I. Introduction

Orthogonal frequency-division multiplexing (OFDM) has been extensively studied to combat RF microwave multipath fading and has emerged as the leading modulation technology for the wireless and wire-line systems in RF domain. Recently, an optical equivalent of RF OFDM called coherent optical OFDM (CO-OFDM) has been proposed [1] and has become a promising technique for high spectral efficiency and dispersion resilient transmission [2], [3]. As the IP traffic continues to grow at a rapid pace, the 100-Gb/s Ethernet is being considered as the next-generation transport standard for IP networks [4]. As the data rate approaches 100 Gb/s and beyond, the electrical bandwidth required for CO-OFDM would be at least 15 GHz [5] and is not cost-effective to implement even with the best commercial digital-to-analog converters (DACs) and analog-to-digital converters (ADCs) in silicon integrated circuit (IC) [6]. To overcome this electrical bandwidth bottleneck, we propose and demonstrate the concept of OBM-OFDM to divide the entire OFDM spectrum into multiple orthogonal bands. Due to the inter-band orthogonality, the multiple OFDM bands with zero or small guard bands can be multiplexed and de-multiplexed without inter-band interference. With this scheme, transmission of 107-Gb/s CO-OFDM signal over 1000 km (10 × 100 km) standard single-mode fiber (SSMF) has been realized using only erbium-doped fiber amplifiers (EDFAs) and without a need for optical dispersion compensation. Although several transmission experiments at 100 Gb/s and above have been demonstrated at longer distances relying on a dispersion-compensation module and Raman amplification (RA) in each span [7], [8], our work has achieved the 1000-km transmission without optical dispersion compensation and without RA beyond 100 Gb/s. The 107-Gb/s OBM-OFDM can be also considered as 5 × 21.4 Gb/s WDM channels without frequency guard band, occupying 32-GHz optical bandwidth, implying a high spectral efficiency of 3.3 bit/s/Hz using only 4-QAM encoding. To the best of our knowledge, we have also achieved a record back-to-back OSNR sensitivity of 15.8 dB at 107 Gb/s for a BER of .