Professor Amin Abbosh
Professor

Amin Abbosh

Email: 
Phone: 
+61 7 334 67936

Background

Prof. Amin Abbosh specializes in Medical Microwave Imaging and Microwave and Millimeter-wave Engineering. His work focuses on designing and developing advanced imaging and sensing systems using electromagnetic techniques at radio-wave frequencies.

Prof. Abbosh’s significant contributions include the creation of innovative imaging systems that leverage his expertise in applied electromagnetics and microwave engineering. He has developed comprehensive analytical and computational frameworks, incorporating signal-processing techniques for detection and AI for classification. This approach has led to a new modality for detection and imaging, combining physics-guided and data-driven methods. His work is protected by over 16 patents.

In Communication Technologies, Prof. Abbosh's work focuses on designing flat-panel, low-cost reconfigurable antennas. These antennas form ground satellite terminals that communicate with low-earth-orbit (LEO) satellites, providing reliable broadband access to remote and regional communities. This technology supports e-health services, distance education, and business productivity, and can be used in various on-the-move environments.

Availability

Professor Amin Abbosh is:
Available for supervision
Media expert

Fields of research

Biomedical engineering Engineering

Qualifications

  • Bachelor of Science, University of Mosul
  • Masters (Coursework) of Science, University of Mosul
  • Doctor of Philosophy, University of Mosul
  • Postgraduate Diploma in Higher Education, The University of Queensland
  • Doctor of Philosophy, The University of Queensland

Research interests

  • Electromagnetic Medical Imaging

    Electromagnetic Medical Imaging Systems including hardware (microwave devices and antennas), applied electromagnetic, computational electromagnetic, signal processing, and artificial intelligence

  • Microwave Engineering

    Antennas, microwave devices

  • Engineering Electromagnetics

    Applied Electromagnetics in Electrical and Biomedical Engineering

  • Artificial Intelligence

    AI in Electromagnetics and Microwave Engineering

Search Professor Amin Abbosh’s works on UQ eSpace

626 works between 1985 and 2025
All (626) Journal Article (348) Book Chapter (3) Conference Publication (262) Other Outputs (13)

21 - 40 of 626 works

Featured

2013

Journal Article

Ultra-Wideband Quasi-Yagi Antenna Using Dual-Resonant Driver and Integrated Balun of Stepped Impedance Coupled Structure

Abbosh, A. (2013). Ultra-Wideband Quasi-Yagi Antenna Using Dual-Resonant Driver and Integrated Balun of Stepped Impedance Coupled Structure. Ieee Transactions On Antennas and Propagation, 61 (7) 6497688, 3885-3888. doi: 10.1109/TAP.2013.2257642

Ultra-Wideband Quasi-Yagi Antenna Using Dual-Resonant Driver and Integrated Balun of Stepped Impedance Coupled Structure

Featured

2013

Other Outputs

Design and analysis of wideband passive microwave devices using planar structures

Abbosh, Amin (2013). Design and analysis of wideband passive microwave devices using planar structures. Professional Doctorate, School of Information Technol and Elec Engineering, The University of Queensland. doi: 10.14264/307019

Design and analysis of wideband passive microwave devices using planar structures

Featured

2013

Journal Article

Modeling human head at microwave frequencies using optimized debye models and FDTD method

Ireland, David and Abbosh, Amin (2013). Modeling human head at microwave frequencies using optimized debye models and FDTD method. IEEE Transactions on Antennas and Propagation, 61 (4) 6417965, 2352-2355. doi: 10.1109/TAP.2013.2242037

Modeling human head at microwave frequencies using optimized debye models and FDTD method

Featured

2013

Journal Article

Accurate effective permittivity calculation of printed center-fed dipoles and its application to quasi yagi-uda antennas

Abbosh, Amin (2013). Accurate effective permittivity calculation of printed center-fed dipoles and its application to quasi yagi-uda antennas. IEEE Transactions on Antennas and Propogation, 61 (4) 6374208, 2297-2300. doi: 10.1109/TAP.2012.2231925

Accurate effective permittivity calculation of printed center-fed dipoles and its application to quasi yagi-uda antennas

Featured

2012

Journal Article

Ultra-wideband crossover using microstrip-to-coplanar waveguide transitions

Abbosh, A., Ibrahim, S. and Karim, M. (2012). Ultra-wideband crossover using microstrip-to-coplanar waveguide transitions. IEEE Microwave and Wireless Components Letters, 22 (10) 6310075, 500-502. doi: 10.1109/LMWC.2012.2218586

Ultra-wideband crossover using microstrip-to-coplanar waveguide transitions

Featured

2012

Journal Article

Wideband planar crossover using two-port and four-port microstrip to slotline transitions

Abbosh, A. M. (2012). Wideband planar crossover using two-port and four-port microstrip to slotline transitions. IEEE Microwave and Wireless Components Letters, 22 (9) 6261565, 465-467. doi: 10.1109/LMWC.2012.2209632

Wideband planar crossover using two-port and four-port microstrip to slotline transitions

Featured

2012

Journal Article

Compact tunable low-pass filter using variable mode impedance of coupled structure

Abbosh, A. (2012). Compact tunable low-pass filter using variable mode impedance of coupled structure. IET Microwaves Antennas and Propagation, 6 (12), 1306-1310. doi: 10.1049/iet-map.2012.0313

Compact tunable low-pass filter using variable mode impedance of coupled structure

Featured

2012

Journal Article

Single layer reflectarray with circular rings and open-circuited stubs for wideband operation

Li, Yuezhou, Bialkowski, Marek E. and Abbosh, Amin M. (2012). Single layer reflectarray with circular rings and open-circuited stubs for wideband operation. IEEE Transactions on Antennas and Propagation, 60 (9) 6231665, 4183-4189. doi: 10.1109/TAP.2012.2207060

Single layer reflectarray with circular rings and open-circuited stubs for wideband operation

Featured

2012

Journal Article

Compact tunable reflection phase shifters using short section of coupled lines

Abbosh, Amin M. (2012). Compact tunable reflection phase shifters using short section of coupled lines. IEEE Transactions on Microwave Theory and Techniques, 60 (8) 6214580, 2465-2472. doi: 10.1109/TMTT.2012.2198232

Compact tunable reflection phase shifters using short section of coupled lines

Featured

2012

Conference Publication

Head phantom for testing microwave systems for head imaging

Mohammed, Beada’a, Abbosh, Amin, Henin, Bassem and Sharpe, Philip (2012). Head phantom for testing microwave systems for head imaging. 2012 Cairo International Biomedical Engineering Conference (CIBEC), Cairo, Egypt, 20 - 22 December 2012. Piscataway, NJ, United States: IEEE. doi: 10.1109/CIBEC.2012.6473320

Head phantom for testing microwave systems for head imaging

Featured

2012

Journal Article

Design method for ultra-wideband bandpass filter with wide stopband using parallel-coupled microstrip lines

Abbosh, Amin M. (2012). Design method for ultra-wideband bandpass filter with wide stopband using parallel-coupled microstrip lines. IEEE Transactions On Microwave Theory And Techniques, 60 (1) 6092516, 31-38. doi: 10.1109/TMTT.2011.2175241

Design method for ultra-wideband bandpass filter with wide stopband using parallel-coupled microstrip lines

Featured

2011

Journal Article

Three-way parallel-coupled microstrip power divider with ultrawideband performance and equal-power outputs

Abbosh, Amin M. (2011). Three-way parallel-coupled microstrip power divider with ultrawideband performance and equal-power outputs. IEEE Microwave and Wireless Components Letters, 21 (12) 6056584, 649-651. doi: 10.1109/LMWC.2011.2170831

Three-way parallel-coupled microstrip power divider with ultrawideband performance and equal-power outputs

Featured

2011

Journal Article

Ultrawideband balanced bandpass filter

Abbosh, Amin M. (2011). Ultrawideband balanced bandpass filter. IEEE Microwave and Wireless Components Letters, 21 (9) 5983414, 480-482. doi: 10.1109/LMWC.2011.2162620

Ultrawideband balanced bandpass filter

Featured

2011

Journal Article

Closed-form design method for tight parallel-coupled microstrip coupler with ultra-wideband performance and practical dimensions

Abbosh, A. M. (2011). Closed-form design method for tight parallel-coupled microstrip coupler with ultra-wideband performance and practical dimensions. Electronics Letters, 47 (9), 547-549. doi: 10.1049/el.2011.0733

Closed-form design method for tight parallel-coupled microstrip coupler with ultra-wideband performance and practical dimensions

Featured

2011

Journal Article

Broadband fixed phase shifters

Abbosh, A.M. (2011). Broadband fixed phase shifters. IEEE Microwave and Wireless Components Letters, 21 (1, Article number 5648370) 5648370, 22-24. doi: 10.1109/LMWC.2010.2079320

Broadband fixed phase shifters

Featured

2010

Journal Article

Strain imaging of the breast by compression microwave imaging

Abbosh, A. and Crozier, S. (2010). Strain imaging of the breast by compression microwave imaging. IEEE Antennas and Wireless Propagation Letters, 9 5685252, 1229-1232. doi: 10.1109/LAWP.2011.2105238

Strain imaging of the breast by compression microwave imaging

Featured

2009

Journal Article

Design of UWB planar band-notched antenna using parasitic elements

Abbosh, Amin and Bialkowski, Marek, E. (2009). Design of UWB planar band-notched antenna using parasitic elements. IEEE Transactions on Antennas and Propagation, 57 (3), 796-799. doi: 10.1109/TAP.2009.2013449

Design of UWB planar band-notched antenna using parasitic elements

Featured

2009

Journal Article

Analytical closed-form solutions for different configurations of parallel-coupled microstrip lines

Abbosh, Amin (2009). Analytical closed-form solutions for different configurations of parallel-coupled microstrip lines. IET Microwaves Antennas & Propagation, 3 (1), 137-147. doi: 10.1049/iet-map:20070308

Analytical closed-form solutions for different configurations of parallel-coupled microstrip lines

Featured

2008

Journal Article

Design of ultrawideband planar monopole antennas of circular and elliptical shape

Abbosh, A. M. and Bialkowski, M.E. (2008). Design of ultrawideband planar monopole antennas of circular and elliptical shape. IEEE Transactions on Antennas and Propagation, 56 (1), 17-23. doi: 10.1109/TAP.2007.912946

Design of ultrawideband planar monopole antennas of circular and elliptical shape

Featured

2008

Journal Article

Miniaturization of planar ultra-wideband antenna via corrugation

Abbosh, A. M. (2008). Miniaturization of planar ultra-wideband antenna via corrugation. IEEE Antennas and Wireless Propagation Letters, 7 2009323, 685-688. doi: 10.1109/LAWP.2008.2009323

Miniaturization of planar ultra-wideband antenna via corrugation

Current funding

  • 2025 - 2029
    Realtime Three-Dimensional Near-Field Microwave Imaging System
    ARC Discovery Projects
    Open grant
  • 2025 - 2029
    Minimally-Invasive Electromagnetic Haemoglobin Sensing
    NHMRC IDEAS Grants
    Open grant
  • 2025 - 2027
    Portable Electromagnetic Torso Scanner
    NHMRC IDEAS Grants
    Open grant
  • 2024 - 2027
    Next-Generation Solvers for Complex Microwave Engineering Problems
    ARC Discovery Projects
    Open grant
  • 2020 - 2028
    Microwave and Photonic Engineering and Applied Electromagnetics
    EM Solutions Pty Ltd
    Open grant

Past funding

  • 2021 - 2022
    Electromagnetic Scanner for Hepatic Steatosis Detection, Classification and Monitoring
    EMvision Medical Devices Ltd
    Open grant
  • 2020 - 2024
    Compact Millimeter-Wave Terminal for LEO Satellite Communications
    ARC Linkage Projects
    Open grant
  • 2019 - 2022
    Microwave Detection of Structural Degradations in Maritime Industry
    ARC Linkage Projects
    Open grant
  • 2019 - 2020
    Development Dielectric Sensor System on Intelligent Amphirols for Mud Farming Tailings Facilities
    Innovation Connections
    Open grant
  • 2018 - 2022
    High Quality and Robust Energy Conversion Systems for Distribution Networks
    ARC Linkage Projects
    Open grant
  • 2018 - 2019
    Broadband human tissue measurements enabled by a new triaxial near field probe
    Keysight Technologies Inc
    Open grant
  • 2018 - 2021
    Engineering the next generation of portable microwave scanners
    ARC Discovery Projects
    Open grant
  • 2018
    Imaging in the nano-scale age: terahertz and millimetre wave microanalysis
    UQ Major Equipment and Infrastructure
    Open grant
  • 2018 - 2022
    Portable brain scanner for early stroke detection and monitoring (CRC-P administered by EMVisions Medical Devices Ltd)
    EMvision Medical Devices Ltd
    Open grant
  • 2017 - 2018
    Portable microwave brain scanner
    UniQuest Pty Ltd
    Open grant
  • 2017 - 2020
    Positive Vehicle Identification with the use of smart sensors, a Transport and Population Research Network project
    UQ Vice-Chancellor's Strategic Initiatives
    Open grant
  • 2017 - 2018
    Development of millimetre-wave non-destructive testing system for marine infrastructure
    Innovation Connections
    Open grant
  • 2017 - 2018
    RFID Licence Plate Antenna
    Innovation Connections
    Open grant
  • 2017
    Advanced Pulsed Power: an emerging technology for science and engineering systems
    UQ Major Equipment and Infrastructure
    Open grant
  • 2016 - 2019
    In-Road Microwave System for Traffic Monitoring and Vehicle Identification
    ARC Linkage Projects
    Open grant
  • 2016 - 2019
    Reconfigurable Antennas for Satellite On-The-Move Communications
    ARC Linkage Projects
    Open grant
  • 2016 - 2017
    Road Curtain Intelligent Sensor
    Research Connections
    Open grant
  • 2016
    Millimetre Waves for Imaging and Sensing
    UQ Major Equipment and Infrastructure
    Open grant
  • 2015 - 2017
    Microwave Head Monitor Using Compressed Sensing and Differential Techniques
    ARC Discovery Projects
    Open grant
  • 2015 - 2017
    Portable Microwave Imaging Technology Using Reconfigurable Radar
    ARC Discovery Projects
    Open grant
  • 2014 - 2015
    Road Curtain Radar
    LicenSys Pty Ltd
    Open grant
  • 2014
    Portable Microwave System for Head Imaging and Stroke Detection
    Agilent Technologies Inc
    Open grant
  • 2014 - 2015
    Reconfigurable reflectarray for satellite on-the-move communication terminals
    UQ Collaboration and Industry Engagement Fund - Seed Research Grant
    Open grant
  • 2013 - 2014
    Road Curtain Antenna (Researchers in Business grant with LicenSys Pty Ltd)
    LicenSys Pty Ltd
    Open grant
  • 2012 - 2014
    Portable Microwave Systems for Imaging and Monitoring of the Human Body
    ARC Discovery Projects
    Open grant
  • 2010 - 2013
    Hybrid Imaging System for Breast Cancer Detection
    ARC Future Fellowships
    Open grant
  • 2010 - 2012
    Microwave System for Early Breast Cancer Detection Employing Ultra Wideband Conformal Array Antenna
    ARC Discovery Projects
    Open grant
  • 2009 - 2011
    Design of Planar Microwave Components and Sub-systems for Wideband Applications
    ARC Discovery Projects
    Open grant
  • 2007 - 2008
    Investigations into Multi-Antenna Wideband Systems for Future Wireless Communications
    UQ Early Career Researcher
    Open grant
  • 2007 - 2009
    Microwave Imaging System for Breast Cancer Detection Using Ultra Wideband Technology
    UQ Postdoctoral Research Fellowship
    Open grant

Availability

Professor Amin Abbosh is:
Available for supervision

Before you email them, read our advice on how to contact a supervisor.

Available projects

  • Multi-channel, multi-frequency measurements systems for medical electromagnetic imaging

    Advances in signal processing platforms and microwave signal capture have allowed for new architectures of sensors to be developed. Specifically, both the ability to capture higher bandwidth and higher dynamic range as well as the associated processing hardware being capable of more calculations per second.

    Harnessing these new capabilities requires a combination of hardware and software processing, and will enable the development of more and lower-cost medical electromagnetic imaging systems.

    A working knowledge of signal processing and electromagnetics is necessary

  • Wideband Medical Electromagnetic Sensors

    Medical Electromagnetic imaging techniques have the potential to be used in the diagnosis and monitoring of different diseases. To that end, electromagnetic sensors that operate efficiently at their near-field and within the frequency of interest should be properly designed to generate and receive utilized electromagnetic waves. This project will aim at designing compact EM sensors, using different techniques such as open-ended coaxial cables or waveguides, substrate-integrated waveguides, or any suitable near-field antenna. Those sensors should have wideband performance and thus the potential to be used as a portable medical probe or scanner.

    The successful candidate should have a strong background in (a) electromagnetic radiation, and (b) microwave engineering

  • Computationally efficient electromagnetic solver using AI

    With the fast progress in forming more complex electromagnetic (EM) structures with many design parameters and large demand for real-time solutions to complex EM problems in embedded devices, the need for a new EM-solving approach that can keep pace with the computational requirements has become more imminent. This project aims at developing a novel computationally efficient EM solver which is implementable on systems with limited resources using a physics-informed sparse deep neural network that solves partial differential forms of Maxwell’s equations without relying on other computational EM solver solutions. The successful candidate will specifically develop signal processing and machine learning algorithms for a real-time electromagnetic solver.

    The successful candidate should have a strong background in Artificial Intelligence & a working knowledge of electromagnetics and signal analysis

  • Reconfigurable Microwave Devices using Smart Materials

    This project aims at utilizing the electrodynamic properties of artificial materials in designing reconfigurable, or tunable, electromagnetic devices at the microwave frequency band, such as antennas, filters, couplers, etc. The reconfigurability might aim at controlling the center operating frequency, bandwidth, radiation pattern or direction, etc. The selected candidate will investigate the effect of different properties of those materials on the electromagnetic reconfigurability of microwave devices.

    The successful candidate should have a strong background in (a) electromagnetics and microwave engineering, and (b) measurement techniques of dielectric properties of materials

  • Electromagnetic Techniques for Brain Function Monitoring

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI-accredited journals), patents, and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Tunable microwave devices (filters, power dividers, couplers, etc)

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Microwave Microscopy for Medical Applications

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Reconfigurable Antennas

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Millimeter-Wave Techniques for Skin Cancer Detection

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Contactless Head Monitor for Newborn Babies

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Antenna beamforming for 5G/6G mobile communication

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Multi-channel, multi-frequency measurements systems for medical electromagnetic imaging

    Advances in signal processing platforms and microwave signal capture have allowed for new architectures of sensors to be developed. Specifically, both the ability to capture higher bandwidth and higher dynamic range as well as the associated processing hardware being capable of more calculations per second.

    Harnessing these new capabilities requires a combination of hardware and software processing, and will enable the development of more and lower-cost medical electromagnetic imaging systems.

    A working knowledge of signal processing and electromagnetics is necessary

  • Wideband Medical Electromagnetic Sensors

    Medical Electromagnetic imaging techniques have the potential to be used in the diagnosis and monitoring of different diseases. To that end, electromagnetic sensors that operate efficiently at their near-field and within the frequency of interest should be properly designed to generate and receive utilized electromagnetic waves. This project will aim at designing compact EM sensors, using different techniques such as open-ended coaxial cables or waveguides, substrate-integrated waveguides, or any suitable near-field antenna. Those sensors should have wideband performance and thus the potential to be used as a portable medical probe or scanner.

    The successful candidate should have a strong background in (a) electromagnetic radiation, and (b) microwave engineering

  • Computationally efficient electromagnetic solver using AI

    With the fast progress in forming more complex electromagnetic (EM) structures with many design parameters and large demand for real-time solutions to complex EM problems in embedded devices, the need for a new EM-solving approach that can keep pace with the computational requirements has become more imminent. This project aims at developing a novel computationally efficient EM solver which is implementable on systems with limited resources using a physics-informed sparse deep neural network that solves partial differential forms of Maxwell’s equations without relying on other computational EM solver solutions. The successful candidate will specifically develop signal processing and machine learning algorithms for a real-time electromagnetic solver.

    The successful candidate should have a strong background in Artificial Intelligence & a working knowledge of electromagnetics and signal analysis

  • Reconfigurable Microwave Devices using Smart Materials

    This project aims at utilizing the electrodynamic properties of artificial materials in designing reconfigurable, or tunable, electromagnetic devices at the microwave frequency band, such as antennas, filters, couplers, etc. The reconfigurability might aim at controlling the center operating frequency, bandwidth, radiation pattern or direction, etc. The selected candidate will investigate the effect of different properties of those materials on the electromagnetic reconfigurability of microwave devices.

    The successful candidate should have a strong background in (a) electromagnetics and microwave engineering, and (b) measurement techniques of dielectric properties of materials

  • Millimeter-Wave Techniques for Skin Cancer Detection

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Electromagnetic Techniques for Brain Function Monitoring

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI-accredited journals), patents, and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Tunable microwave devices (filters, power dividers, couplers, etc)

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Microwave Microscopy for Medical Applications

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Reconfigurable Antennas

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Contactless Head Monitor for Newborn Babies

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Antenna beamforming for 5G/6G mobile communication

    If you require a scholarship from me to do your PhD with my team, I will only support your application if you (1) have a high GPA and sound research record (published papers in decent journals, such as IEEE, IET etc), and (2) graduated from a good university. Please note that at UQ, we do not accept a research record of papers in unaccredited journals.

    If you are interested, please send me an email that includes: Your GPA, publication record (published and accepted papers in only ISI accredited journals), patents and awards (with documented proof of those). If you do not include all that information, we will not respond to your email.

  • Electromagnetic Solver Using Physics - Guided Deep Neural Network

    This project aims to develop a physics-guided, data-driven method for solving complex electromagnetic problems efficiently. The focus of this project will be on medical microwave imaging.

Supervision history

Current supervision

Completed supervision

Enquiries

Contact Professor Amin Abbosh directly for media enquiries about:

  • Antennas
  • Microwave Medical Imaging
  • Microwave Passive Devices
  • Telecommunications

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