Jitter Analysis of Optical Clock Distribution Networks in Silicon Photonics

Author

Krune, Edgar ; Jamshidi, Kambiz ; Voigt, K. ; Zimmermann, L. ; Petermann, K.

Author_Institution

Tech. Univ. Berlin, Berlin, Germany

Volume

32

Issue

22

fYear

2014

fDate

Nov.15, 15 2014

Firstpage

4378

Lastpage

4385

Abstract

The lower limit of timing jitter due to optical and thermal noise is derived for the transmission of pulses as a clock signal. Clock distribution networks are analyzed in silicon photonics in providing pulse trains to electronic circuits. Two photon absorption and free carrier effects in silicon waveguides define maximum output power of the clock distribution network in dependence on pulsewidth and pulse energy. Simulations show that multiple electronic circuits on a silicon chip can be synchronized by optical pulses with femtosecond precision.

Keywords

clock distribution networks; integrated optoelectronics; optical noise; optical waveguides; silicon; thermal noise; timing jitter; two-photon processes; Si; clock signal; femtosecond precision; free carrier effects; jitter analysis; maximum output power; multiple electronic circuits; optical clock distribution networks; optical noise; optical pulses; pulse energy; pulse trains; pulse transmission; pulse width; silicon chip; silicon photonics; silicon waveguides; thermal noise; timing jitter; two-photon absorption; Clocks; Equations; Noise; Optical pulses; Optical waveguides; Timing jitter; Free carrier effects; optical clock distribution; photodetection; silicon photonics; timing jitter; two photon absorption;

fLanguage

English

Journal_Title

Lightwave Technology, Journal of

Publisher

ieee

ISSN

0733-8724

Type

jour

DOI

10.1109/JLT.2014.2356645

Filename

6899577