Xiaodan Pang scite author profile

Abstract-To accommodate the demand of exponentially increased global wireless data traffic, the prospective data rates for wireless communication in the market place will soon reach 100 Gbit/s and beyond. In the lab environment, wireless transmission throughput has been elevated to the level of over 100 Gbit/s attributed to the development of photonic-assisted millimeter wave (MMW) and THz technologies. However, most of recent demonstrations with over 100 Gbit/s data rates are based on spatial or frequency division multiplexing techniques, resulting in increased system's complexity and energy consumption. Here, we experimentally demonstrate a single channel 0.4 THz photonic-wireless link achieving a net data rate of beyond 100 Gbit/s by using a single pair of THz emitter and receiver, without employing any spatial/frequency division multiplexing techniques. The high throughput up to 106 Gbit/s within a single THz channel is enabled by combining spectrally efficient modulation format, ultra-broadband THz transceiver and advanced digital signal processing (DSP) routine. Besides that, our demonstration from system-wide implementation viewpoint also features high transmission stability, and hence shows its great potential to not only decrease the system's complexity, but also meet the requirements of prospective data rates for bandwidth-hungry short-range wireless applications.

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200 Gbps/Lane IM/DD Technologies for Short Reach Optical Interconnects

Pang

Jacobsen

et al. 2020

J. Lightwave Technol.

152

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Client-side optics are facing an ever-increasing upgrading pace, driven by upcoming 5G related services and datacenter applications. The demand for a single lane data rate is soon approaching 200 Gbps. To meet such high-speed requirement, all segments of traditional intensity modulation direct detection (IM/DD) technologies are being challenged. The characteristics of electrical and optoelectronic components, and the performance of modulation, coding and digital signal processing (DSP) techniques are being stretched to their limits. In this context, we witnessed technological breakthroughs in several aspects, including development of broadband devices, novel modulation formats and coding, and high-performance DSP algorithms for the past few years. A great momentum has been accumulated to overcome the aforementioned challenges. In this paper, we focus on IM/DD transmissions, and provide an overview of recent research and development efforts on key enabling technologies for 200 Gbps per lane and beyond. Our recent demonstrations of 200 Gbps short-reach transmissions with 4level pulse amplitude modulation (PAM) and discrete multitone signals are also presented as examples to show the system requirements in terms of device characteristics and DSP performance. Apart from digital coherent technologies and advanced direct detection systems, such as Stokes-vector and Kramers-Kronig schemes, we expect high-speed IM/DD systems will remain advantageous in terms of system cost, power consumption and footprint for short reach applications in the short-to mid-term perspective.

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Comprehensive Study of Equalization-Enhanced Phase Noise in Coherent Optical Systems

Kakkar

Navarro

Schatz

et al. 2015

J. Lightwave Technol.

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140/180/204-Gbaud OOK Transceiver for Inter- and Intra-Data Center Connectivity

Estaran

Mardoyan

Jorge

et al. 2019

J. Lightwave Technol.

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2 × 300 Gbit/s Line Rate PS-64QAM-OFDM THz Photonic-Wireless Transmission

Jia

Zhang

Wang

et al. 2020

J. Lightwave Technol.

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Xiaodan Pang

0.4 THz Photonic-Wireless Link With 106 Gb/s Single Channel Bitrate

200 Gbps/Lane IM/DD Technologies for Short Reach Optical Interconnects

Comprehensive Study of Equalization-Enhanced Phase Noise in Coherent Optical Systems

140/180/204-Gbaud OOK Transceiver for Inter- and Intra-Data Center Connectivity

2 × 300 Gbit/s Line Rate PS-64QAM-OFDM THz Photonic-Wireless Transmission

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