计算机科学
智能电网
认证(法律)
安全通信
计算机安全
重放攻击
安全性分析
智能卡
报文认证码
稳健性(进化)
密码学
弹性(材料科学)
计算机网络
钥匙(锁)
信息物理系统
椭圆曲线密码
通信安全
访问控制
密钥分发
互联网安全
公钥基础设施
互联网
网络安全
方案(数学)
网格
质询-响应身份验证
密钥交换
前向保密
密钥管理
嵌入式系统
公钥密码术
相互认证
电信网络
密码协议
作者
Gagan Kumar,Balaprakasa Rao Killi,Ashok Kumar Das,Youngho Park
标识
DOI:10.1109/jiot.2026.3673083
摘要
The smart grid is a modern electricity network that incorporates sophisticated communication and control technologies to improve efficiency, reliability, and security. This study presents a secure, lightweight authentication and key agreement scheme for multi-layer Internet of Things (IoT)-enabled smart grid systems, targeting the essential requirement to safeguard industrial control networks against cyber threats. The proposed scheme incorporates two security mechanisms to improve authentication and communication security in smart grid systems. Physical Unclonable Functions (PUFs) facilitate secure device authentication between smart meters and the Master Terminal Unit (MTU) by utilizing hardware-level uniqueness, thereby ensuring resilience against cloning attacks. Additionally, post-quantum lattice-based Ring Learning with Errors (RLWE) hard problem ensures secure communication between the MTU and the Remote Terminal Unit (RTU), providing quantum-resistant security and efficient key exchange. The framework’s resilience is rigorously evaluated with the ProVerif security verification tool to confirm its strength against advanced cyberattacks. A formal security analysis quantitatively assesses the cryptographic robustness of the scheme, whereas an informal security analysis examines its ability to withstand practical cyber threats, including replay attacks, man-in-the-middle (MITM) attacks, and device impersonation in actual smart grid environments.
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