Title :
Reconfigurable Digital Functionality of Composite Resonator Vertical Cavity Lasers
Author :
Choquette, Kent D. ; Chen, Chen ; Harren, Ann C Lehman ; Grasso, Daniel M. ; Plant, David V.
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Illinois at Urbana-Champaign, Urbana, IL, USA
Abstract :
The composite resonator vertical cavity surface laser can perform multiple digital functionalities at greater than 10 GHz bandwidth, including: direct intensity modulation, wavelength division multiplexing, multilevel pulse amplitude modulation, and optical picosecond pulse generation. The unique attributes of these microcavity lasers arise from the two strongly coupled optical cavities which can be electrically injected independently. Reconfiguration among multiple functionalities is achieved by control of the three terminal signals input into the laser and can be achieved using a high-speed digital circuit whose logic can be adjusted to provide appropriate modulation voltages to the optically coupled laser cavities. The novel optical properties of composite resonators are reviewed with a focus on several different digital functionalities possible from this semiconductor laser.
Keywords :
laser cavity resonators; micro-optics; optical communication equipment; optical couplers; optical modulation; optical pulse generation; pulse amplitude modulation; reviews; semiconductor lasers; surface emitting lasers; wavelength division multiplexing; composite resonator vertical cavity lasers; direct intensity modulation; electrical injection; high-speed digital circuit; microcavity lasers; modulation voltages; multilevel pulse amplitude modulation; optical picosecond pulse generation; reconfigurable digital functionality; review; semiconductor laser; strongly coupled optical cavities; wavelength division multiplexing; Cavity resonators; Distributed Bragg reflectors; High speed optical techniques; Modulation; Optical resonators; Vertical cavity surface emitting lasers; High speed modulation; semiconductor lasers; vertical cavity surface emitting lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2011.2171328
