2003 - Fellow of the Royal Academy of Engineering (UK)
1997 - IEEE Fellow For contributions to the development of microwave photonic devices and systems.
Alwyn J. Seeds mostly deals with Optoelectronics, Optics, Laser, Semiconductor laser theory and Electronic engineering. His Optoelectronics study frequently links to other fields, such as Semiconductor device. His study in Optics is interdisciplinary in nature, drawing from both Frequency response and Semiconductor.
His work on Quantum well, Spectral purity, Laser frequency and Optical frequencies as part of general Laser research is frequently linked to Controller, bridging the gap between disciplines. His research integrates issues of Phase-locked loop and Photonic integrated circuit in his study of Semiconductor laser theory. His Electronic engineering research incorporates themes from Transmission and Microwave.
His primary areas of investigation include Optoelectronics, Optics, Laser, Photonics and Electronic engineering. Optoelectronics is a component of his Quantum dot laser, Semiconductor laser theory, Photodiode, Terahertz radiation and Silicon studies. His work investigates the relationship between Optics and topics such as Phase-locked loop that intersect with problems in Optical filter.
His Laser research includes elements of Wavelength, Wavelength-division multiplexing and Gallium arsenide. Alwyn J. Seeds combines subjects such as Wireless, Optical fiber, Heterodyne and Antenna with his study of Photonics. His research investigates the connection between Electronic engineering and topics such as Transmission that intersect with issues in Signal.
Alwyn J. Seeds mainly focuses on Optoelectronics, Photonics, Laser, Terahertz radiation and Silicon. His Optoelectronics research incorporates elements of Phase-locked loop and Phase noise. His work carried out in the field of Photonics brings together such families of science as Wireless, Telecommunications, Antenna and Electronic engineering, Bandwidth.
His work deals with themes such as Wavelength-division multiplexing and Superlattice, which intersect with Laser. His Terahertz radiation study is concerned with Optics in general. His Optics course of study focuses on Signal and Transmission.
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A.J. Seeds;K.J. Williams.
Journal of Lightwave Technology (2006)
The 2017 terahertz science and technology roadmap
S S Dhillon;M S Vitiello;E H Linfield;A G Davies.
Journal of Physics D (2017)
IEEE Transactions on Microwave Theory and Techniques (2002)
Electrically pumped continuous-wave III–V quantum dot lasers on silicon
Siming Chen;Wei Li;Jiang Wu;Qi Jiang.
Nature Photonics (2016)
Long-wavelength InAs/GaAs quantum-dot laser diode monolithically grown on Ge substrate
Huiyun Liu;Ting Wang;Qi Jiang;Richard Hogg.
Nature Photonics (2011)
1.3-μm InAs/GaAs quantum-dot lasers monolithically grown on Si substrates.
Ting Wang;Huiyun Liu;Andrew Lee;Francesca Pozzi.
Optics Express (2011)
Optical control of microwave semiconductor devices
A.J. Seeds;A.A.A. De Salles.
IEEE Transactions on Microwave Theory and Techniques (1990)
TeraHertz Photonics for Wireless Communications
Alwyn J. Seeds;Haymen Shams;Martyn J. Fice;Cyril C. Renaud.
Journal of Lightwave Technology (2015)
Optically generated true-time delay in phased-array antennas
I. Frigyes;A.J. Seeds.
IEEE Transactions on Microwave Theory and Techniques (1995)
High-performance phase locking of wide linewidth semiconductor lasers by combined use of optical injection locking and optical phase-lock loop
A.C. Bordonalli;C. Walton;A.J. Seeds.
Journal of Lightwave Technology (1999)
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