A top loading cartridge is provided herein. The top loading cartridge includes a support member, a rail member, and a lock mechanism. The support member to receive an electronic module. The rail member attached to the support member to engage with a tray that receives the top loading server cartridge. The lock mechanism to lock the top loading cartridge.

A framework for an electronic or network cabinet, having a first profile frame and a second profile frame, as well as four depth struts. Each depth strut is directly or indirectly connected at corresponding points to the vertical profile frames. Furthermore, the depth struts are dimensioned so that they can absorb and compensate tilting forces of the vertical profile frames.

Generally, the present disclosure provides for a light engine, in particular a rack-mounted light engine that can be used in a lighting system. The rack mounted light engine can be positioned in an electronics component rack such a light distribution system using hollow light ducts may distribute the light over a large area, such as a data center. Such a light distribution can use a generated light more efficiently by directing the light to the fronts or backs of the electronics cabinet, rather than for general room illumination.

Embodiments of the invention include an active mm-wave interconnect. In an embodiment, the active mm-wave interconnect includes a dielectric waveguide that is coupled to a first connector and a second connector. According to an embodiment, each of the first and second connectors may include a mm-wave engine. In an embodiment, the mm-wave engines may include a power management die, a modulator die, a demodulator die, a mm-wave transmitter die, and a mm-wave receiver die. Additional embodiments may include connectors that interface with predefined interfaces, such as small form-factor pluggables (SFP), quad small form-factor pluggables (QSFP), or octal small form-factor pluggables (OSFP). Accordingly, embodiments of the invention allow for plug and play functionality with existing servers and other high performance computing systems.

A system includes a rack and one or more server systems mounted in the rack. A server system includes a chassis with one or more arrays of devices in the chassis. Each array includes mass storage devices and a server device mounted in the array within the chassis of the server system. The server device occupies no more than an equivalent volume of space in the chassis as one of the mass storage devices. A set of mass storage devices of an array and the server device of the array form a logical node, and a server system may include multiple logical nodes in the same chassis. Each array of devices may be located in a sled that can move into and out of the chassis of the server system.

An information handling system includes a compute device, a side cover, and a bezel. The side cover is placed in physical communication with the compute device. The side cover includes a mounting latch that rotates between an open position and a closed position. When in the closed position, the mounting latch securely mounts the compute device on a component. When bezel is placed in physical communication with the side cover, the bezel locks the mounting latch in the closed position.

Example implementations relate to a security system having an electronic lock including latch and security modules, to control access to electronic devices. The latch module includes a receiver, a handle, and a torque member rotatably coupled to the receiver and handle. The receiver includes a first recess, a second recess, and a lobe to releasably engage the electronic device within the first recess. The security module includes a tension spring, an actuator, and a lock member having a first pin and a second pin. The tension spring is coupled to the lock member to engage the first pin to second recess when the latch module is in a latched configuration, and hold the security module in a lock-in position. The actuator is releasably engaged to the second pin for rotating the lock member to disengage the first pin from second recess, and release the security module from the lock-in position.

An enclosure comprising a housing having a first end and a second end opposite the first end, the housing having a first connector receptacle at the first end, the housing having a surface defining a robot-engaging mechanism, a hook extending from the second end of the housing, and a securement mechanism at the second end of the housing.

A computing and storage system includes a housing having power and cooling facility and a plurality of slots, each slot having interface connection. An interconnecting board is coupled to the interface connection of the plurality of slots. A plurality of baseboards are inserted, each in one of the slots wherein a board interface mates with the interface connection. All of the baseboards have the same form factor and the same board interface and each of the baseboards has a plurality of electronic devices, such that all of the electronic devices mounted onto one of the baseboards are the same. Using the interconnecting board, the various baseboards can be interconnected to form a computing and/or storage machine of different operational characteristics as required by a given task. In addition, the inter connection board is managed to adjust the networking resource allocations for different traffic characteristics and workload requirements.

Technologies for switching network traffic include a network switch. The network switch includes one or more processors and communication circuitry coupled to the one or more processors. The communication circuity is capable of switching network traffic of multiple link layer protocols. Additionally, the network switch includes one or more memory devices storing instructions that, when executed, cause the network switch to receive, with the communication circuitry through an optical connection, network traffic to be forwarded, and determine a link layer protocol of the received network traffic. The instructions additionally cause the network switch to forward the network traffic as a function of the determined link layer protocol. Other embodiments are also described and claimed.