In a method of operating network-based storage devices, a first storage device having a first local key among a plurality of storage devices is set as a first main storage device. The storage devices are connected to each other through a network. A volume of at least a part of the plurality of storage devices is set and managed by the first storage device based on a first control signal received from an external host device. A second local key is received by the first storage device from a second storage device having the second local key among the plurality of storage devices. The first local key and the second local key are transmitted by the first storage device to the external host device.

In a method of operating network-based storage devices, a first storage device having a first local key among a plurality of storage devices is set as a first main storage device. The storage devices are connected to each other through a network. A volume of at least a part of the plurality of storage devices is set and managed by the first storage device based on a first control signal received from an external host device. A second local key is received by the first storage device from a second storage device having the second local key among the plurality of storage devices. The first local key and the second local key are transmitted by the first storage device to the external host device.

Methods and apparatuses for transmitting data through a switch-based network in an in-vehicle communications network system. In an example transmission-based method, the method includes for a transmitter device generating, by a generator, a reservoir data stream (RSSj). The method also includes transmitting the reservoir data stream (RSSj) through the switch-based network. The method further includes, when a new data stream from the transmitter device to a receiver device is needed, replacing, by an injector, at least part of the reservoir data stream (RSSj) by a new data stream.

A system and method for an adaptive network of network access nodes comprises a global network operations center (GNOC) receiving operator inputs and generating a global policy according to the operator inputs. The GNOC and/or a distributed network gateway (GW) generate configuration commands for configurations for at least one of the network access nodes based on the global policy, transmit the configuration commands to at least one of the network access nodes, and receive telemetry from at least one of the network access nodes. The distributed network GW transmits a summary of key performance indicators (KPIs) to the GNOC and the GNOC revises the global policy according to the summary of KPIs.

With advanced compute capabilities and growing convergence of wireless standards, it is desirable to run multiple wireless standards, e.g., 4G, 5G NR, and Wi-Fi, on a single signal processing system. In the present disclosure, two baseband processors are used with each processor dedicated for one type of signal processing, such as 5G or Wi-Fi. The two baseband processors are interlinked via a chip-to-chip interconnect link for ingress and egress data transfer between the two processors. These two processors share an Ethernet link for benefits including cost saving, reduction in overall chipset power, and reduced form factor of the enclosure. Application of the disclosed embodiments may realize concurrent 5G Fronthaul and Wi-Fi traffic processing on the same Ethernet link. Such an application may be applied to other related scenarios, including Ethernet link sharing for dual Wi-Fi baseband processors, and Ethernet link sharing for Wi-Fi and gNodeB deployments, etc.

Methods, systems, and computer programs are presented for processing Ethernet packets at a Field Programmable Gate Array (FPGA). One programmable integrated circuit includes: an internal network on chip (iNOC) comprising rows and columns; clusters, coupled to the iNOC, comprising a network access point (NAP) and programmable logic; and an Ethernet controller coupled to the iNOC. When the controller operates in packet mode, each complete inbound Ethernet packet is sent from the controller to one of the NAPs via the iNOC, where two or more NAPs are configurable to receive the complete inbound Ethernet packets from the controller. The controller is configurable to operate in quad segment interface (QSI) mode where each complete inbound Ethernet packet is broken into segments, which are sent from the controller to different NAPs via the iNOC, where two or more NAPs are configurable to receive the complete inbound Ethernet packets from the controller.

Methods, systems, and computer programs are presented for processing Ethernet packets at a Field Programmable Gate Array (FPGA). One programmable integrated circuit includes: an internal network on chip (iNOC) comprising rows and columns; clusters, coupled to the iNOC, comprising a network access point (NAP) and programmable logic; and an Ethernet controller coupled to the iNOC. When the controller operates in packet mode, each complete inbound Ethernet packet is sent from the controller to one of the NAPs via the iNOC, where two or more NAPs are configurable to receive the complete inbound Ethernet packets from the controller. The controller is configurable to operate in quad segment interface (QSI) mode where each complete inbound Ethernet packet is broken into segments, which are sent from the controller to different NAPs via the iNOC, where two or more NAPs are configurable to receive the complete inbound Ethernet packets from the controller.

A cluster configuration request to form a hyperconverged computing infrastructure (HCI) cluster in a cloud computing environment is processed. Based on the cluster configuration request and any other cluster specifications, a plurality of bare metal computing nodes of the cloud computing environment are configured to operate as an HCI cluster. First, a tenant-specific secure network overlay is formed on a first set of tenant-specific networking hardware resources. Then, the tenant-specific secure network overlay is used by an orchestrator to provision a second set of tenant-specific networking hardware resources. The second set of tenant-specific networking hardware resources are configured to interconnect node-local storage devices into a shared storage pool having a contiguous address space. Top-of-rack switches are configured to form a network overlay on the first set of tenant-specific networking hardware resources. Then, top-of-rack switches are configured to form a layer-2 subnet on the second set of tenant-specific networking hardware resources.

A cluster configuration request to form a hyperconverged computing infrastructure (HCI) cluster in a cloud computing environment is processed. Based on the cluster configuration request and any other cluster specifications, a plurality of bare metal computing nodes of the cloud computing environment are configured to operate as an HCI cluster. First, a tenant-specific secure network overlay is formed on a first set of tenant-specific networking hardware resources. Then, the tenant-specific secure network overlay is used by an orchestrator to provision a second set of tenant-specific networking hardware resources. The second set of tenant-specific networking hardware resources are configured to interconnect node-local storage devices into a shared storage pool having a contiguous address space. Top-of-rack switches are configured to form a network overlay on the first set of tenant-specific networking hardware resources. Then, top-of-rack switches are configured to form a layer-2 subnet on the second set of tenant-specific networking hardware resources.

A network interface apparatus includes: a communication portion adapted to connect the interface apparatus to a wired telecommunications network; a rectifier connected to the communication portion; a power distribution bus connected to the rectifier; a first power controller; a second power controller; a first switch coupled to the first power controller and configured to selectively prevent electrical currents from flowing between the connection portion and the power distribution bus, and a second switch and a third switch each respectively coupled to the second power controller and configured to selectively prevent electrical currents from flowing from the power distribution bus to the connection portion, wherein the second switch is connected in parallel with a rectifier element of the rectifier and the third switch is connected in parallel with a second rectifier element of the rectifier.