Integration of Timetable Planning and Rolling Stock in Rapid Transit Networks

The aim of this paper is to propose an integrated planning model to adequate the offered capacity and system frequencies to attend the increased passenger demand and traffic congestion around urban and suburban areas. The railway capacity is studied in line planning, however, these planned frequencies were obtained without accounting for rolling stock flows through the rapid transit network. In order to provide the problem more freedom to decide rolling stock flows and therefore better adjusting these flows to passenger demand, a new integrated model is proposed, where frequencies are readjusted. Then, the railway timetable and rolling stock assignment are also calculated, where shunting operations are taken into account. These operations may sometimes malfunction, causing localized incidents that could propagate throughout the entire network due to cascading effects. This type of operations will be penalized with the goal of selectively avoiding them and ameliorating their high malfunction probabilities. Swapping operations will also be ensured using homogeneous rolling stock material and ensuring parkings in strategic stations. We illustrate our model using computational experiments drawn from RENFE (the main Spanish operator of suburban passenger trains) in Madrid, Spain. The results show that through this integrated approach a greater robustness degree can be obtained

Seismic Risk Scenarios in Puerto Principe (Haiti). A Tool for Reconstruction and Emergency Planning

The 12 January 2010, an earthquake hit the city of Port-au-Prince, capital of Haiti. The earthquake reached a magnitude Mw 7.0 and the epicenter was located near the town of Léogâne, approximately 25 km west of the capital. The earthquake occurred in the boundary region separating the Caribbean plate and the North American plate. This plate boundary is dominated by left-lateral strike slip motion and compression, and accommodates about 20 mm/y slip, with the Caribbean plate moving eastward with respect to the North American plate (DeMets et al., 2000). Initially the location and focal mechanism of the earthquake seemed to involve straightforward accommodation of oblique relative motion between the Caribbean and North American plates along the Enriquillo-Plantain Garden fault system (EPGFZ), however Hayes et al., (2010) combined seismological observations, geologic field data and space geodetic measurements to show that, instead, the rupture process involved slip on multiple faults. Besides, the authors showed that remaining shallow shear strain will be released in future surface-rupturing earthquakes on the EPGFZ. In December 2010, a Spanish cooperation project financed by the Politechnical University of Madrid started with a clear objective: Evaluation of seismic hazard and risk in Haiti and its application to the seismic design, urban planning, emergency and resource management. One of the tasks of the project was devoted to vulnerability assessment of the current building stock and the estimation of seismic risk scenarios. The study was carried out by following the capacity spectrum method as implemented in the software SELENA (Molina et al., 2010). The method requires a detailed classification of the building stock in predominant building typologies (according to the materials in the structure and walls, number of stories and age of construction) and the use of the building (residential, commercial, etc.). Later, the knowledge of the soil characteristics of the city and the simulation of a scenario earthquake will provide the seismic risk scenarios (damaged buildings). The initial results of the study show that one of the highest sources of uncertainties comes from the difficulty of achieving a precise building typologies classification due to the craft construction without any regulations. Also it is observed that although the occurrence of big earthquakes usually helps to decrease the vulnerability of the cities due to the collapse of low quality buildings and the reconstruction of seismically designed buildings, in the case of Port-au-Prince the seismic risk in most of the districts remains high, showing very vulnerable areas. Therefore the local authorities have to drive their efforts towards the quality control of the new buildings, the reinforcement of the existing building stock, the establishment of seismic normatives and the development of emergency planning also through the education of the population.

Planificación de una red 4G

La intensa evolución tecnológica que está experimentando nuestra sociedad en las últimas décadas hace que se estén desarrollando continuamente nuevas tecnologías que proporcionan mejoras tanto en la calidad como en la seguridad del servicio, este es el caso del 4G. A día de hoy, en España, la cuarta generación de comunicaciones móviles se ve encabezada por LTE, mientras que LTE-Advanced sólo se está implantando en las principales ciudades de nuestro país durante los últimos meses. Por este motivo, se ha creído interesante realizar una planificación sobre una zona que, hasta el momento, no está cubierta por cobertura LTE-Advanced. Además hay que tener en cuenta la naturaleza del terreno en el que trabajaremos, ya que se aleja del suelo urbano que encontramos en las principales ciudades con LTE-Advanced, como Madrid, Barcelona o Valencia. El estudio de esta zona semirural es de gran interés ya que uno de los objetivos de la cuarta generación es hacer llegar conexión a internet de calidad a lugares en los que no puede llegar la fibra óptica, como por ejemplo estas zonas semirurales. Para añadir aún más interés en el estudio, se ha decidido utilizar la banda de 800 MHz para el despliegue de la red. Esta banda que anteriormente era utilizada para la transmisión TDT, recientemente ha quedado liberada, en el conocido como Dividendo Digital para su uso en comunicaciones móviles. La tecnología LTE-Advanced se está empezando a desplegar en esta banda aunque realmente hasta Noviembre del año 2015 no tendremos un uso real de la misma, por lo que en estos momentos las redes 4G están utilizando la banda de 2.6 GHz. La utilización de la banda de 800 MHz conllevará mejoras tanto al usuario como a las operadoras, las cuales iremos viendo a lo largo del desarrollo del proyecto. La planificación pasará por distintas fases de optimización y expansión en las que se analizaran tanto la parte radioeléctrica como su capacidad. Se analizaran señales del tipo RSRP, RSSI o RSRQ y para el análisis de capacidad se definirá un conjunto de usuarios, distribuidos adecuadamente por toda la zona, que permitirá estudiar en detalle la capacidad de nuestra red. Para finalizar, se realizarán varias pruebas que demostrarán lo importante que es la tecnología MIMO tanto en LTE como en LTE-Advanced. ABSTRACT. Nowadays, our society is experiencing an intense pace of technological evolution which causes the constant development of new technologies. In the network planning area, these new technologies are focused on improving both quality and safety of service, with the recent deployment of 4G technologies in our networks. This project focuses on Spain, where the fourth generation of mobile communications is led by LTE, because LTE-Advanced has only been deployed in the largest cities, so far. The goal of this project is to plan, deploy and simulate LTE-Advanced network, of an area that hasn´t yet been covered. Furthermore, it will be taken into account the nature of the terrain where the network will be developed, as it moves away from urban areas in the major cities with LTE-Advanced, including Madrid, Barcelona and Valencia. The study of these semi-rural areas is extremely important because one of the main objectives of the fourth generation technologies is to get high-speed internet access to places that can be reached through other technologies, such as optical fiber. In order to adjust to the actual needs, the project was developed for the 800 MHz band. Those frequencies used to be assigned for digital terrestrial TV, but they have recently been released through the Digital Dividend in 2015 to use with mobile communications. That is the reason why, the LTE-Advanced technology in Spain is starting to be deployed in those frequencies. Despite the freeing of the 800 MHz band, it is not allowed to use it until November 2015, so 4G networks are currently using the 2.6 GHz band. The use of the 800 MHz band will led to advantages and improvements to users and operators, which will be detailed over the project. Each step of the planning of the 4G network is detailed. It is analyzed the optimization and expansion of the network, based on the radio and capacity premises. RSRP, RSSI or RSRQ signals were analyzed and an analysis of the network capacity was carried out. Finally, several tests are developed to show the importance of MIMO in LTE and LTE-Advanced.

Development in Rural Areas Through Capacity Building and Education for Business

This paper is based on a case study located in Avila, central Spain. Its main objectives are to implement an entrepreneurship program and design a plan of capacity building and education for business in order to promote the development of rural areas. The methodological approach of the program is based on the use of tools that permit involving the various actors of the area from the early planning stages. The university's group that is carrying out the field work has relied on these participatory tools in very different areas and contexts for over 25 years. This has allowed the development of an advanced planning model called ?Working With People? that connects expert and experience knowledge in the territories where it is applied. With this methodological approach, the diagnosis of the territory and the design of the program's strategy has been carried out. Once completed the first phase of the program and in order to ensure the sustainability and applicability of future entrepreneurial initiatives, it is necessary to support and strengthen potential entrepreneurs through training activities and capacity building. It relies on ?How to learn from people who live there? to promote investment projects and to teach them with adequate educational skills. In this context, this article aims to study the implementation strategy of these training and capacity building activities studied from an academic perspective, as well as analyzing the potential effects of these actions in promoting entrepreneurship in the territories