The document describes several system design tools for sustainability, including stakeholder system maps, interaction tables, and storyboards. Stakeholder system maps visually depict the stakeholders in a system and their interactions through various flows. Interaction tables show a narrative of system interactions over time from different stakeholder perspectives. Storyboards similarly illustrate system functioning and stakeholder roles through a sequence of images. The tools can be used at different stages of the design process to analyze, conceptualize, develop, and communicate system designs.
1. The document describes various system design tools that can be used when applying the Methodology for Sustainable System Design (MSDS), including stakeholder system maps, interaction tables, and satisfaction offering diagrams.
2. The stakeholder system map is used to visualize the structure of a system by mapping stakeholders and their interactions. The interaction table displays a narrative of interactions through a sequence of images and text.
3. The satisfaction offering diagram represents the core satisfaction provided by a system and related sub-satisfactions, showing how they will be delivered. Templates and libraries are provided to help construct the various tools.
5.2 (Other) System Design Tools Vezzoli 07 08 (28.10.08)vezzoli
The document describes various tools that can be used at different stages of system design for sustainability, including:
1. A system map that visually represents stakeholders and interactions within a system.
2. An interaction table/storyboard that describes frontstage and backstage interactions through a sequence of images and text.
3. An offering diagram that represents a system's core function and additional value functions through subfunctions.
4. A poster that synthesizes a system offering through images, text, slogans.
1.2 evolution of sustainability within design vezzoli 12-13 (41)LeNS_slide
The document discusses the evolution of sustainability within design. It describes how approaches to sustainability in design have shifted over time from:
1) Using low environmental impact materials and energies in the 1970s.
2) Considering the full product life cycle and ecodesign in the 1990s.
3) Designing product-service systems for eco-efficiency since the 2000s.
It argues that while interest in design for sustainability is growing, most design communities still lack solid knowledge and tools for designing with sustainability in mind and are more part of the problem than the solution. The document traces how understanding and practices around sustainable design have progressed over several decades but still have further to evolve.
This document describes three system design tools: the stakeholder system map, interaction table, and storyboard. The stakeholder system map visually maps the stakeholders involved in a system and the flows between them, such as material, information, and financial flows. The interaction table and storyboard are used to design and visualize the functioning of a system through a sequence of images and text describing interactions between stakeholders over time. These tools can be used at different stages of the design process to analyze existing systems, develop new system concepts, and further refine system details. Templates and libraries to support using these tools can be found on the LENS website.
5.1 system design for sustainable energy for all vezzoli 13_14LeNS_slide
The document discusses the importance of sustainable energy for all and distributed renewable energy systems. It argues that sustainable development is not possible without sustainable energy access. Distributed renewable energy, using small-scale local generation from sources like solar and wind, provides environmental, social and economic benefits over large-scale fossil fuel systems. Product-service systems that provide access to energy services rather than requiring ownership of products could facilitate widespread adoption of distributed renewable energy models. The document calls for system design approaches that can develop sustainable energy solutions tailored to local contexts through innovative stakeholder collaborations.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive function. Exercise causes chemical changes in the brain that may help protect against mental illness and improve symptoms for those who already suffer from conditions like depression and anxiety.
1. The document describes various system design tools that can be used when applying the Methodology for Sustainable System Design (MSDS), including stakeholder system maps, interaction tables, and satisfaction offering diagrams.
2. The stakeholder system map is used to visualize the structure of a system by mapping stakeholders and their interactions. The interaction table displays a narrative of interactions through a sequence of images and text.
3. The satisfaction offering diagram represents the core satisfaction provided by a system and related sub-satisfactions, showing how they will be delivered. Templates and libraries are provided to help construct the various tools.
5.2 (Other) System Design Tools Vezzoli 07 08 (28.10.08)vezzoli
The document describes various tools that can be used at different stages of system design for sustainability, including:
1. A system map that visually represents stakeholders and interactions within a system.
2. An interaction table/storyboard that describes frontstage and backstage interactions through a sequence of images and text.
3. An offering diagram that represents a system's core function and additional value functions through subfunctions.
4. A poster that synthesizes a system offering through images, text, slogans.
1.2 evolution of sustainability within design vezzoli 12-13 (41)LeNS_slide
The document discusses the evolution of sustainability within design. It describes how approaches to sustainability in design have shifted over time from:
1) Using low environmental impact materials and energies in the 1970s.
2) Considering the full product life cycle and ecodesign in the 1990s.
3) Designing product-service systems for eco-efficiency since the 2000s.
It argues that while interest in design for sustainability is growing, most design communities still lack solid knowledge and tools for designing with sustainability in mind and are more part of the problem than the solution. The document traces how understanding and practices around sustainable design have progressed over several decades but still have further to evolve.
This document describes three system design tools: the stakeholder system map, interaction table, and storyboard. The stakeholder system map visually maps the stakeholders involved in a system and the flows between them, such as material, information, and financial flows. The interaction table and storyboard are used to design and visualize the functioning of a system through a sequence of images and text describing interactions between stakeholders over time. These tools can be used at different stages of the design process to analyze existing systems, develop new system concepts, and further refine system details. Templates and libraries to support using these tools can be found on the LENS website.
5.1 system design for sustainable energy for all vezzoli 13_14LeNS_slide
The document discusses the importance of sustainable energy for all and distributed renewable energy systems. It argues that sustainable development is not possible without sustainable energy access. Distributed renewable energy, using small-scale local generation from sources like solar and wind, provides environmental, social and economic benefits over large-scale fossil fuel systems. Product-service systems that provide access to energy services rather than requiring ownership of products could facilitate widespread adoption of distributed renewable energy models. The document calls for system design approaches that can develop sustainable energy solutions tailored to local contexts through innovative stakeholder collaborations.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive function. Exercise causes chemical changes in the brain that may help protect against mental illness and improve symptoms for those who already suffer from conditions like depression and anxiety.
This document describes several system design tools for sustainability, including a stakeholder system map, interaction table, and satisfaction offering diagram. The stakeholder system map is a graphical representation that visualizes the configuration of a system by showing stakeholders, flows of interactions between them, and material, information, and financial flows. The interaction table and storyboard are tools to design and visualize the functioning of a system over time through a set of narratives describing interactions between stakeholders from both customer-facing and back-end perspectives. Software and library resources are provided to support using these tools in the design process.
6.2 sustainability system design tools vezzoli 12-13 (33)LeNS_slide
This document describes two tools for orienting system design towards sustainability: the Sustainability Design-Orienting (SDO) toolkit and the Sustainability Interaction Story-Spot. The SDO toolkit is a modular software that supports evaluating existing systems, analyzing best practices, generating sustainable ideas, and checking sustainability improvements. It includes criteria, guidelines, and checklists for environmental, socio-ethical and economic dimensions. The Sustainability Interaction Story-Spot visually represents key sustainability interactions achieved through a concept using images, text, and notes highlighting criteria. Both tools integrate into the design process and aim to improve sustainability of products, services and systems.
3.1 eco efficient system innovation vezzoli-12-13 (33)LeNS_slide
This document discusses system design for eco-efficiency and eco-efficient product-service systems (PSS). It defines eco-efficient PSS as an offer model providing an integrated mix of products and services to fulfill customer demand based on innovative stakeholder interactions. Three types of eco-efficient system innovations are described: adding value to the product life cycle, providing final results to customers, and providing enabling platforms for customers. While eco-efficient PSS have the potential to decouple economic value from environmental impacts, barriers like cultural shifts, business models, and policies have limited their diffusion compared to traditional product sales models.
3.1 eco efficient system innovation vezzoli-10-11LeNS_slide
The document discusses system design for eco-efficiency. It defines eco-efficient system innovation as innovations that delink economic interests from environmental impacts by increasing stakeholder interactions beyond traditional product and process innovations. Three types of eco-efficient system innovations are described: adding value to product lifecycles, providing final results to customers, and providing enabling platforms for customers. Guidelines and criteria are needed to design systems that optimize stakeholder interactions and mix products and services for high eco-efficiency.
2.2 life cycle design strategies cortesi 10-11LeNS_slide
The document discusses several life cycle design criteria for sustainable product design:
1) Resources minimization aims to reduce the consumption of materials and energy throughout a product's life cycle.
2) Low impact resources selection involves choosing materials and energies with the lowest environmental impact considering toxicity and renewability.
3) Product lifespan optimization focuses on extending the useful lifespan of products through durability as well as intensifying product use.
4) Material lifespan extension makes materials last beyond a single product use through recycling, composting, or energy recovery.
5) Design for disassembly facilitates the separation of parts and materials for easier maintenance, repair, reuse, and recycling.
Studer the challenge of sustainable transport systems 01LeNS_slide
This document discusses the challenges of unsustainable transport systems and measures to promote more sustainable transport. It outlines problems with current transport systems such as road safety issues, environmental impacts, and economic costs. It then describes several urban measures that can be taken to encourage sustainable transport, including improving public transit, managing traffic and goods delivery, promoting biking and walking, using pricing strategies, and adopting cleaner vehicles and fuels. The overall goal is to shift people from private vehicles to more sustainable modes of transportation.
5.6 off main-grid systems for access to electricityLeNS_slide
This document discusses off-main-grid systems for electricity access. It defines off-main-grid systems as decentralized or distributed systems that are not connected to the main electricity grid. The document outlines appropriate technologies for off-main-grid systems and compares centralized versus off-main-grid electrification approaches. It also describes different generation technologies that can be used in off-main-grid systems, including conventional diesel, non-conventional renewable energy technologies, and hybrid systems.
2.1 product life cycle design cortesi 10-11LeNS_slide
This document introduces key concepts for product life cycle design including:
1) Product life cycle design (LCD) takes a broader view of design from the single product to the full life cycle stages and functional unit.
2) Life cycle assessment (LCA) is a quantitative method to evaluate the environmental impacts of a product's life cycle from raw material extraction to end of life.
3) LCD aims to minimize environmental impacts across the life cycle by establishing design criteria like reducing resource use, selecting less impactful materials, optimizing product lifespan, and enabling disassembly.
The document discusses a course on System Design for Sustainability (SDS). It provides an overview of the course structure, learning objectives, lecturers, and assignments. The course aims to teach theory and practice of designing sustainable systems of products and services. It includes lectures on sustainability concepts and methods, and a design exercise where students design a sustainable mobility system for a specific foreign context.
The document outlines the design of a sustainable mobility system project involving students from Politecnico di Milano and local universities in emerging contexts. Students are assigned a specific mobility theme and context, and are tasked with developing a sustainable system concept. The concept is to include an analysis of stakeholders and services, as well as a draft product or "module" to adapt vehicles. Students will go through phases of strategic analysis, concept design, and reporting. Local professors will provide feedback and additional information. The goal is a trans-cultural learning process and development of sustainable mobility solutions for various locations.
The document discusses two tools for product-service system design for sustainability: the stakeholder system map and the interaction table (storyboard). The stakeholder system map is a graphical representation that visualizes the stakeholders involved and their physical, informational, financial, and labor flows/interactions. The interaction table is also a graphical representation, consisting of a sequence of images depicting interactions over time between stakeholders, accompanied by short texts describing each stakeholder's role. Both tools are meant to facilitate collaborative and progressive design of the system organization and interactions.
6.1 method for system design for sustainability vezzoli 10-11 (40)LeNS_slide
The document discusses the MSDS (Method for System Design for Sustainability) method for designing sustainable systems. It describes the phases of MSDS including strategic analysis, exploring opportunities, system concept design, and system design. It outlines the goals and tools used in each phase, such as the sustainability design-orienting toolkit, interaction storyboard, and satisfaction offering diagram. The overview emphasizes that MSDS is a modular method to enable starting the process at any phase and focusing on selected dimensions of sustainability.
5.1 method for system design for sustainability vezzoli 09-10 (33)vezzoliDSS
The document describes the MSDS (Method for System Design for Sustainability) which provides a modular and flexible method for designing sustainable systems. The MSDS involves several phases including strategic analysis, exploring opportunities, system concept design, system design and engineering, and communication. Key tools used in the MSDS include the sustainability design-orienting toolkit, system map, interaction table, and satisfaction offering diagram. The overall goal of the method is to design integrated systems that fulfill demands through eco-efficient and socially equitable stakeholder interactions.
3.1 Sustainability system design toolsUtttam Kumar
The document describes the MSDS (Method for System Design for Sustainability) method and tools for designing product-service systems with sustainability in mind. The MSDS method involves several phases including strategic analysis, exploring opportunities, system concept design, system design, and communication. Key tools used in the MSDS method include the Sustainability Design-Orienting toolkit for evaluating sustainability criteria and priorities, as well as system maps, interaction tables, and other tools for conceptualizing and developing sustainable product-service system concepts. The MSDS method is a modular approach that can be started at any phase and focuses on sustainability across environmental, socio-ethical and economic dimensions.
The document describes the Method for System Design for Sustainability (MSDS), which provides methods and tools to orient system design towards more sustainable solutions. MSDS includes phases like strategic analysis, exploring opportunities, and system concept design. It uses tools like the Sustainability Design-Orienting toolkit and Sustainability Interaction Story-Spot to prioritize sustainability criteria, generate ideas, and check sustainability improvements at different design stages. The overall goal of MSDS is to facilitate the design of integrated product-service systems that fulfill demands in more environmentally, socially, and economically sustainable ways.
The document discusses approaches to system design for eco-efficiency. It describes three main approaches: 1) satisfaction-system, which designs all products and services associated with fulfilling a customer demand or satisfaction; 2) stakeholder interactions, which focuses on innovative partnerships between socio-economic stakeholders; and 3) sustainability-oriented systems, which designs the system to optimize criteria like the life of products, reduction of transportation, resources, waste, and toxins. It provides methods and tools to guide system design towards more eco-efficient solutions through analyzing stakeholders and contexts and generating sustainability-oriented ideas.
5.7 Design exercise: system concept evaluationUtttam Kumar
The document outlines the phases and tools for a design exercise to develop a sustainable eating system concept for the Politecnico di Milano university campus in Italy. The exercise will follow the Method for System Design for Sustainability (MSDS) and involve phases of strategic analysis, exploring opportunities, system concept design, system design and engineering, and communication. Students will conduct an analysis of stakeholders and context, generate and select ideas, develop the system concept using tools like system maps and storyboards, and check/visualize the sustainability impacts of the concept.
5.6 Design Exercise System Concept Development And VisualisationLeNS_slide
The document outlines the design phases and schedule for developing a product-service system concept. It details the tools and steps to be used on Thursday from 9:15-18:00 which include creating a system map, satisfaction offering diagram, interaction storyboard, and renderings of product and support concepts. The results are to be uploaded to the LENS-WEB platform by 18:00 in a specified order, including a satisfaction offering diagram, system concept synthesis, system map, interaction storyboard, and localization in a campus map.
5.6 Design exercise: system concept development and visualisationUtttam Kumar
The document outlines the design phases and schedule for developing a product-service system concept. It details the tools and steps to be used on Thursday from 9:15-18:00 which include creating a system map, satisfaction offering diagram, interaction storyboard, and renderings of product and support concepts. The results are to be uploaded to the LENS-WEB platform by 18:00 in a specified order, including a satisfaction offering diagram, system concept synthesis, system map, interaction storyboard, and localization in a campus map.
This document describes several system design tools for sustainability, including a stakeholder system map, interaction table, and satisfaction offering diagram. The stakeholder system map is a graphical representation that visualizes the configuration of a system by showing stakeholders, flows of interactions between them, and material, information, and financial flows. The interaction table and storyboard are tools to design and visualize the functioning of a system over time through a set of narratives describing interactions between stakeholders from both customer-facing and back-end perspectives. Software and library resources are provided to support using these tools in the design process.
6.2 sustainability system design tools vezzoli 12-13 (33)LeNS_slide
This document describes two tools for orienting system design towards sustainability: the Sustainability Design-Orienting (SDO) toolkit and the Sustainability Interaction Story-Spot. The SDO toolkit is a modular software that supports evaluating existing systems, analyzing best practices, generating sustainable ideas, and checking sustainability improvements. It includes criteria, guidelines, and checklists for environmental, socio-ethical and economic dimensions. The Sustainability Interaction Story-Spot visually represents key sustainability interactions achieved through a concept using images, text, and notes highlighting criteria. Both tools integrate into the design process and aim to improve sustainability of products, services and systems.
3.1 eco efficient system innovation vezzoli-12-13 (33)LeNS_slide
This document discusses system design for eco-efficiency and eco-efficient product-service systems (PSS). It defines eco-efficient PSS as an offer model providing an integrated mix of products and services to fulfill customer demand based on innovative stakeholder interactions. Three types of eco-efficient system innovations are described: adding value to the product life cycle, providing final results to customers, and providing enabling platforms for customers. While eco-efficient PSS have the potential to decouple economic value from environmental impacts, barriers like cultural shifts, business models, and policies have limited their diffusion compared to traditional product sales models.
3.1 eco efficient system innovation vezzoli-10-11LeNS_slide
The document discusses system design for eco-efficiency. It defines eco-efficient system innovation as innovations that delink economic interests from environmental impacts by increasing stakeholder interactions beyond traditional product and process innovations. Three types of eco-efficient system innovations are described: adding value to product lifecycles, providing final results to customers, and providing enabling platforms for customers. Guidelines and criteria are needed to design systems that optimize stakeholder interactions and mix products and services for high eco-efficiency.
2.2 life cycle design strategies cortesi 10-11LeNS_slide
The document discusses several life cycle design criteria for sustainable product design:
1) Resources minimization aims to reduce the consumption of materials and energy throughout a product's life cycle.
2) Low impact resources selection involves choosing materials and energies with the lowest environmental impact considering toxicity and renewability.
3) Product lifespan optimization focuses on extending the useful lifespan of products through durability as well as intensifying product use.
4) Material lifespan extension makes materials last beyond a single product use through recycling, composting, or energy recovery.
5) Design for disassembly facilitates the separation of parts and materials for easier maintenance, repair, reuse, and recycling.
Studer the challenge of sustainable transport systems 01LeNS_slide
This document discusses the challenges of unsustainable transport systems and measures to promote more sustainable transport. It outlines problems with current transport systems such as road safety issues, environmental impacts, and economic costs. It then describes several urban measures that can be taken to encourage sustainable transport, including improving public transit, managing traffic and goods delivery, promoting biking and walking, using pricing strategies, and adopting cleaner vehicles and fuels. The overall goal is to shift people from private vehicles to more sustainable modes of transportation.
5.6 off main-grid systems for access to electricityLeNS_slide
This document discusses off-main-grid systems for electricity access. It defines off-main-grid systems as decentralized or distributed systems that are not connected to the main electricity grid. The document outlines appropriate technologies for off-main-grid systems and compares centralized versus off-main-grid electrification approaches. It also describes different generation technologies that can be used in off-main-grid systems, including conventional diesel, non-conventional renewable energy technologies, and hybrid systems.
2.1 product life cycle design cortesi 10-11LeNS_slide
This document introduces key concepts for product life cycle design including:
1) Product life cycle design (LCD) takes a broader view of design from the single product to the full life cycle stages and functional unit.
2) Life cycle assessment (LCA) is a quantitative method to evaluate the environmental impacts of a product's life cycle from raw material extraction to end of life.
3) LCD aims to minimize environmental impacts across the life cycle by establishing design criteria like reducing resource use, selecting less impactful materials, optimizing product lifespan, and enabling disassembly.
The document discusses a course on System Design for Sustainability (SDS). It provides an overview of the course structure, learning objectives, lecturers, and assignments. The course aims to teach theory and practice of designing sustainable systems of products and services. It includes lectures on sustainability concepts and methods, and a design exercise where students design a sustainable mobility system for a specific foreign context.
The document outlines the design of a sustainable mobility system project involving students from Politecnico di Milano and local universities in emerging contexts. Students are assigned a specific mobility theme and context, and are tasked with developing a sustainable system concept. The concept is to include an analysis of stakeholders and services, as well as a draft product or "module" to adapt vehicles. Students will go through phases of strategic analysis, concept design, and reporting. Local professors will provide feedback and additional information. The goal is a trans-cultural learning process and development of sustainable mobility solutions for various locations.
The document discusses two tools for product-service system design for sustainability: the stakeholder system map and the interaction table (storyboard). The stakeholder system map is a graphical representation that visualizes the stakeholders involved and their physical, informational, financial, and labor flows/interactions. The interaction table is also a graphical representation, consisting of a sequence of images depicting interactions over time between stakeholders, accompanied by short texts describing each stakeholder's role. Both tools are meant to facilitate collaborative and progressive design of the system organization and interactions.
6.1 method for system design for sustainability vezzoli 10-11 (40)LeNS_slide
The document discusses the MSDS (Method for System Design for Sustainability) method for designing sustainable systems. It describes the phases of MSDS including strategic analysis, exploring opportunities, system concept design, and system design. It outlines the goals and tools used in each phase, such as the sustainability design-orienting toolkit, interaction storyboard, and satisfaction offering diagram. The overview emphasizes that MSDS is a modular method to enable starting the process at any phase and focusing on selected dimensions of sustainability.
5.1 method for system design for sustainability vezzoli 09-10 (33)vezzoliDSS
The document describes the MSDS (Method for System Design for Sustainability) which provides a modular and flexible method for designing sustainable systems. The MSDS involves several phases including strategic analysis, exploring opportunities, system concept design, system design and engineering, and communication. Key tools used in the MSDS include the sustainability design-orienting toolkit, system map, interaction table, and satisfaction offering diagram. The overall goal of the method is to design integrated systems that fulfill demands through eco-efficient and socially equitable stakeholder interactions.
3.1 Sustainability system design toolsUtttam Kumar
The document describes the MSDS (Method for System Design for Sustainability) method and tools for designing product-service systems with sustainability in mind. The MSDS method involves several phases including strategic analysis, exploring opportunities, system concept design, system design, and communication. Key tools used in the MSDS method include the Sustainability Design-Orienting toolkit for evaluating sustainability criteria and priorities, as well as system maps, interaction tables, and other tools for conceptualizing and developing sustainable product-service system concepts. The MSDS method is a modular approach that can be started at any phase and focuses on sustainability across environmental, socio-ethical and economic dimensions.
The document describes the Method for System Design for Sustainability (MSDS), which provides methods and tools to orient system design towards more sustainable solutions. MSDS includes phases like strategic analysis, exploring opportunities, and system concept design. It uses tools like the Sustainability Design-Orienting toolkit and Sustainability Interaction Story-Spot to prioritize sustainability criteria, generate ideas, and check sustainability improvements at different design stages. The overall goal of MSDS is to facilitate the design of integrated product-service systems that fulfill demands in more environmentally, socially, and economically sustainable ways.
The document discusses approaches to system design for eco-efficiency. It describes three main approaches: 1) satisfaction-system, which designs all products and services associated with fulfilling a customer demand or satisfaction; 2) stakeholder interactions, which focuses on innovative partnerships between socio-economic stakeholders; and 3) sustainability-oriented systems, which designs the system to optimize criteria like the life of products, reduction of transportation, resources, waste, and toxins. It provides methods and tools to guide system design towards more eco-efficient solutions through analyzing stakeholders and contexts and generating sustainability-oriented ideas.
5.7 Design exercise: system concept evaluationUtttam Kumar
The document outlines the phases and tools for a design exercise to develop a sustainable eating system concept for the Politecnico di Milano university campus in Italy. The exercise will follow the Method for System Design for Sustainability (MSDS) and involve phases of strategic analysis, exploring opportunities, system concept design, system design and engineering, and communication. Students will conduct an analysis of stakeholders and context, generate and select ideas, develop the system concept using tools like system maps and storyboards, and check/visualize the sustainability impacts of the concept.
5.6 Design Exercise System Concept Development And VisualisationLeNS_slide
The document outlines the design phases and schedule for developing a product-service system concept. It details the tools and steps to be used on Thursday from 9:15-18:00 which include creating a system map, satisfaction offering diagram, interaction storyboard, and renderings of product and support concepts. The results are to be uploaded to the LENS-WEB platform by 18:00 in a specified order, including a satisfaction offering diagram, system concept synthesis, system map, interaction storyboard, and localization in a campus map.
5.6 Design exercise: system concept development and visualisationUtttam Kumar
The document outlines the design phases and schedule for developing a product-service system concept. It details the tools and steps to be used on Thursday from 9:15-18:00 which include creating a system map, satisfaction offering diagram, interaction storyboard, and renderings of product and support concepts. The results are to be uploaded to the LENS-WEB platform by 18:00 in a specified order, including a satisfaction offering diagram, system concept synthesis, system map, interaction storyboard, and localization in a campus map.
5.5 Design exercise: strategic analysis and sustainability-oriented ideas gen...Utttam Kumar
The document outlines the design phases and schedule for developing a product-service system concept. It details the tools and steps to be used on Thursday from 9:15-18:00 which include creating a system map, satisfaction offering diagram, interaction storyboard, and renderings of product and support concepts. The results are to be uploaded to the LENS-WEB platform by 18:00 in a specified order, including a satisfaction offering diagram, system concept synthesis, system map, interaction storyboard, and localization in a campus map.
The document outlines the design of a sustainable mobility system project involving students from Politecnico di Milano and local universities in emerging contexts. Students are assigned a mobility theme and context, and are tasked with developing a sustainable system concept. The concept is reviewed by professors from both universities. The goal is to incubate innovative sustainable mobility solutions and foster cross-cultural learning through a collaborative design process. Key aspects of the concepts to be designed include stakeholders, services, and a modular product draft to adapt vehicles for specific transportation needs.
3.2 System Design For Eco Efficiency Vezzoli 07 08 (28.10.08)vezzoli
The document discusses system design for eco-efficiency. It describes an approach that involves designing integrated systems of products and services to fulfill demands while promoting new socio-economic stakeholder interactions and participated design between stakeholders, with the goal of orienting these processes toward more eco-efficient solutions. It lists several criteria for system design for eco-efficiency, including optimizing the system life, reducing transportation and distribution, minimizing resources and waste, conserving and using biocompatible materials, and reducing toxins.
6.1 method for system design for sustainabilityLeNS_slide
The document describes the Method for System Design for Sustainability (MSDS), which provides a framework to support the design of sustainable product-service systems. The MSDS method involves several phases - strategic analysis, exploring opportunities, system concept design, system design and engineering, and communication. It utilizes various tools to analyze sustainability priorities, generate ideas, develop system concepts, and evaluate concepts. The overall goal of the method is to guide designers in developing innovative system interactions and solutions that continuously improve environmental, socio-ethical and economic sustainability.
3.2 system design for eco efficiency vezzoli-10-11 (34)LeNS_slide
The document discusses system design for eco-efficiency, which involves designing interactions between stakeholders to fulfill a customer satisfaction demand in an environmentally sustainable way. It defines system design for eco-efficiency as designing 1) the satisfaction system to meet a demand, 2) interactions between stakeholders, and 3) the system for intrinsic eco-efficiency. Criteria for system design for eco-efficiency include optimizing system life, reducing transportation, resources and waste, and minimizing toxicity. Methods and tools are presented to guide system design towards more sustainable solutions.
1.3 Evolution Of Sustainability Within DesignLeNS_slide
The document discusses the evolution of sustainability within design. It describes four key approaches: 1) Use of low impact materials/energies, 2) Product life cycle design/ecodesign, 3) (Product-service) system design for eco-efficiency, and 4) Design for social equity and cohesion. For each approach, it provides examples of methods and tools developed to help implement them. It also summarizes some applied research projects conducted by Polimi/DIS in system design for sustainability.
6.2 sustainability system design tools vezzoli 10-11 (32)LeNS_slide
The document describes two tools for orienting system design towards sustainability:
1) The Sustainability Design-Orienting (SDO) toolkit is a modular software that helps define priorities, generate ideas, and check sustainability improvements.
2) The Sustainability Interaction Story-Spot visually represents key stakeholder interactions and highlights the sustainability criteria achieved through short descriptions and images. Both tools aim to guide designers in developing more sustainable solutions.
6.1 method for system design for sustainability vezzoli 14-15 (71)LeNS_slide
The document describes the MSDS (Method for System Design for Sustainability) method. It was created to support the design of sustainable product-service system solutions. The MSDS method involves several phases and tools to guide designers in strategically analyzing the context, generating ideas, and developing concepts for sustainable systems. It aims to be modular and adaptable to different design processes and projects. Key tools described include the Sustainability Design-Orienting toolkit to inspire sustainable solutions, and the Sustainability Interaction Story-Spot and System Map to visualize system interactions and configurations.
6.1 method for system design for sustainability vezzoli 14-15 (71)Emanuela Emy
The document describes the MSDS (Method for System Design for Sustainability) method. It was created to support the design of sustainable product-service system solutions. The MSDS method involves several phases and tools to guide designers in strategically analyzing the context, generating ideas, and developing concepts for sustainable systems. It aims to be modular and adaptable to different design processes and projects. Key tools described include the Sustainability Design-Orienting toolkit to inspire sustainable solutions, and the Sustainability Interaction Story-Spot to visualize system interactions and impacts.
5.1 Sustainability Oriented System Design Methods And Tools Vezzoli 07 08 (28...vezzoli
The document describes methods and tools for system design for sustainability, including the MEPSS methodology and its phases. It introduces the Sustainability Design-Orienting (SDO) toolkit that can be used to orient system design towards sustainable solutions. The SDO toolkit includes criteria, guidelines, and tools to generate ideas, check improvements, and visualize sustainability impacts at different stages of the design process. It also describes the interaction story-spot tool that visually depicts key interactions of a system idea in relation to sustainability goals.
The document outlines the schedule and tasks for a design exercise focused on developing a system concept for sustainability, including analyzing the context, generating ideas, developing the concept, and presenting the concept in a plenary presentation on July 17th. Students will work on conceptualizing and visualizing the system concept's sustainability qualities, then refine and formalize the concept in a presentation format to be handed over and presented. The presentation will cover satisfaction diagrams, concept descriptions, interaction boards, system maps, and product renderings developed as part of the concept.
Similar to 6.3 (other) system design tools vezzoli 10-11 (65) (20)
Flat packed and easy assembled stool - King & Webbon.pptxLeNS_slide
The flat-packed lab stool can be assembled in less than 15 minutes using an allen wrench. It is made from sustainably sourced beech ply in the UK. The stool is stackable, making it suitable for small spaces. The lab stool collaboration between King & Webbon design studio and the Science Museum aims to create furniture designed to last rather than be disposable through its flat-pack design that can be assembled on-site to reduce transportation energy consumption and packaging waste.
The document discusses sustainable energy access for all as essential for sustainable development. It outlines that over 1 billion people lack electricity access and over 2 billion rely on inefficient and polluting biomass for cooking. Distributed renewable energy (DRE) is presented as a promising model to achieve universal access through small-scale, decentralized energy generation near the point of use, often from solar, wind and other renewable sources. DRE can help transition away from unsustainable centralized fossil fuel systems towards greater environmental, social and economic sustainability.
This document outlines a design exercise for students to develop sustainable product-service systems (S.PSS) that provide distributed renewable energy (DRE) for households in African communities. Students will design systems for eating or clothing care in villages/townships in Botswana, Uganda, South Africa, or Kenya. The exercise involves analyzing the context, generating ideas, and developing system concepts. Students will consider environmental, socio-ethical, and economic sustainability dimensions. They will create system maps, interaction tables, and storyboards to illustrate their concepts. The goal is to design DRE systems that provide essential household functions through sustainable energy access for communities.
6.4 sustainable for all design orienting toolsLeNS_slide
This document provides an overview of tools and methods for designing sustainable distributed renewable energy (DRE) systems oriented towards achieving sustainable energy for all. It describes a sustainable design orienting scenario (SDOS) approach for generating ideas for product-service systems applied to DRE in low and middle income contexts. The SDOS uses scenario narratives, videos and diagrams to inspire idea generation. It also outlines several forms and online databases for evaluating energy needs, production potential, and dimensions for a proposed DRE system concept. The tools are intended to guide the design process from idea generation through concept development and evaluation.
The document describes three tools for system design for sustainability: the stakeholder system map, interaction table, and satisfaction offering diagram. The stakeholder system map visually maps out the stakeholders in a system and their interactions through flows of materials, information, finances, and labor. The interaction table and storyboard tools are used to design and visualize the functioning of a system over time through narratives and images of interactions between stakeholders. The satisfaction offering diagram maps out what satisfactions or benefits a system offers to different stakeholder groups.
6.2 sustainability system design tools vezzoli 14-15 (34)LeNS_slide
This document describes two sustainability-orienting system design tools: the Sustainability Design-Orienting (SDO) toolkit and the Sustainability Interaction Story-Spot. The SDO toolkit is a modular software that guides designers in evaluating existing systems, identifying best practices, generating sustainable ideas, and checking concepts against sustainability criteria. The Sustainability Interaction Story-Spot visually depicts key stakeholder interactions that improve sustainability criteria through images and short texts. Both tools integrate into the design process to increase orientation of concepts toward sustainable outcomes.
0.0 introduzione corso metodi dxs vezzoli 14-15 (16)LeNS_slide
This document outlines the structure and content of a course on System Design for Sustainability taught by Carlo Vezzoli at Politecnico di Milano. The course includes both theoretical and practical components. The theoretical section will cover introductions to sustainable product systems and design methods. The practical section involves a group project to develop concepts for sustainable product-service systems for food services on campus. Recommended readings and online learning resources are also listed. The document provides background on the Learning Network on Sustainability (LeNS) project, which developed an open-source online platform for sharing materials on sustainable design.
This document provides guidelines for designing sustainable product-service systems applied to distributed renewable energy systems. It outlines various configurations for distributed renewable energy offers, such as stand-alone home systems, mini-grids connecting multiple systems, and systems connected to main grids. It also recommends complementing energy offers with lifecycle services like design, installation, maintenance, repair, upgrading, and end-of-life treatment. Further guidelines include offering ownerless energy systems with full services, using systems as enabling platforms, adding energy-using products, and delinking payment from pure energy consumption. The overall aim is to optimize distributed renewable energy configurations and make the systems more sustainable and affordable.
This document provides guidelines for designing sustainable product-service systems applied to distributed renewable energy systems. It suggests offering standalone and mini-grid DRE systems, complementing the DRE offer with lifecycle services, offering ownerless DRE systems with full services, and delinking payment from pure watt consumption to make costs more affordable. The guidelines are presented over six pages and cover optimizing DRE system configuration, complementing the offer with design, installation, and maintenance services, and adding energy using products to the offer.
This document provides guidelines for designing sustainable product-service systems (S.PSS) applied to distributed renewable energy (DRE) systems. It suggests 6 areas to focus on: 1) Optimizing DRE system configurations, 2) Complementing DRE offers with lifecycle services, 3) Offering ownerless DRE systems with full services, 4) Offering ownerless DRE systems as an enabling platform, 5) Adding ownerless energy-using products to DRE offers, and 6) Delinking payments from pure watt consumption to make costs more affordable. The overall aim is to provide sustainable energy access through optimized DRE system designs coupled with comprehensive lifecycle services.
5.1 sustainable energy for all vezzoli 14-15_(34)LeNS_slide
The document discusses the importance of sustainable energy for all as a key enabler of sustainable development. It argues that distributed renewable energy (DRE) systems offer a promising model for achieving sustainable energy for all through a paradigm shift away from centralized non-renewable energy systems. DRE involves small-scale energy generation from renewable resources like solar and wind located near the point of use. Sustainable product-service systems (S.PSS) are also presented as a business model that could facilitate widespread adoption of DRE by reducing costs and giving access to necessary goods and services.
5.2 system design for sustainable energy for all vezzoli 14_15_(29)LeNS_slide
This document proposes a sustainability design-orienting scenario (SDOS) for applying a product-service system (PSS) to distributed renewable energy (DRE) systems. It presents 4 visions for how a PSS approach could provide sustainable energy access for all. The visions include: 1) DRE systems and daily life energy products provided to individuals/communities in exchange for periodic payments, 2) DRE systems provided to power small businesses' equipment in exchange for periodic payments, 3) DRE systems and packages of energy products provided to individuals/communities where payment is based on product usage, and 4) Packages of DRE systems and startup equipment provided to entrepreneurs to launch businesses where payment is based on periodic fees. The goal
4.2 system design for social equity vezzoli 14-15 (23) (n)LeNS_slide
This document discusses system design for social equity and cohesion. It defines system design as designing interactions between stakeholders in a system to fulfill customer demands in a sustainable way. It presents criteria for social equity and cohesion in system design, such as improving employment, enabling sustainable consumption, and empowering local resources. Methods and tools are needed to guide system design according to these criteria. The document also introduces an emerging methodology for system design for sustainability and a toolkit for sustainability design orientation.
4.1 towards social equity and cohesion vezzoli 14-15 (22)LeNS_slide
This document discusses approaches to promoting social equity and cohesion through system design. It proposes that product-service systems (PSS) and distributed economies (DE) are promising models, and that applying sustainable PSS approaches to DE could facilitate locally-based, small-scale sustainable opportunities for all contexts, including low-income areas. A key hypothesis presented is that a sustainable PSS approach applied to DE could help diffuse various forms of DE in low and middle-income contexts by fostering locally-based, networked small enterprises and initiatives that democratize access to sustainable resources.
1.2 evolution of sustainability in design vezzoli 14-15 (41) (n)LeNS_slide
This document discusses the evolution of sustainability within design. It describes how design's role has expanded over time from intervening on products and materials to intervening on entire systems and consumption patterns. Specifically, it outlines how design has progressed from focusing on low-impact materials in the 1970s to life cycle design and ecodesign in the 1990s to system design for eco-efficiency starting in the 2000s. The document also notes that while design's potential role in sustainability has increased over time, many within the design community still lack knowledge and skills related to design for sustainability.
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This document discusses system design for eco-efficiency. It defines system design for eco-efficiency as designing innovative interactions between stakeholders in a satisfaction system where economic interests drive environmental benefits. It presents approaches for designing the satisfaction system and stakeholders' interactions. It outlines criteria for system design for eco-efficiency, including optimizing the system life, reducing transportation, minimizing resources and waste, and reducing toxicity. Methods and tools are presented for applying these criteria to guide system design towards more sustainable solutions.
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6.3 (other) system design tools vezzoli 10-11 (65)
1. carlo vezzoli politecnico di milano . INDACO dpt. . DIS . School of design . Italy Learning Network on Sustainability course System Design for Sustainability Subject 6 . Methods and tools for SDS learning resource 6.3 (Other) system design tools
2. CONTENTS . DESCPRIPTION OF SDS TOOLS . (STAKEHOLDER) SYSTEM MAP . INTERACTION TABLE and STORY-BOARD . SATISFACTION OFFERING DIAGRAM . SDS TOOLS COMMON CHARACTERISTICS
3. DESCPRIPTION OF SDS TOOLS . aims and description . how to use . integration in the MSDS design process . software and/or other supports
4. The tool was developed by Francois Jégou within the EU funded research: HiCS - Highly Customerised Solutions, Solution-oriented design, production and delivery systems (European Research, GROWTH Programme / European 5th Framework). (STAKEHOLDER) SYSTEM MAP
5. (STAKEHOLDER) SYSTEM MAP AIM: to design (co-design) and visualise the configuration of the system, describing the involved stakeholders and their interactions
6. (STAKEHOLDER) SYSTEM MAP WHAT IT CONSISTS OF: a graphical representation containing: > stakeholders involved > flows/interactions: physical, financial informational, and labor performance
7. (STAKEHOLDER) SYSTEM MAP WHAT IT CONSISTS OF: > a codified representation: because it's a "technical drawing“ allowing to represent alternative system in a reproducible and comparable way
8. (STAKEHOLDER) SYSTEM MAP WHAT IT CONSISTS OF: > a progressive representation: because is a "formalisation-in-progress" since is giving a more and more accurate picture of the configuration along its development
10. Platform boundary System boundary secondary stakeholders main stakeholders (STAKEHOLDER) SYSTEM MAP
11. Catering provider Health adviser Offices E-meal Food providers E-meal appliance producer Structure icon Characterization icon Slogan (STAKEHOLDER) SYSTEM MAP
12. structure characterisation + slogan Bio food provider + icon Bio food provider = Logistic provider Local delivery shop Logistic provider + + + + = = BASIC RULE TO REPRESENT EACH STAKEHOLDER (STAKEHOLDER) SYSTEM MAP Local delivery shop
13. Catering provider Health adviser Offices E-meal Food providers E-meal appliance producer MAIN STAKEHOLDER Big icon SECONDARY STAKEHOLDER Small icon (STAKEHOLDER) SYSTEM MAP
14. Food providers Health adviser E-meal diet advice service with meal ordering employees order the day before by internet… companies contract service for their employees… meals are delivered in companies… employees pick-up their meal when they want… vegetable, dairy and bread products ARROW + DESCRIPTION (STAKEHOLDER) SYSTEM MAP Catering provider E-meal appliance producer Offices
15. Food providers Health adviser E-meal diet advice service with meal ordering employees order the day before by internet… companies contract service for their employees… meals are delivered in companies… employees pick-up their meal when they want… vegetable, dairy and bread products MATERIAL FLOWS (STAKEHOLDER) SYSTEM MAP Catering provider E-meal appliance producer Offices
16. Food providers Health adviser E-meal diet advice service with meal ordering employees order the day before by internet… companies contract service for their employees… meals are delivered in companies… employees pick-up their meal when they want… vegetable, dairy and bread products INFORMATION FLOWS (STAKEHOLDER) SYSTEM MAP Catering provider E-meal appliance producer Offices
17. Food providers Health adviser E-meal diet advice service with meal ordering employees order the day before by internet… companies contract service for their employees… meals are delivered in companies… employees pick-up their meal when they want… vegetable, dairy and bread products FINANCIAL FLOWS (STAKEHOLDER) SYSTEM MAP Catering provider E-meal appliance producer Offices
18. E-meal diet advice service with meal ordering employees order the day before by internet… companies contract service for their employees… meals are delivered in companies… employees pick-up their meal when they want… vegetable, dairy and bread products (STAKEHOLDER) SYSTEM MAP Catering provider Food providers Health adviser E-meal appliance producer Offices DARK GREY CORE FLOWS LIGHT GREY SECONDARY FLOWS
19. start E-meal diet advice service with meal ordering 2. employees order the day before by internet… 1. companies contract service for their employees… 3. meals are delivered in companies… 4. employees pick-up their meal when they want… vegetable, dairy and bread products READING ORDER (STAKEHOLDER) SYSTEM MAP Catering provider Food providers Health adviser E-meal appliance producer Offices
20. READING ORDER start (STAKEHOLDER) SYSTEM MAP Catering provider Food providers Health adviser E-meal appliance producer Offices E-meal diet advice service with meal ordering 2. employees order the day before by internet… 1. companies contract service for their employees… 3. meals are delivered in companies… 4. employees pick-up their meal when they want… vegetable, dairy and bread products
21. integration in the design process increasing the detail level (STAKEHOLDER) SYSTEM MAP STRATEGIC ANALYSIS EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING describe the system configuration of the reference structure and of best practices formalisation of the tentative system configuration ideas development of the system configuration concept further development (in details) of the system configuration
22. SOFTWARE AND OTHER SUPPORTS: . standardized icons built using presentation software (e.g. open office, powerpoint ). . a basic template facilitate the construction of the System Map in a systematic and uniform way. > www.lens.polimi.it / tool a powerpoint file could be downloaded, in which you can find… (STAKEHOLDER) SYSTEM MAP
23. industrial company services company local shop collective house public istitution local association individual house school mobile shop PUBLIC ISTITUTIONS OR ASSOCIATIONS HOMES COMPANIES AND STORES … structure icons… (STAKEHOLDER) SYSTEM MAP
24. … characterization icons (activities)… EATING TRANSPORTING COMMUNICATING WORKING IN OFFICE (STAKEHOLDER) SYSTEM MAP
26. … flows Material flow Information flow Financial flow core PSS performance one way flow exchange 1. vegetables timing and description of the flow Labour performance alternative PSS performance, implementation or back-office flows (STAKEHOLDER) SYSTEM MAP
27. SOFTWARE AND OTHER SUPPORTS: COPY AND PASTE THE ELEMENTS FROM THE LIBRARIES TO THE LAYOUT (STAKEHOLDER) SYSTEM MAP
28. SOFTWARE AND OTHER SUPPORTS: on www.lens.polimi.it “ Tools” section (STAKEHOLDER) SYSTEM MAP OPEN SOURCE LIBRARIES
29. INTERACTION TABLE and STORY-BOARD INTERACTION TABLE STORY BOARD The tools were developed by DIS unit of research from the work did by Daniela Sangiorgi within the EU funded research: MEPSS European research project (Methodology for Product Service Systems) Growth Programme / European 5th Framework.
30. AIM: to design (co-design) and visualise the functioning of the system as a multiple-row (one for each stakeholder) narrative (story) of the front-desk (with the clients) and back-stage interactions (between other stakeholders) INTERACTION TABLE
31. WHAT IT CONSISTS OF: it is a graphical representation containing: > the sequence of images , representing (in time) the various interactions of the different stakeholders > and short texts , describing the specific role played by each stakeholders in each single interaction INTERACTION TABLE
34. INTERACTION TABLE IMAGES SHOULD CONTAINE ONLY NECESSARY ELEMENTS… ...A BACKGROUND REPRESENTING THE CONTEXT OF EACH ACTION … AND THE STAKEHOLDERS (HIGHLIGHTED FROM THE BACKGROUND)
38. integration in the design process increasing the detail level INTERACTION TABLE STRATEGIC ANALYSIS EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING analyze the existing system and/or the best practices describing various interactions further development (in details) of all the system interactions visualization of the interactions of the developed concept
39. SOFTWARE AND OTHER SUPPORTS: Based on spreadsheet applications (e.g. open-office, excel ) [model downloadable www.lens.polimi.it / tools] INTERACTION TABLE
40. combine the images to realize the visualization: CONTEXT IMAGES PEOPLE IMAGES INTERACTION TABLE SOFTWARE AND OTHER SUPPORTS: Open source library of images www.lens.polimi.it
41. if the aim is to show (to the client or to the other actors involved in the project) the functioning of the system… INTERACTION TABLE … INTERACTION TABLE is not the most effective tool
42. STORY BOARD if the aim is to show (to the client or to the other actors involved in the project) the functioning of the system… … it is suggested to use the STORY BOARD
43. STORY BOARD AIM: to visualise the functioning of the system as single row (all stakeholders in one) narrative (story) of the front-desk (with the clients) and back-stage interactions (between other stakeholders)
44. IN WHAT IT CONSISTS OF: abstract of the interaction table showing, in one single linear sequence, the functioning of the system (back stage and front office interactions) STORY BOARD
45. PRESENTATION SUPPORT (1) PAPER visualisation of the interactions on one or more pages STORY BOARD
46. STORY BOARD ABSTRACT FROM INTERACTION TABLE: ONLY THE INTERACTIONS FUNCTIONAL TO THE NARRATIVE SINGLE LINEAR SEQUENCE
49. STORY BOARD 6 The Reconstructed team manages all the data using a database. Moreover it works as a service hub for people who want to work as drivers. NAVIGATOR INTERACTION IMAGE TEXT INTERACTION NUMBER
50. STORY BOARD 6 The Reconstructed team manages all the data using a database. Moreover it works as a service hub for people who want to work as drivers. INDICATION OF THE DIFFERENT SYSTEM PHASES INDICATIONOF THE DIFFERENT ACTORS LINK BETWEEN THE VISUALISED INTERACTION AND THE WHOLE SEQUENCE
51. STORY BOARD 6 The Reconstructed team manages all the data using a database. Moreover it works as a service hub for people who want to work as drivers. COLOUR OF THE FRAME CHARACTERISES THE ACTOR
52. integration in the design process increasing the detail level INTERACTION TABLE (STORY-BOARD) STRATEGIC ANALYSIS EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING present the sequence of the system interactions (on concept level) present the sequence of the system interactions (on a executive level)
53. SOFTWARE: STORY BOARD PRESENTATION ON PAPER SUPPORT graphic softwares (for ex. Adobe Photoshop, Illustrator,…)
54. SOFTWARE: STORY BOARD graphic softwares (for ex. Adobe Photoshop, Illustrator, ecc.) for the images elaboration slideshow software (Microsoft Powerpoint or Open Office) for the vialusation PRESENTATION ON VIDEO
55. SATISFACTION OFFERING DIAGRAM WEEKLY/DAILY PREORDER FOOD DELIVERY The tools was developed by Francois Jégou within the EU funded research: MEPSS European research project (Methodology for Product Service Systems) Growth Programme / European 5th Framework. INGREDIENTS SELECTION
56. AIM: describe in one shot the main satisfaction offered to the user/customer, and how this is delivered SATISFACTION OFFERING DIAGRAM
57. IN WHAT IT CONSISTS OF: is a graphical representation that containing: > the visualisation of the core satisfaction provided by the system > the visualisation of the sub-offers (through which the satisfaction is delivered) > the description of how the sub-offers will be delivered SATISFACTION OFFERING DIAGRAM
59. WEEKLY/DAILY PREORDER FOOD DELIVERY SATISFACTION OFFERING DIAGRAM INGREDIENTS SELECTION Cooperatives of local producers provide the campus Biologic food Students select food basing on seasonal availability On line preorder based on the disponibility Using internet or campus’ information points Where you want inside the campus Using rickshaws SUB-OFFER HOW THE SUB-OFFER ARE DELIVERED
60. integration in the design process increasing the detail level SATISFACTION OFFERING DIAGRAM STRATEGIC ANALYSIS EXPLORING OPPORTUNITIES SYSTEM CONCEPT DESIGN SYSTEM DESIGN (AND ENGIN.) COMMUNICATION ANALYSIS OF THE PROJECT PROMOTERS ANALYSIS OF THE REFERENCE CONTEXT ANALYSIS OF BEST PRACTICES ANALYSIS OF THE REFERENCE STRUCTURE DEFINITION OF SUSTAINABILITY DESIGN PRIORITIES IDEAS GENERATION ORIENTED TO SUSTAINABILITY DEVELEPMENT OF THE SUSTAINABILITY DESIGN ORIENTING SCENARIO - VISIONS/CLUSTERS/IDEAS VISIONS, CLUSTERS AND IDEAS SELECTION SYSTEM CONCEPT DEVELOPMENT ENV., SOC. & ECON. CHECK SYSTEM DEVELOPMENT (EXECUTIVE LEVEL) ENV., SOC. & ECON. CHECK DOCUMENTS EDITING describe the offer delivered by the system detailing the sub-satisfactions describe the different emerged ideas, indicating the main satisfaction delivered by the system describe the offer delivered by the system detailing all the sub-satisfactions
63. DESIGN (CO-DESIGN) AND VISUALISATIO TOOLS System map Satisfaction offering diagram Solution element Interaction table Story-board Stakeholders motivation matrix VISUALISATION DESIGN CO-DESIGN
64. Tools that evolve in details during the development of the project System map Satisfaction offering diagram Solution element Interaction table PROGRESSIVE TOOLS Story-board Stakeholder motivation matrix PROJECT DEVELOPMENT + LEVEL OF DETAIL _