Evolving dynamic self-adaptation policies of mHealth systems for long-term monitoring.

Tele-rehabilitation can complement traditional rehabilitation therapies by providing valuable information that can help in the evaluation, monitoring, and treatment of patients. Many patient tele-monitoring systems that integrate wearable technology are emerging as an effective tool for the long-term surveillance of rehabilitation progression, enabling continuous sampling of patient real-time movement in a non-invasive way, without affecting the normal daily activity of the outpatient, who, therefore, will not need to make frequent clinic visits. One of the main challenges of tele-rehabilitation systems is to pay special attention to the diversity of dysfunctions in patients by offering devices with customized behaviours adaptable to the physical conditions of each patient at the different stages of the rehabilitation therapy. Long-term monitoring systems need an adaptation policy to autonomously reconfigure their behaviour according to vital signs read during the physical activity of the patient, the remaining battery level, or the required accuracy of collected data. However, it would alsobe desirable to adjust such adaptation policies over time, according to the patient's evolution. This work presents a wearable patient-monitoring system for tele-rehabilitation that is able to dynamically self-configure its internal behaviour to the current context of the outpatient according to a set of adaptation policies that optimize battery consumption, taking into account other QoS parameters at the same time. Our system is also able to self-adapt its internal adaptation policies as a patient's condition improves, while maintaining the system's efficiency. We illustrate our proposal with a real mHealth case study. The results of the experiments show that the system updates the adaptation policies, taking into account specific indicators of the disease. The validation results show that the evolution of the self-adaptation policies correlates with the progression of different patients.

A Software Product Line Process to Develop Agents for the IoT.

One of the most important challenges of this decade is the Internet of Things (IoT), which aims to enable things to be connected anytime, anyplace, with anything and anyone, ideally using any path/network and any service. IoT systems are usually composed of heterogeneous and interconnected lightweight devices that support applications that are subject to change in their external environment and in the functioning of these devices. The management of the variability of these changes, autonomously, is a challenge in the development of these systems. Agents are a good option for developing self-managed IoT systems due to their distributed nature, context-awareness and self-adaptation. Our goal is to enhance the development of IoT applications using agents and software product lines (SPL). Specifically, we propose to use Self-StarMASMAS, multi-agent system) agents and to define an SPL process using the Common Variability Language. In this contribution, we propose an SPL process for Self-StarMAS, paying particular attention to agents embedded in sensor motes.

Dynamic reconfiguration of security policies in wireless sensor networks.

Providing security and privacy to wireless sensor nodes (WSNs) is very challenging, due to the heterogeneity of sensor nodes and their limited capabilities in terms of energy, processing power and memory. The applications for these systems run in a myriad of sensors with different low-level programming abstractions, limited capabilities and different routing protocols. This means that applications for WSNs need mechanisms for self-adaptation and for self-protection based on the dynamic adaptation of the algorithms used to provide security. Dynamic software product lines (DSPLs) allow managing both variability and dynamic software adaptation, so they can be considered a key technology in successfully developing self-protected WSN applications. In this paper, we propose a self-protection solution for WSNs based on the combination of the INTER-TRUST security framework (a solution for the dynamic negotiation and deployment of security policies) and the FamiWare middleware (a DSPL approach to automatically configure and reconfigure instances of a middleware for WSNs).We evaluate our approach using a case study from the intelligent transportation system domain.

iMuseumA: an agent-based context-aware intelligent museum system.

Currently, museums provide their visitors with interactive tour guide applications that can be installed in mobile devices and provide timely tailor-made multimedia information about exhibits on display. In this paper, we argue that mobile devices not only could provide help to visitors, but also to museum staff. Our goal is to integrate, within the same system, multimedia tour guides with the management facilities required by museums. In this paper, we present iMuseumA (intelligent museum with agents), a mobile-based solution to customize visits and perform context-aware management tasks. iMuseumA follows an agent-based approach, which makes it possible to interact easily with the museum environment and make decisions based on its current status. This system is currently deployed in the Museum of Informatics at the Informatics School of the University of Málaga, and its main contributions are: (i) a mobile application that provides management facilities to museum staff by means of sensing and processing environmental data; (ii) providing an integrated solution for visitors, tour guides and museum staff that allows coordination and communication enrichment among different groups of users; (iii) using and benefiting from group communication for heterogeneous groups of users that can be created on demand.