Microwave Photonics and Sensors Group

The Microwave Photonics and Sensors (MPS) Group is focused on developing theoretical, simulations and experimental techniques for investigation of the followings:

• All-optical processing and controlling of RF signals.
• Microwave photonic signal processing by exploiting intrinsic nonlinear effects in Optical Fibre for future Radar and Wireless communication Systems.
• Microwave Photonic Downconversion/upconversion with high conversion efficiency using novel configuration schemes over a wide range of frequencies with high SFDR, low noise and suppression of high-order harmonics at any spectrum.

The MPS Group has developed and demonstrated experimentally non-invasive wearable body sensors for continuous monitoring and measuring of key health parameters such as:

• Blood Pressure.
• Blood Oxygen Saturation (SpO2),
• Body Temperature.
• Glucose Levels in Blood

In addition to this the MPS has extensive expertise on designing Biosensors, photonic sensors and soil sensors for medical and environmental applications, including Brillouin Scattering for imaging applications.

In civilian aerospace systems there is increasing demand for higher information capacity links to both ground stations and space based satellite networks for a wide range of applications including: on-board “Wi-Fi”, passenger and crew telecommunication and data communication, airframe and engine health monitoring systems, air traffic control communication, GPS and continuous airplane status and location monitoring. 

Similarly in military aerospace live video feeds from the aircraft in addition to the continuous monitoring and control of on- board systems are envisaged. Photonics being largely Radio Frequency (RF) “blind”, hold the key prospect of combining multiple RF radios into a single architecture and antenna either through processing in parallel or serially in time.  RF analogue photonic linking is a very promising technique due to the low insertion loss, system integration compactness, huge bandwidth capacity, security and immunity to EMI. 

The Microwave Photonics and Sensors Group is collaborating closely with leading national and international industries and universities, working on the above stated research topic. Due to our close collaboration with industry, several patents have been filed jointly with the support from the industry. This page lists some, amongst other, areas of current interest as well as areas of opportunity for future work.

The group is working closely with physics, biosciences, materials, computer sciences and information security groups here at Royal Holloway, London University. 

To apply for an MSc by Research or PhD within the Microwave Photonics and Sensors, please email the Head of Group, Dr Haxha at shyqyri.haxha@rhul.ac.uk with details about your research interests as well as a summary of your academic qualifications (a brief one to two page CV will be useful) and if you are self-funded or require funding. After you have liaised with Dr Haxha, you will be able to register an account on Royal Holloway Direct to formally submit your application.

More details on the application process can be found here. 

For more information on postdoctoral, fellowship and visiting opportunities, please email the Head of Group, Dr Haxha at shyqyri.haxha@rhul.ac.uk with your CV and a brief statement of your research interest and career aspirations.

Dr Vladimir Dyo is a Lecturer in Communications and Signal Processing at the Department of Electronic Engineering, Royal Holloway, University of London. He received an MSc in Data Communications, Networks and Distributed Systems (DCNDS) from University College London in 2003 and subsequently completed a PhD under supervision of Prof Cecilia Mascolo in 2009. He is a recipient of prestigious Shell Centenary Scholarship (~£25k), EPSRC/Vodafone Dorothy Hodgkin Postgraduate Award (~£75k) and a winner of the an UCL Anvil Prize for his postgraduate research.

Prior to joining the Royal Holloway University of London, he was a founding member of Electronic Engineering degreees at University of Bedfordshire. In 2008-2009 he was a research intern at Microsoft Research Cambridge, UK. In 2007, he was a visiting researcher at Computer Lab, University of Cambridge.  Dr Vladimir Dyo has extensive expertise in the Internet of Things and was involved in research projects and consultancies on intelligent condition monitoring, vehicle classification, RF-sensing, and localisation. He has published in IEEE Sensors Journal, IEEE Access, IET Communications, ACM Transactions on Sensor Networks, as well as in highly selective top conferences such as ACM SenSys and IEEE/ACM DCOSS.  Dr Vladimir Dyo is a Fellow of Higher Education Academy and has an extensive experience teaching at undergraduate and postgraduate levels.

Research Projects:
* Pedestrian Radar enhancement for increased road safety, Moshon Ltd, 2023-2024
* Early fault detection for electric pumps, Innovate UK KTP grant with Deckpro Pumps/ Uptime Systems, 2020-2022
* Novel algorithms for solar-powered in-road sensors to measure speed and classify vehicles to inform intelligent traffic management decisions, Innovate UK grant 39455-289165, 2014-2015
* Battery-assisted EV charging system.  Innovation in Manufacturing, Aerospace and Green Economy (IMAGE) grant, 2019
* RF-sensing based motion detection and analysis, consultancy with Network Rail, UK, 2016
* Investigation of Blockchain and LoRA communication systems, consultancy with CyberAir Ltd, 2016

Dr Beenish Ayaz is Chartered Engineer (CEng), board member of IMechE MICG (Mechatronics, Informatics and Control Group), Senior member of the Institute of Electrical and Electronics Engineers (SMIEEE), England Representative, committee member of IEEE Oceanic Engineering Society (OES) chapter and fellow of Higher Education Academy (FHEA). She is working as Director of Internationalisation at the School of Engineering, Physical and Mathematical Sciences (EPMS) and Lecturer in Electronic Engineering at Royal Holloway University of London. She did her PhD in Wireless Sensor Networks from University of Aberdeen, UK, MSc in Information and Communications Engineering from Karlsruhe Institute of Technology (KIT), Germany and BEng (Hons) in Electronics Engineering from University of Engineering and Technology, Pakistan.

Beenish designed a 3D sensor node deployment architecture for underwater wireless sensor network, ensuring reliable communication and full coverage of the monitored region underwater, in her PhD research work. She also developed a dynamically reconfigurable (self-sustainable) routing protocol for underwater wireless sensor network. She won the Best Presentation award for her research work at the 8th International Conference on Sensing Technology (ICST 2014) in Liverpool, UK. Her research areas are Wireless Sensor Network (WSN), Underwater WSN, Robotic WSN, electronic biomaterials and sustainable engineering design. She also possesses work experience at Siemens and has been awarded the University Performance Award in Feb 2025.

Prof. Ian Flint is a visiting Professor at RHUL. Prof. Flint received his BSc in Physics with Maths from Reading University, in 1975. In 1982, he received his PhD from Reading University on “The electron spin resonance of low temperature irradiated diamond”. He was the first to identify the role of self-interstitials to enhanced diffusion of impurities. He is a physicist, previously working for 10 years in the Universities of Reading (1978 year to 1982), Hull University (from 1982 to 1983) Oxford University (1983 to 1985) Bath University (1985 to 1989) and on optoelectronics and Solid State physics.

In 2004 Prof. Flint received BAE Systems Chairman’s Gold individual award for a photonic microwave filter design. Prof. Flint is inventor of Seventeen filled patents for three different companies in the last 20 years. He has a wide range research expertise and development roles in university and industry. Initially working in solid state physics and then integrated photonics. On moving to industry his work allowed first commercially back-illuminated CCD devices. These back-illuminated processes allowed major systems like the Hubble space telescope (the current WFC3 devices). These devices are sixteen times more sensitive in the blue and UV wavelength than the previous device. He is the inventor of large number of patent filing awards within Marconi Optical Components, Selex (Leonardo). Marconi, E2V, BAE systems. Patents are filed in RF sampling and RF down conversion, Laser Hybridisation; Laser machined waveguides; Integrated Optical Isolators Micro Mechanical devices; Blowing fibre into coil winding; Monitoring surface properties; In situ waveguide deposition; Microwave photonic filters; Multi Input receiver, RF Sampling; Simulated Brillouin  Scattering, Imaging Devices and Systems..etc.

Contact details:

Microwave Photonics and Sensors

Department of Electronic Engineering

School of Engineering, Physical and Mathematical Sciences

Royal Holloway, University of London, Egham, Surrey, TW20 0EX, United Kingdom

Tel: +44 (0)178444 3183

Email: Ian.Flint@rhul.ac.uk

Selected publications:

1. F. AbdelMalek, W. Aroua, S. Haxha and I. Flint. Light-switching-light optical transistor based on metallic nanoparticle cross-chains geometry incorporating Kerr nonlinearity. Annalen der Physik, vol. 528, issue 7-8, pp. 560-570, 2016.
2. J. Sarma. I. Flint, Electrically variable couplers for integrated optical circuits. IEE Proceedings Vol 135 Pt.J No 3 June 1988 p268-275
3. I. Flint and J.N. Lomer.The formation of E.S.R centers A-2 and A-3 in diamond, electron irradiated below 30K and an interpretation in terms of self   di-interstitial complexes. Physica B&C Vol 116 B+C No1-3 pl83-6 Feb 1983
4. I.T.Flint , H.J Francis, A.D.Holland , A.Wells, X-ray sensitive CCD’s from 0KeV to 1MeV, The 10^th Symposium on Photoelectronic Imaging devices 1991. Imperial College university of London 1991. IOP conference series ISBN 0-85498 -411-9pp 281

Selected Patents:

• Laser Hybridisation                    GB0124916.8  (Marconi /Bookham)
• Laser machined waveguides       GB 0126560.2 (Marconi/Bookham)                         
• Integrated Optical Isolators        GB0124355.9 (Marconi/Bookham)
• Micro Mechanical devices            GB 001852.7   ( company EEV)
• Blowing fibre into coil winding     GB 0106763.6 (Marconi/Bookham)
• Monitoring surface properties      GB 0106792.5 (Marconi/Bookham)
• Insitu waveguide deposition        GB 0106794.1 (Marconi/Bookham)
• Microwave photonic filters           GB 05270013.5 (SELEX/ BAE Systems)
• Multi Input receiver                    GB 0407568.5   (SELEX/ BAE  Systems)
• Reduction of Intermodulation Distortions: GB1900552.9.
• A method of driving an MZM, an SSBs post manufacture GB1821175.5
• Distortion removal with stimulated (dynamic) Brillouin scattering GB1717084.6