Projektbeschreibung
Silizium-Photonik-Mikrowellenoszillatoren nähern sich Kommerzialisierung
Hochwertige Mikrowellenquellen sind für zahlreiche Anwendungen wie zum Beispiel Radare, drahtlose Netzwerke und Satelliten überaus nützlich. Insbesondere optoelektronische Oszillatoren haben gegenüber ihren elektronischen Gegenstücken viele Vorteile. So sind sie unempfindlich gegenüber elektromagnetischen Störungen, leicht, kompakt und für die Langstreckenübertragung geeignet. Das EU-finanzierte Projekt SIOMO hat die Kommerzialisierung eines optoelektronischen Mikrowellenoszillators auf Silizium-Photonik-Basis zum Ziel, der sich auf die kürzlich im Rahmen des Projekts PHENOMEN vorgestellte Kavitäts-Optomechanik stützt. Dieser Mikrowellenoszillator, der nicht in sich selbst rückkoppelt, weist bei Frequenzen im Gigahertzbereich bemerkenswert niedrige Rauschzahlen auf.
Ziel
High-quality microwave sources are required in multiple applications (radar, wireless networks, satellites, etc.). Typically, low-noise microwave oscillators are made by applying frequency multiplication to an electronic source. This requires a cascade of frequency-doubling stages, which strongly reduces the power of the final signal. Recently, different techniques to produce microwave tones via optical means have been proposed. The resulting device is an optoelectronic oscillator (OEO), with many advantages with respect to its electronic counterparts (immunity to EM interference, low weight, compactness, long-distance transport, etc).
In the FET-Open project PHENOMEN, partner UPV designed and demonstrated a novel optomechanical cavity on a silicon chip displaying, for the first time, a localized mechanical mode at frequencies around 4 GHz within a full phononic bandgap and with a large OM coupling rate. By pumping the cavity with a blue-detuned laser, a high-Q microwave tone at f = 3.874 GHz is created at driving power of the order of 1mW. The noise figure of this OEO becomes as low as -101 dBc/Hz at 100 kHz, which is a remarkable good value for an OEO oscillating at GHz frequencies without any feedback mechanism. In addition, stronger pumping of the cavity enables the generation of multiple harmonics, thus reaching microwave frequencies above 10 GHz. Therefore, with the advantages of extreme compactness and Silicon-technology compatibility, this approach is a very promising candidate to build ultraweight OEOs, highly appropriate for space applications. Notably, the use of photonic technologies in space is one of the main activities of partner DAS.
SIOMO aims at turning a silicon-photonics optoelectronic oscillator based on cavity optomechanics - recently demonstrated in the FET-Open project PHENOMEN by partner UPV - into a genuine economic innovation by addressing its technological transfer to the space sector via partner DAS.
Wissenschaftliches Gebiet
- natural sciencesphysical scienceselectromagnetism and electronicsoptoelectronics
- natural sciencesphysical sciencesopticscavity optomechanics
- engineering and technologymechanical engineeringvehicle engineeringaerospace engineeringsatellite technology
- engineering and technologyelectrical engineering, electronic engineering, information engineeringinformation engineeringtelecommunicationsradio technologyradar
- natural scienceschemical sciencesinorganic chemistrymetalloids
Programm/Programme
Thema/Themen
Aufforderung zur Vorschlagseinreichung
Andere Projekte für diesen Aufruf anzeigenUnterauftrag
H2020-FETOPEN-2018-2019-2020-03
Finanzierungsplan
CSA - Coordination and support actionKoordinator
46022 Valencia
Spanien