Regular Articles

Vol. 22, No. 10, pp. 60–65, Oct. 2024. https://doi.org/10.53829/ntr202410ra1

Transponder Aggregator for 64-degree CDC-ROADM Nodes

Keita Yamaguchi, Kenya Suzuki, and Osamu Moriwaki

Abstract

Colorless, directionless, and contentionless reconfigurable optical add/drop multiplexing (CDC-ROADM) nodes will require throughputs exceeding 8 Pbit/s by 2035, and transponder aggregators supporting high-degree and multi-band functionality will be crucial devices. We demonstrated a low-loss multicast switch capable of supporting a 300-nm bandwidth and 64 degrees, a suitable device for this purpose. The prototype’s insertion loss was less than 8.0 dB in all paths, and the extinction ratio exceeded 40 dB.

Keywords: ROADM, MCS, WSS

PDF

1. Introduction

Colorless, directionless, and contentionless reconfigurable optical add/drop multiplexing (CDC-ROADM) has been widely deployed in core and metro networks due to its high flexibility [1–5]. Due to the rapid growth in network traffic at a rate of 30% per year, the handling granularity and node throughput at ROADM nodes have increased by approximately 10 times over the last decade (Table 1). Extrapolating this trend, it is anticipated that in 2035, signal handling granularity will reach 10 Tbit/s, and node throughput will be required in the order of 8 Pbit/s. In contrast, the frequency-utilization efficiency is approaching saturation [5]. Instead of increasing capacity per band, it is essential to increase the wavelength bandwidth and number of connected degrees of nodes, which is equivalent to the number of connected transmission fibers. For example, on the basis of a 16-degree node using the C+L bands currently in practical use, a configuration that triples throughput by 2030 can be achieved by combining a 1.5-fold increase in bandwidth (utilizing the S-band) and a doubling of the number of fibers (supporting 32 degrees). By 2035, a configuration could achieve eight times the throughput by doubling the bandwidth and quadrupling the number of fibers (supporting 64 degrees).


Table 1. Configuration of CDC-ROADM nodes and various requirements.

Even within such high-throughput nodes, the functionality of CDC to interconnect transponders in any direction at any wavelength remains important. To fulfil this requirement, transponder aggregators (TPAs) supporting increasingly wide wavelength bands and an extended number of degrees are necessary. We analyzed the requirements for TPAs in this context and their impact on switching characteristics and developed multicast switches (MCSs) as suitable enablers. We also developed a prototype 64×4 MCS, based on a planar lightwave circuit (PLC) platform for 64-degree links, and demonstrated its operation with less than 8-dB loss from the S- to L-bands and a high extinction ratio at a bandwidth of 300 nm.

2. TPA for future CDC-ROADM nodes

A conceptual diagram of a CDC-ROADM node supporting multi-degree and multi-band functionality is shown in Fig. 1. It consists of a wavelength cross-connect [6–8] and transponder aggregation [9–12]. The typical configuration consists of a pair of wavelength-selective switches (WSSs) for each link degree and wavelength-path routing. Therefore, the expansion of link degrees is accompanied by an increase in the number of WSSs. WSSs with multi-band support can also accommodate signals over a wide wavelength band [13, 14]. TPAs, however, offer CDC functionality, namely the capability to connect transponders to all link degrees regardless of wavelength. Thus, two qualitative changes are required: an increase in the number of ports on the side connecting to the WSSs and support for a wider wavelength range.


Fig. 1. Schematic of a CDC-ROADM node supporting multi-degree and multi-band functionality.

Two types of switches are currently in practical use as TPAs, the characteristics of which are summarized in Fig. 2. One type is the contentionless M×N WSS with multiple 1×N WSSs and M×1 switches facing each other. This type of switch can independently switch each wavelength channel, resulting in no intrinsic loss and achieving an insertion loss as low as 7 dB even when accommodating numerous transponders [10]. However, the integration of multiple WSSs into a single module with spatial optics leads to relatively high size and cost. The other type is an MCS with 1×N splitters and M×1 switches facing each other [11]. This switch can be built using only waveguides, reducing size and cost. However, as the number of channel ports increases with the number of transponders to be accommodated, branching losses occur at the splitter. For example, the branching losses when the number of channel ports is 4 and 8 is 6 and 9 dB, respectively.


Fig. 2. Types and characteristics of TPAs.

For both types of switches, the figure of merit (FoM) of the switching scale is the product of the number of degree ports, which are the ports connected to the WSS in each degree, and the number of channel ports [9]. The same FoM can be achieved at a similar size and cost on the same platform. To accommodate an increase in the number of link degrees of nodes, the number of degree ports in the TPA is increased, and the number of channel ports is reduced accordingly, assuming the same FoM. The graph in Fig. 3 shows the relationship between the number of channel ports and insertion loss of the TPA in relation to the number of link degrees. The FoM is assumed to be 16 × 26 = 416 for the M×N WSS [14] and 16 × 16 = 256 for the MCS [15]. Note that the insertion loss of the MCS decreases with the number of channel ports, and the number of link degrees of the nodes increases. The loss of the M×N WSS remains constant at around 8 dB regardless of the number of node degrees, while the loss of the MCS decreases to the same level as the number of node degrees increases to 64. The number of channel ports corresponding to 64 degrees is 6 for the M×N WSS and 4 for the MCS, which is not a significant difference. This indicates that in a CDC-ROADM node in 2035, when the number of node degrees will increase to 64, the disadvantages in terms of optical characteristics of the MCS caused by losses due to branching are almost eliminated, and the size and cost advantages become more prominent. The number of transponders that can be connected to the TPA is reduced to 6 or 4, which is inconsistent with expanding node capacity, but considering the trend of increasing handling granularity, parallelization can solve the mismatch.


Fig. 3. Varied numbers of channel ports of a TPA switch with number of node degrees.

3. 64×4 MCS based on PLC

A prototype 64×4 MCS with a silica-based PLC was demonstrated to verify low-loss operation across multiple bands and support for high-order links. The PLC uses a 2%-Δ core and was fabricated through a combination of flame hydrolysis deposition and reactive ion etching [16]. The circuit configuration comprises a combination of a 16-in-1 4×4 MCS and 4-in-1 1×16 switch circuits. The chip size is 85 × 50 mm, and the Mach–Zehnder interferometer switch and splitter/coupler are designed for the wide wavelength bandwidth, as previously reported [17].

The evaluation results of the optical properties from the S- to L-bands on the prototype are as follows. The average insertion losses in the S-band (1500 nm), C-band (1568 nm), and L-band (1612 nm) were 7.49, 7.37, and 7.40 dB, respectively. Figure 4(a) shows histograms of the insertion loss in each band for all connection paths, including the connection losses at the single-mode-fiber-waveguide interface at two locations. All connection paths and wavelength bands exhibit insertion losses below 8 dB, which is almost equivalent to the M×N WSS over a wider wavelength band. Figure 4(b) shows the extinction ratio in each band for all connection paths, demonstrating a robust extinction ratio of over 40 dB under all conditions.


Fig. 4. Histograms of (a) insertion loss and (b) extinction ratio experimental values for the 64×4 MCS prototype.

The transmission spectra are shown next. Figure 5(a) shows the extinction-ratio spectrum for the connection between a single degree port (Deg #22) and all channel ports (Ch #1, #2, #3, #4). Similarly, Figure 5(b) shows the extinction-ratio spectrum for the connection between a single channel port (Ch #1) and four degree ports (Deg #1, 22, 43, 64). In both cases, the extinction ratio remains above 40 dB across the wide range of 1400–1700 nm, equivalent to more than a four-band wavelength range from the S- to U-bands. These results indicate that PLC-based MCSs supporting 64-degree links can operate with low losses and high extinction ratios over a wide bandwidth of 300 nm and beyond. As the number of links increases in future CDC-ROADM nodes, the size and cost advantages of PLC-MCS will become more prominent, rendering this type of switch a suitable TPA.


Fig. 5. Extinction-ratio spectra between (a) a single degree port and all channel ports and (b) a single channel port and four degree ports.

4. Summary

In contrast to the CDC-ROADM node configuration of 16 degrees using the C+L bands, which is currently being implemented, in 2035, a configuration with 8 times the throughput can be envisaged by supporting 4 bands and 64 degrees, corresponding to double the bandwidth and 4 times the number of fibers. To provide CDC functionality in such a node, a TPA corresponding to the increased bandwidth and number of degrees is required. In this context, we developed an MCS as a suitable enabler. We also developed a prototype 64×4 PLC-MCS supporting 64 degrees and demonstrated its operation with less than 8-dB loss from the S- to L-bands, alongside a high extinction ratio at a bandwidth of 300 nm.

References

[1] P. N. Ji and Y. Aono, “Colorless and directionless multi-degree reconfigurable optical add/drop multiplexers,” Proc. of the 19th Annual Wireless and Optical Communications Conference (WOCC 2010), Shanghai, China, pp. 1–5, 2010.
https://doi.org/10.1109/WOCC.2010.5510664
[2] S. Yamamoto, H. Taniguchi, Y. Kisaka, S. Camatel, Y. Ma, D. Ogawa, K. Hadama, M. Fukutoku, T. Goh, and K. Suzuki, “First demonstration of a C + L band CDC-ROADM with a simple node configuration using multiband switching devices,” Opt. Express, Vol. 29, No. 22, pp. 36353–36365, 2021.
https://doi.org/10.1364/OE.433383
[3] K. Suzuki, O. Moriwaki, K. Hadama, K. Yamaguchi, H. Taniguchi, Y. Kisaka, D. Ogawa, M. Takeshita, S. Camatel, Y. Ma, and M. Fukutoku, “A Transponder Aggregator With Efficient Use of Filtering Function for Transponder Noise Suppression,” J. Lightw. Technol., Vol. 41, No. 10, pp. 3074–3083, 2023.
https://doi.org/10.1109/JLT.2023.3240252
[4] Y. Ma, K. Suzuki, I. Clarke, A. Yanagihara, P. Wong, T. Saida, and S. Camatel, “Novel CDC ROADM Architecture Utilizing Low Loss WSS and MCS without Necessity of Inline Amplifier and Filter,” Proc. of the 42nd Optical Fiber Communication Conference (OFC 2019), M1A.3, San Diego, CA, USA, 2019.
https://doi.org/10.1364/OFC.2019.M1A.3
[5] K. Suzuki, M. Ota, Y. Morimoto, K. Yamaguchi, F. Hamaoka, S. Sugawara, T. Sasai, T. Kobayashi, M. Nakamura, S. Katayose, T. Umeki, D. Ogawa, Y. Ma, S. Camatel, M. Fukutoku, Y. Miyamoto, and O. Moriwaki, “Double-decker CDC-ROADM node for multi-band network with wavelength band granularity,” Proc. of the 47th Optical Fiber Communication Conference (OFC 2024), Th1I.2, San Diego, CA, USA, 2024.
https://doi.org/10.1364/OFC.2024.Th1I.2
[6] K. Yamaguchi, Y. Ikuma, M. Nakajima, K. Suzuki, M. Itoh, and T. Hashimoto, “M×N Wavelength Selective Switches Using Beam Splitting By Space Light Modulators,” IEEE Photon. J., Vol. 8, No. 2, 0600809, 2016.
https://doi.org/10.1109/JPHOT.2016.2527705
[7] R. Hashimoto, S. Yamaoka, Y. Mori, H. Hasegawa, K. Sato, K. Yamaguchi, K. Seno, and K. Suzuki, “First Demonstration of Subsystem-Modular Optical Cross-Connect Using Single-Module 6×6 Wavelength-Selective Switch,” J. Lightw. Technol., Vol. 36, No. 7, pp. 1435–1442, 2018.
https://doi.org/10.1109/JLT.2018.2800082
[8] N. Nemoto, Y. Ikuma, K. Suzuki, O. Moriwaki, T. Watanabe, M. Itoh, and T. Takahashi, “8×8 Wavelength Cross Connect with Add/Drop Ports Integrated in Spatial and Planar Optical Circuit,” Proc. of the 41st European Conference on Optical Communication (ECOC 2015), Tu.3.5.1, Valencia, Spain, 2015.
https://doi.org/10.1109/ECOC.2015.7341950
[9] Y. Ikuma, K. Suzuki, N. Nemoto, E. Hashimoto, O. Moriwaki, and T. Takahashi, “Low-Loss Transponder Aggregator Using Spatial and Planar Optical Circuit,” J. Lightw. Technol., Vol. 34, No. 1, pp. 67–72, 2016.
https://doi.org/10.1109/JLT.2015.2464673
[10] P. D. Colbourne, S. McLaughlin, C. Murley, S. Gaudet, and D. Burke, “Contentionless Twin 8×24 WSS with Low Insertion Loss,” Proc. of the 41st Optical Fiber Communication Conference (OFC 2018), Th4A.1, San Diego, CA, USA, 2018.
https://doi.org/10.1364/OFC.2018.Th4A.1
[11] T. Watanabe, K. Suzuki, and T. Takahashi, “Silica-based PLC Transponder Aggregators for Colorless, Directionless, and Contentionless ROADM,” Proc. of the 35th Optical Fiber Communication Conference and Exposition and National Fiber Optic Engineers Conference (OFC/NFOEC 2012), Los Angeles, CA, USA, OTh3D.1, 2012.
https://doi.org/10.1364/OFC.2012.OTh3D.1
[12] Press release issued by Lumentum, “Lumentum Recognized in Three Optical Communications Product Categories at 2024 Lightwave Innovation Reviews,” Feb. 22, 2024.
https://www.lumentum.co.jp/ja/media-room/news-releases/lumentum-recognized-three-optical-communications-product-categories-2024
[13] K. Seno, K. Yamaguchi, K. Suzuki, and T. Hashimoto, “Wide-Passband C+L-band Wavelength Selective Switch by Alternating Wave-Band Arrangement on LCOS,” Proc. of the 44th European Conference on Optical Communication (ECOC 2018), We1C.6, Rome, Italy, 2018.
https://doi.org/10.1109/ECOC.2018.8535452
[14] GlobeNewswire, “Finisar Australia Releases World’s First C+L-band Wavelength Selective Switch,” Aug. 2020.
https://www.globenewswire.com/news-release/2020/08/31/2086099/0/en/Finisar-Australia-Releases-World-s-First-C-L-band-Wavelength-Selective-Switch.html
[15] A. Yanagihara, K. Yamaguchi, T. Goh, and K. Suzuki, “Surface Mount Technology for Silica-Based Planar Lightwave Circuit and Its Application to Compact 16×16 Multicast Switch,” IEICE Trans. Electron., Vol. E103-C, No. 11, pp. 679–684, 2020.
https://doi.org/10.1587/transele.2019OCP0008
[16] K. Okamoto, “Recent progress in high-silica planar lightwave circuits,” Proc. of Integrated Photonics Research, ThE1, Monterey, CA, USA, 1991.
https://doi.org/10.1364/IPR.1991.ThE1
[17] T. Goh, K. Yamaguchi, and A. Yanagihara, “Multiband Optical Switch Technology,” Proc. of the 45th Optical Fiber Communication Conference (OFC 2022), W4B.1, San Diego, CA, USA, 2022.
https://doi.org/10.1364/OFC.2022.W4B.1
Keita Yamaguchi
Senior Manager, Signal Processing Device Project, NTT Device Innovation Center.
He received a B.S. and M.S. in physics from Tsukuba University, Ibaraki, and Dr. Eng. in computational science and engineering from Nagoya University, Aichi, in 2009, 2011, and 2019. In 2011, he joined NTT. He is currently with NTT Device Innovation Center. His research interests include silica-based waveguides. He has been a member of the subcommittee of Passive Components of the Optical Fiber Communication Conference (OFC) since 2024. He is a member of the Institute of Electronics, Information and Communication Engineers (IEICE) and Optica.
Kenya Suzuki
Distinguished Researcher, Signal Processing Device Project, NTT Device Innovation Center.
He received a B.E. and M.E. in electrical engineering and Dr. Eng. in electronics engineering from the University of Tokyo in 1995, 1997, and 2000. In 2000, he joined NTT. From September 2004 to September 2005, he was a visiting scientist with the Research Laboratory of Electronics at the Massachusetts Institute of Technology, Cambridge, MA, USA. From 2008 to 2010, he was with NTT Electronics Corporation, where he was involved in the development and commercialization of silica-based waveguide devices. In 2014, he was a guest chair professor at the Tokyo Institute of Technology. He served as the secretary of the Optoelectronics Research Technical Committee of IEICE from 2014 to 2016. He was a member of the subcommittee of Passive Optical Devices for Switching and Filtering of the OFC from 2019 to 2021 and served as the chair of the subcommittee in 2022. He is currently a distinguished researcher at NTT Device Innovation Center. His research interests include optical functional devices, optical signal processing and automation of device design, and fabrication and evaluation of optical devices. He was the recipient of the Young Engineer Award and Electronics Society Activity Testimonial from IEICE in 2003 and 2016. He is a member of the Institute of Electrical and Electronics Engineers (IEEE), Optica, IEICE, and the Physical Society of Japan (JPS).
Osamu Moriwaki
Director, Signal Processing Device Project, NTT Device Innovation Center.
He received a B.E. and M.E. in electrical engineering from the University of Tokyo in 1998 and 2000. In 2000, he joined NTT. He is an expert committee member of the Technical Committee on Photonic Network of IEICE. His research interests include optical switching devices and wavelength division multiplexed network systems. He is a member of IEEE and IEICE.

↑ TOP