101-0193-00L  Systemic Design Labs: RE:GENERATE Alpine-Urban Circularity

SemesterAutumn Semester 2021
LecturersT. Luthe
Periodicitynon-recurring course
Language of instructionEnglish



Courses

NumberTitleHoursLecturers
101-0193-00 SSystemic Design Labs: RE:GENERATE Alpine-Urban Circularity
Intro: 24.9.21, 14-17h
Block (excursion/field work): 13.-17.10.21, full days
Final presentation: 10.12.21, 14-17h
30s hrsT. Luthe

Catalogue data

AbstractSystemic design (SD) optimizes an entire system as a whole, rather than its parts in isolation. SD is iterative, recursive and circular, requires creative, curious, informed and critical systems thinking and doing, yielding radical resource efficiency. It systems mapping, design thinking, footprint assessment, network analysis, test planning, prototyping, fabrication, social experiments.
Learning objectiveThe teaching purpose of Systemic Design Labs (SDL) is to better tackle the complexity of today’s sustainability challenges. Often, in current education we learn to disassemble design challenges into their bits and parts for individual optimization. While being useful for developing topical expertise, this reductionism to parts with less emphasis on their interaction does not match with the growing complexity of today’s challenges. In contrast, systemic design approaches a task from a holistic perspective, zooming out of a system to reveal its structure and connections between its parts – to zoom in on the hub of influence that matters most.
The objectives of the course are to introduce students to Systemic Design as theory, methodology and practice. This includes whole systems thinking, circularity, cross-scale design, Gigamapping, and many more. The course stimulates overall reflective eco-social thinking in design, planning and engineering disciplines.
ContentDesign Challenge: How to re-design alpine-urban circularity? How to revive mountain livelihoods, focusing on local identity, resilient landscapes and a regenerative economy? What is a regenerative relation between the alpine and the urban? Covid has accelerated and intensified a traditionally challenging relation of the alpine (mountain livelihoods) and the urban. Both depend on each other, but there are as well many unsustainable elements in this relation, especially for the alpine.

The specific design challenge is to identify and layout a holistic, partly quantified and visualized systems strategy for building a resilient community economy in relation to the actual Covid driven pressure factors in the relation of the alpine with the urban.
We build upon former ETH SDL students who developed a systems maps for the community of Ostana, Italy, that embraces local identity, revitalizes cultural and landscape biodiversity, and creates alpine-urban circularity.

This course will extend this systems map to more clearly understand the urban component, the source market, and design in new opportunities of urban-alpine regeneration, for circularity, for new ways of tourism, of mobility, in a creative economy.

Recap of former SDL courses:
In Ostana, a clear connection is between the local identity (culture, traditions, visions) which is formed by Occitan culture (food, music, dance, language), traditional stone building architecture which is under pressure to carefully evolve with new needs for carbon-neutral and net-positive buildings, and the Monte Viso landscape. How does a re-growing economy that should be regenerative and circular by design, correlate with innovation in architecture, with population growth and associated challenges in mobility, waste systems and supplies, with growing tourism, new agro-forestry practices like industrial hemp and Paulownia, while impacts of climate change are clearly visible? How does the community design a vision that is based on cooperation on different governance scales, balancing local identity and urgently needed international innovation?

Deliverables & output: This SDL course RE:GENERATE builds upon related work from former courses hosted and lead by the MonViso Institute (i.e. on social innovation, mobility, architecture and local identity, tourism, circular economy, land use change) to develop and design foundations for an extension of the existing, visualized and partly quantified systems map, that will support ongoing and future innovation processes in this community. The focus now is on the urban integration into new, regenerative business models of the alpine, and in regenerative relation between both as a model for the future. This course will thus develop an extended graphical systems map from the alpine to the urban, backed up by a technical report, and connected with the existing systems maps of Ostana and the surrounding valley.
Lecture notessee learning materials and https://systemicdesignlabs.ethz.ch/
Literaturee.g. Striebig, B. and Ogundipe, A. 2016. Engineering Applications in Sustainable Design and Development. ISBN-10: 8131529053.
Jones, P. 2014. Design research methods for systemic design: Perspectives from design education and practice. Proceedings of ISSS 2014, July 28 – Aug1, 2014, Washington, D.C.

Blizzard, J. L. and L. E. Klotz. 2012. A framework for sustainable whole systems design. Design Studies 33(5).

Brown, T. and J. Wyatt. 2010. Design thinking for social innovation. Stanford Social Innovation Review. Stanford University.

Fischer, M. 2015. Design it! Solving Sustainability problems by applying design thinking. GAIA 24/3:174-178.

Luthe, T., Kaegi, T. and J. Reger. 2013. A Systems Approach to Sustainable Technical Product Design. Combining life cycle assessment and virtual development in the case of skis. Journal of Industrial Ecology 17(4), 605-617. DOI: 10.1111/jiec.12000
Prerequisites / NoticeDepending on the Covid situation, some part of the course will be virtual via Zoom, using a Miro design board.
If possible, we will do a field trip. Some travel costs may apply.
Students need to be motivated to design in teams on the preparation of the deliverables, a systemic strategy map and a written report.
CompetenciesCompetencies
Subject-specific CompetenciesConcepts and Theoriesassessed
Techniques and Technologiesassessed
Method-specific CompetenciesAnalytical Competenciesassessed
Decision-makingassessed
Media and Digital Technologiesassessed
Problem-solvingassessed
Project Managementassessed
Social CompetenciesCommunicationassessed
Cooperation and Teamworkassessed
Customer Orientationassessed
Leadership and Responsibilityassessed
Self-presentation and Social Influence assessed
Sensitivity to Diversityassessed
Negotiationassessed
Personal CompetenciesAdaptability and Flexibilityassessed
Creative Thinkingassessed
Critical Thinkingassessed
Integrity and Work Ethicsassessed
Self-awareness and Self-reflection assessed
Self-direction and Self-management assessed

Performance assessment

Performance assessment information (valid until the course unit is held again)
Performance assessment as a semester course
ECTS credits4 credits
ExaminersT. Luthe
Typegraded semester performance
Language of examinationEnglish
RepetitionRepetition only possible after re-enrolling for the course unit.

Learning materials

 
Main linkSystemic Design Labs
Only public learning materials are listed.

Groups

No information on groups available.

Restrictions

Places20 at the most
Waiting listuntil 23.09.2021

Offered in

ProgrammeSectionType
Civil Engineering MasterRecommended Electives of Master ProgrammeWInformation
Geomatics MasterRecommended Electives of Master Degree ProgrammeWInformation
Spatial Development and Infrastructure Systems MasterRecommended Electives of Master Degree ProgrammeWInformation