A communication interface apparatus in a tank gauging system. The communication interface includes a memory and a processor couple to the memory. The processor communicates using a control application with a tank inventory system that operates over a serial connection; and communicates using a wireless application with tank gauging equipment that operates over a wireless connection

A network system for a data center is described in which a switch fabric provides full mesh interconnectivity such that any servers may communicate packet data to any other of the servers using any of a number of parallel data paths. Moreover, according to the techniques described herein, edge-positioned access nodes, optical permutation devices and core switches of the switch fabric may be configured and arranged in a way such that the parallel data paths provide single L2/L3hop, full mesh interconnections between any pairwise combination of the access nodes, even in massive data centers having tens of thousands of servers. The plurality of optical permutation devices permute communications across the optical ports based on wavelength so as to provide full-mesh optical connectivity between edge-facing ports and core-facing ports without optical interference.

In some examples, a switching system includes a plurality of fabric endpoints and a multi-stage switching fabric having a plurality of fabric planes each having a plurality of stages to switch data units between any of the plurality of fabric endpoints. A fabric endpoint of the fabric endpoints is configured to send, to a switch of a first one of the stages and within a first fabric plane of the plurality of fabric planes, a self-ping message destined for the fabric endpoint. The fabric endpoint is configured to send, in response to determining the fabric endpoint has not received the self-ping message after a predetermined time, an indication of a connectivity fault for the first fabric plane.

A method and apparatus including a cache controller coupled to a cache memory, wherein the cache controller receives a plurality of cache access requests, performs a pre-sorting of the plurality of cache access requests by a first stage of the cache controller to order the plurality of cache access requests, wherein the first stage functions by performing a presorting and pre-clustering process on the plurality of cache access requests in parallel to map the plurality of cache access requests from a first position to a second position corresponding to ports or banks of a cache memory, performs the combining and splitting of the plurality of cache access request by a second stage of the cache controller, and applies the plurality of cache access requests to the cache memory at line speed.

Communication network systems are disclosed. In one or more implementations, the communication network system includes a plurality of network devices. Each of the plurality of network devices incorporates one or more multi-port switches, where each multi-port switch includes a connection to the network device incorporating the multi-port switch and a connection to at least one other port of another multi-port switch incorporated by another respective one of the plurality of network devices.

Some examples provide a method for automatic network assembly. The following instructions may be used to implement automatic network assembly in a modular infrastructure. Instructions to automatically connect a management port to a management network. Instructions to automatically connect link ports to form a scalable ring. Instructions to automatically connect each modular infrastructure management device to a bay management network port.

A network switch includes circuitry and multiple ports, including multiple input ports and at least one output port, configured to connect to a communication network. The circuitry includes multiple distinct-flow counters, which are each associated with a respective input port and with the output port, and which are configured to estimate respective distinct-flow counts of distinct data flows received via the respective input ports and destined to the output port. The circuitry is configured to store packets that are destined to the output port and were received via the multiple input ports in multiple queues, to determine a transmission schedule for the packets stored in the queues, based on the estimated distinct-flow counts, and to transmit the packets via the output port in accordance with the determined transmission schedule.

A communication system includes a plurality of leaf switches connected to a plurality of spine switches in topology of a Latin square Fat-Tree, and a plurality of information processing apparatus, wherein each of the information processing apparatuses performs first all reducing, wherein each of first information processing apparatuses performs second all reducing, on the basis of the result of the first all reducing, between the first information processing apparatus and another first information processing apparatus connected to a leaf switch connected to a first spine switch corresponding to a first direction in an area, wherein each of the first information processing apparatuses performs third all reducing, on the basis of the result of the second all reducing, between the first information processing apparatus and another first information processing apparatus connected to a leaf switch connected to a second spine switch corresponding to a second direction in the area.

The technology disclosed herein enables an L3 network fabric including one or more spine switches having a leaf-spine topology to be self-expanded. In a particular embodiment, a method provides transferring one or more probe messages from each of the spine switches. The probe messages detect whether new computing nodes have been attached to the communication network. The method further provides receiving a reply to at least one of the probe messages. The reply identifies a new computing node that is not yet included in the L3 fabric. In response to the reply, the method provides confirming physical network interfaces of the spine switches indicate valid connections to one or more new leaf switches of the new computing node, using L3 discovery protocols to ensure the connections conform to the leaf-spine topology, and transferring probe packets between the spine switches and leaf switches, including the new leaf switches, of computing nodes connected thereto to confirm configuration of all connections between the spine switches and the leaf switches of the computing nodes. Moreover, the method provides configuring L3 protocols for routing communications exchanged with the new computing node.

Embodiments of the invention relate to faulty recovery mechanisms for a three-dimensional (3-D) network on a processor array. One embodiment comprises a multidimensional switch network for a processor array. The switch network comprises multiple switches for routing packets between multiple core circuits of the processor array. The switches are organized into multiple planes. The switch network further comprises a redundant plane including multiple redundant switches. Multiple data paths interconnect the switches. The redundant plane is used to facilitate full operation of the processor array in the event of one or more component failures.