| dc.description.abstract | The industrial control system (ICS) refers to a collection of various types of control systems commonly found in industrial sectors and critical infrastructures such as energy, oil and gas, transportation, and manufacturing. The supervisory control and data acquisition (SCADA) system is a type of ICS that controls and monitors operations and industrial
processes scattered across a large geographic area.
SCADA systems are relying on information and communication technology to improve the efficiency of operations. This integration means that SCADA systems are targeted by the same threats and vulnerabilities that affect ICT assets. This means that the cybersecurity problem in SCADA system is exacerbated by the IT heritage issue. If the control system is compromised due to this connection, serious consequences may follow. This leads to the necessity to have an integrated framework that covers both safety and security risk analysis in this context.
This thesis proposes an integrated risk analysis framework that comprise of four stages, and that build on the advances of risk science and industry standards, to improve understanding of SCADA system complexity, and manage risks considering process safety and cybersecurity in a holistic approach.
The suggested framework is committed to improving safety and security risk analysis by examining the expected consequences through integrated risk identifications and identifying adequate safeguards and countermeasures to defend cyber-attack scenarios. A simplified SCADA system and an undesirable scenario of overpressure in the pipeline are presented in which the relevant stages of the framework are applied. | |
