Innovative Decoding Methods for Increased Error Correction of Reed-Solomon Codes and Related Ring Codes. The project addresses the holy grail in the area of Reed-Solomon/BCH decoding, namely the derivation of algebraic soft-decision decoding algorithms. These codes are the most frequently used error-correcting block codes and their performance does not fulfill its full potential due to the lack of algebraic soft-decision decoding methods. In the project the system-theoretic behavioural view is e ....Innovative Decoding Methods for Increased Error Correction of Reed-Solomon Codes and Related Ring Codes. The project addresses the holy grail in the area of Reed-Solomon/BCH decoding, namely the derivation of algebraic soft-decision decoding algorithms. These codes are the most frequently used error-correcting block codes and their performance does not fulfill its full potential due to the lack of algebraic soft-decision decoding methods. In the project the system-theoretic behavioural view is employed, which has proved itself successful in this area in recent years. The project aims to connect soft-decision decoding methods with the decoding of ring codes. Outcomes are decoding methods and algorithms for the australian telecommunications industry that enable increased error correction for Reed-Solomon/BCH codes and related ring codes.Read moreRead less
Advanced error control coding techniques for scalable blockchains. The project aims to investigate the application of error-control coding theory in blockchains, focusing on reducing the storage, computation, and communication overheads, as well as increasing the throughput of blockchain networks. The ambition is to develop coding theory in a completely new territory: decentralised, untrusted, and peer-to-peer networks. The intended outcome is to greatly extend the current state of the art of th ....Advanced error control coding techniques for scalable blockchains. The project aims to investigate the application of error-control coding theory in blockchains, focusing on reducing the storage, computation, and communication overheads, as well as increasing the throughput of blockchain networks. The ambition is to develop coding theory in a completely new territory: decentralised, untrusted, and peer-to-peer networks. The intended outcome is to greatly extend the current state of the art of the theory of error-control codes, previously investigated only in the context of centralised architectures, where a server coordinates every task. Practically, the project should provide significant benefits in terms of cost-effectiveness of blockchains, increase in their processing speed, and security enhancement. Read moreRead less
Practical unified framework for secure e-consent mechanism for health records. This project is driven by modern applications of cryptography and network security and their applications in securing e-health by enabling secure Personal Health Records (PHRs), which will play an important role in the future healthcare industry.