Abstract
The emerging smart city is driving massive transformations of modern cities, facing the huge influx of sensor data from IoT devices. Edge computing distributes computing tasks to the near-edge end, which greatly enhances the service quality of IoT applications, that is, ultralow latency, large capacity, and high throughput. However, due to the constrained resource of IoT devices, currently, systems with a centralized model are vulnerable to attacks, such as DDoS from IoT botnet and central database failure, which can hardly provide high-confidence services. Recently, blockchain with a high security promise is considered to provide new approaches to enhancing the security of IoT systems. However, blockchain and IoT have obvious incompatibility, and low-capacity IoT devices can hardly be incorporated into blockchain with high computing requirements. In this paper, a blockchain-edge computing hybrid system (BEHS) is presented to make the adaptation of blockchain to edge computing and provide trustworthy IoT management services for a smart city. A novel extensible consensus protocol designed for proof-of-work, named proof-of-contribution (PoC), is proposed to regulate the data upload behaviors of nodes, especially the data upload frequency of IoT device nodes, so as to protect the system from attack about frequency. In order to secure the data privacy and authenticity, a data access control scheme is designed by integrating symmetric encryption with asymmetric encryption algorithm. We implemented a concrete BEHS on Ethereum, realized the function of PoC mechanism via smart contracts, and conducted a case study for smart city. The extensive evaluations and analyses show that the proposed PoC mechanism can effectively detect and automatically manage the behavior of nodes, and the time cost of data access control scheme is within an acceptable range.
Highlights
A novel proof-of-contribution consensus mechanism is proposed to regulate the behavior of nodes, especially IoT device nodes, securing the system from malicious attacks
We start by introducing the specific parameters setting of Ethereum-based blockchain-edge computing hybrid system (BEHS), and we evaluate the performance of the system, including the effectiveness of PoC and the cost of data access control scheme (DACS)
For a sensing device with abnormal behaviors, PoC will limit its future rewards in several cycles. e negative impact of the abnormal behavior will gradually decrease over time but cannot be erased. erefore, the reward of node with abnormal behavior will always be less than node without abnormal behavior with the same performance
Summary
Due to the constrained resource, IoT devices can hardly adapt to consensus algorithms with high computational complexity and large storage requirement, such as proof-of-work [13] and proof-of-stake [14], which makes IoT devices fall out system supervision and become vulnerabilities. E questionable credibility of IoT devices and the complexity of the network pose challenges to information security and data privacy of large-scale smart city systems. To address the aforementioned challenges, we proposed a novel blockchain-edge computing hybrid system (BEHS) to provide trustworthy IoT service for smart cities. A novel proof-of-contribution consensus mechanism is proposed to regulate the behavior of nodes, especially IoT device nodes, securing the system from malicious attacks. (2) A proof-of-contribution (PoC) consensus mechanism is developed to provide a trustworthy management method for the nodes in IoT systems.
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