Title :
VCSEL-Based Light Sources—Scalability Challenges for VCSEL-Based Multi-100- Gb/s Systems
Author :
Hofmann, Werner ; Bimberg, Dieter
Author_Institution :
Center of Nanophotonics, Tech. Univ. of Berlin, Berlin, Germany
Abstract :
Future high-performance computers require optical interconnects with aggregated Exa-Byte/s data transport. Densely packed arrays of vertical-cavity surface-emitting lasers (VCSELs) might present the only feasible technical solution. The high-speed properties of semiconductor lasers, however, are strongly affected by their operating temperature. Thermal crosstalk becomes dominant when densely packed arrays of high-speed VCSELs are required. In this paper, we derive the maximum bandwidth of future VCSEL-based optical interconnects from the influence of device heating occurring in high-speed VCSEL arrays. Furthermore, we estimate the scalability of this technology and address the challenges. From our calculations we obtain, that VCSEL arrays are scalable from a bandwidth density of 100 Gbps/mm2 with today´s devices up to a technological limit of 15 Tbps/mm2.
Keywords :
high-speed optical techniques; light sources; optical communication equipment; optical crosstalk; optical interconnections; semiconductor laser arrays; surface emitting lasers; thermo-optical effects; VCSEL; bandwidth density; bit rate 100 Gbit/s; densely packed arrays; light sources; optical interconnects; scalability; semiconductor lasers; thermal crosstalk; vertical-cavity surface-emitting lasers; Bandwidth; Heat sinks; Optical interconnections; Scalability; Servers; Vertical cavity surface emitting lasers; VCSEL arrays; Vertical-cavity surface-emitting laser (VCSEL); energy efficiency; high-performance computing; optical interconnects; scalability;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2012.2218588
