Biblio

Critical infrastructures such as the electricity grid can be severely impacted by cyber-attacks on its supply chain. Hence, having a robust cybersecurity infrastructure and management system for the electricity grid is a high priority. This paper proposes a cyber-security protocol for defense against man-in-the-middle (MiTM) attacks to the supply chain, which uses encryption and cryptographic multi-party authentication. A cyber-physical simulator is utilized to simulate the power system, control system, and security layers. The correctness of the attack modeling and the cryptographic security protocol against this MiTM attack is demonstrated in four different attack scenarios.

A detailed model of an attack on the power grid involves both a preparation stage as well as an execution stage of the attack. This paper introduces a novel Hybrid Attack Model (HAM) that combines Probabilistic Learning Attacker, Dynamic Defender (PLADD) model and a Markov Chain model to simulate the planning and execution stages of a bad data injection attack in power grid. We discuss the advantages and limitations of the prior work models and of our proposed Hybrid Attack Model and show that HAM is more effective compared to individual PLADD or Markov Chain models.

This paper surveys some prior work regarding attack models in a cyber-physical system and discusses the potential benefits. For comparison, the full paper will model a bad data injection attack scenario in power grid using the surveyed prior work.

In this demo, we present an immersive virtual reality (VR) system which integrates multimodal interaction sensors (i.e., smartphone, Kinect v2, and Myo armband) and streaming technology to improve the VR experience. The integrated system solves the common problems in most VR systems: (1) the very limited playing area due to transmission cable between computer and display/interaction devices, and (2) non-intuitive way of controlling virtual objects. We use Unreal Engine 4 to develop an immersive VR game with 6 interactive levels to demonstrate the feasibility of our system. In the game, the user not only can freely walk within a large playing area surrounded by multiple Kinect sensors but also select the virtual objects to grab and throw with the Myo armband. The experiment shows that our idea is workable for VR experience.