| Abstract |
Flying Ad Hoc networks, (FANETs) in recent years, have actively been used in monitoring landscape, military and mapping terrains. However, with the advent of the emerging concept of smart cities and new business applications, these flying devices and drones have found a new use case in the medical and governance sector. But these networks suffer from the major problem of centralization. Although centralization does provide reliability and efficiency but also poses the threat of a single point of failure. Meanwhile, blockchain widely known for its decentralization is heavily researched and can be utilized in this case to offer a solution to the problem of centralization of FANETs. Therefore, in this paper, we propose a decentralized architecture of flying ad hoc nodes based on blockchain and using Practical byzantine fault tolerance (PBFT) for consensus among nodes. By employing PBFT, the architecture is not only computationally efficient and fast. In addition, we have used a gossip protocol for passing messages among nodes. Lastly, we have simulated the working of our model and the experimental results show that the proposed method works with nearly constant throughput and latency while increasing the network size and approximately constant message overhead with increase transaction for given network size. © 2020 The Authors. Published by Elsevier B.V. |
