How to break access control in a controlled manner

The Electronic Medical Record (EMR) integrates heterogeneous information within a Healthcare Institution stressing the need for security and access control. The Biostatistics and Medical Informatics Department from Porto Faculty of Medicine has recently implemented a Virtual EMR (VEMR) in order to integrate patient information and clinical reports within a university hospital. With more than 500 medical doctors using the system on a daily basis, an access control policy and model were implemented. However, the healthcare environment has unanticipated situations (i.e. emergency situations) where access to information is essential. Most traditional policies do not allow for overriding. A policy that allows for Break-The-Glass (BTG) was implemented in order to override access control whilst providing for non-repudiation mechanisms for its usage. The policy was easily integrated within the model confirming its modularity and the fact that user intervention in defining security procedures is crucial to its successful implementation and use

Access Control Within MQTT-based IoT environments

IoT applications, which allow devices, companies, and users to join the IoT ecosystems, are growing in popularity since they increase our lifestyle quality day by day. However, due to the personal nature of the managed data, numerous IoT applications represent a potential threat to user privacy and data confidentiality. Insufficient security protection mechanisms in IoT applications can cause unauthorized users to access data. To solve this security issue, the access control systems, which guarantee only authorized entities to access the resources, are proposed in academic and industrial environments. The main purpose of access control systems is to determine who can access specific resources under which circumstances via the access control policies. An access control model encapsulates the defined set of access control policies. Access control models have been proposed also for IoT environments to protect resources from unauthorized users. Among the existing solutions, the proposals which are based on Attribute-Based Access Control (ABAC) model, have been widely adopted in the last years. In the ABAC model, authorizations are determined by evaluating attributes associated with the subject, object, and environmental properties. ABAC model provides outstanding flexibility and supports fine-grained, context-based access control policies. These characteristics perfectly fit the IoT environments. In this thesis, we employ ABAC to regulate the reception and the publishing of messages exchanged within MQTT-based IoT environments. MQTT is a standard application layer protocol that enables the communication of IoT devices. Even though the current access control systems tailored for IoT environments in the literature handle data sharing among the IoT devices by employing various access control models and mechanisms to address the challenges that have been faced in IoT environments, surprisingly two research challenges have still not been sufficiently examined. The first challenge that we want to address in this thesis is to regulate data sharing among interconnected IoT environments. In interconnected IoT environments, data exchange is carried out by devices connected to different environments. The majority of proposed access control frameworks in the literature aimed at regulating the access to data generated and exchanged within a single IoT environment by adopting centralized enforcement mechanisms. However, currently, most of the IoT applications rely on IoT devices and services distributed in multiple IoT environments to satisfy users’ demands and improve their functionalities. The second challenge that we want to address in this thesis is to regulate data sharing within an IoT environment under ordinary and emergency situations. Recent emergencies, such as the COVID-19 pandemic, have shown that proper emergency management should provide data sharing during an emergency situation to monitor and possibly mitigate the effect of the emergency situation. IoT technologies provide valid support to the development of efficient data sharing and analysis services and appear well suited for building emergency management applications. Additionally, IoT has magnified the possibility of acquiring data from different sensors and employing these data to detect and manage emergencies. An emergency management application in an IoT environment should be complemented with a proper access control approach to control data sharing against unauthorized access. In this thesis, we do a step to address two open research challenges related to data protection in IoT environments which are briefly introduced above. To address these challenges, we propose two access control frameworks rely on ABAC model: the first one regulates data sharing among interconnected MQTT-based IoT environments, whereas the second one regulates data sharing within MQTT-based IoT environment during ordinary and emergency situations.IoT applications, which allow devices, companies, and users to join the IoT ecosystems, are growing in popularity since they increase our lifestyle quality day by day. However, due to the personal nature of the managed data, numerous IoT applications represent a potential threat to user privacy and data confidentiality. Insufficient security protection mechanisms in IoT applications can cause unauthorized users to access data. To solve this security issue, the access control systems, which guarantee only authorized entities to access the resources, are proposed in academic and industrial environments. The main purpose of access control systems is to determine who can access specific resources under which circumstances via the access control policies. An access control model encapsulates the defined set of access control policies. Access control models have been proposed also for IoT environments to protect resources from unauthorized users. Among the existing solutions, the proposals which are based on Attribute-Based Access Control (ABAC) model, have been widely adopted in the last years. In the ABAC model, authorizations are determined by evaluating attributes associated with the subject, object, and environmental properties. ABAC model provides outstanding flexibility and supports fine-grained, context-based access control policies. These characteristics perfectly fit the IoT environments. In this thesis, we employ ABAC to regulate the reception and the publishing of messages exchanged within MQTT-based IoT environments. MQTT is a standard application layer protocol that enables the communication of IoT devices. Even though the current access control systems tailored for IoT environments in the literature handle data sharing among the IoT devices by employing various access control models and mechanisms to address the challenges that have been faced in IoT environments, surprisingly two research challenges have still not been sufficiently examined. The first challenge that we want to address in this thesis is to regulate data sharing among interconnected IoT environments. In interconnected IoT environments, data exchange is carried out by devices connected to different environments. The majority of proposed access control frameworks in the literature aimed at regulating the access to data generated and exchanged within a single IoT environment by adopting centralized enforcement mechanisms. However, currently, most of the IoT applications rely on IoT devices and services distributed in multiple IoT environments to satisfy users’ demands and improve their functionalities. The second challenge that we want to address in this thesis is to regulate data sharing within an IoT environment under ordinary and emergency situations. Recent emergencies, such as the COVID-19 pandemic, have shown that proper emergency management should provide data sharing during an emergency situation to monitor and possibly mitigate the effect of the emergency situation. IoT technologies provide valid support to the development of efficient data sharing and analysis services and appear well suited for building emergency management applications. Additionally, IoT has magnified the possibility of acquiring data from different sensors and employing these data to detect and manage emergencies. An emergency management application in an IoT environment should be complemented with a proper access control approach to control data sharing against unauthorized access. In this thesis, we do a step to address two open research challenges related to data protection in IoT environments which are briefly introduced above. To address these challenges, we propose two access control frameworks rely on ABAC model: the first one regulates data sharing among interconnected MQTT-based IoT environments, whereas the second one regulates data sharing within MQTT-based IoT environment during ordinary and emergency situations

Towards a Pervasive Access Control within Video Surveillance Systems

Part 1: Cross-Domain Conference and Workshop on Multidisciplinary Research and Practice for Information Systems (CD-ARES 2013)International audienceThis paper addresses two emerging challenges that multimedia distributed systems have to deal with: the user’s constant mobility and the information’s sensitivity. The systems have to adapt, in real time, to the user’s context and situation in order to provide him with relevant results without breaking the security and privacy policies. Distributed multimedia systems, such as the oneproposed by the LINDO project, do not generally consider both issues. In this paper, we apply an access control layer on top of the LINDO architecture that takes into consideration the user’s context and situation and recommends alternative resources to the user when he is facing an important situation. The proposed solution was implemented and tested in a video surveillance use case

Access Control In and For the Real World

Access control is a core component of any information-security strategy. Researchers have spent tremendous energy over the past forty years defining abstract access-control models and proving various properties about them. However, surprisingly little attention has been paid to how well these models work in real socio-technical systems (i.e., real human organizations). This dissertation describes the results of two qualitative studies (involving 52 participants from four companies, drawn from the financial, software, and healthcare sectors) and observes that the current practice of access control is dysfunctional at best. It diagnoses the broken assumptions that are at the heart of this dysfunction, and offers a new definition of the access-control problem that is grounded in the requirements and limitations of the real world