Intel® Ethernet Network Adapter I350-T4

The Intel Ethernet Network Adapter I350-T4 for OCP 3.0 includes enhancements for both virtualized and iSCSI environments. Intel uses
a suite of hardware assists that improve overall system performance by lowering the I/O overhead in virtualized environments. iSCSI simplifies SAN connectivity by eliminating the need for SAN-specific adapters or switches.

This adapter also includes power management technologies such as Energy Efficient Ethernet (EEE) and DMA Coalescing (DMAC). With advanced Power Management Technologies, customers can configure power options on the adapter and more effectively manage their power consumption.

The OCP NIC 3.0 specification defines a standardized design for a new generation of network adapters. Simple and straightforward form factors, clear manageability requirements, and improved serviceability help simplify deployment for current and emerging capabilities.

All Intel® Ethernet I350 Series Adapters include these technologies:

Flexible I/O Virtualization
The Intel® Ethernet Network Adapter I350 family includes Intel® Virtualization Technology for connectivity (Intel® VT-c) to deliver I/O virtualization and Quality of Service (QoS) features designed directly into the controller on the adapter. I/O virtualization advances network connectivity models used in today’s servers to more efficient models by providing Flexible Port Partitioning (FPP), multiple Rx/Tx queues, and on- controller QoS functionality that can be used in both virtual and non-virtual server deployments.
By taking advantage of the PCI-SIG SR-IOV specification, Intel® Ethernet products enable Flexible Port Partitioning (FPP). With FPP, virtual controllers can be used by the Linux host directly and/or assigned to virtual machines. With this port partitioning, administrators can create up to eight dedicated connections on a single Ethernet port for use in
bare-metal and virtualized server deployments.
In a bare-metal Linux server, host processes can be assigned to dedicated network resources to provide traffic isolation and balanced bandwidth allocation.
In a virtualized environment, a VM can be assigned to a virtual controller to reduce the CPU overhead seen when using a software-based network
bridge by offloading network traffic management to
the controller.