Sistema pericial para auditoria de registos clínicos

O registo clinico é um documento hospitalar confidencial, nele é registado todo o percurso clinico de um determinado paciente. Esse percurso é registado através da atribuição de códigos descritos num sistema de classificação, também denominados de dados da codificação. Os dados da codificação são armazenados electronicamente numa Base de Dados, e é a partir dela que certas medidas, tais como facturação hospitalar, financiamentos hospitalares anuais, tratamentos médicos, ou até mesmo dados epidemiológicos, são adotadas. Portanto torna-se fundamental a garantia da qualidade na área da codificação clinica, para isso é necessário recorrer a processos de auditorias aos registos clínicos. O processo de auditoria é uma atividade independente de avaliação, cujo objetivo visa acrescentar valor e melhorar os objetos e processos da auditoria. Atualmente uma ferramenta denominada de Programa Auditor é utilizada, contudo essa ferramenta demonstra uma tecnologia já ultrapassada. A Tese que se pretende defender é a de que, através de Sistemas Periciais, é possível realizar auditorias internas aos registos clínicos. Pretende-se ainda demonstrar que dos Sistemas Periciais e um benefício para os peritos na área, pois diminui a probabilidade de erros e torna o processo de verificação menos moroso. Neste contexto, o objetivo desta Dissertação prende-se em definir e implementar um Sistema Pericial que permita a auditoria de registos clínicos hospitalares. O Sistema Pericial dever a ainda ser capaz de traduzir o raciocínio do perito, detectando assim diversos tipos de erros que traduzem num registo clínico não conforme. Por sua vez, foi desenvolvido um protótipo de um Sistema Pericial para auditoria de registos clínicos em linguagem PROLOG. Este mesmo protótipo serviu de base à realização de uma experiência que permitiu comparar com o programa Auditor e verificar a sua aplicabilidade no dia-a-dia hospitalar.

Fractional Dynamics of Computer Virus Propagation

We propose a fractional model for computer virus propagation. The model includes the interaction between computers and removable devices. We simulate numerically the model for distinct values of the order of the fractional derivative and for two sets of initial conditions adopted in the literature. We conclude that fractional order systems reveal richer dynamics than the classical integer order counterpart. Therefore, fractional dynamics leads to time responses with super-fast transients and super-slow evolutions towards the steady-state, effects not easily captured by the integer order models.

Fractional State Space Analysis of Temperature Time Series

Atmospheric temperatures characterize Earth as a slow dynamics spatiotemporal system, revealing long-memory and complex behavior. Temperature time series of 54 worldwide geographic locations are considered as representative of the Earth weather dynamics. These data are then interpreted as the time evolution of a set of state space variables describing a complex system. The data are analyzed by means of multidimensional scaling (MDS), and the fractional state space portrait (fSSP). A centennial perspective covering the period from 1910 to 2012 allows MDS to identify similarities among different Earth’s locations. The multivariate mutual information is proposed to determine the “optimal” order of the time derivative for the fSSP representation. The fSSP emerges as a valuable alternative for visualizing system dynamics.

Quality-of-service aware routing for static and mobile IPv6-based low-power and lossy sensor networks using RPL

The Internet of Things (IoT) has emerged as a paradigm over the last few years as a result of the tight integration of the computing and the physical world. The requirement of remote sensing makes low-power wireless sensor networks one of the key enabling technologies of IoT. These networks encompass several challenges, especially in communication and networking, due to their inherent constraints of low-power features, deployment in harsh and lossy environments, and limited computing and storage resources. The IPv6 Routing Protocol for Low Power and Lossy Networks (RPL) [1] was proposed by the IETF ROLL (Routing Over Low-power Lossy links) working group and is currently adopted as an IETF standard in the RFC 6550 since March 2012. Although RPL greatly satisfied the requirements of low-power and lossy sensor networks, several issues remain open for improvement and specification, in particular with respect to Quality of Service (QoS) guarantees and support for mobility. In this paper, we focus mainly on the RPL routing protocol. We propose some enhancements to the standard specification in order to provide QoS guarantees for static as well as mobile LLNs. For this purpose, we propose OF-FL (Objective Function based on Fuzzy Logic), a new objective function that overcomes the limitations of the standardized objective functions that were designed for RPL by considering important link and node metrics, namely end-to-end delay, number of hops, ETX (Expected transmission count) and LQL (Link Quality Level). In addition, we present the design of Co-RPL, an extension to RPL based on the corona mechanism that supports mobility in order to overcome the problem of slow reactivity to frequent topology changes and thus providing a better quality of service mainly in dynamic networks application. Performance evaluation results show that both OF-FL and Co-RPL allow a great improvement when compared to the standard specification, mainly in terms of packet loss ratio and average network latency. 2015 Elsevier B.V. Al