**Author details**

Jing Wang\*, Zhensheng Jia, Luis Alberto Campos and Curtis Knittle CableLabs, Louisville, CO, United States

\*Address all correspondence to: j.wang@cablelabs.com

© 2018 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/ by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

**87**

*Delta-Sigma Digitization and Optical Coherent Transmission of DOCSIS 3.1 Signals in Hybrid…*

Report.pdf

nbnco.com.au/content/dam/nbnco2/ documents/HFC%20Delivering%20 Gigabit%20Broadband%20Ovum%20

[10] Hamzeh B, Toy M, Fu Y, Martin J. DOCSIS 3.1: Scaling broadband cable to gigabit speeds. IEEE Communications

[11] Toy M, Martin J, Schmitt M, Blake V.

Magazine. 2015;**53**(3):108-113

Next generation cable networks with DOCSIS 3.1 technology. IEEE Communications Magazine.

[12] Mehmood H, Rahman S, Cioffi JM. Bit loading profiles for high-speed data in DOCSIS 3.1. IEEE Communications Magazine.

[13] Rice D. DOCSIS 3.1 technology and hybrid fiber coax for multi-Gbps broadband. In: Optical Fiber Communication Conference (OFC)

[14] Salib H. FTTU: MSO perspective. Optical Fiber Communications Conference (OFC) 2016; paper Th1I.1

[15] Cable Television Laboratories, Inc. Data-Over-Cable Service

Interface Specifications, DOCSIS 3.1. Physical Layer Specification, CM-SP-PHYv3.1-I09-160602; Jun 2016

[16] Cable Television Laboratories, Inc. DOCSIS 3.1 Physical & MAC Layer Quick Reference Pocket Guide; Sep 2014

[17] Sundaresan K. DOCSIS 3.1 High Level Overview at NANOG 59. Cable Television Laboratories, Inc; 2013. https://www.nanog.org/sites/default/ files/wed.general.sundaresan.docsis.35.

[18] Al-Banna A, Cloonan T. The spectral efficiency of DOCSIS 3.1 systems. Arris

pdf

2015;**53**(3):106-107

2015;**53**(3):114-120

2015; paper Th4B.1

*DOI: http://dx.doi.org/10.5772/intechopen.82522*

[1] Kramer G, Pesavento G. Ethernet passive optical network (EPON): Building a next-generation optical access network. IEEE Communications

[2] Park S-J, Lee C-H, Jeong K-T, Park H-J, Ahn J-G, Song K-H. Fiber-to-thehome services based on wavelengthdivision-multiplexing passive optical network. Journal of Lightwave Technology. 2004;**22**(11):2582-2591

[3] Luo Y, Zhou X, Effenberger F, Yan X,

Peng G, Qian Y, et al. Time- and wavelength-division multiplexed passive optical network (TWDM-PON) for next-generation PON stage 2 (NG-PON2). Journal of Lightwave Technology. 2013;**31**(4):587-593

[4] China Mobile. C-RAN the Road towards Green RAN (Version 2.5).

[5] Checko A, Christiansen HL, Yan Y, Scolari L, Kardaras G, Berger MS, et al. Cloud RAN for mobile networks—A

Communications Surveys & Tutorials.

[6] Pfeiffer T. Next generation mobile fronthaul and midhaul architectures.

[7] Pizzinat A, Chanclou P, Saliou F, Diallo T. Things you should know about fronthaul. IEEE Journal of Lightwave Technology. 2015;**33**(5):1077-1083

[8] Toy M. Cable Networks, Services, and Management. IEEE Press Series on Networks and Services Management. John Wiley & Sons; 2015. ISBN-10:

[9] Ovum report. HFC: Delivering Gigabit Broadband. http://www.

White Paper; Oct 2011

technology overview. IEEE

IEEE/OSA Journal of Optical Communications and Networking.

2015;**17**(1):405-426

2015;**7**(11):B38-B45

1118837592, chapter 1

Magazine. 2002;**40**(2):66-73

**References**

*Delta-Sigma Digitization and Optical Coherent Transmission of DOCSIS 3.1 Signals in Hybrid… DOI: http://dx.doi.org/10.5772/intechopen.82522*
