Technologies for lifecycle management include multiple computing devices in communication with a lifecycle management server. On boot-up, a computing device loads a lightweight firmware boot environment. The lightweight firmware boot environment connects to the lifecycle management server and downloads one or more firmware images for controllers of the computing device. The controllers includes baseboard management controllers, network interface controllers, solid-state drive controllers, or other controllers. The lifecycle management server selects firmware images and/or versions of firmware images based on the controllers or the computing device. The computing device installs each firmware image to a controller memory device coupled to a controller, and in use, each controller accesses the firmware image in the controller memory device.

Racks and rack pods to support a plurality of sleds are disclosed herein. Switches for use in the rack pods are also disclosed herein. A rack comprises a plurality of sleds and a plurality of electromagnetic waveguides. The plurality of sleds are vertically spaced from one another. The plurality of electromagnetic waveguides communicate data signals between the plurality of sleds.

This disclosure provides a switch assembly structure and a display device. The switch assembly structure comprises: a switch assembly (100); an assembly housing (400) provided with a first groove (410); a first clamping member (500) provided with a second groove (510), wherein the first clamping member (500) has a first state of being securely connected with the assembly housing (400) and a second state of being separate from the assembly housing (400); wherein, in the second state, the switch assembly (100) is able to mate with the first groove (410) or the second groove (510); and in the first state, the first groove (410) and the second groove (510) combine to form a switch mounting hole (10), and the switch assembly (100) is secured in the switch mounting hole (10) by a securable connection of the first clamping member (500) with the assembly housing (400).

Technologies for generating manifest data for a sled include a sled to generate manifest data indicative of one or more characteristics of the sled (e.g., hardware resources, firmware resources, a configuration of the sled, or a health of sled components). The sled is also to associate an identifier with the manifest data. The identifier uniquely identifies the sled from other sleds. Additionally, the sled is to send the manifest data and the associated identifier to a server. The sled may also detect a change in the hardware resources, firmware resources, the configuration, or component health of the sled. The sled may also generate an update of the manifest data based on the detected change, where the update specifies the detected change in the hardware resources, firmware resources, the configuration, or component health of the sled. The sled may also send the update of the manifest data to the server.

A scalable system for high-power computer, comprising a plurality of motherboard chassis, inserted in a computer rack mounting kit, each motherboard chassis, being configured to receive at least one motherboard module, said plurality of inner chassis forming a stack of inner chassis, the stack being configured to receive an outer floating bracket chassis, said outer chassis being inserted by a second longitudinal end of each inner chassis forming the stack of inner chassis, each said outer floating bracket chassis being configured to accommodate at least one double floating bracket being configured to house a cable box capable of connecting the connectors of a plurality of motherboard modules, arranged in said inner chassis of the stack, to each other, the system being characterized in that the double floating bracket comprises at least several floating attachment means.

A module for a digital display panel includes a circuit board, a first face of which presents a network of light emitting diodes. The module also includes a chassis fixed on a second face of the circuit board, and a water permeable connector mounted on the circuit board. The chassis includes a base around the water permeable connector, a top part of the base having at least one groove, wherein a seal is inserted. Further, the module includes a power supply unit fitted with a continuous voltage connector surrounded by a ferrite and fitted in the water permeable connector. The power supply unit is attached to the chassis so that a lower plate of the power supply unit co-operates with the seal of the base to ensure a seal around the water permeable connector and the DC voltage connector of the power supply unit.

A module for a digital display panel includes an electronic board, a first face of which has an array of light-emitting diodes arranged in rows and columns with a substantially constant pitch. The module further includes a frame fastened onto a second face of the electronic board opposite the first face and at least one water-permeable connector for an optical fiber, mounted on the frame. The frame includes a baseplate integrating the at least one water-permeable connector. The module includes a cover attached to the baseplate so as to form a watertight volume inside the baseplate. The cover includes at least one opening provided with sealing means intended to ensure sealing around at least one optical fiber connected to the at least one water-permeable connector.

An apparatus and a method of use are disclosed herein. The apparatus comprises a disaggregated fault tolerant backplane having a front side and a back side with at least two daughter card slots configured on the front side and configured to receive slot fanout signals over the backplane. The apparatus further comprises at least two switch boards (SBs) configured to provide electrical power to the at least two daughter card slots and at least one main fanout board (MFB) configured to send and receive SB control signals to and from the at least two SBs. The at least one MFB connects to the backplane through at least one MFB connector configured on the back side of the backplane. In one embodiment, the MFB receives control signals from the daughter card slots and sends slot fanout signals to the daughter card slots.

A socket connector includes a housing having a top, a bottom, a first side wall and a second side wall forming cavities that receive power sockets. The housing includes pin access openings through the bottom that receive power pins mated to the power sockets. Each power socket includes a cable socket receiving a power cable and a pin socket that receives the power pin. The power socket electrically connects the power cable and the power pin. The socket connector includes latches each having a latch release and a latch arm operably coupled to the latch release. The latch arm extends along the corresponding pin access opening and includes a latching surface aligned with the pin access opening configured to engage the power pin to retain the power pin in the housing. The release button is actuated to release the latch arm from the power pin and allow removal of the power pin from the housing.

Methods and devices for selectively presenting a user interface on a second screen. More particularly, the method includes a change in the display mode of a multiple screen device from a first screen to a second screen while the device is closed. The change in the display mode may be made in response to a request from an application. The application may be executed and have the user interface window associated with the application moved to a second screen. The change to the second screen can be requested based on input into the application or automatically generated based on the type of application. In response to the request from the application, the device can render the user interface in the second screen.