Spectral Efficient Coding Schemes in Optical Communications

T. Lotz, W. Sauer-Greff, R. Urbansky
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引用次数: 2

Abstract

Achieving high spectral efficiency in optical transmissions has recently attracted much attention, aiming to satisfy the ever increasing demand for high data rates in optical fiber communications. Therefore, strong Forward Error Correction (FEC) coding in combination with multilevel modulation schemes is mandatory to approach the channel capacity of the transmission link. In this paper we give design rules on the joint optimization of coding and signal constellations under practical considerations. We give trade-offs between spectral efficiency and hardware complexity, by comparing coding schemes using capacity achieving constellations with bit-interleaved coded modulation and iterative decoding (BICM-ID) against applying conventional square quadrature amplitude modulation (QAM) constellations but employing powerful low complexity low-density parity-check (LDPC) codes. Both schemes are suitable for optical single carrier (SC) and optical orthogonal frequency-division multiplexing (OFDM) transmission systems, where we consider the latter one in this paper, due to well-studied equalization techniques in wireless communications. We numerically study the performance of different coded modulation formats in optical OFDM transmission, showing that for a fiber optical transmission link of 960 km reach the net spectral efficiency can be increased by ≈0.4 bit/s/Hz to 8.61 bit/s/Hz at a post FEC BER of <10-15 by using coded optimized constellations instead of coded 64-QAM.In this paper we propose a high spectral efficient coded modulation scheme for implementation in future optical communication systems operating at data rates beyond 400 Gb/s. In detail, we adapt the “Turbo Principle” to BICM-ID[8] and combine it with a high-rate outer algebraic code to obtain a post-FEC BER <10-15, which is a typical demand in optical transponders. Furthermore we give simple design principles for the design of BICM-ID based on the extrinsic information transfer (EXIT) chart analysis[9]. The optical channel is considered to be weakly-nonlinear. Therefore the proposed techniques are also applicable for single-carrier transmission; however we consider OFDM since it appears to be more appropriate for the high order modulation formats and efficient equalization algorithms that are well established in wireless communications.
光通信中的频谱高效编码方案
为了满足日益增长的光纤通信对高数据速率的需求,在光传输中实现高频谱效率是近年来备受关注的问题。因此,强前向纠错(FEC)编码与多电平调制方案相结合是必要的,以接近传输链路的信道容量。本文从实际考虑出发,给出了编码与信号星座联合优化的设计原则。我们给出了频谱效率和硬件复杂性之间的权衡,通过比较使用比特交错编码调制和迭代解码(BICM-ID)的容量实现星座的编码方案与使用传统的方形正交调幅(QAM)星座但使用强大的低复杂度低密度奇偶校验(LDPC)代码的编码方案。这两种方案都适用于光单载波(SC)和光正交频分复用(OFDM)传输系统,由于无线通信中的均衡技术得到了充分的研究,本文将考虑后一种方案。数值研究了不同编码调制格式在光OFDM传输中的性能,结果表明,在960 km的光纤传输链路上,在FEC后误码率<10-15的情况下,采用编码优化星座代替编码64-QAM,净频谱效率可提高约0.4 bit/s/Hz至8.61 bit/s/Hz。在本文中,我们提出了一个高频谱效率的编码调制方案,以实现未来的光通信系统在数据速率超过400gb /s。具体而言,我们将“Turbo原理”应用于BICM-ID[8],并将其与高速率外代数码相结合,获得fec后的BER <10-15,这是光转发器的典型需求。此外,我们给出了基于外在信息传递(extrinsic information transfer, EXIT)图分析的BICM-ID设计的简单设计原则[9]。光通道被认为是弱非线性的。因此,所提出的技术也适用于单载波传输;然而,我们考虑OFDM,因为它似乎更适合无线通信中建立的高阶调制格式和有效的均衡算法。
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来源期刊
International Journal of Online Engineering
International Journal of Online Engineering COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-
自引率
0.00%
发文量
0
审稿时长
12 weeks
期刊介绍: We would like to inform you, that iJOE, the ''International Journal of Online Engineering'' will accept now also papers in the field of Biomedical Engineering and e-Health''. iJOE will therefore be published from January 2019 as the ''International Journal of Online and Biomedical Engineering''. The objective of the journal is to publish and discuss fundamentals, applications and experiences in the fields of Online Engineering (remote engineering, virtual instrumentation and online simulations, etc) and Biomedical Engineering/e-Health. The use of cyber-physical systems, virtual and remote controlled devices and remote laboratories are the directions for advanced teleworking/e-working environments. In general, online engineering is a future trend in engineering and science. Due to the growing complexity of engineering tasks, more and more specialized and expensive equipment as well as software tools and simulators, shortage of highly qualified staff, and the demands of globalization and collaboration activities, it become essential to utilize cyber cloud technologies to maximize the use of engineering resources. Online engineering is the way to address these issues. Considering these, one focus of the International Journal of Online and Biomedical Engineering is to provide a platform to publish fundamentals, applications and experiences in the field of Online Engineering, for example: Remote Engineering Internet of Things Cyber-physical Systems Digital Twins Industry 4.0 Virtual Instrumentation. An important application field of online engineering tools and principles are Biomedical Engineering / e-Health. Topics we are interested to publish are: Automation Technology for Medical Applications Big Data in Medicine Biomedical Devices Biosensors Biosignal Processing Clinical Informatics Computational Neuroscience Computer-Aided Surgery.
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