Structure-Property Relationships and Charge Transport Modeling of Organic Molecular Materials

From the perspective of a new-generation opto-electronic technology based on organic semiconductors, a major objective is to achieve a deep and detailed knowledge of the structure-property relationships, in order to optimize the electronic, optical, and charge transport properties by tuning the chemical-physical characteristics of the compounds. The purpose of this dissertation is to contribute to such understanding, through suitable theoretical and computational studies. Precisely, the structural, electronic, optical, and charge transport characteristics of several promising organic materials recently synthesized are investigated by means of an integrated approach encompassing quantum-chemical calculations, molecular dynamics and kinetic Monte Carlo simulations. Particular care is addressed to the rationalization of optical and charge transport properties in terms of both intra- and intermolecular features. Moreover, a considerable part of this project involves the development of a home-made set of procedures and parts of software code required to assist the modeling of charge transport properties in the framework of the non-adiabatic hopping mechanism applied to organic crystalline materials. As a first part of my investigations, I mainly discuss the optical, electronic, and structural properties of several core-extended rylene derivatives, which can be regarded to as model compounds for graphene nanoribbons. Two families have been studied, consisting in bay-linked perylene bisimide oligomers and N-annulated rylenes. Beside rylene derivatives, my studies also concerned electronic and spectroscopic properties of tetracene diimides, quinoidal oligothiophenes, and oxygen doped picene. As an example of device application, I studied the structural characteristics governing the efficiency of resistive molecular memories based on a derivative of benzoquinone. Finally, as a second part of my investigations, I concentrate on the charge transport properties of perylene bisimides derivatives. Precisely, a comprehensive study of the structural and thermal effects on the charge transport of several core-twisted chlorinated and fluoro-alkylated perylene bisimide n-type semiconductors is presented.

A threshold hypothesis of institutional change: collective action in the Italian Alps during the 13th - 19th centuries.

This dissertation is about collective action issues in common property resources. Its focus is the “threshold hypothesis,” which posits the existence of a threshold in group size that drives the process of institutional change. This hypothesis is tested using a six-century dataset concerning the management of the commons by hundreds of communities in the Italian Alps. The analysis seeks to determine the group size threshold and the institutional changes that occur when groups cross this threshold. There are five main findings. First, the number of individuals in villages remained stable for six centuries, despite the population in the region tripling in the same period. Second, the longitudinal analysis of face-to-face assemblies and community size led to the empirical identification of a threshold size that triggered the transition from informal to more formal regimes to manage common property resources. Third, when groups increased in size, gradual organizational changes took place: large groups split into independent subgroups or structured interactions into multiple layers while maintaining a single formal organization. Fourth, resource heterogeneity seemed to have had no significant impact on various institutional characteristics. Fifth, social heterogeneity showed statistically significant impacts, especially on institutional complexity, consensus, and the relative importance of governance rules versus resource management rules. Overall, the empirical evidence from this research supports the “threshold hypothesis.” These findings shed light on the rationale of institutional change in common property regimes, and clarify the mechanisms of collective action in traditional societies. Further research may generalize these conclusions to other domains of collective action and to present-day applications.

Sustainable processes using heterogeneous acid catalysts. Some examples of industrial interest.

In recent years the need for the design of more sustainable processes and the development of alternative reaction routes to reduce the environmental impact of the chemical industry has gained vital importance. Main objectives especially regard the use of renewable raw materials, the exploitation of alternative energy sources, the design of inherently safe processes and of integrated reaction/separation technologies (e.g. microreactors and membranes), the process intensification, the reduction of waste and the development of new catalytic pathways. The present PhD thesis reports results derived during a three years research period at the School of Chemical Sciences of Alma Mater Studiorum-University of Bologna, Dept. of Industrial Chemistry and Materials (now Dept. of Industrial Chemistry “Toso Montanari”), under the supervision of Prof. Fabrizio Cavani (Catalytic Processes Development Group). Three research projects in the field of heterogeneous acid catalysis focused on potential industrial applications were carried out. The main project, regarding the conversion of lignocellulosic materials to produce monosaccharides (important intermediates for production of biofuels and bioplatform molecules) was financed and carried out in collaboration with the Italian oil company eni S.p.A. (Istituto eni Donegani-Research Center for non-Conventional Energies, Novara, Italy) The second and third academic projects dealt with the development of green chemical processes for fine chemicals manufacturing. In particular, (a) the condensation reaction between acetone and ammonia to give triacetoneamine (TAA), and (b) the Friedel-Crafts acylation of phenol with benzoic acid were investigated.

Structure-property relations in polymers from renewable resources

The present research project focuses its attention on the study of structure-property relations in polymers from renewable sources (bio-based polymers) such as polymers microbially produced, i.e. polyhydrohyalkanoates (PHAs) or chemically synthesized using monomers from renewable sources, i.e. polyammide 11 (PA11). By means of a broad spectrum of experimental techniques, the influence of different modifications on bio-based polymers such as blending with other components, copolymerization with different co-monomers and introduction of branching to yield complex architectures have been investigated. The present work on PHAs focused on the study of the dependence of polymer properties on both the fermentation process conditions (e.g. bacterial strain and carbon substrate used) and the method adopted to recover PHAs from cells. Furthermore, a solvent-free method using an enzyme and chemicals in an aqueous medium, was developed in order to recover PHAs from cells. Such a method allowed to recover PHA granules in their amorphous state, i.e. in native form useful for specific applications (e.g. paper coating). In addition, a commercial PHA was used as polymeric matrix to develop biodegradable and bio-based composites for food packaging applications. Biodegradable, non-toxic, food contact plasticizers and low cost, widely available lignocellulosic fibers (wheat straw fibers) were incorporated in such a polymeric matrix, in order to decrease PHA brittleness and the polymer cost, respectively. As concerns the study of polyamide 11, both the rheological and the solid-state behavior of PA11 star samples with different arm number and length was studied. Introduction of arms in a polymer molecule allows to modulate melt viscosity behavior which is advantageous for industrial applications. Also, several important solid-state properties, in particular mechanical properties, are affected by the presence of branching. Given the importance of using ‘green’ synthetic strategies in polymer chemistry, novel poly(-amino esters), synthesized via enzymatic-catalyzed polymerization, have also been investigated in this work.

Contamination of Alpine snow and ice at Colle Gnifetti, Swiss/Italian Alps, from nuclear weapons tests

Plutonium is present in the environment as a consequence of atmospheric nuclear tests, nuclear weapons production and industrial releases over the past 50 years. To study temporal trends, a high resolution Pu record was obtained by analyzing 52 discrete samples of an alpine firn/ice core from Colle Gnifetti (Monte Rosa, 4450 m a.s.l.), dating from 1945 to 1990. The 239Pu signal was recorded directly, without decontamination or preconcentration steps, using an Inductively Coupled Plasma - Sector Field Mass Spectrometer (ICP-SFMS) equipped with an high efficiency sample introduction system, thus requiring much less sample preparation than previously reported methods. The 239Pu profile reflects the three main periods of atmospheric nuclear weapons testing: the earliest peak lasted from 1954/55 to 1958 and was caused by the first testing period reaching a maximum in 1958. Despite a temporary halt of testing in 1959/60, the Pu concentration decreased only by half with respect to the 1958 peak due to long atmospheric residence times. In 1961/62 Pu concentrations rapidly increased reaching a maximum in 1963, which was about 40% more intense than the 1958 peak. After the signing of the "Limited Test Ban Treaty" between USA and USSR in 1964, Pu deposition decreased very sharply reaching a minimum in 1967. The third period (1967-1975) is characterized by irregular Pu concentrations with smaller peaks (about 20-30% of the 1964 peak) which might be related to the deposition of Saharan dust contaminated by the French nuclear tests of the 1960s. The data presented are in very good agreement with Pu profiles previously obtained from the Col du Dome ice core (by multi-collector ICP-MS) and Belukha ice core (by Accelerator Mass Spectrometry, AMS). Although a semi-quantitative method was employed here, the results are quantitatively comparable to previously published results.

A Question of Title: Property Rights and Asset Values

This paper examines the impact of land title systems on property values. The predominant system in the U.S., the recording system, awards title to claimants over current possessors, whereas the Torrens registration system awards title to the current owner. In theory, the registration system maximizes property value, all else equal, but in practice, the systems differ depending on the risk of a claim and administrative costs. A natural experiment in Cook County, Illinois, where both systems have existed since 1897, allows a test of the theory. The results, based on commercial and industrial properties, reveal that parcels tend to self-select into the two systems based on the predictions of the theory.

Geochemistry of samples from Valtournenche, Western Italian Alps

Slices of polycyclic metasediments (marbles and meta-cherts) are tectonically amalgamated with the polydeformed basement of the Dent Blanche tectonic system along a major Alpine shear zone in the Western Alps (Becca di Salé area, Valtournenche Valley). A combination of techniques (structural analysis at various scales, metamorphic petrology, geochronology and trace element geochemistry) was applied to determine the age and composition of accessory phases (titanite, allanite and zircon) and their relation to major minerals. The results are used to reconstruct the polyphase structural and metamorphic history, comprising both pre-Alpine and Alpine cycles. The pre-Alpine evolution is associated with low-pressure high-temperature metamorphism related to Permo-Triassic lithospheric thinning. In meta-cherts, microtextural relations indicate coeval growth of allanite and garnet during this stage, at ~ 300 Ma. Textures of zircon also indicate crystallization at HT conditions; ages scatter from 263-294 Ma, with a major cluster of data at ~ 276 Ma. In impure marble, U-Pb analyses of titanite domains (with variable Al and F contents) yield apparent 206Pb/238U dates range from Permian to Jurassic. Chemical and isotopic data suggest that titanite formed at Permian times and was then affected by (extension-related?) fluid circulation during the Triassic and Jurassic, which redistributed major elements (Al and F) and partially opened the U-Pb system. The Alpine cycle lead to early blueschist facies assemblages, which were partly overprinted under greenschist facies conditions. The strong Alpine compressional overprint disrupted the pre-Alpine structural imprint and/or reactivated earlier structures. The pre-Alpine metamorphic record, preserved in these slices of metasediments, reflects the onset of the Permo-Triassic lithospheric extension to Jurassic rifting.

Propagation of Nuclear Data Uncertainties in Transmutation Calculations Using ACAB Code

The assessment of the accuracy of parameters related to the reactor core performance (e.g., ke) and f el cycle (e.g., isotopic evolution/transmutation) due to the uncertainties in the basic nuclear data (ND) is a critical issue. Different error propagation techniques (adjoint/forward sensitivity analysis procedures and/or Monte Carlo technique) can be used to address by computational simulation the systematic propagation of uncertainties on the final parameters. To perform this uncertainty assessment, the ENDF covariance les (variance/correlation in energy and cross- reactions-isotopes correlations) are required. In this paper, we assess the impact of ND uncertainties on the isotopic prediction for a conceptual design of a modular European Facility for Industrial Transmutation (EFIT) for a discharge burnup of 150 GWd/tHM. The complete set of uncertainty data for cross sections (EAF2007/UN, SCALE6.0/COVA-44G), radioactive decay and fission yield data (JEFF-3.1.1) are processed and used in ACAB code.

Low latency LDGM code for multimedia-packet stream in bursty packet loss networks

In this paper we present a FEC scheme based on simple LDGM codes to protect packetized multimedia streams. We demonstrate that simple LDGM codes working with a limited number of packets (small values of k) obtain recovery capabilities, against bursty packet losses, that are similar to those of other more complex FEC-based schemes designed for this type of channels.

Run-Time Dynamically-Adaptable FPGA-Based Architecture for High-Performance Autonomous Distributed Systems

Esta tesis doctoral se enmarca dentro del campo de los sistemas embebidos reconfigurables, redes de sensores inalámbricas para aplicaciones de altas prestaciones, y computación distribuida. El documento se centra en el estudio de alternativas de procesamiento para sistemas embebidos autónomos distribuidos de altas prestaciones (por sus siglas en inglés, High-Performance Autonomous Distributed Systems (HPADS)), así como su evolución hacia el procesamiento de alta resolución. El estudio se ha llevado a cabo tanto a nivel de plataforma como a nivel de las arquitecturas de procesamiento dentro de la plataforma con el objetivo de optimizar aspectos tan relevantes como la eficiencia energética, la capacidad de cómputo y la tolerancia a fallos del sistema. Los HPADS son sistemas realimentados, normalmente formados por elementos distribuidos conectados o no en red, con cierta capacidad de adaptación, y con inteligencia suficiente para llevar a cabo labores de prognosis y/o autoevaluación. Esta clase de sistemas suele formar parte de sistemas más complejos llamados sistemas ciber-físicos (por sus siglas en inglés, Cyber-Physical Systems (CPSs)). Los CPSs cubren un espectro enorme de aplicaciones, yendo desde aplicaciones médicas, fabricación, o aplicaciones aeroespaciales, entre otras muchas. Para el diseño de este tipo de sistemas, aspectos tales como la confiabilidad, la definición de modelos de computación, o el uso de metodologías y/o herramientas que faciliten el incremento de la escalabilidad y de la gestión de la complejidad, son fundamentales. La primera parte de esta tesis doctoral se centra en el estudio de aquellas plataformas existentes en el estado del arte que por sus características pueden ser aplicables en el campo de los CPSs, así como en la propuesta de un nuevo diseño de plataforma de altas prestaciones que se ajuste mejor a los nuevos y más exigentes requisitos de las nuevas aplicaciones. Esta primera parte incluye descripción, implementación y validación de la plataforma propuesta, así como conclusiones sobre su usabilidad y sus limitaciones. Los principales objetivos para el diseño de la plataforma propuesta se enumeran a continuación: • Estudiar la viabilidad del uso de una FPGA basada en RAM como principal procesador de la plataforma en cuanto a consumo energético y capacidad de cómputo. • Propuesta de técnicas de gestión del consumo de energía en cada etapa del perfil de trabajo de la plataforma. •Propuestas para la inclusión de reconfiguración dinámica y parcial de la FPGA (por sus siglas en inglés, Dynamic Partial Reconfiguration (DPR)) de forma que sea posible cambiar ciertas partes del sistema en tiempo de ejecución y sin necesidad de interrumpir al resto de las partes. Evaluar su aplicabilidad en el caso de HPADS. Las nuevas aplicaciones y nuevos escenarios a los que se enfrentan los CPSs, imponen nuevos requisitos en cuanto al ancho de banda necesario para el procesamiento de los datos, así como en la adquisición y comunicación de los mismos, además de un claro incremento en la complejidad de los algoritmos empleados. Para poder cumplir con estos nuevos requisitos, las plataformas están migrando desde sistemas tradicionales uni-procesador de 8 bits, a sistemas híbridos hardware-software que incluyen varios procesadores, o varios procesadores y lógica programable. Entre estas nuevas arquitecturas, las FPGAs y los sistemas en chip (por sus siglas en inglés, System on Chip (SoC)) que incluyen procesadores embebidos y lógica programable, proporcionan soluciones con muy buenos resultados en cuanto a consumo energético, precio, capacidad de cómputo y flexibilidad. Estos buenos resultados son aún mejores cuando las aplicaciones tienen altos requisitos de cómputo y cuando las condiciones de trabajo son muy susceptibles de cambiar en tiempo real. La plataforma propuesta en esta tesis doctoral se ha denominado HiReCookie. La arquitectura incluye una FPGA basada en RAM como único procesador, así como un diseño compatible con la plataforma para redes de sensores inalámbricas desarrollada en el Centro de Electrónica Industrial de la Universidad Politécnica de Madrid (CEI-UPM) conocida como Cookies. Esta FPGA, modelo Spartan-6 LX150, era, en el momento de inicio de este trabajo, la mejor opción en cuanto a consumo y cantidad de recursos integrados, cuando además, permite el uso de reconfiguración dinámica y parcial. Es importante resaltar que aunque los valores de consumo son los mínimos para esta familia de componentes, la potencia instantánea consumida sigue siendo muy alta para aquellos sistemas que han de trabajar distribuidos, de forma autónoma, y en la mayoría de los casos alimentados por baterías. Por esta razón, es necesario incluir en el diseño estrategias de ahorro energético para incrementar la usabilidad y el tiempo de vida de la plataforma. La primera estrategia implementada consiste en dividir la plataforma en distintas islas de alimentación de forma que sólo aquellos elementos que sean estrictamente necesarios permanecerán alimentados, cuando el resto puede estar completamente apagado. De esta forma es posible combinar distintos modos de operación y así optimizar enormemente el consumo de energía. El hecho de apagar la FPGA para ahora energía durante los periodos de inactividad, supone la pérdida de la configuración, puesto que la memoria de configuración es una memoria volátil. Para reducir el impacto en el consumo y en el tiempo que supone la reconfiguración total de la plataforma una vez encendida, en este trabajo, se incluye una técnica para la compresión del archivo de configuración de la FPGA, de forma que se consiga una reducción del tiempo de configuración y por ende de la energía consumida. Aunque varios de los requisitos de diseño pueden satisfacerse con el diseño de la plataforma HiReCookie, es necesario seguir optimizando diversos parámetros tales como el consumo energético, la tolerancia a fallos y la capacidad de procesamiento. Esto sólo es posible explotando todas las posibilidades ofrecidas por la arquitectura de procesamiento en la FPGA. Por lo tanto, la segunda parte de esta tesis doctoral está centrada en el diseño de una arquitectura reconfigurable denominada ARTICo3 (Arquitectura Reconfigurable para el Tratamiento Inteligente de Cómputo, Confiabilidad y Consumo de energía) para la mejora de estos parámetros por medio de un uso dinámico de recursos. ARTICo3 es una arquitectura de procesamiento para FPGAs basadas en RAM, con comunicación tipo bus, preparada para dar soporte para la gestión dinámica de los recursos internos de la FPGA en tiempo de ejecución gracias a la inclusión de reconfiguración dinámica y parcial. Gracias a esta capacidad de reconfiguración parcial, es posible adaptar los niveles de capacidad de procesamiento, energía consumida o tolerancia a fallos para responder a las demandas de la aplicación, entorno, o métricas internas del dispositivo mediante la adaptación del número de recursos asignados para cada tarea. Durante esta segunda parte de la tesis se detallan el diseño de la arquitectura, su implementación en la plataforma HiReCookie, así como en otra familia de FPGAs, y su validación por medio de diferentes pruebas y demostraciones. Los principales objetivos que se plantean la arquitectura son los siguientes: • Proponer una metodología basada en un enfoque multi-hilo, como las propuestas por CUDA (por sus siglas en inglés, Compute Unified Device Architecture) u Open CL, en la cual distintos kernels, o unidades de ejecución, se ejecuten en un numero variable de aceleradores hardware sin necesidad de cambios en el código de aplicación. • Proponer un diseño y proporcionar una arquitectura en la que las condiciones de trabajo cambien de forma dinámica dependiendo bien de parámetros externos o bien de parámetros que indiquen el estado de la plataforma. Estos cambios en el punto de trabajo de la arquitectura serán posibles gracias a la reconfiguración dinámica y parcial de aceleradores hardware en tiempo real. • Explotar las posibilidades de procesamiento concurrente, incluso en una arquitectura basada en bus, por medio de la optimización de las transacciones en ráfaga de datos hacia los aceleradores. •Aprovechar las ventajas ofrecidas por la aceleración lograda por módulos puramente hardware para conseguir una mejor eficiencia energética. • Ser capaces de cambiar los niveles de redundancia de hardware de forma dinámica según las necesidades del sistema en tiempo real y sin cambios para el código de aplicación. • Proponer una capa de abstracción entre el código de aplicación y el uso dinámico de los recursos de la FPGA. El diseño en FPGAs permite la utilización de módulos hardware específicamente creados para una aplicación concreta. De esta forma es posible obtener rendimientos mucho mayores que en el caso de las arquitecturas de propósito general. Además, algunas FPGAs permiten la reconfiguración dinámica y parcial de ciertas partes de su lógica en tiempo de ejecución, lo cual dota al diseño de una gran flexibilidad. Los fabricantes de FPGAs ofrecen arquitecturas predefinidas con la posibilidad de añadir bloques prediseñados y poder formar sistemas en chip de una forma más o menos directa. Sin embargo, la forma en la que estos módulos hardware están organizados dentro de la arquitectura interna ya sea estática o dinámicamente, o la forma en la que la información se intercambia entre ellos, influye enormemente en la capacidad de cómputo y eficiencia energética del sistema. De la misma forma, la capacidad de cargar módulos hardware bajo demanda, permite añadir bloques redundantes que permitan aumentar el nivel de tolerancia a fallos de los sistemas. Sin embargo, la complejidad ligada al diseño de bloques hardware dedicados no debe ser subestimada. Es necesario tener en cuenta que el diseño de un bloque hardware no es sólo su propio diseño, sino también el diseño de sus interfaces, y en algunos casos de los drivers software para su manejo. Además, al añadir más bloques, el espacio de diseño se hace más complejo, y su programación más difícil. Aunque la mayoría de los fabricantes ofrecen interfaces predefinidas, IPs (por sus siglas en inglés, Intelectual Property) comerciales y plantillas para ayudar al diseño de los sistemas, para ser capaces de explotar las posibilidades reales del sistema, es necesario construir arquitecturas sobre las ya establecidas para facilitar el uso del paralelismo, la redundancia, y proporcionar un entorno que soporte la gestión dinámica de los recursos. Para proporcionar este tipo de soporte, ARTICo3 trabaja con un espacio de soluciones formado por tres ejes fundamentales: computación, consumo energético y confiabilidad. De esta forma, cada punto de trabajo se obtiene como una solución de compromiso entre estos tres parámetros. Mediante el uso de la reconfiguración dinámica y parcial y una mejora en la transmisión de los datos entre la memoria principal y los aceleradores, es posible dedicar un número variable de recursos en el tiempo para cada tarea, lo que hace que los recursos internos de la FPGA sean virtualmente ilimitados. Este variación en el tiempo del número de recursos por tarea se puede usar bien para incrementar el nivel de paralelismo, y por ende de aceleración, o bien para aumentar la redundancia, y por lo tanto el nivel de tolerancia a fallos. Al mismo tiempo, usar un numero óptimo de recursos para una tarea mejora el consumo energético ya que bien es posible disminuir la potencia instantánea consumida, o bien el tiempo de procesamiento. Con el objetivo de mantener los niveles de complejidad dentro de unos límites lógicos, es importante que los cambios realizados en el hardware sean totalmente transparentes para el código de aplicación. A este respecto, se incluyen distintos niveles de transparencia: • Transparencia a la escalabilidad: los recursos usados por una misma tarea pueden ser modificados sin que el código de aplicación sufra ningún cambio. • Transparencia al rendimiento: el sistema aumentara su rendimiento cuando la carga de trabajo aumente, sin cambios en el código de aplicación. • Transparencia a la replicación: es posible usar múltiples instancias de un mismo módulo bien para añadir redundancia o bien para incrementar la capacidad de procesamiento. Todo ello sin que el código de aplicación cambie. • Transparencia a la posición: la posición física de los módulos hardware es arbitraria para su direccionamiento desde el código de aplicación. • Transparencia a los fallos: si existe un fallo en un módulo hardware, gracias a la redundancia, el código de aplicación tomará directamente el resultado correcto. • Transparencia a la concurrencia: el hecho de que una tarea sea realizada por más o menos bloques es transparente para el código que la invoca. Por lo tanto, esta tesis doctoral contribuye en dos líneas diferentes. En primer lugar, con el diseño de la plataforma HiReCookie y en segundo lugar con el diseño de la arquitectura ARTICo3. Las principales contribuciones de esta tesis se resumen a continuación. • Arquitectura de la HiReCookie incluyendo: o Compatibilidad con la plataforma Cookies para incrementar las capacidades de esta. o División de la arquitectura en distintas islas de alimentación. o Implementación de los diversos modos de bajo consumo y políticas de despertado del nodo. o Creación de un archivo de configuración de la FPGA comprimido para reducir el tiempo y el consumo de la configuración inicial. • Diseño de la arquitectura reconfigurable para FPGAs basadas en RAM ARTICo3: o Modelo de computación y modos de ejecución inspirados en el modelo de CUDA pero basados en hardware reconfigurable con un número variable de bloques de hilos por cada unidad de ejecución. o Estructura para optimizar las transacciones de datos en ráfaga proporcionando datos en cascada o en paralelo a los distinto módulos incluyendo un proceso de votado por mayoría y operaciones de reducción. o Capa de abstracción entre el procesador principal que incluye el código de aplicación y los recursos asignados para las diferentes tareas. o Arquitectura de los módulos hardware reconfigurables para mantener la escalabilidad añadiendo una la interfaz para las nuevas funcionalidades con un simple acceso a una memoria RAM interna. o Caracterización online de las tareas para proporcionar información a un módulo de gestión de recursos para mejorar la operación en términos de energía y procesamiento cuando además se opera entre distintos nieles de tolerancia a fallos. El documento está dividido en dos partes principales formando un total de cinco capítulos. En primer lugar, después de motivar la necesidad de nuevas plataformas para cubrir las nuevas aplicaciones, se detalla el diseño de la plataforma HiReCookie, sus partes, las posibilidades para bajar el consumo energético y se muestran casos de uso de la plataforma así como pruebas de validación del diseño. La segunda parte del documento describe la arquitectura reconfigurable, su implementación en varias FPGAs, y pruebas de validación en términos de capacidad de procesamiento y consumo energético, incluyendo cómo estos aspectos se ven afectados por el nivel de tolerancia a fallos elegido. Los capítulos a lo largo del documento son los siguientes: El capítulo 1 analiza los principales objetivos, motivación y aspectos teóricos necesarios para seguir el resto del documento. El capítulo 2 está centrado en el diseño de la plataforma HiReCookie y sus posibilidades para disminuir el consumo de energía. El capítulo 3 describe la arquitectura reconfigurable ARTICo3. El capítulo 4 se centra en las pruebas de validación de la arquitectura usando la plataforma HiReCookie para la mayoría de los tests. Un ejemplo de aplicación es mostrado para analizar el funcionamiento de la arquitectura. El capítulo 5 concluye esta tesis doctoral comentando las conclusiones obtenidas, las contribuciones originales del trabajo y resultados y líneas futuras. ABSTRACT This PhD Thesis is framed within the field of dynamically reconfigurable embedded systems, advanced sensor networks and distributed computing. The document is centred on the study of processing solutions for high-performance autonomous distributed systems (HPADS) as well as their evolution towards High performance Computing (HPC) systems. The approach of the study is focused on both platform and processor levels to optimise critical aspects such as computing performance, energy efficiency and fault tolerance. HPADS are considered feedback systems, normally networked and/or distributed, with real-time adaptive and predictive functionality. These systems, as part of more complex systems known as Cyber-Physical Systems (CPSs), can be applied in a wide range of fields such as military, health care, manufacturing, aerospace, etc. For the design of HPADS, high levels of dependability, the definition of suitable models of computation, and the use of methodologies and tools to support scalability and complexity management, are required. The first part of the document studies the different possibilities at platform design level in the state of the art, together with description, development and validation tests of the platform proposed in this work to cope with the previously mentioned requirements. The main objectives targeted by this platform design are the following: • Study the feasibility of using SRAM-based FPGAs as the main processor of the platform in terms of energy consumption and performance for high demanding applications. • Analyse and propose energy management techniques to reduce energy consumption in every stage of the working profile of the platform. • Provide a solution with dynamic partial and wireless remote HW reconfiguration (DPR) to be able to change certain parts of the FPGA design at run time and on demand without interrupting the rest of the system. • Demonstrate the applicability of the platform in different test-bench applications. In order to select the best approach for the platform design in terms of processing alternatives, a study of the evolution of the state-of-the-art platforms is required to analyse how different architectures cope with new more demanding applications and scenarios: security, mixed-critical systems for aerospace, multimedia applications, or military environments, among others. In all these scenarios, important changes in the required processing bandwidth or the complexity of the algorithms used are provoking the migration of the platforms from single microprocessor architectures to multiprocessing and heterogeneous solutions with more instant power consumption but higher energy efficiency. Within these solutions, FPGAs and Systems on Chip including FPGA fabric and dedicated hard processors, offer a good trade of among flexibility, processing performance, energy consumption and price, when they are used in demanding applications where working conditions are very likely to vary over time and high complex algorithms are required. The platform architecture proposed in this PhD Thesis is called HiReCookie. It includes an SRAM-based FPGA as the main and only processing unit. The FPGA selected, the Xilinx Spartan-6 LX150, was at the beginning of this work the best choice in terms of amount of resources and power. Although, the power levels are the lowest of these kind of devices, they can be still very high for distributed systems that normally work powered by batteries. For that reason, it is necessary to include different energy saving possibilities to increase the usability of the platform. In order to reduce energy consumption, the platform architecture is divided into different power islands so that only those parts of the systems that are strictly needed are powered on, while the rest of the islands can be completely switched off. This allows a combination of different low power modes to decrease energy. In addition, one of the most important handicaps of SRAM-based FPGAs is that they are not alive at power up. Therefore, recovering the system from a switch-off state requires to reload the FPGA configuration from a non-volatile memory device. For that reason, this PhD Thesis also proposes a methodology to compress the FPGA configuration file in order to reduce time and energy during the initial configuration process. Although some of the requirements for the design of HPADS are already covered by the design of the HiReCookie platform, it is necessary to continue improving energy efficiency, computing performance and fault tolerance. This is only possible by exploiting all the opportunities provided by the processing architectures configured inside the FPGA. Therefore, the second part of the thesis details the design of the so called ARTICo3 FPGA architecture to enhance the already intrinsic capabilities of the FPGA. ARTICo3 is a DPR-capable bus-based virtual architecture for multiple HW acceleration in SRAM-based FPGAs. The architecture provides support for dynamic resource management in real time. In this way, by using DPR, it will be possible to change the levels of computing performance, energy consumption and fault tolerance on demand by increasing or decreasing the amount of resources used by the different tasks. Apart from the detailed design of the architecture and its implementation in different FPGA devices, different validation tests and comparisons are also shown. The main objectives targeted by this FPGA architecture are listed as follows: • Provide a method based on a multithread approach such as those offered by CUDA (Compute Unified Device Architecture) or OpenCL kernel executions, where kernels are executed in a variable number of HW accelerators without requiring application code changes. • Provide an architecture to dynamically adapt working points according to either self-measured or external parameters in terms of energy consumption, fault tolerance and computing performance. Taking advantage of DPR capabilities, the architecture must provide support for a dynamic use of resources in real time. • Exploit concurrent processing capabilities in a standard bus-based system by optimizing data transactions to and from HW accelerators. • Measure the advantage of HW acceleration as a technique to boost performance to improve processing times and save energy by reducing active times for distributed embedded systems. • Dynamically change the levels of HW redundancy to adapt fault tolerance in real time. • Provide HW abstraction from SW application design. FPGAs give the possibility of designing specific HW blocks for every required task to optimise performance while some of them include the possibility of including DPR. Apart from the possibilities provided by manufacturers, the way these HW modules are organised, addressed and multiplexed in area and time can improve computing performance and energy consumption. At the same time, fault tolerance and security techniques can also be dynamically included using DPR. However, the inherent complexity of designing new HW modules for every application is not negligible. It does not only consist of the HW description, but also the design of drivers and interfaces with the rest of the system, while the design space is widened and more complex to define and program. Even though the tools provided by the majority of manufacturers already include predefined bus interfaces, commercial IPs, and templates to ease application prototyping, it is necessary to improve these capabilities. By adding new architectures on top of them, it is possible to take advantage of parallelization and HW redundancy while providing a framework to ease the use of dynamic resource management. ARTICo3 works within a solution space where working points change at run time in a 3D space defined by three different axes: Computation, Consumption, and Fault Tolerance. Therefore, every working point is found as a trade-off solution among these three axes. By means of DPR, different accelerators can be multiplexed so that the amount of available resources for any application is virtually unlimited. Taking advantage of DPR capabilities and a novel way of transmitting data to the reconfigurable HW accelerators, it is possible to dedicate a dynamically-changing number of resources for a given task in order to either boost computing speed or adding HW redundancy and a voting process to increase fault-tolerance levels. At the same time, using an optimised amount of resources for a given task reduces energy consumption by reducing instant power or computing time. In order to keep level complexity under certain limits, it is important that HW changes are transparent for the application code. Therefore, different levels of transparency are targeted by the system: • Scalability transparency: a task must be able to expand its resources without changing the system structure or application algorithms. • Performance transparency: the system must reconfigure itself as load changes. • Replication transparency: multiple instances of the same task are loaded to increase reliability and performance. • Location transparency: resources are accessed with no knowledge of their location by the application code. • Failure transparency: task must be completed despite a failure in some components. • Concurrency transparency: different tasks will work in a concurrent way transparent to the application code. Therefore, as it can be seen, the Thesis is contributing in two different ways. First with the design of the HiReCookie platform and, second with the design of the ARTICo3 architecture. The main contributions of this PhD Thesis are then listed below: • Architecture of the HiReCookie platform including: o Compatibility of the processing layer for high performance applications with the Cookies Wireless Sensor Network platform for fast prototyping and implementation. o A division of the architecture in power islands. o All the different low-power modes. o The creation of the partial-initial bitstream together with the wake-up policies of the node. • The design of the reconfigurable architecture for SRAM FPGAs: ARTICo3: o A model of computation and execution modes inspired in CUDA but based on reconfigurable HW with a dynamic number of thread blocks per kernel. o A structure to optimise burst data transactions providing coalesced or parallel data to HW accelerators, parallel voting process and reduction operation. o The abstraction provided to the host processor with respect to the operation of the kernels in terms of the number of replicas, modes of operation, location in the reconfigurable area and addressing. o The architecture of the modules representing the thread blocks to make the system scalable by adding functional units only adding an access to a BRAM port. o The online characterization of the kernels to provide information to a scheduler or resource manager in terms of energy consumption and processing time when changing among different fault-tolerance levels, as well as if a kernel is expected to work in the memory-bounded or computing-bounded areas. The document of the Thesis is divided into two main parts with a total of five chapters. First, after motivating the need for new platforms to cover new more demanding applications, the design of the HiReCookie platform, its parts and several partial tests are detailed. The design of the platform alone does not cover all the needs of these applications. Therefore, the second part describes the architecture inside the FPGA, called ARTICo3, proposed in this PhD Thesis. The architecture and its implementation are tested in terms of energy consumption and computing performance showing different possibilities to improve fault tolerance and how this impact in energy and time of processing. Chapter 1 shows the main goals of this PhD Thesis and the technology background required to follow the rest of the document. Chapter 2 shows all the details about the design of the FPGA-based platform HiReCookie. Chapter 3 describes the ARTICo3 architecture. Chapter 4 is focused on the validation tests of the ARTICo3 architecture. An application for proof of concept is explained where typical kernels related to image processing and encryption algorithms are used. Further experimental analyses are performed using these kernels. Chapter 5 concludes the document analysing conclusions, comments about the contributions of the work, and some possible future lines for the work.

Criterios de restauración, intervención y revitalización del patrimonio industrial : la fábrica de gas de San Paolo en Roma

La tesis está centrada en el patrimonio industrial, y trata de ahondar en los temas enunciados en el título, Criterios de restauración, intervención y revitalización del patrimonio industrial (capítulo 1). La fábrica de gas de San Paolo en Roma (capítulo 2): En el primer capítulo, se profundiza en los criterios institucionalizados de actuación en el patrimonio, pero también se habla sobre la singularidad, los valores originales, estratificados en cada construcción y su contexto. Ello resume la intención de la doctoranda al entender la necesidad del análisis de cada obra en modo profundo, concreto y abierto a novedosos acercamientos, antes de su transformación. Al hablar de intervención frente a restauración, se aborda la conocida polémica que plantea el modo de acercarse al legado histórico. Parece necesario enunciar cómo se consideran en el trabajo estos términos. Mientras la restauración (como diría Cesare Brandi, constituye el momento metodológico del reconocimiento de la obra de arte en su consistencia física y en su doble polaridad estética e histórica, en orden a su transmisión al futuro) es una acción más restrictiva, que implica atención suma a la recuperación y conservación de los valores significativos y únicos del bien, en comunicación con un (posible) equipo interdisciplinar; por intervención se entiende aquí un desarrollo más personal y libre por parte del proyectista, en el que se produce un proceso dialéctico entre la preexistencia y el posicionamiento crítico adoptado a la hora de dar un obligado nuevo uso a ese bien. Es decir, el contraste está en el diferente reconocimiento de la materialidad física y sus significados. En torno a la restauración/intervención, se analizan las perspectivas de actuación en España e Italia, contrastando factores como la formación del arquitecto o el entorno laboral-cultural, y utilizando el método analítico comparativo de casos. Habría un tercer concepto: el de revitalización del patrimonio industrial, Éste hace referencia a su transformación, a sus usos más comunes y compatibles, a la redimensión artística que ha experimentado la arquitectura industrial gracias al arte contemporáneo y a su relación con la Modernidad. Por último, se enuncia en el título el caso de estudio, la Fábrica, que ocupa el segundo capítulo. Se trata de un enorme conjunto industrial singular semi abandonado en el confín del centro histórico, cuyo protagonista es un gran gasómetro, que la autora ha tenido la oportunidad de descubrir en su estancia en la Ciudad Eterna. Este barrio constituyó el primer y único sector industrial de la Roma moderna a inicios del siglo XX. Por varias causas históricas y voluntad política, la ciudad prácticamente no tuvo más desarrollo industrial que el área mencionada, donde se implantaron servicios y actividades de gran transformación (Matadero, Mercados Generales, Almacenes Fluviales, Central Montemartini o esta fábrica). A partir de 1920, se empezó a construir un tejido productivo que la llevó de la situación de posguerra al milagro económico. Frente al mito de la Roma monumental o de la Roma cotidiana, aparece el aspecto industrial como mito de la contemporaneidad. Sin embargo, esta ciudad es demasiado antigua como para convertirse en moderna, y su proceso industrial en contraste con su larga historia resulta breve. La inmediata relación de la fase industrial romana con el resultado de este desarrollo viene identificada con las instalaciones señaladas, más significativas por su excepcionalidad que por la duración del momento irrepetible que representan. Su presencia física perdura a pesar de su abandono, aisladas tras su muro perimetral y casi desconocidas. Esto las hace apetecibles para la especulación inmobiliaria y resultan un caso de estudio ideal para realizar un Plan de Intervención Global, en el que determinar una serie de intervenciones necesarias, usos compatibles y directrices para la ordenación del conjunto, coherentes con los conceptos manejados en el primer capítulo. ABSTRACT The thesis focuses on industrial heritage, delving into the topics listed in its title, Criteria for the restoration, intervention and revitalisation of industrial heritage (chapter 1). The San Paolo gas factory in Rome (chapter 2): Chapter one elaborates on the official criteria to take action on heritage, but also deals with the singularity and original values unique to each construction and its context. This underlines the PhD candidate’s intentions by understanding the need for an in-depth and specific analysis, open to novel approaches to each site before its transformation. When speaking of intervention, as opposed to restoration, we address the well-known controversy that stems from the different ways of approaching historical heritage. It seems necessary to explain how these terms are interpreted in this piece of work. Whereas restoration (as Cesare Brandi would say, constitutes the methodological moment in which the work of art is appreciated in its material form and in its historical and aesthetic duality, with a view to transmitting it to the future) is a more restrictive action, demanding the utmost attention to the recovery and preservation of the piece of heritage’s defining and exceptional values, (ideally) in communication with a interdisciplinary team. By intervention, we hereby understand a more personal and free procedure carried out by the designer in which a dialectical process takes place between preexistence and the critical stance taken in order to give that good a much needed new use. That is, contrast lies in the different recognition of physical materiality and its meanings. As for the restoration/intervention dilemma, the different courses of action followed in Spain and Italy will be analysed, contrasting the architects’ training, the labourcultural environment and taking an analytical comparative case study method. There is a third concept: the revitalisation of industrial heritage, which refers to its transformation, its most common and compatible uses, the artistic redimensioning that industrial architecture has experienced thanks to contemporary art, and its relationship with Modernity. Lastly, the title refers to the case study, i.e., the analysis of the Factory, which makes up chapter 2. It is an enormous and semiabandoned peerless industrial complex on the edge of the historical city centre whose main landmark is a huge gasometer, which the author had the chance to discover during her stay in the Eternal City. This district made up the first and only industrial sector in the modern Rome of the early 20th century. Due to a number of reasons, both historical and political, barely no further industrial development took place in the city beyond the mentioned area, where processing services and activities were set up (Slaughterhouse, General Markets, Riverside Warehouses, Montemartini Power Plant or the said factory). In the 1920s began the construction of the productive fabric that raised the city from its postwar plight to the economic miracle. As opposed to the myth of monumental Rome and daily-life Rome, this industrial Rome rose as contemporaneity’s myth. However, this city is too ancient to become modern, and its industrial process strikes us as brief when confronted with its long history. The close relationship between Rome’s industrial stage and the consequences of this development is best represented by the aforementioned facilities, more relevant due to their uniqueness than the length of the once-in-a-lifetime moment they represent. Their physical presence lives on despite abandonment and isolation, as they stand vastly unknown behind their perimeter walls. This renders them appealing to property speculators, becoming an ideal case study for the creation of a Global Intervention Plan in which to determine a series of necessary actions, compatible uses and directives, all of them consistent with the concepts dealt with in chapter 1. RIASSUNTO La tesi è focalizzata sul patrimonio industriale e cerca di approfondire le tematiche contenute nel titolo, Criteri di restauro, intervento e rivitalizzazione del patrimonio industriale (capitolo 1). La Fabbrica del gas di San Paolo a Roma (capitolo 2): Nel primo capitolo vengono presi in esame i criteri istituzionalizzati di attuazione nel patrimonio, ma si parla anche della unicità, i valori originali, stratificati in ogni costruzione ed il suo contesto. Questo riassume l’intenzione della dottoranda di capire la necessità dell’analisi di ogni opera in modo profondo, concreto e aperto a nuovi approcci, prima della sua trasformazione. Nel parlare di intervento versus restauro, si affronta la famosa polemica che considera il modo di avicinarsi all’eredità storica. Appare necessario precisare come questi termini sono considerati in questo lavoro. Mentre il restauro (come direbbe Cesare Brandi, costituisce il momento metodologico del riconoscimento dell’opera d’arte nella sua consistenza fisica e nella duplice polarità estetica e storica, in vista della sua trasmissione nel futuro) è un’azione più restrittiva, e quindi implica massima attenzione al recupero e conservazione dei valori significativi ed unici del bene, in comunicazione con una (eventuale) squadra interdisciplinare; per intervento si intende qui un processo più personale e libero del progettista, nel quale si produce uno sviluppo dialettico tra la preesistenza e la posizione critica adottata quando si deve dare un nuovo uso di quel bene. Vale a dire che il contrasto risiede nel diverso riconoscimento della materialità fisica e i loro significati. Intorno al restauro / intervento, si analizzano le prospettive di attuazione in Spagna e Italia, contrastando diversi fattori come la formazione dell’architetto o l’ambiente lavorativo-culturale, ed impiegando il metodo analitico comparativo dei casi. Ci sarebbe un terzo concetto: quello della rivitalizzazione del patrimonio industriale. Questo fa riferimento alla sua trasformazione, ai suoi usi più comuni e compatibili, al ridimensionamento artistico vissuto dall’archeologia industriale grazie all’arte contemporanea ed al suo rapporto con la Modernità. In ultimo, si enuncia nel titolo il caso di studio, ovvero l’analisi della Fabbrica, che occupa il secondo capitolo. Si tratta di un enorme complesso industriale semi-abbandonato al confine con il centro storico, il cui protagonista è un grande gasometro, che l’autrice ha avuto modo di scoprire durante il suo soggiorno nella Città Eterna. Questo quartiere costituì il primo e unico moderno settore industriale della Roma moderna all’inizio del Novecento. Per diverse ragioni storiche e volontà politiche, la città praticamente non ha subito ulteriore sviluppo industriale oltre l’area citata, dove si impiantarono servizi e attività di grande trasformazione (Mattatoio, Mercati Generali, Magazzini Generali, Centrale Montemartini o questa fabbrica). Dal 1920, si inizió a costruire un tessuto prodottivo che portò la città dalla situazione post-bellica al miracolo economico. Di fronte al mito della Roma monumentale o della Roma quotidiana, appare questa Roma industriale come mito della contemporaneità. Tuttavia, questa città è troppo antica per diventare moderna, ed il suo processo industriale in contrasto con la sua lunga storia risulta breve. Il rapporto diretto della fase industriale romana con il risultato di questo sviluppo viene identificato con gli impianti segnalati, più significativi per la loro unicità che per la durata del momento irripetibile che rappresentano. La loro presenza fisica perdura nonostante l’abbandono, isolati dietro il loro muro di cinta e quasi sconosciuti. Questo li rende auspicabile per la speculazione immobiliare e sono un caso ideale per eseguire un Piano di Intervento Globale, che determini una serie di interventi necessari, usi compatibili e linee guida per la pianificazione del tutto, in linea con i concetti utilizzati nel primo capitolo.

An economic analysis of unilateral refusals to license intellectual property

The intellectual property laws in the United States provide the owners of intellectual property with discretion to license the right to use that property or to make or sell products that embody the intellectual property. However, the antitrust laws constrain the use of property, including intellectual property, by a firm with market power and may place limitations on the licensing of intellectual property. This paper focuses on one aspect of antitrust law, the so-called “essential facilities doctrine,” which may impose a duty upon firms controlling an “essential facility” to make that facility available to their rivals. In the intellectual property context, an obligation to make property available is equivalent to a requirement for compulsory licensing. Compulsory licensing may embrace the requirement that the owner of software permit access to the underlying code so that others can develop compatible application programs. Compulsory licensing may undermine incentives for research and development by reducing the value of an innovation to the inventor. This paper shows that compulsory licensing also may reduce economic efficiency in the short run by facilitating the entry of inefficient producers and by promoting licensing arrangements that result in higher prices.