Analysis

imec demonstrate hybrid CMOS silicon photonics transceiver

6th March 2015
Siobhan O'Gorman
0

At the the 2015 International Solid State Circuits Conference, imec, in collaboration with the Tyndall National Institute, the University of Leuven (KULeuven) and the Ghent University, demonstrated a 4x20Gb/s Wavelength Division Multiplexing (WDM) hybrid CMOS silicon photonics transceiver. 

Hybrid CMOS silicon photonics transceivers, which transmit and receive data over single-mode optical fibre, are expected to be of particular importance in next-gen datacentre connectivity. By leveraging existing CMOS manufacturing and 3D assembly infrastructure, the hybrid CMOS silicon photonics platform enables high integration density and reduced power consumption, as well as high yield and low manufacturing cost. Combined with wavelength division multiplexing capability, highly scalable single-mode optical transceivers can be constructed, meeting the growing need for interconnect bandwidth in next-gen cloud infrastructure.

Imec’s CMOS silicon photonics transceiver comprises a Silicon Photonics (SiPh) chip, a flip-chip integrated with a low-power 40nm CMOS chip. The SiPh chip, fabricated on imec’s 25Gb/s silicon photonics platform (iSiPP25G), comprises an array of four compact 25Gb/s ring modulators which are coupled to a common bus waveguide to allow WDM transmission. On the receive side, a ring-based, low-loss (2dB) demultiplexing filter with 300GHz channel spacing is implemented and further connected to an array of four 25Gb/s Ge waveguide photodetectors. Both the ring modulators and the ring WDM filters include highly efficient integrated heating elements to tune their resonant wavelengths to the desired WDM channels. The CMOS chip includes four differential 20Gb/s ring modulator drivers and four 20Gb/s trans-impedance amplifiers. A 12-channel single-mode fibre array is packaged onto the grating coupler array on the chip, using a planar approach developed at Tyndall National Institute.

Error-free operation was demonstrated in a 20Gb/s loop-back experiment for all four WDM channels as well as with two channels running together. The dynamic power consumption of the transceiver, including the CMOS driver and receiver, was less than 2pJ/bit. Thermal tuning of the WDM channel wavelengths consumed only 7mW/nm per channel. The transceiver can be further scaled to higher bandwidth capacity by adopting more advanced CMOS technology and by adding more WDM channels, enabling optical modules for 100GbE, 400GbE and beyond for future datacentre interconnects.

Product Spotlight

Upcoming Events

View all events
Newsletter
Latest global electronics news
© Copyright 2024 Electronic Specifier