NTT Docomo Expands Open vRAN Options in its 5G OREC

We have done quite a few blog posts on NTT Docomo on our blogs (see related posts at the bottom) as they always share a lot of latest useful and relevant information. In a blog post last year, we talked about their 5G Open RAN Ecosystem (OREC). 

Back in September, NTT Docomo announced that it will be adding a fourth type of flexible and highly scalable virtualized base station (vRAN) to its verification environment for Open RAN that will allow equipment and components of various vendors to integrate via standardized specifications. The press release said:

The new virtualized base station will combine NEC Corporation's open virtualized RAN software, Red Hat Openshift, Qualcomm Technologies, Inc.'s inline accelerator cards and Hewlett Packard Enterprise's servers. This will be DOCOMO's first time to use the Qualcomm® X100 5G RAN Accelerator Card and the HPE ProLiant DL110 Telco server, the latter optimized specifically for Open RAN workloads to improve system performance and power efficiency.

Since February, DOCOMO has been providing global carriers with access to its Shared Open Lab environment to allow them to mix and match the equipment and components of various vendors in order to verify performance with virtualized base stations. In addition to three types of virtualized base station equipment/system configurations that carriers have been accessing so far, the new configuration will become available for verification in the Shared Open Lab starting in 2023.

As the increasing global availability of 5G continues to raise interest in Open RAN, DOCOMO has been a leader in helping telecoms worldwide to prepare to introduce this highly versatile new technology. In February 2021, DOCOMO was joined by 12 global equipment vendors in establishing the 5G Open RAN Ecosystem (OREC) to promote Open RAN, which supported the development of the virtualized base station being announced today.

DOCOMO and its OREC partners plan to continue adding new equipment/system combinations before and after commercializing virtualized base stations, which is expected within the current fiscal year ending in March 2023.

Through the promotion of Open RAN, DOCOMO looks forward to continuing to enhance the efficiency and flexibility mobile communication networks around the world.

In fact their OREC page has this and a lot more details here.

At Telecom Infra Project's Fyuz 22 conference, NTT Docomo and other operators shared their vision, progress and approach to Open RAN. You can watch the panel discussion here.

Related Posts:

• Telecoms Infrastructure Blog: NTT Docomo's 5G Network is based on 'Open RAN' Principles
• Telecoms Infrastructure Blog: NTT Docomo's 5G RAN Infrastructure
• The 3G4G Blog: Open RAN Terminology and Players
• Operator Watch Blog: NTT Docomo outlines their 5G Journey and 5G Network Deployment details
• Operator Watch Blog: NTT Docomo is Open and Virtualized Networks Leader
• Telecoms Infrastructure Blog: Docomo 5G Open Innovation Cloud
• Connectivity Technology Blog: NTT Docomo and Airbus Demonstrate Zephyr HAPS Wireless Broadband Connectivity
• Free 6G Training: NTT Docomo is Hoping to Repeat 5G Experimental Trials Success with 6G
• Free 6G Training: Special Articles on 5G Evolution & 6G in NTT Docomo Technical Journal
• Free 6G Training: NTT Docomo's revised '5G Evolution and 6G' White Paper 

NTT Docomo's 5G RAN Infrastructure

We looked at NTT Docomo's 5G Journey and 5G Network Deployment details recently here. In this post we will look at the 5G Infrastructure that Docomo is using in their network. It is detailed in their latest Technical Journal here. In this post we will look at the infrastructure part only.

The 5G network configuration is shown in Figure 4. With a view to 5G service development, NTT DOCOMO developed a Central Unit (CU) that consolidates the Base Band (BB) signal processing section supporting 5G, extended existing BB processing equipment known as high-density Base station Digital processing Equipment (BDE), and developed a 5G Radio Unit (RU) having signal transmit / receive functions. Furthermore, to have a single CU accommodate many RUs, NTT DOCOMO developed a 5G version of the FrontHaul Multiplexer (FHM) deployed in LTE. Each of these three types of equipment is described below.

1) CU
(a) Development concept: With the aim of achieving a smooth rollout of 5G services, NTT DOCOMO developed a CU that enables area construction without having to replace existing equipment while minimizing the construction period and facility investment. This was accomplished by making maximum use of the existing high-density BDE that performs BB signal processing, replacing some of the cards of the high-density BDE, and upgrading the software to support 5G.

(b) CU basic specifications: An external view of this CU is shown in Photo 1. This equipment has the features described below (Table 3). As described above, this equipment enables 5G-supporting functions by replacing some of the cards of the existing high-density BDE. In addition, future software upgrades will load both software supporting conventional 3G/LTE/LTE-Advanced and software supporting 5G. This will enable the construction of a network supporting three generations of mobile communications from 3G to 5G with a single CU.

The existing LTE-Advanced system employs advanced Centralized RAN (C-RAN) architecture proposed by NTT DOCOMO. This architecture is also supported in 5G with the connection between CU and RUs made via the fronthaul. Standardization of this fronthaul was promoted at the Open RAN (O-RAN) Alliance jointly established in February 2018 by five operators including NTT DOCOMO.  Since the launch of 5G services, the fronthaul in the NTT DOCOMO network was made to conform to these O-RAN fronthaul specifications that enable interoperability between different vendors, and any CU and RU that conform to these specifications can be interconnected regardless of vendor. The specifications for inter-connecting base-station equipment also con-form to these O-RAN specifications, which means that a multi-vendor connection can be made between a CU supporting 5G and a high-density BDE supporting LTE-Advanced. This enables NTT DOCOMO to deploy a CU regardless of the vendor of the existing high-density BDE and to quickly and flexibly roll out service areas where needed while making best use of existing assets. In addition, six or more fronthaul connections can be made per CU and the destination RU of each fronthaul connection can be se-lected. Since 5G supports wideband trans-mission beyond that of LTE-Advanced, the fronthaul transmission rate has been extend-ed from the existing peak rate of 9.8 Gbps to a peak rate of 25 Gbps while achieving a CU/RU optical distance equivalent to that of the existing high-density BDE.

2) RU
(a) Development concept: To facilitate flexible area construction right from the launch of 5G services, NTT DOCOMO developed the low-power Small Radio Unit (SRU) as the RU for small cells and developed, in particular, separate SRUs for each of the 3.7 GHz, 4.5 GHz, and 28 GHz frequency bands provided at the launch of the 5G pre-commercial service in September 2019. Furthermore, with an eye to early expansion of the 5G service area, NTT DOCOMO developed the Regular power Radio Unit (RRU) as the RU for macrocells to enable the efficient creation of service areas in suburbs and elsewhere.

A key 5G function is beamforming that aims to reduce interference with other cells and thereby improve the user’s quality of experience. To support this function, NTT DOCOMO developed a unit that integrates the antenna and 5G radio section (antenna-integrated RU). It also developed a unit that separates the antenna and 5G radio section (antenna-separated RU) to enable an RU to be placed alongside existing 3G/LTE/LTE-Advanced Radio Equipment (RE) and facilitate flexible installation even for locations with limited space or other constraints.

(b) SRU basic specifications: As described above, NTT DOCOMO developed the SRU to enable flexible construction of 5G service areas. It developed, in particular, antenna-integrated SRUs to support each of the 3.7 GHz, 4.5 GHz, and 28 GHz frequency bands provided at the launch of the 5G pre-commercial service and antenna-separated SRUs to support each of the 3.7 GHz and 4.5 GHz frequency bands (Photo 2). These two types of SRUs have the following features (Table 4).

The antenna-integrated RU is equipped with an antenna panel to implement the beamforming function. In the 3.7 GHz and 4.5 GHz bands, specifications call for a maximum of 8 beams, and in the 28 GHz band, for a maximum of 64 beams. An area may be formed with the number of transmit/receive beams tailored to the TDD Config used by NTT DOCOMO. In addition, the number of transmit/receive branches is 4 for the 3.7 GHz and 4.5 GHz bands and 2 for the 28 GHz band, and MIMO transmission/reception can be performed with a maximum of 4 layers for the former bands and a maximum of 2 layers for the latter band.

The antenna-separated SRU is configured with only the radio as in conventional RE to save space and facilitate installation. With this type of SRU, the antenna may be installed at a different location. Moreover, compared to the antenna-integrated SRU operating in the same frequency band, the antenna-separated SRU reduces equipment volume to 6.5ℓ or less. The antenna-separated SRU does not support the beamforming function, but features four transmit/receive branches the same as the antenna-integrated SRU for the same frequency band.

(c) RRU basic specifications: The RRU was developed in conjunction with the 5G service rollout as high-power equipment compared with the SRU with a view to early expansion of the 5G service area (Photo 3). This type of equipment has the following features (Table 5).

Compared with existing Remote Radio Equipment (RRE) for macrocells, the volume of RRU equipment tends to be larger to support 5G broadband, but in view of the latest electronic device trends, NTT DOCOMO took the lead in developing and deploying an antenna-separated RRU that could save space and reduce weight. Maximum transmission power is 36.3 W/100 MHz/branch taking the radius of a macrocell area into account. The RRU features four transmit/receive branches and achieves the same number of MIMO transmission/reception layers as the antenna-separated SRU.
NTT DOCOMO also plans to deploy an antenna-integrated RRU at a later date. The plan here is to construct 5G service areas in a flexible manner making best use of each of these models while taking installation location and other factors into account.

3) 5G FHM
The 5G FHM is equipment having a multiplexing function for splitting and combining a maximum of 12 radio signals on the fronthaul. It was developed in conjunction with the 5G service rollout the same as RRU (Photo 4).

If no 5G FHM is being used, each RU is accommodated as one cell, but when using a 5G FHM, a maximum of 12 RUs can be accommodated as one cell in a CU. At the launch of 5G services, this meant that more RUs could be accommodated in a single CU when forming a service area in a location having low required radio capacity (Figure 5). Additionally, since all RUs transmit and receive radio signals of the same cell, the 5G FHM can inhibit inter-RU interference and the occurrence of Hand-Over (HO) control between RUs as in the conventional FHM. Furthermore, the 5G FHM supports all of the 5G frequency bands, that is, the 3.7 GHz, 4.5 GHz, and 28 GHz bands, which means that service areas can be constructed in a flexible manner applying each of these frequency bands as needed.

All the fronthaul and other interfaces that Docomo used in their network was based on O-RAN alliance specifications. In a future post, we will look at some of the details.

Related Posts: 

• Operator Watch Blog: NTT Docomo outlines their 5G Journey and 5G Network Deployment details
• The 3G4G Blog: NTT Docomo's Vision on 5G Evolution and 6G
• Connectivity Technology Blog: Futuristic Glass Antenna by NTT Docomo and AGC
• Telecoms Infrastructure Blog: Docomo 5G Open Innovation Cloud
• Operator Watch Blog: NTT Docomo Provides an Overview of 5G Commercial Service
• Operator Watch Blog: NTT Docomo's Aggressive 5G Expansion Plan
• Operator Watch Blog: NTT Docomo's 5G Launch on 25 March 2020
• Operator Watch Blog: NTT Docomo presentation on 5G Launch Plans and Use Cases Solutions Partnership
• The 3G4G Blog: Couple of talks by NTT Docomo on 5G and Beyond (pre-6G)
• The 3G4G Blog: Nice short articles on 5G in 25th Anniversary Special NTT Docomo Technical Journal
• Telecoms Infrastructure Blog: NTT Docomo's Underground LTE Small Cells with possibility to deploy 5G in future
• Connectivity Technology Blog: Will NB-IoT Survive?
• Telecoms Infrastructure Blog: Drones for Tower Inspections and Optimization
• Operator Watch Blog: NTT Docomo: Bringing 5G to the Rugby World Cup
• Operator Watch Blog: NTT Docomo's Green Base Stations
• Operator Watch Blog: Japan allocates 5G Spectrum in 3.7GHz, 4.5GHz and 28GHz bands

SuperMicro's 5G Pole-Mounted DU Server Solution

Back in December 2019, Supermicro launched Server Class Edge Systems for Open 5G Radio Access Network (RAN) Solutions. These new SuperServers offer O-RAN Open-Platform Software, Intel Xeon Scalable Processors, GPUs, FPGA and IP65-rated protective enclosures for Pole-Mounted Cell Tower Deployments. The solutions for 5G cell tower deployments leverage fully-configurable SuperServers based on 2nd Gen Intel Xeon Scalable processors and Intel Xeon D processors, O-RAN compliant partner software, and ability to operate in harsh environments. These capabilities accelerate the mobile network evolution from proprietary hardware/software to open source software and disaggregated hardware for 5G installations.

The press release states:

“Supermicro’s data center customers and global telecommunication operators are asking for non-proprietary disaggregated hardware and software 5G solutions supporting multi-vendor web-scale networks, said Charles Liang, president, and CEO of Supermicro. “Supermicro’s new SuperServer solutions provide the 5G network infrastructure with maximum deployment flexibility and efficient total cost of ownership (TCO).”

Supermicro’s two new systems are its first servers for 5G, the Intelligent Edge, and other embedded applications to be based on 2nd Gen Intel Xeon processors. The E403-9P-FN2T is built for demanding environments and includes three PCI-E slots for GPU and FPGA accelerator cards. The compact 1U 1019P-FHN2T is well-suited for controlled environments such as micro data centers and re-purposed central office locations and features two full-height full-length PCI-E slots.

With these expansion slots, Supermicro can provide real-time Edge AI inferencing via GPU cards, and accelerate 5G RAN software and open-standard site-to-site communication using the Intel FPGA Programmable Acceleration Card N3000. These new servers complement Supermicro’s successful Intel Xeon D-based 1019D and E403 models. Supermicro is developing IP65-rated protective enclosures to meet the needs of outdoor environments such as cell towers and microcell sites.

5G Physical Layer splits can be seen in the picture above. While 4G used the BBU + RRU/RRH architecture, 5G will have a Central Unit (CU) and a Distributed Unit (DU). A Radio Unit (RU) may be present in some scenarios as well.

The Outdoor Edge Systems page on their website provides more information about the Pole-Mounted IP65 Server Platform for 5G and the Intelligent Edge. We will end with a video that depicts their vision



Related Posts:

• The 3G4G Blog: A quick tutorial on Open RAN, vRAN & White Box RAN
• Telecoms Infrastructure Blog: Ultimate Guide to the Telecom Infra Project (TIP)
• The 3G4G Blog: SCF Releases 5G Functional API to Enable Open Small Cells Ecosystem