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) |
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
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:
3GPP standards specifications that define the Layer 1 compliance are:
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 |
|
gNB RLC |
|
gNB PDCP |
|
gNB SDAP |
|
gNB X2AP |
|
gNB NGAP |
|
gNB F1AP |
|
gNB GTP-U |
|
5G Core Features
OAI CN | OAI CN supports AMF, AUSF, NRF, NSSF, SMF, UDM, UDR, UPF network functions of the 5GC |