Measurements and Prediction of Pedestrian Walking Loads on an Aluminium Catwalk

During the last two decades the topic of human induced vibration has attracted a lot of attention among civil engineering practitioners and academics alike. Usually this type of problem may be encountered in pedestrian footbridges or floors of paperless offices. Slender designs are becoming increasingly popular, and as a consequence, the importance of paying attention to vibration serviceability also increases. This paper resumes the results obtained from measurements taken at different points of an aluminium catwalk which is 6 m in length by 0.6 m in width. Measurements were carried out when subjecting the structure to different actions:1)Static test: a steel cylinder of 35 kg was placed in the middle of the catwalk; 2)Dynamic test: this test consists of exciting the structure with singles impulses; 3)Dynamic test: people walking on the catwalk. Identification of the mechanical properties of the structure is an achievement of the paper. Indirect methods were used to estimate properties including the support stiffness, the beam bending stiffness, the mass of the structure (using Rayleigh method and iterative matrix method), the natural frequency (using the time domain and frequency domain analysis) and the damping ratio (by calculating the logarithmic decrement). Experimental results and numerical predictions for the response of an aluminium catwalk subjected to walking loads have been compared. The damping of this light weight structure depends on the amplitude of vibration which complicates the tuning of a structural model. In the light of the results obtained it seems that the used walking load model is not appropriate as the predicted transient vibration values (TTVs) are much higher than the measured ones.

Desarrollo de un modelo de riesgo de colisión en espacios aéreos de área terminal

El transporte aéreo es un sector estratégico para el crecimiento económico de cualquier país. La estabilidad y el desarrollo de este modo de transporte tienen un pilar fundamental en una operación segura, especialmente cuando las previsiones indican escenarios de crecimiento continuo del tráfico aéreo. La estimación del riesgo y, por tanto, del nivel de seguridad de un entorno operativo se ha basado en métodos indirectos como puede ser la cuantificación y análisis de los reportes voluntarios de incidentes o el uso de modelos de riesgo de colisión enfocados a escenarios operativos parciales, como puede ser un espacio aéreo oceánico. La operación en un área terminal de maniobra es compleja, con distintos flujos de tráfico de arribada y salida a uno o varios aeropuertos, con cambios frecuentes en el rumbo y velocidad de las aeronaves y con instrucciones tácticas del control de tráfico aéreo para secuenciar y separar las aeronaves El objetivo de la presente Tesis es complementar los actuales métodos de monitorización de la seguridad que presentan sus limitaciones, con el desarrollo de un modelo de riesgo de colisión para áreas terminales de alta densidad que se base en datos objetivos como son las trazar radar de las aeronaves y que tenga en cuenta la complejidad de la operación en un área terminal. Para evaluar el modelo desarrollado se ha implementado una herramienta prototipo en MATLAB© que permite procesar un número masivo de trazar radar para un escenario de área terminal y calcular un valor del riesgo de colisión para el escenario analizado. El prototipo ha sido utilizado para estimar la probabilidad de colisión para distintos escenarios del área terminal de Madrid. El uso de trazas radar permite monitorizar el nivel de riesgo de escenarios reales de manera periódica estableciendo niveles de alerta temprana si se detecta que el valor de riesgo se desvía en exceso, pero también permite evaluar el nivel de riesgo de diseños de espacio aéreo o de nuevos modos de operación a partir de las trazas radar obtenidas en las simulaciones en tiempo real o acelerado y actuar en fases tempranas de los proyectos. ABSTRACT The air transport is a strategic sector for the economic growth of any country. The stability and development of the transport mode have a fundamental pillar in a safe operation, especially when long-term forecasts show scenarios of continuous growth in air traffic. Risk estimation and therefore the level of safety in an operational airspace has been based on indirect methods such as the quantification and analysis of voluntary reports of safety incidents or use of collision risk models focused on partial or simple operational scenarios such as an oceanic airspace. The operation on a terminal maneuvering area is complex, with different traffic flows of arrival and departure at one or more airports, with frequent changes in direction and speed of aircraft and tactical instructions of air traffic control to sequence and separate aircraft. The objective of this Thesis is to complement existing methods of monitoring safety that have their limitations, with the development of a collision risk model for high-density terminal areas that is based on objective data such as aircraft radar tracks and taking into account the complexity of the operation in a terminal area. To evaluate the developed model a prototype tool was implemented with MATLAB© that can process massive numbers of radar tracks for a terminal area scenario and computing a collision risk value for that scenario. The prototype has been used to estimate the probability of collision for different scenarios of the terminal area of Madrid. The use of radar tracks allows to monitor the level of risk of real scenarios periodically establishing levels of early warning when the risk value deviates too much, but also to assess the risk level of airspace designs or modes of operations from the radar tracks obtained in real or fast time simulations and act in the early stages of projects.

Comparison of methods for downscaling runoff from regional climate models in Spanish basins

At present there is much literature that refers to the advantages and disadvantages of different methods of statistical and dynamical downscaling of climate variables projected by climate models. Less attention has been paid to other indirect variables, like runoff, which play a significant role in evaluating the impact of climate change on hydrological systems. Runoff presents a much greater bias in climate models than other climate variables, like temperature or precipitation. It is very important to identify the methods that minimize bias while downscaling runoff from the gridded results of climate models to the basin scale