# Mode-Division Multiplexing for Silicon Photonic Network-on-chip

**Authors:** Xinru Wu, Chaoran Huang, Ke Xu, Chester Shu, and Hon Ki Tsang

arXiv: 1702.03216 · 2017-08-02

## TL;DR

This paper demonstrates a silicon photonic intra-chip optical communication link using mode-division multiplexing with advanced modulation, achieving 2x100 Gb/s capacity in a compact, integrated setup suitable for high bandwidth on-chip data transfer.

## Contribution

The work introduces a compact, integrated MDM-based optical link with advanced modulation formats supporting 100 Gb/s per mode, enabling high-capacity on-chip communications.

## Key findings

- Each mode channel achieves 100 Gb/s line rate.
- The system supports a total capacity of 2x100 Gb/s.
- Net payload data rate is 84 Gb/s per mode.

## Abstract

Optical interconnect is a potential solution to attain the large bandwidth on-chip communications needed in high performance computers in a low power and low cost manner. Mode-division multiplexing (MDM) is an emerging technology that scales the capacity of a single wavelength carrier by the number of modes in a multimode waveguide, and is attractive as a cost-effective means for high bandwidth density on-chip communications. Advanced modulation formats with high spectral efficiency in MDM networks can further improve the data rates of the optical link. Here, we demonstrate an intra-chip MDM communications link employing advanced modulation formats with two waveguide modes. We demonstrate a compact single wavelength carrier link that is expected to support 2x100 Gb/s mode multiplexed capacity. The network comprised integrated microring modulators at the transmitter, mode multiplexers, multimode waveguide interconnect, mode demultiplexers and integrated germanium on silicon photodetectors. Each of the mode channels achieves 100 Gb/s line rate with 84 Gb/s net payload data rate at 7% overhead for hard-decision forward error correction (HD-FEC) in the OFDM/16-QAM signal transmission.

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Source: https://tomesphere.com/paper/1702.03216