An indirect numerical method for a time-optimal state-constrained control problem in a steady two-dimensional fluid flow

This article concerns the problem of computing solutions to state-constrained optimal control problems whose trajectory is affected by a flow field. This general mathematical framework is particularly pertinent to the requirements underlying the control of Autonomous Underwater Vehicles in realistic scenarii. The key contribution consists in devising a computational indirect method which becomes effective in the numerical computation of extremals to optimal control problems with state constraints by using the maximum principle in Gamkrelidze's form in which the measure Lagrange multiplier is ensured to be continuous. The specific problem of time-optimal control of an Autonomous Underwater Vehicle in a bounded space set, subject to the effect of a flow field and with bounded actuation, is used to illustrate the proposed approach. The corresponding numerical results are presented and discussed

A comparative Long-memory Analysis between Spanish, Mexican and U.S. interest rates

Evidence exists that many natural facts are described better as a fractal. Although fractals are very useful for describing nature, it is also appropiate to review the concept of random fractal in finance. Due to the extraordinary importance of Brownian motion in physics, chemistry or biology, we will consider the generalization that supposes fractional Brownian motion introduced by Mandelbrot. The main goal of this work is to analyse the existence of long range dependence in instantaneous forward rates of different financial markets. Concretelly, we perform an empirical analysis on the Spanish, Mexican and U.S. interbanking interest rate. We work with three time series of daily data corresponding to 1 day operations from 28th March 1996 to 21st May 2002. From among all the existing tests on this matter we apply the methodology proposed in Taqqu, Teverovsky and Willinger (1995).fractional brownian motion., long-memory processes, interest rate analysis

Fixing news deserts, the public radio way

Professional project report submitted in partial fulfillment of the requirements for the degree of Masters of Arts in Journalism from the School of Journalism, University of Missouri--Columbia.As the journalism crisis deepens, cross-newsroom collaborations have become more common in recent years. These projects offer news outlets the possibility of sharing resources with each other to create original reporting that would otherwise be too costly or difficult for a sinlge entity to produce. This study examines how one collaborative project in the American South is attempting to fix 'news deserts' by creating a regional newsroom integrated by National Public Radio and several of its affiliated member stations, the challenges they overcame to get the collaboraton started, and the ways in which they are measuring success and trying to ensure its sustainability

Simulation of a solar funnel cooker using MATLAB

A software for the calculation of the radiation heat transfer in solar funnel cookers by means of the radiosity method has been developed in Matlab. The software has been used to study a folding solar cooker. The cooker geometry is discretized using a triangular mesh where a piecewise constant approximation is assumed for the radiosity function. Form factors, including self-occlusions, are calculated by properly refining the triangular mesh. The concentration factor of the solar cooker is estimated as a function of its position and orientation with respect to that of the Sun.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Thick-restarted joint Lanczos bidiagonalization for the GSVD

The computation of the partial generalized singular value decomposition (GSVD) of large-scale matrix pairs can be approached by means of iterative methods based on expanding subspaces, particularly Krylov subspaces. We consider the joint Lanczos bidiagonalization method, and analyze the feasibility of adapting the thick restart technique that is being used successfully in the context of other linear algebra problems. Numerical experiments illustrate the effectiveness of the proposed method. We also compare the new method with an alternative solution via equivalent eigenvalue problems, considering accuracy as well as computational performance. The analysis is done using a parallel implementation in the SLEPc library

Universal features of entanglement entropy in the honeycomb Hubbard model

The entanglement entropy is a unique probe to reveal universal features of strongly interacting many-body systems. In two or more dimensions these features are subtle, and detecting them numerically requires extreme precision, a notoriously difficult task. This is especially challenging in models of interacting fermions, where many such universal features have yet to be observed. In this paper we tackle this challenge by introducing a new method to compute the R\'enyi entanglement entropy in auxiliary-field quantum Monte Carlo simulations, where we treat the entangling region itself as a stochastic variable. We demonstrate the efficiency of this method by extracting, for the first time, universal subleading logarithmic terms in a two dimensional model of interacting fermions, focusing on the honeycomb Hubbard model at $T=0$. We detect the universal corner contribution due to gapless fermions throughout the Dirac semi-metal phase and at the Gross-Neveu-Yukawa critical point, as well as the universal Goldstone mode contribution in the antiferromagnetic Mott insulating phase

Desarrollo de librerías de firma ciega para OpenSSL

OpenSSL is a cryptographic suite that was initially aimed at providing an implementation of the Transport Layer Security (TLS) and Secure Sockets Layer (SSL) protocols; although has now become a cryptographic suite with a much broader scope. OpenSSL is intended to be used as a library, it's open source and it's developed by a worldwide community of volunteers. Today, OpenSSL incorporates many of the "classic" security mechanisms, mainly related to provide authentication and confidentiality. However, these mechanisms are not sufficient to deal with other more-complex security challenges, especially those related to privacy and anonymity, which require new specific mechanisms. The main objective of this TFG is the implementation of one of these mechanisms, the blind signature, for OpenSSL. This particular type of signature allows the signer to sign a message without actually knowing its contents. The fact of developing this TFG within the OpenSSL umbrella is an added motivation to the authors since OpenSSL is probably the most important and widely-use cryptographic suite. Another objective of this TFG is the implementation of an electronic currency system that uses the proposed blind-signature library for OpenSSL. This system acts as a proof of proper performance of this library. As a result of the work done, we have got a fully functional library that allows the generation of a valid signature without knowing the contents of the message to be signed. Furthermore, we have deployed an electronic currency system that makes proper use of the provided OpenSSL blind-signature libraries.OpenSSL es una suite criptográfica inicialmente dedicada a proveer una implementación de los protocolos Transport Layer Security (TLS) y Secure Sockets Layer (SSL), pero que actualmente se ha convertido en una suite criptográfica de carácter generalista. OpenSSL está pensado para poder ser utilizado como librería, su código es abierto y está desarrollado por voluntarios

Effects of locally generated wind waves on the momentum budget and subtidal exchange in a coastal plain estuary

Author Posting. © American Geophysical Union, 2019. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research-Oceans 124(2), (2019):1005-1028, doi:10.1029/2018JC014585.A numerical model with a vortex force formalism is used to study the role of wind waves in the momentum budget and subtidal exchange of a shallow coastal plain estuary, Delaware Bay. Wave height and age in the bay have a spatial distribution that is controlled by bathymetry and fetch, with implications for the surface drag coefficient in young, underdeveloped seas. Inclusion of waves in the model leads to increases in the surface drag coefficient by up to 30% with respect to parameterizations in which surface drag is only a function of wind speed, in agreement with recent observations of air‐sea fluxes in estuaries. The model was modified to prevent whitecapping wave dissipation from generating breaking forces since that contribution is integrally equivalent to the wind stress. The proposed adjustment is consistent with previous studies of wave‐induced nearshore currents and with additional parameterizations for breaking forces in the model. The mean momentum balance during a simulated wind event was mainly between the pressure gradient force and surface stress, with negligible contributions by vortex, wave breaking (i.e., depth‐induced), and Stokes‐Coriolis forces. Modeled scenarios with realistic Delaware bathymetry suggest that the subtidal bay‐ocean exchange at storm time scales is sensitive to wave‐induced surface drag coefficient, wind direction, and mass transport due to the Stokes drift. Results herein are applicable to shallow coastal systems where the typical wave field is young (i.e., wind seas) and modulated by bathymetry.This work was supported by National Science Foundation Coastal SEES grant 1325136. We acknowledge Christopher Sommerfield's Group, Jia‐Lin Chen, and Julia Levin who provided assistance with the model configuration. We also thank Nirnimesh Kumar, Greg Gerbi, Melissa Moulton, and the Rutgers Ocean Modeling group for constructive feedback. Insightful comments by two anonymous reviewers helped improve the manuscript. Model files are available in an open access repository (https://doi.org/10.5281/zenodo.1695900).2019-07-2