ASSESSING AND IMPROVING SECURITY AWARENESS AND CONCERNS IN TELEWORKING

Biliangyu Wu (10716789)

29 April 2021

<p>The unexpected and unprecedented global pandemic of COVID-19 has brought dramatic changes to the whole world. As a result of social distancing instituted to slow the pandemic, teleworking has become the new norm in many organizations. The prevalence of teleworking has brought not only benefits to organizations, but also security risks. Although teleworking has existed for decades and many security related issues have been studied by previous research, the researcher didn’t find any studies that have assessed organization employee’s security awareness and concerns in teleworking. Considering the vital importance of human security awareness in protecting information security, it is necessary to learn the security awareness situation in teleworking. Furthermore, employees with low security awareness should be trained to improve the awareness level. Therefore, this research intends to examine the current teleworking security awareness and concerns in organizations by conducting a survey of workers. Through the survey answers, the researcher found that the security awareness varies in groups of teleworkers who are at different ages, from different industries and different-sized organizations. Meanwhile, the researcher also found that COVID-19 pandemic does not have much impact on people’s security concern in teleworking scenarios. <br></p>

Computer System Security

Private Policing and Security Services

Teleworking

Security Awareness

Assessment

Security Concern

Deep Learning Based Models for Cognitive Autonomy and Cybersecurity Intelligence in Autonomous Systems

Ganapathy Mani (8840606)

21 June 2022

Cognitive autonomy of an autonomous system depends on its cyber module's ability to comprehend the actions and intent of the applications and services running on that system. The autonomous system should be able to accomplish this without or with limited human intervention. These mission-critical autonomous systems are often deployed in unpredictable and dynamic environments and are vulnerable to evasive cyberattacks. In particular, some of these cyberattacks are Advanced Persistent Threats where an attacker conducts reconnaissance for a long period time to ascertain system features, learn system defenses, and adapt to successfully execute the attack while evading detection. Thus an autonomous system's cognitive autonomy and cybersecurity intelligence depend on its capability to learn, classify applications (good and bad), predict the attacker's next steps, and remain operational to carryout the mission-critical tasks even under cyberattacks. In this dissertation, we propose novel learning and prediction models for enhancing cognitive autonomy and cybersecurity in autonomous systems. We develop (1) a model using deep learning along with a model selection framework that can classify benign and malicious operating contexts of a system based on performance counters, (2) a deep learning based natural language processing model that uses instruction sequences extracted from the memory to learn and profile the behavior of evasive malware, (3) a scalable deep learning based object detection model with data pre-processing assisted by fuzzy-based clustering, (4) fundamental guiding principles for cognitive autonomy using Artificial Intelligence (AI), (5) a model for privacy-preserving autonomous data analytics, and finally (6) a model for backup and replication based on combinatorial balanced incomplete block design in order to provide continuous availability in mission-critical systems. This research provides effective and computationally efficient deep learning based solutions for detecting evasive cyberattacks and increasing autonomy of a system from application-level to hardware-level. <br>

Private policing and security services

Knowledge representation and reasoning

Pattern recognition

System and network security

Data mining and knowledge discovery

Artificial Intelligence

Cybersecurity

Deep Learning

Machine Learning

Cryptomining

Cryptojacking

Natural Language Processing

Malware

Combinatorics

Autonomous Systems

Cognitive Autonomy

Applied Computer Science

Computer System Security

Private Policing and Security Services

Pattern Recognition and Data Mining

USING REINFORCEMENT LEARNING FOR ACTIVE SHOOTER MITIGATION

Robert Eugen Bott (11791199)

20 December 2021

This dissertation investigates the value of deep reinforcement learning (DRL) within an agent-based model (ABM) of a large open-air venue. The intent is to reduce civilian casualties in an active shooting incident (ASI). There has been a steady increase of ASIs in the United States of America for over 20 years, and some of the most casualty-producing events have been in open spaces and open-air venues. More research should be conducted within the field to help discover policies that can mitigate the threat of a shooter in extremis. This study uses the concept of dynamic signage, controlled by a DRL policy, to guide civilians away from the threat and toward a safe exit in the modeled environment. It was found that a well-trained DRL policy can significantly reduce civilian casualties as compared to baseline scenarios. Further, the DRL policy can assist decision makers in determining how many signs to use in an environment and where to place them. Finally, research using DRL in the ASI space can yield systems and policies that will help reduce the impact of active shooters during an incident.

Computer Software

Autonomous Vehicles

Simulation and Modelling

Private Policing and Security Services

Active shooter

Active shooting incident

Modeling and Simulation (M&S)

Machine Learning

reinforcement learning

Homeland security

AnyLogic

Pathmind

Mass casualty incidents

mass casualty scenarios

Outdoor Venues

Open-air venues

Open spaces

active shooter mitigation

uav

shooter detection

dynamic signage