PhD in Biomedical, Electrical and System Engineering

Academic Year 2022-2023
Subject area Engineering Studies
Cycle 38
Coordinator Prof. Michele Monaci
Language English, Italian
Duration 3 years

Application deadline: Dec 14, 2022 at 11:59 PM (Expired)

2nd NRRP Call for Applications - Further PhD positions

Enrolment: From Feb 02, 2023 to Feb 12, 2023 - On www.studenti.unibo.it, PhD candidates awarding NRRP positions should use NRRP forms only

Doctoral programme start date: Mar 01, 2023

NRRP loghi

Application deadline: Aug 02, 2022 at 11:59 PM (Expired)

NRRP Call for Applications

Enrolment: From Sep 26, 2022 to Oct 05, 2022 - On www.studenti.unibo.it download NRRP forms only

Doctoral programme start date: Nov 01, 2022

NRRP loghi

Application deadline: Jun 09, 2022 at 11:59 PM (Expired)

Call for Applications

Positions: More information in the PhD Programme Table

Enrolment: From Jul 29, 2022 to Aug 29, 2022

Doctoral programme start date: Nov 01, 2022

Main Department
Department of Electrical, Electronic, and Information Engineering "Guglielmo Marconi" - DEI
Curricula
  1. Automatic Control and Operational Research
  2. Bioengineering
  3. Electrical Engineering
Research topics

Curriculum 1: Automatic Control and Operational Research

The scientific areas involved in this Curriculum are Automatic Control (ING-INF/04) and Operational Research (MAT/09). These are fundamental subjects for the Master Courses in Management and Information (Electronics, Computer Science, Telecommunications, Biomedical, Automation) Engineering. Moreover, they are also present in most other Master Courses in Engineering and (as far as MAT/09 is concerned) also in Business Administration and Science. The unifying methodological aspect is the System Approach, which provides a very powerful viewpoint to face most problems in modern engineering as well as in many other applied sectors. The basic subjects (system theory, control theory, mathematical optimization, estimation methods, filtering and identification, simulation) provide very useful tools to deal with and solve in a formal and general way complex problems that are often faced with special-purpose procedures, sometimes of empirical type.

  • System and control theory
  • Nonlinear control
  • Geometric approach to control
  • Robotics
  • Motion control
  • Diagnosis of dynamic systems
  • Identification of dynamic systems
  • Aerial traffic control
  • Electric drives
  • Combinatorial optimization
  • Distributed optimization
  • Graph theory
  • Transportation and distribution (logistics) problems
  • Network optimization problems
  • Cutting and loading problems
  • Integration between predictive and prescriptive analytics.

The methodologies of many of these topics are of interest to candidates in other curricula of the doctorate. For this reason, common events and activities will be organized among the three curricula to encourage interaction among candidates and the sharing of methodologies, cultural exchange and multidisciplinary education.

Curriculum 2: Bioengineering

The Bioengineering curriculum promotes the acquisition of advanced skills of highly interdisciplinary character (from engineering to medical and biological sciences, from mathematics and physics to computer science) to face - by means of innovative tools and solutions - complex problems in the field of the life sciences. The curriculum offers a wide spectrum of research themes, involving electronic, information and industrial aspects of bioengineering:

  • Biomedical Imaging
  • Biomedical Signals and Data Processing
  • Biomechanics and Motor Function Control
  • Rehabilitation Engineering
  • Biomedical Instrumentation and Artificial Organs
  • Models of Physiological and Biological Systems
  • Computational Neuroscience
  • Molecular, Cellular and Tissue Engineering.

Strong connections exist between the various themes; frequently, the training and research activities are placed at the intersection of several themes. Each research project will pursue a specific objective: improvement of physiopathological knowledge, progress in diagnostic and therapeutic techniques, advancement in assistive and rehabilitation technologies, optimization of health-care management. The interaction with the other two curricula - thanks also to common courses and seminars with special emphasis on electrotechnics, control and optimization - certainly stimulates the sharing of methodologies, the cultural exchange and the multidisciplinary training necessary for an effective approach to bioengineering problems.

Curriculum 3: Electrical Engineering

The Electrical Engineering curriculum provides a wide scientific and technical-professional training in electrical engineering, with good base knowledge, capacity for technological and design innovation, and specific electrical knowledge. The Ph.D. candidate must be able to apply the analytical tools and the knowledge concerning the advanced technologies typical of electrical/electromechanical sector also to other engineering leading sectors. The scientific areas involved in this Curriculum are: Electrotechnics (ING-IND/31), Converters, electrical machines and drives (ING-IND/32), Electrical energy systems (ING-IND/33) and Electrical and electronic measurements (ING-INF/07). In particular, the Curriculum in Electrical Engineering aims to develop modern electrical DFC competencies and technologies such as:

  • power electronics
  • electric drives for automation, robotics, and traction
  • unconventional electric machines
  • methods of analysis, management and design of the electric power systems
  • electricity market
  • innovative architectures for the electric distribution
  • computer-aided design of electric power systems and components
  • rational use of energy and renewable sources
  • electromagnetic compatibility
  • interactions of electromagnetic fields with biological systems
  • electromagnetic characterization of materials
  • applied superconductivity
  • applied magneto hydrodynamics
  • plasma engineering
  • magnetic system engineering.
  • The activities of the course are customized to each student.
Job opportunities and potential areas of employment
At the end of the PhD course, students will have developed the ability to deal with problems of high conceptual and technological complexity by means of a rigorous and strongly multidisciplinary approach, will be able to manage innovative projects working both individually and within a group, will be able to evaluate the impact of new technological and methodological solutions in the development of systems, devices and services, as well as in management of plants and processes. Therefore, the skills obtained in the doctoral course can be spent with profit for:
- research positions in national and international academic institutions
- research positions within private or public research bodies
- innovation and technology transfer projects, which are particularly encouraged at regional and national level
- positions of responsibility in R&D departments of companies within the fields involved in the PhD Course
Thanks to the wide network of cooperation established by the members of the PhD Committee with external institutions, during the PhD course students have the opportunity to get in contact with companies and research centers and to approach real problems relate dto production of devices and services.
Admission Board

NRRP Call - Further PhD Positions
Appointed by RD 952/2022 Prot. n. 0357333 of 02/12/2022

Surname Name University / Institution Role Email
Breschi Marco Università di Bologna Member
Cristofolini Andrea Università di Bologna Member
Zarri Luca Università di Bologna Member
Rinaldi Paola Università di Bologna Substitute
Sandrolini Leonardo Università di Bologna Substitute
Tani Angelo Università di Bologna Substitute

Call for Application and NRRP Call
Appointed by RD 830/2022 Prot. n. 0127511 of 30/05/2022
Confirmed by RD 1103/2022 Prot. n. 0162873 of 17/07/2022

Surname Name University / Institution Role email Curriculum
Cuppini Cristiano Università di Bologna Member Bioengineering
Palli Gianluca Università di Bologna Member Automatic Control and Operational Research
Zarri Luca Università di Bologna Member Electrical Engineering
Grandi Gabriele Università di Bologna Substitute Electrical Engineering
Macchelli Alessandro Università di Bologna Substitute Automatic Control and Operational Research
Magosso Elisa Università di Bologna Substitute Bioengineering

* The following shall take part in the work of the Examination Board as expert members for positions linked to specific research topics:

  • Riccardo Morici - Energy Technology Srl
  • Antonio Trotta - Eni SpA
  • Lorenzo Marconi - Fiels Robotics
  • Gildo Bosi - Sacmi Imola
  • Luca Mezzo - Mind Srl
  • Claudio Caremi - Optit Srl
  • Giorgio Crugnola - Free2move eSolution
  • Paolo Prati - Sol et Salus Spa
  • Francesco Maffessanti - Maria Cecilia Hospital
  • Paolo Tubertini - IRCCS Azienda Ospedaliero-Universitaria di Bologna
  • Daniele Bertin - Calzoni Srl
Learning outcomes

The aim is to prepare researchers in order to allow them to develop research and professional activities. The PhD course has therefore the following goals for the students:

  • use of tools and general methods of scientific research
  • methods and technologies of each curriculum
  • international comparison
  • fit autonomously in research team with the ability to manage projects and working groups.

The first two objectives are achieved mainly in the first year, while the third and fourth goal in the next two years. These objectives are achieved through the study, documentation, research and dissemination of results. The curricula of the course, tailored to each student, require such activities organized in line with the development of an independent research project in agreement with a supervisor. The skills acquired will be spent from the professional point of view, both in Italy and abroad, within academic institutions, public and private research centres, and industries.

Activities to be carried out by Doctoral candidates

Activity of the PhD student consists in carrying out a scientifically relevant and innovative research project in one of the subjects of the Course. Project development often involves the cooperation with major companies or research centers. The research activity, under the constant supervision of a professor/researcher, is organized over three years. The first year is mainly devoted to the study of literature and theoretical in-depth analysis of methods and technologies necessary for project development; to this aim, the student will attend courses specifically designed for the PhD program or from second-level degree courses and will participate to doctoral schools and seminars. The second and third years are devoted to research activity, also including experimental practice. To this end, the PhD student can benefit of advanced equipment and instrumentation available at DEI laboratories available for all disciplines of the PhD. During this period, the student participates to scientific conferences and workshops, to interact with the international scientific community; moreover, the student spends a research period at qualified international research institutions. The final part of the 3rd year is devoted to the preparation of the final dissertation with emphasis on critical analysis of the results, selection of the most important and original contributions, identification of future developments. Given the interdisciplinary nature of the disciplines of the PhD Course, the student will take advantage of events and seminars organized as part of the 3 curricula and by the University of Bologna (e.g., by the Institute for Advanced Studies), which promote an exchange of skills and cultural opportunities.

Research training activities compliant with the Doctoral programme's learning outcomes

The PhD student in Biomedical, Electrical, and Systems Engineering must:

  • Start with basic introductory studies (including literature search), attending courses and seminars either organized ad hoc or chosen among the ones available at the Bologna University. This activity is carried out mainly during the 1st year
  • Join one or more areas of active research at DEI. This activity of general training also includes the participation at annual national and international specific doctorate schools (mainly during the 1st and 2nd year)
  • Propose and autonomously develop a research project, using also the indications from the tutor and the members of the PhD Committee. This specialized training activity includes the participation in conferences and specialized courses, as well as a training period abroad
  • Commit to disseminate the research results through the publication of articles in international journals (mainly on the 2nd and 3rd year) and through the publication of the dissertation, as well as its final discussion.

In the three years of the PhD course the student should carry on a training activity equivalent to at least 180 hours. At the end of each academic year, the members of the PhD Committee evaluate the activities of each student with the aim of monitoring the achievement of the educational goals.

Internationalization features

The Doctorate promotes several internationalization initiatives including:

  • strong cooperation links between the PhD Council members and highly-reputed research centers and Universities in European, American, and Asiatic countries
  • a mandatory training period abroad for each PhD student, normally lasting 6 months (minimum 3), at an high qualified foreign institution.

PhD students mobility is also promoted by specific programmes of the University of Bologna (such as Marco Polo Program) which contribute to financially sustain the overseas training of the PhD students. Initiatives to attract and encourage enrollment of foreign students in the PhD course through:

  • opening the PhD Course to students from foreign countries and funded by specific international mobility programs (eg Erasmus Mundus, China Scholarship Council, CONICYT, Marie Curie, individual agreements, foreign national programmes)
  • publicizing the PhD calls on the most important specialized scientific networks
  • personal contacts of Council members with colleagues of the foreign research institutes.
Expected research results and products

The research activity, joint with specialized and interdisciplinary training, is expected to produce results with relevant impacts on basic knowledge and/or technological-methodological advancement and/or applications in clinical, health-care, electrical, energetic, automation, robotics, optimization and transportation fields. These results should lead to the following products: presentations at international conferences and publications on journals, to disseminate research methods and results to scientific community. The student is encouraged to produce publications in cooperation with the international institute where he/she spends a training period abroad; Participation in the preparation of project proposals to be submitted to national or European competitive calls; Contributions to the development of patents and to technology transfer, thanks to the strong applicative character of many research issues carried out by the students. In order for these products and results to be actually achieved, students’ training and research activities are strictly monitored throughout the 3-year period. Besides the constant supervision by the tutor, the PhD Committee periodically verifies the adequacy of the training activities followed by the students (courses, seminars, schools, conferences), the progress of their research activity, and attained products (articles, projects, patents). Admission to the next year or to final examination is conditional on the fulfillment of minimum requirements.