Securing industrial control systems: Developing a SCADA/IoT test bench and evaluating lightweight cipher performance on hardware simulator

IF 4.1 3区工程技术 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

International Journal of Critical Infrastructure Protection Pub Date : 2024-08-23 DOI:10.1016/j.ijcip.2024.100705

Darshana Upadhyay , Sagarika Ghosh , Hiroyuki Ohno , Marzia Zaman , Srinivas Sampalli

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引用次数: 0

Abstract

This paper addresses the critical need for enhancing security in Supervisory Control and Data Acquisition (SCADA) networks within Industrial Control Systems (ICSs) to protect the industrial processes from cyber-attacks. The purpose of our work is to propose and evaluate lightweight security measures to safeguard critical infrastructure resources. The scope of our effort involves simulating a secure SCADA/IoT-based hardware test bench for ICSs, utilizing Modbus and MQTT communication protocols. Through case studies in remote servo motor control, water distribution systems, and power system voltage level indicators, vulnerabilities such as Denial of Service (DoS) and Man-in-The-Middle (MiTM) attacks are identified, and security recommendations are provided. To execute our work, we deploy lightweight ciphers such as Prime Counter & Hash Chaining (PCHC) and Ascon algorithm with Compression Rate (ACR) for secure information exchange between the plant floor and the control center. Evaluation of these ciphers on Raspberry Pi focuses on execution speed and memory utilization. Additionally, a comparison with the AGA-12 protocol standard for SCADA networks is conducted to underscore the efficacy of the proposed security measures. Our findings include the identification of SCADA network vulnerabilities and the proposal of lightweight security measures to mitigate risks. Performance evaluation of the proposed ciphers on Raspberry Pi demonstrates their effectiveness, emphasizing the importance of deploying such measures to ensure resilience against cyber threats in SCADA environments.

查看原文本刊更多论文

确保工业控制系统的安全：开发 SCADA/IoT 测试台并在硬件模拟器上评估轻量级密码性能

本文论述了加强工业控制系统（ICS）内的监控与数据采集（SCADA）网络安全性以保护工业流程免受网络攻击的迫切需要。我们工作的目的是提出并评估轻量级安全措施，以保护关键基础设施资源。我们的工作范围包括利用 Modbus 和 MQTT 通信协议，为 ICS 模拟基于 SCADA/IoT 的安全硬件测试台。通过对远程伺服电机控制、配水系统和电力系统电压等级指示器的案例研究，我们确定了拒绝服务（DoS）和中间人（MiTM）攻击等漏洞，并提供了安全建议。为了开展工作，我们部署了轻量级密码，如 Prime Counter & Hash Chaining (PCHC) 和 Ascon algorithm with Compression Rate (ACR)，用于工厂底层和控制中心之间的安全信息交换。在 Raspberry Pi 上对这些密码的评估主要集中在执行速度和内存利用率上。此外，还与 SCADA 网络的 AGA-12 协议标准进行了比较，以强调所建议的安全措施的有效性。我们的研究结果包括识别 SCADA 网络漏洞和提出轻量级安全措施以降低风险。在树莓派（Raspberry Pi）上对所建议的密码进行的性能评估证明了其有效性，强调了部署此类措施以确保抵御 SCADA 环境中网络威胁的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Critical Infrastructure Protection COMPUTER SCIENCE, INFORMATION SYSTEMS-ENGINEERING, MULTIDISCIPLINARY

CiteScore

8.90

自引率

5.60%

发文量

审稿时长

>12 weeks

期刊介绍： The International Journal of Critical Infrastructure Protection (IJCIP) was launched in 2008, with the primary aim of publishing scholarly papers of the highest quality in all areas of critical infrastructure protection. Of particular interest are articles that weave science, technology, law and policy to craft sophisticated yet practical solutions for securing assets in the various critical infrastructure sectors. These critical infrastructure sectors include: information technology, telecommunications, energy, banking and finance, transportation systems, chemicals, critical manufacturing, agriculture and food, defense industrial base, public health and health care, national monuments and icons, drinking water and water treatment systems, commercial facilities, dams, emergency services, nuclear reactors, materials and waste, postal and shipping, and government facilities. Protecting and ensuring the continuity of operation of critical infrastructure assets are vital to national security, public health and safety, economic vitality, and societal wellbeing. The scope of the journal includes, but is not limited to: 1. Analysis of security challenges that are unique or common to the various infrastructure sectors. 2. Identification of core security principles and techniques that can be applied to critical infrastructure protection. 3. Elucidation of the dependencies and interdependencies existing between infrastructure sectors and techniques for mitigating the devastating effects of cascading failures. 4. Creation of sophisticated, yet practical, solutions, for critical infrastructure protection that involve mathematical, scientific and engineering techniques, economic and social science methods, and/or legal and public policy constructs.