A cable manager includes a backbone assembly and at least one side wall extending from the backbone assembly. The at least one side wall optionally includes one or more cable finger units. The backbone assembly includes a spine member having an extruded construction. The spine member includes one or more channels extending substantially an entire length thereof to facilitate easy attachment, removal and/or repositioning of a structure relative to the spine member. The cable manager optionally includes an accessory rod, a half-spool assembly, a cable finger accessory, a strap/buckle accessory, and/or a door assembly having an interference-free hinge set.

An apparatus comprises a body portion configured to be disposed above an electronic equipment rack. The apparatus further comprises one or more first openings in the body portion. The one or more first openings are configured for receiving a first plurality of cables routed through the one or more first openings. At least one bracket is attached to a side surface of the body portion and configured to be attached to a top surface of the electronic equipment rack. The at least one bracket comprises one or more second openings configured for receiving a second plurality of cables routed through the one or more second openings into the electronic equipment rack.

Technologies for composing a managed node with multiple processors on multiple compute sleds to cooperatively execute a workload include a memory, one or more processors connected to the memory, and an accelerator. The accelerator further includes a coherence logic unit that is configured to receive a node configuration request to execute a workload. The node configuration request identifies the compute sled and a second compute sled to be included in a managed node. The coherence logic unit is further configured to modify a portion of local working data associated with the workload on the compute sled in the memory with the one or more processors of the compute sled, determine coherence data indicative of the modification made by the one or more processors of the compute sled to the local working data in the memory, and send the coherence data to the second compute sled of the managed node.

Certain aspects of the present disclosure include a support frame having a rear side, a bottom section, a connector bracket, a first perimeter section, a second perimeter section, and a rotatable bracket. The bottom section defines a width of the support frame. The connector bracket extends upright from the bottom section. The first perimeter section and the second perimeter section extend upright from opposing ends of the bottom section. The first perimeter section and the second perimeter section are substantially parallel to the connector bracket. The rotatable bracket is rotatably coupled at one end to the first perimeter section. The rotatable bracket is configured, at another end, to removably couple to the connector bracket, thereby enclosing an opening when the rotatable bracket is in a closed configuration. The opening is defined by the first perimeter section, a portion of the bottom section, the connector bracket, and the rotatable bracket.

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.

Example implementations relate to a cable management arm for a computing system. The cable management arm includes a pair of latches, a pair of first bars, and a second bar. The pair of latches is detachably connectable to a chassis of the computing system. Each first bar has a first end pivotably connected to a respective latch of the pair of latches, and a second end connected to the second bar for defining an open space therebetween. The open space provides a non-interfering entrance for accessing the one or more electronic components from rear side of the chassis. The second bar supports the cables connected to the one or more electronic components. The pair of first bars is pivotable relative to the pair of latches such that the second bar is movable to a plurality of preset positions for providing the clearance from the cables during service event, for instance.

A configurable instrument includes a mainframe having one or more processors, a chassis having slots to accept one or more instrument modules, a communication bus coupled to all of the instrument modules inserted in the slots, and a communication backplane, separate from the communication bus, and configured to allow point-to-point communication between any pair of modules inserted in the slots.

A breakout cable, including a first portion of the cable coupled to a network switch, wherein at least a first section of the first portion is located within a volume inside of side walls of the computing rack, the first section of the first portion including first and second connectors and extending in a first direction; a second portion of the cable including a third connector, the third connector coupled to the first connector of the first portion and the first network interface module connected to a first server, the second portion of the cable extending in a second direction transverse to the first direction; a third portion of the cable including a fourth connector and, the fourth connector coupled to the second connector of the first portion and the second network interface module connected to a second server, the third portion of the cable extending in the second direction.

A server chassis includes a baseboard, a power distribution board, and a busbar module. The baseboard includes a front end and a rear end. The front end and the rear end define a chassis depth. The power distribution board is positioned on the baseboard. The busbar module includes a chassis-side busbar connector. The chassis-side busbar connector is configured to mate with a rack-side busbar connector. The rack-side busbar connector is positioned on a rack having a rack depth. The busbar module is adjustable, such that the chassis-side busbar connector mates with the rack-side busbar connector in a first configuration and a second configuration. In the first configuration, the rack depth is approximately equal to the chassis depth. In the second configuration, the rack depth is greater than the chassis depth.

A method of adapting an electronic equipment structure for cable management, the method comprising: providing a cable manager having one or more cable finger units extending from a frame, the frame including at least one spine member having an extruded construction and one or more ledges that extend along a length thereof; providing an accessory rod assembly having a base member and an accessory rod, wherein the base member includes a front-facing socket, a rear-facing hook, and a rotatable knob having a threaded end received within a threaded portion at a side of the base member, and wherein the accessory rod has an extruded construction and a generally uniform, at least partially cylindrical, cross-sectional shape; positioning the rear-facing hook of the base member against one side of the one or more ledges of the at least one spine member; rotating the rotatable knob such that the threaded end is wound within the threaded portion of the base member and bears on an opposite side of the one or more ledges of the at least one spine member, thereby clamping the at least one spine member between the rear-facing hook and the rotatable knob; and positioning a proximal end of the accessory rod within the front-facing socket of the base member such that the accessory rod extends therefrom into a cable management space.