Ring constructions and algorithms for enhancing performance of BCH codes. BCH codes form a major class of codes used in modern communication systems. The aim of this project is to enhance the efficiency of this class of codes by combining them in constructions enabling correction of deletion and insertion errors, and develop efficient implementations of encoding and decoding algorithms incorporating soft decision methods for enhanced error correction. Significance of the project is explained by ....Ring constructions and algorithms for enhancing performance of BCH codes. BCH codes form a major class of codes used in modern communication systems. The aim of this project is to enhance the efficiency of this class of codes by combining them in constructions enabling correction of deletion and insertion errors, and develop efficient implementations of encoding and decoding algorithms incorporating soft decision methods for enhanced error correction. Significance of the project is explained by the role of fast, secure and reliable communications in modern information and communication technology. Expected outcomes include new efficient algorithms and commercial modules available for symbolic computation systems with applications in telecommunications industry.
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Ultrasound in muscle vascular research, and gene therapy. This project focuses on ultrasound and microbubbles for the imaging of microvascular blood flow patterns in skeletal muscle and as a modality for drug delivery. The aim is to develop and refine technology specifically for (i) assessment of muscle microvascular flow in health and disease, and for (ii) delivery of state-of-the art gene constructs to endothelial cells that control blood flow in the muscle microvasculature. We anticipate impr ....Ultrasound in muscle vascular research, and gene therapy. This project focuses on ultrasound and microbubbles for the imaging of microvascular blood flow patterns in skeletal muscle and as a modality for drug delivery. The aim is to develop and refine technology specifically for (i) assessment of muscle microvascular flow in health and disease, and for (ii) delivery of state-of-the art gene constructs to endothelial cells that control blood flow in the muscle microvasculature. We anticipate improved technology for early diagnosis of impairment in microvascular flow relevant to muscle insulin resistance and novel therapeutics that improve muscle microvascular blood flow applicable to the treatment of diabetes.Read moreRead less