Microwave Detection of Structural Degradation in Maritime Industry. Novel applications of microwave technology to inspection systems in marine infrastructure will transform industry practice. By utilizing multi-mode antennas, the project aims to develop a gold-standard in microwave inspection, delivering more accurate and early detection of defects. The project aims will be achieved by combining innovative microwave technology, featuring multi-mode antennas and novel processing and imaging algor ....Microwave Detection of Structural Degradation in Maritime Industry. Novel applications of microwave technology to inspection systems in marine infrastructure will transform industry practice. By utilizing multi-mode antennas, the project aims to develop a gold-standard in microwave inspection, delivering more accurate and early detection of defects. The project aims will be achieved by combining innovative microwave technology, featuring multi-mode antennas and novel processing and imaging algorithms, with ground-breaking smart scanning and unmanned marine vehicle implementations. This innovative outcome obviates the need for current industry approaches based on inaccurate and tedious manual inspections, yielding massive cost savings and reductions in hazard associated with unanticipated structural failure.Read moreRead less
Opening a New Era of High-Performance Microwave Devices. We propose a conceptually new method of manufacturing high-performance microwave components at the low-cost and short lead time using liquid form conductors and 3D printing technology. Innovation consists in developing surface roughness free waveguide- and coaxial-based RF and microwave devices, in one-single-piece. This technique can be further extended to create high-performance reconfigurable RF and microwave devices such as filters, an ....Opening a New Era of High-Performance Microwave Devices. We propose a conceptually new method of manufacturing high-performance microwave components at the low-cost and short lead time using liquid form conductors and 3D printing technology. Innovation consists in developing surface roughness free waveguide- and coaxial-based RF and microwave devices, in one-single-piece. This technique can be further extended to create high-performance reconfigurable RF and microwave devices such as filters, antennas, directional couplers, phase shifters and switches by manipulating the locations of the liquid conductors. Furthermore, the method will enable the management of heat generated in high-power applications. Australian telecommunication industry and defence will benefit from the outcome of this project.Read moreRead less
Engineering the Next Generation of Broadband Terahertz Technologies. This project proposes a new broadband, high-power, laser technology for THz sensing. This semiconductor laser based THz technology is crucial for a wide range of applications requiring the acquisition of THz spectral signatures of materials and high-frame rate hyper-spectral THz imaging. We propose two pathways to engineer this novel THz technology: using a tuneable, coupled-cavity quantum cascade semiconductor laser and by c ....Engineering the Next Generation of Broadband Terahertz Technologies. This project proposes a new broadband, high-power, laser technology for THz sensing. This semiconductor laser based THz technology is crucial for a wide range of applications requiring the acquisition of THz spectral signatures of materials and high-frame rate hyper-spectral THz imaging. We propose two pathways to engineer this novel THz technology: using a tuneable, coupled-cavity quantum cascade semiconductor laser and by creating the broad emission spectra through active mode locking in a THz semiconductor laser. The THz laser coupled with the self-detection technique is the key to realising this, and will be explored both in model and experiment.Read moreRead less