Biblio

During its nascent stages, Programmable Logic Controllers (PLC) were made robust to sustain tough industrial environments, but little care was taken to raise defenses against potential cyberthreats. The recent interconnectivity of legacy PLCs and SCADA systems with corporate networks and the internet has significantly increased the threats to critical infrastructure. To counter these threats, researchers have put their efforts in finding defense mechanisms that can protect the SCADA network and the PLCs. Encryption is a critical component of security and therefore has been used by many organizations to protect data on the network. However, since PLC vendors don't make available information about their hardware or software, it becomes challenging to embed encryption into their devices, especially if they rely on legacy protocols. This paper describes an alternative design using an open source PLC that was modified to encrypt all data it sends over the network, independently of the protocol used. Experimental results indicated that the encryption layer increased the security of the link without causing a significant overhead.

With an immense number of threats pouring in from nation states and hacktivists as well as terrorists and cybercriminals, the requirement of a globally secure infrastructure becomes a major obligation. Most critical infrastructures were primarily designed to work isolated from the normal communication network, but due to the advent of the "Smart Grid" that uses advanced and intelligent approaches to control critical infrastructure, it is necessary for these cyber-physical systems to have access to the communication system. Consequently, such critical systems have become prime targets; hence security of critical infrastructure is currently one of the most challenging research problems. Performing an extensive security analysis involving experiments with cyber-attacks on a live industrial control system (ICS) is not possible. Therefore, researchers generally resort to test beds and complex simulations to answer questions related to SCADA systems. Since all conclusions are drawn from the test bed, it is necessary to perform validation against a physical model. This paper examines the fidelity of a virtual SCADA testbed to a physical test bed and allows for the study of the effects of cyber- attacks on both of the systems.