Scenarios for Educational and Game Activities using Internet of Things Data

Raising awareness among young people and changing their behavior and habits concerning energy usage and the environment is key to achieving a sustainable planet. The goal to address the global climate problem requires informing the population on their roles in mitigation actions and adaptation of sustainable behaviors. Addressing climate change and achieve ambitious energy and climate targets requires a change in citizen behavior and consumption practices. IoT sensing and related scenario and practices, which address school children via discovery, gamification, and educational activities, are examined in this paper. Use of seawater sensors in STEM education, that has not previously been addressed, is included in these educational scenaria

The District Energy-Efficient Retrofitting of Torrelago (Laguna de Duero – Spain)

The urban growth is estimated to reach up the 66 % by 2050 and consequently the need of resources within the cities will increase significantly. This, combined with the 40 % of energy consumption and 36 % of CO2 emissions of the building sector, makes necessary to accelerate the transition towards more sustainable cities. The CITyFiED project contributes to this transition, aiming to develop an innovative and holistic methodological approach for energy-efficient district renovation and deliver three large scale demonstration cases in the cities of Lund (Sweden), Laguna de Duero (Spain) and Soma (Turkey). CITyFiED methodology consists of several phases that ease the decision-making tasks towards the district renovation, considering the energy efficiency as the main pillar and local authorities as clients. For the case of Torrelago district (Spain) the intervention consists of a set of energy conservative measures including the facąde retrofitting of 143.025 m2 of living space in 31 twelve-storey buildings; the renovation of the district heating network with a new biomass thermal plant; the integration of renewable energy sources, including a micro-cogeneration system, and the installation of individual smart meters. After the renovation action, one-year monitoring campaign is ongoing. The CITyFiED monitoring platform will collect information from the energy systems and deliver environmental, technical, economic and social key performance indicators by March 2019. At the end of the project the achievement of the predefined goals will be verified: Up to 36 % of energy saving and 3,429 tons-CO2/yr emissions saving covering the 59,4 % of the energy consumption with renewable sources.The research and results presented in this paper evolve from activities related to the CITyFiED project, which has received funding from the European Commission under the Grant Agreement no. 609129. This article is the result of cooperative research work of many experts from various countries and we would like to gratefully acknowledge the rest of the CITyFiED partners

National Biodiversity Strategies and Action Plans: Natural Catalysts for Accelerating Action on Sustainable Development Goals

In 2010, the Conference of Parties of the Convention on Biological Diversity (CBD) agreed to an ambitious set of 20 targets, called the Aichi Biodiversity Targets, as part of their commitment to the CBD Strategic Plan. One of the Targets (Target 17) called for each country to revise its National Biodiversity Strategies and Action Plan (NBSAP) in accordance with the Aichi Biodiversity Targets. From 2010 to November 2016, virtually all countries have revised, or are currently completing the revision of, their NBSAP. As of November 2016, 123 countries (76 of them eligible for official development assistance) have submitted post-2010 NBSAPs. At the same time, the world agreed to an ambitious set of 17 Goals and 169 Targets in 2015, called the Sustainable Development Goals (SDGs). The absence of a widely accepted taxonomy for describing NBSAP actions makes any systematic and cross-cutting analysis of NBSAPs difficult. Moreover, the collective contribution of specific NBSAP actions to SDGs has not yet been studied. The purpose of this report is to systematically understand the breadth and depth of actions proposed across all NBSAPs, to propose a common framework for analysis, and to understand the relationship between NBSAPs and the SDGsThe data in this report comes from more than 6000 actions included in NBSAPs of 60 countries. These NBSAPs have all been submitted to the Secretariat of the CBD after 2010, and all are from countries eligible to received funding from the Global Environmental Facility. The researchers tagged each of the actions in this analysis not only by the thematic categories and generic actions of this taxonomy, but also by the associated primary and secondary SDGs and their associated targets (as well as by Aichi Biodiversity Targets). In doing so, the collective impact of the contribution of NBSAPs toward fulfilling the SDGs is beginning to emerge. The data from this analysis are far richer and more complex than this interim report can convey. However, it is clear from this preliminary analysis that the impact of NBSAP actions extends far beyond Goal 14 (Life Below Water) and Goal 15 (Life on Land). The NBSAP examples of actions provided under each of the categories illustrate how a single action can contribute to multiple goals. The actions included across all NBSAPs would, if fully implemented, catalyze progress in national food security, water security, livelihoods, economic growth, disaster risk reduction, health, gender and climate resilience, among other goals. Furthermore, because NBSAPs are adopted as policy instruments, they provide a ready pathway for fast implementation of national sustainable development goals.Investing in biodiversity and ecosystems through NBSAP actions also ensures that no one is left behind in the implementation of the SDGs. Nature provides a safety net to billions of people around the world: 1.6 billion people depend on forests for jobs, livelihoods, food and fuel; one out of eight people depend on fisheries for their livelihoods; and more than 4 billion people depend on medicines derived from forests for their health.  Investing in nature helps ensure that the most vulnerable people in society, especially the more than 800 million people living in poverty, have a durable safety net.The recommendations included at the end of this report highlight the potential need for targeted support to countries to implement key thematic areas. The authors hope that this preliminary analysis will enable governments, and the organizations that support them, to focus their efforts on supporting those thematic areas that will have the most impact in accelerating progress in implementing NBSAP actions. They also hope this report will encourage donor organizations to consider supporting the implementation of NBSAP actions that have direct SDG outcomes

User-centric Privacy Engineering for the Internet of Things

User privacy concerns are widely regarded as a key obstacle to the success of modern smart cyber-physical systems. In this paper, we analyse, through an example, some of the requirements that future data collection architectures of these systems should implement to provide effective privacy protection for users. Then, we give an example of how these requirements can be implemented in a smart home scenario. Our example architecture allows the user to balance the privacy risks with the potential benefits and take a practical decision determining the extent of the sharing. Based on this example architecture, we identify a number of challenges that must be addressed by future data processing systems in order to achieve effective privacy management for smart cyber-physical systems.Comment: 12 Page

Transition UGent: a bottom-up initiative towards a more sustainable university

The vibrant think-tank ‘Transition UGent’ engaged over 250 academics, students and people from the university management in suggesting objectives and actions for the Sustainability Policy of Ghent University (Belgium). Founded in 2012, this bottom-up initiative succeeded to place sustainability high on the policy agenda of our university. Through discussions within 9 working groups and using the transition management method, Transition UGent developed system analyses, sustainability visions and transition paths on 9 fields of Ghent University: mobility, energy, food, waste, nature and green, water, art, education and research. At the moment, many visions and ideas find their way into concrete actions and policies. In our presentation we focused on the broad participative process, on the most remarkable structural results (e.g. a formal and ambitious Sustainability Vision and a student-led Sustainability Office) and on recent actions and experiments (e.g. a sustainability assessment on food supply in student restaurants, artistic COP21 activities, ambitious mobility plans, food leftovers projects, an education network on sustainability controversies, a transdisciplinary platform on Sustainable Cities). We concluded with some recommendations and reflections on this transition approach, on the important role of ‘policy entrepreneurs’ and student involvement, on lock-ins and bottlenecks, and on convincing skeptical leaders

Chatham House Report: Changing Climate, Changing Diets: Pathways to Lower Meat Consumption

No abstract available

Interacting with Smart Environments: Users, Interfaces, and Devices

A Smart Environment is an environment enriched with disappearing devices, acting together to form an “intelligent entity”. In such environments, the computing power pervades the space where the user lives, so it becomes particularly important to investigate the user’s perspective in interacting with her surrounding. Interaction, in fact, occurs when a human performs some kind of activity using any computing technology: in this case, the computing technology has an intelligence of its own and can potentially be everywhere. There is no well-defined interaction situation or context, and interaction can happen casually or accidentally. The objective of this dissertation is to improve the interaction between such complex and different entities: the human and the Smart Environment. To reach this goal, this thesis presents four different and innovative approaches to address some of the identified key challenges. Such approaches, then, are validated with four corresponding software solutions, integrated with a Smart Environment, that I have developed and tested with end-users. Taken together, the proposed solutions enable a better interaction between diverse users and their intelligent environments, provide a solid set of requirements, and can serve as a baseline for further investigation on this emerging topic