Back to Search Start Over

III-V on silicon micro-photonic circuits for frequency downconversion of RF signals

Authors :
Shahram Keyvaninia
L. Thomassen
Roel Baets
Erwin Bente
M. Tassaert
Sylwester Latkowski
Gunther Roelkens
J Marien
Photonic Integration
Source :
INTERNATIONAL CONFERENCE ON SPACE OPTICS-ICSO 2014, International Conference on Space Optics, ICSO 2014
Publication Year :
2017
Publisher :
SPIE, 2017.

Abstract

RF frequency downconverters are of key importance in communication satellites. Classically, this is implemented using an electronic mixer. In this paper we explore the use of photonic technology to realize the same functionality. The potential advantages of such an approach compared to the classical microwave solutions are that it is lighter weight, has lower power consumption and can be made smaller if photonic technology is used. An additional advantage is the fact that the optical local oscillator (LO) reference can easily be transported over longer distances than the equivalent LO signal in the microwave domain due to the large bandwidth and low loss and dispersion of optical fiber. Another big advantage is that one can envision the use of short pulse trains as the LO - starting off from a sinusoidal RF reference - in order to exploit subsampling. Subsampling avoids the need for high frequency LO references, which is especially valuable if a downconversion over several 10s of GHz is required. In this paper we present the operation principle of such a photonic frequency downconverter and describe the performance of the developed micro-photonic building blocks required for this functionality. These micro-photonic building blocks are implemented on a III-V semiconductor-on-silicon photonic platform. The components include a micro-photonic hybridly modelocked laser, a 30GHz electroabsorption modulator and an intermediate frequency (1.5GHz) photodetector.

Details

ISSN :
0277786X and 1996756X
Database :
OpenAIRE
Journal :
International Conference on Space Optics — ICSO 2014
Accession number :
edsair.doi.dedup.....4215e90d6e9c6bc8c1bb5422a6fb94a7
Full Text :
https://doi.org/10.1117/12.2304216