Aerial RAN CoLab Over-the-Air - ARC-OTA 1.3
ARC-OTA v1.3

Product Brief

  • A wideband, real-time platform to replace existing narrow-band, non-real-time systems

  • A full-featured platform for NG wireless evolution

  • C/C++ programmable from the physical layer through to the Core Node (CN)

  • Quick network onboarding and algorithm development in real-time networks

  • Accelerated AI experimentation in wireless RAN workloads

  • A pipeline for data collection, storage, and parsing using 3GPP schema for wireless communication.

The configuration and capabilities of ARC-OTA 1.3 are outlined in the following sections.

Number Antennas

4T4R

Number of Component Carriers 1x 100MHz carrier
Subcarrier Spacing (PDxCH; PUxCH, SSB) 30kHz
FFT Size 4096
MIMO layers DL: 2 layers; UL: 1 layers
Duplex Mode Release 15 SA TDD
Number of RRC connected UEs 16
Number of UEs/TTI 2
Frame structure and slot format DDDDDDSUUU
DDDSU
User plane latency (RRC connected mode) < 10ms one way for DL and UL
Synchronization and Timing IEEE 1588v2 PTP; SyncE; LLS-C3
Frequency Band n78
Max Transmit Power 22dBM at RF connector
Peak Throughput KPI DL: ~460Mbps; UL: ~112Mbps
Bi-directional UDP Traffic > 4.0 hours exercised (Dell R750 + A100X)
> 4.0 hours exercised (Gigabyte + A100 + CX6-DX)
Note

OTA test was performed with the following configuration: Samsung S22 + Gigabyte + DDDDDDSUUU.

Feature

Description

Software Containers A 3GPP Release 15 compliant and O-RAN 7.2 split 5G SA 4T4R wireless stack, with all network elements from Radio Access Network and 5G Core. Aerial CUDA-Accelerated RAN Layer 1 is integrated with Open Air Alliance (OAI) (https://openairinterface.org/) Distributed Unit (DU), Centralized Unit(CU), or a 5G NR gNB and 5G Core Node(CN) network elements.
Deployment Blueprint A blueprint to ease developer onboarding, staging, and integration of all advanced 5G network components, including step-by-step verification through bi-directional UDP traffic with tutorials, FAQs, and troubleshooting tips to configure all the network components for a quick-turnaround live network. SDK Manager automation takes this a step further and automates developer environment setup.
Network Component Blueprint Advanced 5G NR network component blueprint and NVIDIA lab integrated and OTA-qualified HW BOM manifest.
Source Code Access Complete access to source code in C/C++, from Layer 1 through 5GC to jump start customizations and next-generation algorithm research
Service Management The Kubernetes Service Management optional developer extension from Sterling provides two capabilities: Kubernetes Service Orchestration and Service Monitoring.

5G Fronthaul Features

RU Category

Category A

FH Split Compliance 7.2x with DL low-PHY to include Precoding, Digital BF, iFFT+CP and UL low-PHY to include FFT-CP, Digital BF
FH Ethernet Link 25Gbps x 1 lane
Transport encapsulation Ethernet
Transport header eCPRI
C Plane Conformant to O-RAN-WG4.CUS.0-v02.00 7.2x split
U Plane Conformant to O-RAN-WG4.CUS.0-v02.00 7.2x split
S Plane Conformant to O-RAN-WG4.CUS.0-v02.00 7.2x split
M Plane Conformant to O-RAN-WG4.CUS.0-v02.00 7.2x split
RU Beamforming Type Code book based

5G NR gNB Features

image61.png

Component

Capabilities

gNB PHY Aerial CUDA-Accelerated RAN Layer 1 PHY (cuPHY) adheres to 3GPP Release 15 standard specifications to deliver the following capabilities. PHY capabilities include the following:
  • Error detection on the transport channel and indication to higher layers
  • FEC encoding/decoding of the transport channel
  • Hybrid ARQ soft combining
  • Rate matching of the coded transport channel to physical channels
  • Mapping of the coded transport channel onto physical channels
  • Power weighting of physical channels
  • Modulation and demodulation of physical channels including
  • Frequency and time synchronization
  • Radio characteristics measurements and indication to higher layers
  • Multiple Input Multiple Output (MIMO) antenna processing
  • Transmit Diversity (TX diversity)
  • Digital and Analog Beamforming
  • RF processing

3GPP standards specifications that define the Layer 1 compliance are:

  • TS 38.211 (38.211 v15.8.0) numerologies, physical resources, modulation, sequence, signal generation
  • TS 38.212 (38.212 v15.8.0) Multiplexing and channel coding
  • TS 38.213 (38.213v15.8.0) Physical layer procedures for control
  • TS 38.214 (38.214v15.8.0) Physical layer procedures for data
  • TS 38.215 (38.215v15.8.0) Physical layer measurements
  • TS 38.104 (base station radio Tx and Rx) Base Station (BS) radio transmission and reception

Aerial CUDA-Accelerated RAN complies with ORAN FH CUS specification version 3 (version 4 for power scaling) Aerial CUDA-Accelerated RAN complies with northbound interfaces adopted by industry based on Small Cells Forum for Layer 1 and Layer 2 (SCF FAPI).

gNB MAC
  • MAC -> PHY configuration using NR FAPI P5 interface
  • MAC <-> PHY data interface using FAPI P7 interface for BCH PDU, DCI PDU, PDSCH PDU
  • Scheduler procedures for SIB1
  • Scheduler procedures for RA
    • Contention Free RA procedure
    • Contention Based RA procedure
      • Msg3 can transfer uplink CCCH, DTCH or DCCH messages
      • CBRA can be performed using MAC CE or C-RNTI
  • Scheduler procedures for CSI-RS
  • MAC downlink scheduler
    • phy-test scheduler (fixed allocation and usable also without UE)
    • regular scheduler with dynamic allocation
    • MCS adaptation from HARQ BLER
  • MAC header generation (including timing advance)
  • ACK / NACK handling and HARQ procedures for downlink
  • MAC uplink scheduler
    • phy-test scheduler (fixed allocation)
    • regular scheduler with dynamic allocation
    • HARQ procedures for uplink
  • Scheduler procedures for SRS reception
    • Periodic SRS reception
    • Channel rank computation up to 2x2 scenario
    • TPMI computation based on SRS up 4 antenna ports and 2 layers
  • MAC procedures to handle CSI measurement report
    • evaluation of RSRP report
    • evaluation of CQI report
  • MAC scheduling of SR reception
  • Bandwidth part (BWP) operation
    • Handle multiple dedicated BWPs
    • BWP switching through RRCReconfiguration method
gNB RLC
  • Segmentation and reassembly procedures
  • RLC Acknowledged mode supporting PDU retransmissions
  • RLC Unacknowledged mode
  • DRBs and SRBs establishment/handling and association with RLC entities
  • Timers implementation
  • Interfaces with PDCP, MAC
  • Interfaces with gtp-u (data Tx/Rx over F1-U at the DU)
  • Send/Receive operations according to 38.322 Rel.16
gNB PDCP
  • Integrity protection and ciphering procedures
  • Sequence number management, SDU discard and in-order delivery
  • Radio bearer establishment/handling and association with PDCP entities
  • Interfaces with RRC, RLC
  • Interfaces with gtp-u (data Tx/Rx over N3 and F1-U interfaces)
  • Send/Receive operations according to 38.323 Rel.16
gNB SDAP
  • Establishment/Handling of SDAP entities.
  • Transfer of User Plane Data
  • Mapping between a QoS flow and a DRB for both DL and UL
  • Marking QoS flow ID in both DL and UL packets
  • Reflective QoS flow to DRB mapping for UL SDAP data PDUs
  • Send/Receive operations according to 37.324 Rel.15
gNB X2AP
  • Integration of X2AP messages and procedures for the exchanges with the eNB over X2 interface according to 36.423 Rel. 15
gNB NGAP
  • Integration of NGAP messages and procedures for the exchanges with the AMF over N2 interface according to 38.413 Rel. 15
    • NGAP Setup request/response
    • NGAP Initial UE message
    • NGAP Initial context setup request/response
    • NGAP Downlink/Uplink NAS transfer
    • NGAP UE context release request/complete
    • NGAP UE radio capability info indication
    • NGAP PDU session resource setup request/response
  • Interface with RRC
gNB F1AP
  • Integration of F1AP messages and procedures for the control plane exchanges between the CU and DU entities according to 38.473 Rel. 16
    • F1 Setup request/response
    • F1 DL/UL RRC message transfer
    • F1 Initial UL RRC message transfer
    • F1 UE Context setup request/response
    • F1 gNB CU configuration update
  • Interface with RRC
  • Interface with gtp-u (tunnel creation/handling for F1-U interface)
gNB GTP-U
  • New gtp-u implementation supporting both N3 and F1-U interfaces according to 29.281 Rel.15
    • Interfaces with RRC, F1AP for tunnel creation
    • Interfaces with PDCP and RLC for data send/receive at the CU and DU respectively (F1-U interface)
    • Interface with SDAP for data send/receive, capture of GTP-U Optional Header, GTP-U Extension Header and PDU Session Container.

5G Core Features

OAI CN OAI CN supports AMF, AUSF, NRF, NSSF, SMF, UDM, UDR, UPF network functions of the 5GC

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