Our targets cater to small, medium, and large AI/HPC data centers, offering the capability to manage the interconnection of over 100K GPUs. Each Optical virtual Circuit Switch (OvCS) is equipped with 32, 64, or 128 wavelengths of 400G/800G each.

DOVINSY-5232: Engineered for 50 server racks (800 GPUs), featuring 25 OvCSs each with 32 400G ports, delivering 102.4 Tbps bandwidth.

DOVINSY-7264: Tailored for a maximum of 196 server racks (3136 GPUs), equipped with 49 OvCSs boasting 64 800G ports each, achieving a bandwidth of 409.6 Tbps.

DOVINSY-Cluster-based: Designed for higher-scale setups, supporting the interconnection of more than 100K GPUs.


Product Features
DOVINSY Boasts SDN+ Optical Thruway Control for Smart Networking
Proactive Control: thruways are made available whenever needed.

Reactive Control: Thruways are dynamically adjusted as needed, based on a load-balancing mechanism.

The real-time dashboard ensures smooth operations of DOVINSY system, enabling the management staff to oversee the real time operational status and be alerted if any problems are detected.



Ultra-Low Latency and Ultra-High Bandwidth
Ethernet switching network exhibits poor performance under higher traffic loads and burstness.

DOVINSY guarantees an end-to-end tail latency of less than 10μs, ensuring superior performance even under high traffic loads and locality considerations.

DOVINSY seamlessly supports various data rates per wavelength, such as 400G and 800G, without requiring any modifications. With the current product models, DOVINSY achieves ultra-high bandwidth that is 2 times higher than that of electrical switching network solutions.

Superior Energy Efficiency
The DOVINSY system achieves remarkable 90% power savings compared to electronic switching systems, making it the most power-efficient datacenter networking technology in the industry.

DU Inline Accelerator Card
Introduction & Overview
5G RAN virtualization involves CU (Centralized Unit) and DU (Distributed Unit) virtualization. The hardware platform is generally a COTS server with NIC and hardware accelerators, where needed. Especially in compute-heavy scenarios, hardware deployments can significantly accelerate any open RAN implementation and raw performance, reducing the number of CPU cores required and power consumption. Looking at the architecture for layer 1 acceleration, there are two fundamental approaches – look-aside acceleration and inline acceleration. The principal difference between them is that in look-aside acceleration, only selected functions are sent to the accelerator and back to the CPU. In inline acceleration, parts of or the whole data flow and functions are sent through the accelerator. For higher bandwidth Open RAN applications, full L1 processing offload may be required. In this case, an inline hardware DU acceleration will likely deliver the best results with the lowest latency and minimum cores required.
The PAC series is the world’s 1st ASIC-based PCIe DU solution, which leverages NXP’s LayerscapeR Access family of programmable baseband processors (LA-12 series+LX-2 series) to provide multiple 25GbE eCPRI interfaces and maximum support for four 4T4R 100Mhz RRH/RU. With less OPEX and leveraging the current facility with the minimal installation process, GENEViSiO’s PCIe accelerator card, built with a powerful NXP 5G solution in PCIe x8 form factor, can be easily deployed in the existing platforms to run the O-RAN fronthaul protocols and to offload the DU function onto the host. On the other hand, the PAC-01x could work seamlessly with the CU in the MEC servers for the lower layer split (LLS) to ensure the quality of the ultra-low latency as well as the bandwidth. With the different software configurations to support high-PHY offload or full DU/REC offload, memory expansion, and 1pps & GPS timing synchronization, the PCIe accelerator will bring more flexibility and empower the end customer with more 5G capabilities in edge computing. Moreover, either in the Public or local 5G infrastructure, the different sizes of the PAC series could easily fit into the existing equipment and move to the 5G with low latency and high-speed bandwidth on the fly. (See the NXP introduction video: Genevisio DU Inline Accelerator Card Video ) Open Fronthaul Small Cell
Introduction & Overview
NPN series is a Small Cell with open front haul solutions. Through the cloud deployment, it can be Small Cell with open fronthaul (DU+CU) or DU only. Small Cell with open fronthaul is an essential ingredient for flexibility of deployment. Open front haul provides RU connectivity to Small Cell to fulfill different radio technology and radio bands from sub 6 to mmWave.
Small Cell solution is under 85W to provide at least 4 x CC (4T4R 100Mhz) performance and indoor-friendly, acoustic solutions with good flexibility for different installations like DIN-rail or wall mount systems.
NPN series is an industrial temperature fanless model for hard environments like manufacturing, power substation, railway, agriculture, and environment monitoring 5G applications, etc. Open fronthaul provides RU connectivity to a Small Cell to fulfill different radio technology and radio bands from sub 6 to mmWave. 5G UPF Accelerator Card
Introduction & Overview
The UPF acceleration plays a key role in the 5G core network to realize the transformative vision of low latency and high throughput. 5G core networks transform data processing, offering enhanced speed, volume, and services. It enhances mobile broadband experiences and supports many different verticals like VR, IoT, Automotive, and Healthcare; however, these 5G services set very challenging and demanding requirements on latency and throughput for a better experience. The User Plane Function (UPF) is an essential 5G core component that handles the critical operation of processing subscriber traffic between the RAN (Radio Access Network) and the DN (Data Network). The operators will need a solution that can handle network functions like low latency switching and slicing without sacrificing throughput. GENEViSiO’s UPF SmartNIC solution PAC-u10 supporting low latency and high throughput requirements will be one of the best solutions for carrier building 5G core networks.