NOVEL MICROWAVE TECHNOLOGIES AND DESIGN TECHNIQUES FOR MULTILAYER CIRCUITS FOR WIRELESS COMMUNICATIONS. Miniaturization of mobile handsets and other wireless equipment is limited by the slow progress in integrating passive elements. Two novel technologies Low Temperature Co-fired Ceramics (LTCC) and Micro Electro Mechanical Systems (MEMS) offer the capacity to significantly miniaturise RF and microwave circuits and increase their efficiency and capabilities. The proposal deals with development o ....NOVEL MICROWAVE TECHNOLOGIES AND DESIGN TECHNIQUES FOR MULTILAYER CIRCUITS FOR WIRELESS COMMUNICATIONS. Miniaturization of mobile handsets and other wireless equipment is limited by the slow progress in integrating passive elements. Two novel technologies Low Temperature Co-fired Ceramics (LTCC) and Micro Electro Mechanical Systems (MEMS) offer the capacity to significantly miniaturise RF and microwave circuits and increase their efficiency and capabilities. The proposal deals with development of novel microwave technologies and techniques for optimization, characterization, simulation, design and fabrication of advanced LTCC materials and LTCC and MEMS based miniaturized circuits for 3G and beyond of Wireless Communication. The outcomes of the project will be of significant benefit to the Australian Telecommunications industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775614
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, ....National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, biologists and medical scientists to safely detect the intrinsic electromagnetic properties of electronic materials and tumours in biological tissues or poor quality agricultural produce. This comprehensive material characterisation facility will therefore benefit the peoples of Australasia in many significant and diverse ways.Read moreRead less
Quantum Nanoscience. This project will deliver a new Australian capability in the core nanotechnology of quantum electromechanical systems. Nanotechnology is a suite of techniques and processes to create new materials and devices through complex processing of constituents at the nanoscale and, in the case of quantum electromechanical systems, even with moving parts. At the nanoscale, quantum principles apply. New nano-fabrication methods are now available to build nano-electromechanical systems ....Quantum Nanoscience. This project will deliver a new Australian capability in the core nanotechnology of quantum electromechanical systems. Nanotechnology is a suite of techniques and processes to create new materials and devices through complex processing of constituents at the nanoscale and, in the case of quantum electromechanical systems, even with moving parts. At the nanoscale, quantum principles apply. New nano-fabrication methods are now available to build nano-electromechanical systems (NEMS), integrated with electronics and nano optics and cooled into the quantum regime. Quantum electromechanical systems (QEMS) enable new sensors with ultimate sensitivity limited only by the Heisenberg uncertainty principle, with applications in photonics, metrology and bio molecular imaging.Read moreRead less