Microresonator Frequency Comb Based High-Speed Transmission of Intensity Modulated Direct Detection Data

TL;DR

This paper demonstrates high-speed data transmission using microresonator frequency combs with direct detection, achieving 120 Gb/s and 240 Gb/s over 2 km fiber, suitable for data center applications.

Contribution

It introduces the use of microresonator frequency combs with a single laser for direct detection high-speed data transmission, expanding their application beyond coherent detection.

Findings

Achieved 120 Gb/s and 240 Gb/s data rates over 2 km fiber.

Low power penalty of 0.1 dB compared to back-to-back.

Compatible with industry standards for data center transceivers.

Abstract

Globally, the long-haul transmission of ultra-high bandwidth data is enabled through coherent communications. Driven by the rapid pace of growth in interconnectivity over the last decade, long-haul data transmission has reached capacities on the order of tens to hundreds of terabits per second, over fiber reaches which may span thousands of kilometers. Data center communications however operate in a different regime, featuring shorter reaches and characterized as being more cost and power sensitive. While integrated microresonator frequency combs are poised to revolutionize light sources used for high-speed data transmission over fiber, their use has been limited to coherent detection schemes. In this paper, we demonstrate the use of microresonator frequency combs pumped with a single laser for the transmission of high-speed data, importantly using direct detection schemes. We achieve 120 Gb/s and 240 Gb/s aggregate data transmission for 30 Gb/s non-return-to-zero (NRZ) and 60 Gb/s pulse modulation amplitude 4 (PAM4) modulation formats respectively over 2 km of optical fiber, exceeding the reach, single lane data rate, and aggregate data rates specified in Parallel Single Mode 4 (PSM4) and Course Wavelength Division Multiplex 4 (CWDM4) multi-source agreements. Remarkably, we achieve an extremely low power penalty of 0.1 dB compared to back-to-back characterization. The results firmly cement CMOS-compatible micro-resonator frequency combs based high-speed data transmission as a viable technology for the cost and power sensitive data center transceiver industry.