● use image processing software to radiometrically and geometrically correct satellite images at different resolutions; evaluate the coverage elements from a qualitative and quantitative point of view and make a photo-interpretation of these elements; identify color-composite images and standardized "indices" that amplify the interpretative skills by highlighting the characteristics of the coverage elements.
Making judgements
By sharing presentations, documents and specific publications, the course will develop students' analytical skills and independent judgment, stimulating the evaluation of the specific system dealt with in order to identify the critical elements and the possible improvements. During the lessons, LCA and satellite image analysis software will also be used to present application cases, even complex ones, encouraging students to discuss interpretative hypotheses and possible analytical solutions to the highlighted problems. At the end of the course, students will be able to work on the topics covered both independently and as members of a team.
Communication skills
The teacher will stimulate the students' communication skills, inviting them to discussion and analysis on the topics and application cases dealt with.
Learning skills
The sharing of the material relating to the course, the discussion and identification of the main actors in reference to the covered topics, the identification of how the concepts of sustainable development and circular economy interact with all anthropogenic production/consumption activities: all this will help the students to develop a strong ability to continue, in total autonomy, the study and the professional and scientific updating on the topics dealt with
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Educational objectives The course is designed to equip students with a broad training in, and
understanding of, energy production, delivery, consumption, efficiency,
economics, policy and regulation. These are considered in the context
of the sustainability of energy supply and consumption patterns, both
locally and globally.
A feature of the course is its broad approach to the development of
sustainable routes to the generation and supply of energy within which
renewable energy is a key theme. The course is engineering-based but
also covers a wider range of topics including economics, sustainability
and environmental studies.On successful completion of this course, students will be able to:
Understand and evaluate alternative modes of energy supply, including
fossil-fuelled, nuclear and renewables-based supply, appreciate the
development of and constraints on carbon- and non carbon-based energy
resources, understand the challenges and constraints on end-use
efficiency of energy, appreciate the economic, policy and regulatory
frameworks within which decisions on energy futures are made, be
conversant with the problems of energy distribution and the constraints
on present distribution systems, critically analyse competing claims in
the energy sector, evaluate options for energy supply, distribution,
utilisation, articulate environmental sustainability of energy supply
systems, analyse the technical:economic interaction of developments in
the energy system
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