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access icon free VCSEL-based optical links in burst-mode slow optical power ramp-up and how to achieve ultra-short wake-up times

© The Institution of Engineering and Technology
Received 29/06/2017, Published 18/08/2017
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Optical links in datacentres operate mainly in burst mode. The utilisation might be as low as 10%, i.e. most of the time the link is idle, but still consumes power. It would therefore be desirable to put these links into a low-power sleep mode during idle signal by reducing the bias, and to operate the electronics and laser only when data is actually being transmitted. The laser is typically implemented with vertical cavity surface-emitting lasers (VCSELs). VCSELs should not be biased below their threshold current as otherwise an extensive turn-on delay will be incurred. A significant wake-up time is still observed in VCSELs even if the bias is not reduced during idle and only logic zeros are transmitted. With reduced bias, an unacceptable wake-up time is observed. The authors present measured data and propose a high-amplitude wake-up pulse at the beginning of the data burst, to significantly speed up the wake-up time. Measurements show the effectiveness of this pulse.

Inspec keywords: laser cavity resonators; optical communication equipment; computer centres; optical pulse generation; surface emitting lasers; optical links

Other keywords: idle signal; burst-mode slow optical power ramp-up; ultra-short wake-up times; high-amplitude wake-up pulse; VCSEL-based optical links; wake-up time; turn-on delay; sleep mode; datacentres; logic zeros; vertical cavity surface-emitting laser; data burst

Subjects: Optical communication equipment; Design of specific laser systems; Laser beam modulation, pulsing and switching; mode locking and tuning; Laser beam modulation, pulsing and switching; mode locking and tuning; Semiconductor lasers; Free-space optical links; Lasing action in semiconductors; Ultrafast optical techniques; Laser resonators and cavities; Optical communication devices, equipment and systems; Laser resonators and cavities

References

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