REGINNA 4.0 Third Summer School: «Deep Tech training on Industry 4.0, Artificial Intelligence, Nanotechnology and Entrepreneurship»

Europe/Madrid
204A (University of Leon)

204A

University of Leon

Escuela de Ingenierías Industrial, Informática y Aeroespacial
Description

UPDATE July 8, 2024: LAST DAYS! Examinations open until July 14, 2024

The registration for the asynchronous version of the Third Summer School of the  REGINNA 4.0 project has already been closed. Anyway, you can still carry out the online examination until July 14, that can be found in this link.

Upon successful completion of the exam, you will receive a certificate of achievement. This certificate can be converted to ECTS credits at some universities (the exact number depends on the university). The Summer School entails 25 hours of teaching and 25 hours of personal work by the student. For instance, the University of León recognises 2 ECTS in exchange of the Summer School.

We would want to thank the more than 650 students who have registered into the Summer School (more than 320 in the asynchronous version only).


Update May 30, 2024: Asynchronous version of the Third Summer School launched!

We are pleased to announce that the third free Summer School of the REGINNA 4.0 project, funded by the European Institute of Innovation & Technology (EIT) is now open to make asynchronously online to all students. Details are shown below:

  • Language: English
  • Modality: On-line asynchronous (at your own pace!)
  • Cost: Free of charge
  • Registration deadline: 07/07/2024
  • Examination deadline: 14/07/2024
  • ECTS credits: Passing an online test will allow university students to receive a certificate awarded by the EIT that might be redeemed for ECTS credits at their university. 
  • Contact: victor.gonzalez@unileon.es and l.fernandez@unileon.es

Recordings and materials from the conferences are available by accessing each contribution at https://indico.ung.si/event/34/contributions/.

The exam can be found at this link. You will receive a password to complete the exam when you complete the registration.

Upon successful completion of the exam, participants will receive a certificate awarded by the EIT.

Participating universities:

  • University of Nova Gorica (Slovenia)
  • University of Udine (Italy)
  • University of León (Spain)
  • Vasyl Stefanyk National Precarpathian University (Ukraine).

Registration can be done at the following link: https://indico.ung.si/event/34/registrations/28/


Update May 29, 2024: Online exam. Last deadline extension

For those students who have not yet passed the examination of the regular REGINNA 4.0 Third Summer School, the deadline to make it has been extended until June 7. You can now make it, accessing though this link.


Update May 20, 2024: Online exam deadline extended

For those students who have not yet passed the examination of the REGINNA 4.0 Third Summer School, the deadline to make it has been extended until May 31. You can now make it, accessing though this link.


Update May 3, 2024: Online exam available

Thank you for your interest in this Summer School! We hope that it has been interesting for you.

You can now make the online exam, accessing though this link. You can make it at any moment during the next 2 weeks.


The third Summer School of the REGINNA 4.0, funded by the European Institute of Innovation & Technology (EIT) will be held at the University of León (Spain). It will deepen in the topics of artificial intelligence and additive manufacturing in industry 4.0, nanotechnology and Innovation and entrepreneurship in nanotechnology, Industry 4.0 and artificial intelligence.

We will connect students with academics, businesses, public bodies and non-governmental organisations to explore innovations, business development and transfer of ideas from laboratory to the market. 

 

The summer school will be held in hybrid mode, completely in English. It will consist of three days of lectures spread over three different weeks (Friday, April 12; Friday, April 19; and Friday, May 3). The Summer School registration and attendance are free of charge.

Upon successfully completed examination, the participants will receive an EIT-Labelled certificate.

Participants can participate online or in-person. Those students who come in person can come one, two or the three days, following the rest of the Summer School online. Participants attending in person will be offered two free coffee breaks and one free lunch break each day.
The videos of the lectures will be recorded and published online, so the students can follow the Summer School asynchronously.

Registration deadlines:

  • 12/04/2024 online participation

  • 19/04/2024 in-person participation

 

The venue of the conference is the School of Industrial, Informatics and Aerospace Engineering of the University of León.

Participating Universities:

  • University of Nova Gorica (Slovenia)

  • University of Udine (Italy)

  • University of León (Spain)

  • Vasyl Stefanyk Precarpathian National University (Ukraine)

 

Funded by the European Union. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union. Neither the European Union can be held responsible for them.

 

Consortium logos

    • 7
      Additive manufacturing as a mean for supporting rapid development of innovative products 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      1. What is additive manufacturing and its basic operating principle (10 minutes)
      2. Review of groups of technologies and materials in additive manufacturing (40 minutes)
      3. Capabilities, advantages, constraints and limits of additive manufacturing (15 minutes)
      4. Application of additive manufacturing for innovating. Scope of application (15 minutes)
      5. Trends and future of additive manufacturing (10 minutes)
      6. Practical case using free software (45 minutes)

      Objective competences:
      Comprehensive overview of the different additive manufacturing technologies.
      Knowledge about limits and advantages of additive processes compared to traditional manufacturing.
      Basic knowledge about the actions for preparing, manufacturing and post-processing a part in additive manufacturing.
      Practical simulation of a case

      Intended learning outcomes:
      1. To know the reason behind the revolution of additive manufacturing in manufacturing of products
      2. To understand the reason which justify the consideration of additive manufacturing as one of the key enabling technologies in strategic agendas
      3. To know the range of industrial technologies for additive manufacturing
      4. To understand the process flow when manufacturing a product by additive manufacturing

      Speakers: Joaquín Barreiro García (Universidad de León), Mrs Sofía Peláez
    • 11:30
      Coffee break (free of charge) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial
    • 8
      Additive manufacturing as a mean for supporting rapid development of innovative products 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      1. What is additive manufacturing and its basic operating principle (10 minutes)
      2. Review of groups of technologies and materials in additive manufacturing (40 minutes)
      3. Capabilities, advantages, constraints and limits of additive manufacturing (15 minutes)
      4. Application of additive manufacturing for innovating. Scope of application (15 minutes)
      5. Trends and future of additive manufacturing (10 minutes)
      6. Practical case using free software (45 minutes)

      Objective competences:
      Comprehensive overview of the different additive manufacturing technologies.
      Knowledge about limits and advantages of additive processes compared to traditional manufacturing.
      Basic knowledge about the actions for preparing, manufacturing and post-processing a part in additive manufacturing.
      Practical simulation of a case

      Intended learning outcomes:
      1. To know the reason behind the revolution of additive manufacturing in manufacturing of products
      2. To understand the reason which justify the consideration of additive manufacturing as one of the key enabling technologies in strategic agendas
      3. To know the range of industrial technologies for additive manufacturing
      4. To understand the process flow when manufacturing a product by additive manufacturing

      Speakers: Joaquín Barreiro García (Universidad de León), Mrs Sofía Peláez
    • 9
      Reverse engineering and inspection in digital factory 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      1. What is reverse engineering and difference with inspection (5 minutes)
      2. Review of technologies for reverse engineering (15 minutes)
      3. Technologies for automated inspection in coordinate metrology (5 minutes)
      4. Capabilities, advantages, constraints and limits of optical systems for reverse engineering and inspection (10 minutes)
      5. Practical case of part reconstruction and modelling (10 minutes)

      Objective competences:
      Comprehensive overview of the different sensors for reverse engineering and coordinate based inspection.
      Knowledge about limits and advantages of sensors.
      Basic knowledge about the actions for preparing, scanning and post-processing a part in reverse engineering and inspection.
      Practical simulation of a case.

      Intended learning outcomes:
      To know the map of technologies used in 3D scanning of parts.
      To understand the working principle of optical sensors for reverse engineering or inspection in a digital factory.
      To understand the benefits of using reverse engineering for reconstruction of parts in a competitive world-class context.
      To understand the process steps when scanning a part for geometry modification or inspection
      To understand the strong link between reverse engineering and additive manufacturing

      Speakers: Joaquín Barreiro García (Universidad de León), Mrs Sara Giganto
    • 13:30
      Lunch break (free of charge) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial
    • 10
      Nanomaterials: Introduction 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      Nanotechnology and nanomaterials.
      Classifications of nanomaterials, their properties.
      Historical overview of nanomaterials.
      Reasons for special properties of nanoscale materials.
      Classical and quantum size effects.
      Basic concepts of quantum physics.
      The energy of an electron in an atom.
      Harmonic oscillator: transition from classical to quantum theory.
      Wave-particle duality. Uncertainty principle.
      Condensed matter physics. Electrons in crystals.
      Quantum dots and their applications.
      Applications of nanomaterials.

      Objective competences:
      Overview of nanomaterials (history and properties).
      Modern applications of nanomaterials.
      Basic concepts of quantum physics.

      Intended learning outcomes:
      Participants will gain general knowledge about nanomaterials and their properties.
      Participants will be able to identify different types of nanomaterials.
      Participants will distinguish between classical and quantum size effects.
      Participants will understand the basic concept of quantum mechanics.

      Literature
      Akkerman, Q. A. "Lead Halide Perovskite Nanocrystals: A New Age of Semiconductive Nanocrystals." 2019. http://dx.doi.org/10.13140/RG.2.2.23651.81442
      Ali, Ali Salman. “Application of Nanomaterials in Environmental Improvement.” IntechOpen eBooks, 2020, https://doi.org/10.5772/intechopen.91438
      Arulmani, S., et al. “Introduction to Advanced Nanomaterials.” Elsevier eBooks, 2018, pp. 1–53. https://doi.org/10.1016/b978-0-12-813731-4.00001-1
      Findik, Fehim. “Nanomaterials and Their Applications.” Periodicals of Engineering and Natural Sciences (PEN), vol. 9, no. 3, International University of Sarajevo, June 2021, p. 62. https://doi.org/10.21533/pen.v9i3.1837
      Kumar, Pawan, et al. “Nanostructured Materials: A Progressive Assessment and Future Direction for Energy Device Applications.” Coordination Chemistry Reviews, vol. 353, Elsevier BV, Dec. 2017, pp. 113–41. https://doi.org/10.1016/j.ccr.2017.10.005
      Negri, Viviana, et al. “Carbon Nanotubes in Biomedicine.” Topics in Current Chemistry, vol. 378, no. 1, Springer Science+Business Media, Jan. 2020, https://doi.org/10.1007/s41061-019-0278-8
      O’Brien, Stephen, et al. “Synthesis of Monodisperse Nanoparticles of Barium Titanate: Toward a Generalized Strategy of Oxide Nanoparticle Synthesis.” Journal of the American Chemical Society, vol. 123, no. 48, American Chemical Society, Nov. 2001, pp. 12085–86. https://doi.org/10.1021/ja011414a
      Raghvendra, R., et al. "Diagnostics and therapeutic application of gold nanoparticles." International Journal of Pharmacy and Pharmaceutical Science, vol. 6, 2014, pp. 74-87
      Sahoo, Biswa Mohan, et al. “Nanotechnology: A Novel Approach for Drug Development in Health Care System.” Current Nanomaterials, vol. 5, no. 1, June 2020, pp. 12–25. https://doi.org/10.2174/2405461505666200320152824
      Schwabl, Franz. “Quantum Mechanics.” Springer eBooks, 2007, https://doi.org/10.1007/978-3-540-71933-5
      Wu, Bing-Fei. “Quantum Mechanics”. 2023, https://doi.org/10.1007/978-981-19-7626-1

      Speaker: Mrs Liliia Turovska
    • 16:00
      Coffee break (free of charge) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial
    • 11
      Nanomaterials: Magic of carbon 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      Carbon. Allotropes.
      Electronic structure of carbon.
      Diamond:properties.
      Graphite: properties.
      Graphene:unique properties, crystal structure, production.
      Graphene oxide and graphite oxide.
      Obtaining graphene oxide.
      Reduced graphene oxide.
      Carbon nanotubes: synthesis, chirality, properties.
      Fullerenes: synthesis,properties, application.
      Applications of carbon nanomaterials.
      Biochar. Porous carbon.

      Objective competences:
      Review of the main properties of allotropic modifications of carbon.
      Graphene: unique properties and applications.
      Methods for obtaining graphene oxide and reduced graphene oxide.
      Overview of methods for experimental study of graphene materials.

      Intended learning outcomes:
      Participants will gain general knowledge about carbon materials.
      Participants will distinguish between different allotropic modifications of carbon.
      Participants will understand the various approaches to obtaining GO and rGO.
      Participants will be able to distinguish the results of an experimental study of graphene materials.
      Literature
      Ahlawat, Jyoti, et al. “Application of Carbon Nano Onions in the Biomedical Field: Recent Advances and Challenges.” Biomaterials Science, vol. 9, no. 3, Royal Society of Chemistry (RSC), 2021, pp. 626–44. Crossref, https://doi.org/10.1039/d0bm01476a
      Avouris, Phaedon. “Graphene: electronic and photonic properties and devices.” Nano letters vol. 10,11 (2010): 4285-94. https://doi.org/10.1021/nl102824h
      “Carbonaceous Composite Materials.” Materials Research Foundations, 2018, https://doi.org/10.21741/9781945291975
      “Chemistry of the Main Group Elements (Barron).” Chemistry LibreTexts, 8 Sept. 2020, https://chem.libretexts.org/Bookshelves/Inorganic_Chemistry/Chemistry_of_the_Main_Group_Elements_(Barron)
      Gao, Wei. “Graphene Oxide.” Springer eBooks, 2015, https://doi.org/10.1007/978-3-319-15500-5
      “Graphene, Nanotubes and Quantum Dots-Based Nanotechnology.” Elsevier eBooks, 2022, https://doi.org/10.1016/c2020-0-01826-8
      Hybrid Orbitals — Overview & Examples https://www.expii.com/t/hybrid-orbitals-overview-examples-8366
      Maiti, Debabrata, et al. “Carbon-Based Nanomaterials for Biomedical Applications: A Recent Study.” Frontiers in Pharmacology, vol. 9, Frontiers Media, Mar. 2019, https://doi.org/10.3389/fphar.2018.01401
      Matsumoto, Kazuhiko. “Frontiers of Graphene and Carbon Nanotubes.” Springer eBooks, 2015, https://doi.org/10.1007/978-4-431-55372-4
      Mbayachi, V.B., et al. “Graphene Synthesis, Characterization and Its Applications: A Review.” Results in Chemistry, vol. 3, Elsevier BV, Jan. 2021, p. 100163. https://doi.org/10.1016/j.rechem.2021.100163
      Neto, A. H. Castro, et al. “The Electronic Properties of Graphene.” Reviews of Modern Physics, vol. 81, no. 1, American Physical Society, Jan. 2009, pp. 109–62. https://doi.org/10.1103/revmodphys.81.109
      Orbital Hybridization: sp1, sp2, and sp3 Hybridization, Examples https://researchtweet.com/orbital-hybridization-sp1-sp2-sp3-hybridization/
      Patel, Dinesh Kumar, et al. “Carbon Nanotubes-Based Nanomaterials and Their Agricultural and Biotechnological Applications.” Materials, vol. 13, no. 7, Multidisciplinary Digital Publishing Institute, Apr. 2020, p. 1679. https://doi.org/10.3390/ma13071679
      Tîlmaciu, Carmen, and May Morris. “Carbon Nanotube Biosensors.” Frontiers in Chemistry, vol. 3, Frontiers Media, Oct. 2015, https://doi.org/10.3389/fchem.2015.00059

      Speaker: Mrs Volodymyra Boichuk
    • 12
      Introduction to Industrial Cybersecurity 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      1. Relevance of industrial cybersecurity
      2. Distinctive features of industrial control systems
      3. Threats, vulnerabilities and impact
      4. Known incidents
      5. Security measures in industrial control systems

      Objective competences:
      1. Awareness of cybersecurity risks in industrial control systems and critical infrastructures
      2. Overview of the features of industrial control systems in contrast to traditional information systems
      3. Overview of threats, vulnerabilities and countermeasures in industrial control systems

      Intended learning outcomes:
      1. Understand the relevance of cybersecurity in industrial control systems and critical infrastructures
      2. Understand the main threats and vulnerabilities in industrial control systems in contrast to traditional information systems
      3. Acquire a high-level view of procedures and measures available to mitigate cybersecurity risks.

      Literature
      K. Stouffer, S. Lightman, V. Pillitteri, M. Abrams & A. Hahn. NIST Special Publication 800-82 Rev. 2. Guide to Industrial Control Systems (ICS) Security https://doi.org/10.6028/NIST.SP.800-82r2

      Speaker: Mr Miguel Ángel Prada Medrano
    • 11:30
      Coffee break (free of charge) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial
    • 13
      An Introduction to Quantum computing 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      Participants will learn about quantum phenomena, which govern nature. These quantum phenomena will be explained through photon's interference, which will be introduced by double-slit and double-beam splitter experiments. Next, classical computation will be compared to quantum computation. Quantum bit will be introduced. Participants will learn through an example of the quantum algorithm, presented in real quantum computer and in a quantum computer simulator.

      Objective competences:
      Learn about quantum nature of photons and possibility of application in quantum computing
      Learn about the definition of quantum bit (qubit)
      See a tutorial on quantum programming in quantum computer or quantum computer simulator

      Intended learning outcomes:
      Understand the difference between classical and quantum computing
      Understanding what is qubit
      Obtain an idea of quantum computing algorithm

      Literature
      [1] P. Kaye, R. Laflamme, and M. Mosca, An Introduction to Quantum Computing, Repr (Oxford University Press, Oxford, 2010).

      Speaker: Egon Pavlica (UNG)
    • 14
      Innovation on the field (real cases) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      From invention to innovation
      Art & Design Thinking
      Cases of innovation

      Objective competences:
      Overview and critical reflection on the main differences between invention and innovation

      Intended learning outcomes:
      Understanding how inventions become innovations
      Reflect on real cases of innovation

      Speaker: Mr Simon Mokorel (RRA NORTH PRIMORSKA)
    • 13:30
      Lunch break (free of charge) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial
    • 15
      Entrepreneurship and start-up management 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      1. What is an entrepreneur? (Lecture)
      2. Approaches to the start-up phase (Lecture)
      3. The lean start-up approach in action (Hands-on)

      Objective competences:
      1. An overview of the features of entrepreneurial activities
      2. A discussion of various approaches that individuals may adopt when they start a new venture
      3. An application of the lean start-up approach to a business case

      Intended learning outcomes:
      1. Knowing the economic function of entrepreneurship
      2. Knowing the strengths and weaknesses of different patterns to the start-up
      3. Being able to apply the principles of the “lean start-up” methodology to an entrepreneurial idea

      Literature
      1. Ries, E. (2011). The lean startup: How today's entrepreneurs use continuous innovation to create radically successful businesses. Currency.
      2. Eisenmann, T. R., Ries, E., & Dillard, S. (2012). Hypothesis-driven entrepreneurship: The lean startup. Harvard Business School Entrepreneurial Management Case, (812-095).

      Speaker: Giancarlo Lauto (Department of Economics and Statistics)
    • 16:00
      Coffee break (free of charge)
    • 16
      Business strategies in high-innovation potential areas (Nanotechnology, Industry 4.0, Artificial intelligence) 204A

      204A

      University of Leon

      Escuela de Ingenierías Industrial, Informática y Aeroespacial

      Syllabus outline:
      This course aims to equip students with knowledge and skills in business strategy development and management process of its implementation in high-innovation potential areas (Nanotechnology, Industry 4.0, Artificial intelligence). This course focuses on strategic analysis, strategic planning, developing and implementing strategies.

      Objective competences:
      A comprehensive overview of business strategies in high-innovation potential areas (Nanotechnology, Industry 4.0, Artificial intelligence)
      A comprehensive overview of key methods in business strategic analysis in high-innovation potential areas
      Practical skills for business strategic analysis in high-innovation potential areas
      Practical skills for formulating the vision, mission, objectives and road map in startups in high-innovation potential areas
      Practical skills for building a business model canvas for startups in high-innovation potential areas

      Intended learning outcomes:
      1. Understanding the importance of business planning in the process of creating startups
      2. Students will be able to perform the business strategic analysis in high-innovation potential areas.
      3. Students will be able to formulate the vision, mission, objectives and road map in startups in high-innovation potential areas
      4. Students will be able to build a business model canvas for startups in high-innovation potential areas.
      4. Mini-Internship to get started with business strategic planning in startups in Nanotechnology, Industry 4.0, Artificial intelligence

      Literature
      Hunsaker, B.T.; Knowles, J. Effective Innovation Begins with Strategic Direction. MIT Sloan Manag. Rev. 2021, 11. Available online: https://sloanreview.mit.edu/article/effective-innovation-begins-with-strategic-direction/.
      Wolf, V.; Dobrucka, R.; Przekop, R.; Haubold, S. Innovation strategies in the context of the paradigm of the five dimensions of innovation strategy. Logforum 2021, 17, 205–211.
      Gaubinger, K.; Rabl, M.; Swan, S.; Werani, T. Innovation Strategy. In Innovation and Product Management; Springer: Berlin/Heidelberg, Germany, 2015; pp. 61–80.

      Speaker: Mrs Valentina Yakubiv (VASYL STEFANYK PRECARPATHIAN NATIONAL UNIVERSITY)