Sustainability assessment within the residential building sector: a practical life cycle method applied in a developed and a developing country

More than ever, the residential building sector is concerned with improving the social, economicand environmental indicators of sustainability. In order to overcome the increasing concern of today'sresource depletion, environmental considerations and to address sustainability indicators, a practicallife cycle method has been proposed to decision making integrating environmental and socioeconomicalaspects to analyse the impact of sustainability within the residential building sector usingtwo practical life cycle methods. One method is the Material and Energy Analysis (MEA) which issuggested as an appropriate tool to provide a systematic picture of the direct and physical flows of theuse of natural resources and the other is the environmental management tool of Life CycleAssessment (LCA) as a complement to evaluate environmental impacts throughout the life cycle of thesystem.Furthermore, the method provides sustainability information that facility an adequate decisionmaking towards sustainable development at macro and micro levels. Sustainability assessment atmacro level is determined by exogenous variables that can influence the development of a country.Meanwhile sustainable at the micro level is made within the limits of the whole building life cycle,starting from the construction, use (operation and maintenance) and finishing with the end-of-lifephase. To illustrate it, a case study has been carried out based on the application to two buildings, onelocated in Barcelona, Spain and one situated in Pamplona, Colombia. Then, the main objective of thisthesis is to propose a practical life cycle method including environmental and socio-economicalaspects to evaluate indicators that explicitly measure the residential building sector's impacts. Thisthesis has also provided initiatives for residential dwellings to reduce environmental impacts and assiststakeholders in improving customer patterns during the dwelling life cycle.The findings of this thesis state that the appropriate combination of building materials,improvement in behaviours and patterns of cultural consumption, and the application of governmentcodes would enhance decision-making in the residential building sector towards sustainability. Thedifference in consumption in Colombia and Spanish dwellings is not only due to the variation in resultsfor bio-climatic differences but also because of the consumption habits in each country. Theimportance of consumption habits of citizens and the need to decouple socio-economic developmentfrom energy consumption are sought for achieving sustainability from a life cycle perspective. There isa crucial necessity to provide satisfaction to basic needs and comfort requirements of population withreasonable and sustainable energy consumption.Therefore, there is no doubt that applying environmental managements tools as Life CycleAssessment (LCA) and Material and Energy Analysis (MEA) to the full building life cycle can be veryimportant for reducing environmental loads and thereby improving sustainability indicators. Then, anyimprovement in building sustainability is oriented generally to building materials, energy use and wastemanagement in all phases of the building life cycle, having always in mind that building has to bexxviiiaccessible from an economical and social part of view. The type of standard dwelling variessubstantially depending on the geographic location where it is built. Climate, technological, cultural,socio-economical differences clearly define the standard of a building in any context and in any region.This leads to important differences in the LCA results and it means that any extrapolation of existingEuropean LCA data to the case of a developing country would imply important errors. However, thefunction is always the same, to provide protection and housing for its habitants.Hoy en día, el sector residencial busca mejorar los indicadores de sostenibilidad en los aspectossociales, económicos y ambientales. Con el fin de considerar la creciente preocupación delagotamiento de los recursos naturales y buscar reducir las emisiones adversa al medio ambiente, unmétodo practico basado en el ciclo de vida se ha propuesto para la evaluación socio-económica yevaluación del impacto ambiental en sector residencial utilizando dos métodos. El primero es elAnálisis de Materiales y de Energía (AME) que proporciona una visión sistemática de los flujosdirectos e indirectos de la utilización de los recursos naturales y el segundo método es el Análisis delCiclo de Vida (ACV) como complemento para evaluar los impactos ambientales en todo el ciclo devida del sistema.Adicionalmente, el método proporciona información de sostenibilidad permitiendo la adecuadatoma de decisiones hacia el desarrollo sostenible en los niveles macro y micro. Evaluación de laSostenibilidad en el nivel macro está determinado por variables exógenas que influyen en eldesarrollo de un país. Mientras tanto, sostenibilidad en el nivel micro hace referencia dentro de loslímites de todo el ciclo de vida de una vivienda, comenzando por la fase de construcción, uso(operación y mantenimiento) y terminando con la fase final. Para ilustrarlo, un caso de estudio ha sidollevado a cabo en la aplicación de dos edificios, uno situado en Barcelona, España y otro situado enPamplona, Colombia. Por consiguiente, el objetivo principal de esta tesis es proponer un método quetenga en cuenta los aspectos medio-ambientales y socio-económicos que tiendan a mejorar lasostenibilidad y que explícitamente midan los impactos del sector de residencial. Esta tesis también propone iniciativas de mejora en las viviendas residenciales que conlleven a reducir los impactos ambientales y asistir a los agentes involucrados del sector.Las conclusiones de esta tesis soportan que la combinación adecuada de materiales deconstrucción, el buen comportamiento en los patrones de consumo, y la aplicación de códigos y leyes mejoraran los aspectos sostenibles en el sector de la construcción. La diferencia en el consumo en las viviendas de Colombia y en las Españolas no sólo se debe a la variación de las diferencias bioclimáticas,sino también por los hábitos de consumo en cada país. Se puede observar la importancia de los hábitos de consumo de los ciudadanos y la necesidad de disociar el desarrollo socioeconómico del consumo de energía. Existe una necesidad fundamental de dar satisfacción a las necesidades básicas y requerimientos de confort de la población con un consumo energético razonable y sostenible.Por lo tanto, no hay duda de que la aplicación de herramientas medioambientales como el análisis del ciclo de vida (ACV) y análisis de materiales y energía (AME) es muy importante para minimizar el impacto ambiental y buscar mejorar los indicadores de sostenibilidad. Queda implícito entonces que cualquier mejora en la sostenibilidad está orientado generalmente a la selección apropiada de materiales de construcción, el uso eficiente de energía y la correcta gestión de residuos en todas las fases del ciclo de vida del edificio, teniendo siempre en cuenta que el edificio tiene que ser accesible desde una parte económica y social. El tipo de vivienda estándar varía sustancialmente dependiendo de la ubicación geográfica donde se construya. Aspectos como el clima, la tecnología, la cultura y las diferencias socio-económicas definen claramente el nivel de un edificio en cualquier contexto y en cualquier región. Esto da lugar a importantes diferencias en los resultados del ACV y significa que cualquier extrapolación de datos europeos existentes del ACV para el caso de un paísen desarrollo implicaría errores importantes. Sin embargo, la función es siempre la misma,proporcionar protección y vivienda para sus habitante

ENERGY CONSUMPTION OF MOBILE PHONES

Battery consumption in mobile applications development is a very important aspect and has to be considered by all the developers in their applications. This study will present an analysis of different relevant concepts and parameters that may have an impact on energy consumption of Windows Phone applications. This operating system was chosen because limited research related thereto has been conducted, even though there are related studies for Android and iOS operating systems. Furthermore, another reason is the increasing number of Windows Phone users. The objective of this research is to categorise the energy consumption parameters (e.g. use of one thread or several threads for the same output). The result for each group of experiments will be analysed and a rule will be derived. The set of derived rules will serve as a guide for developers who intend to develop energy efficient Windows Phone applications. For each experiment, one application is created for each concept and the results are presented in two ways; a table and a chart. The table presents the duration of the experiment, the battery consumed in the experiment, the expected battery lifetime, and the energy consumption, while the charts display the energy distribution based on the main threads: UI thread, application thread, and network thread

A WEB-BASED ENVIRONMENTAL TOOLKIT TO SUPPORT SMES IN THE IMPLEMENTATION OF AN ENVIRONMENTAL MANAGEMENT SYSTEM

With small and medium sized-enterprises (SMEs) taking up the majority of the global businesses, it is important they act in an environmentally responsible manner. Environmental management systems (EMS) help companies evaluate and improve their environmental impact but they often require human, financial, and temporary resources that not all SMEs can afford. This research encompasses interviews with representatives of two small enterprises in Germany to provide insights into their understanding, and knowledge of an EMS and how they perceive their responsibility towards the environment. Furthermore, it presents a toolkit created especially for small and medium-sized enterprises. It serves as a simplified version of an EMS based on the ISO 14001 standard and is evaluated by target users and appropriate representatives. Some of the findings are: while open to the idea of improving their environmental impact, SMEs do not always feel it is their responsibility to do so; they seem to lack the means to fully implement an EMS. The developed toolkit is considered useful and usable and recommendations are drawn for its future enhancement