A data storage device includes an electrical connector configured to receive an input voltage to power electronics of the data storage device. The data storage device further includes a fuse electrically coupled between the electrical connector and the electronics. The fuse is configured to output a signal indicative of current being inputted to the data storage device. The data storage device further includes a controller configured to calculate power based on the input voltage and the signal indicative of the current.

Embodiments directed at the design of an optically-enabled server based on using carbon nanotube based non-volatile memory and eliminating hard drives and/or solid-state drives. The disclosed optically-enabled server houses a plurality of blade servers connected to one another via high-speed optical interconnects instead of copper-based interconnects. In some embodiments, the high-speed optical interconnects include an optical interface generated from mating an electrical mezzanine connector included within an input/output interconnect module with corresponding mezzanine slots located on the motherboard of a blade server such that the optical interface provides the optical pathways for routing optical signals (between the plurality of blade servers and one or more external devices) generated using light of multiple wavelengths. In some embodiments, the disclosed design advantageously provides a 100-fold speed advantage over a single conventional optical blade edge server and a 3-fold energy savings over standard DDR4 Synchronous Dynamic Random-Access Memory (SDRAM) memory of the same size.

Techniques for managing data center electronic devices in a data center include operating data center server devices that define a particular amount of computing power of a data center, the devices supported in server racks positioned in a frame assembly that includes bays defined along a lengthwise dimension of the frame assembly, the bays arranged in stacked layers that include at least a first layer of bays and a second layer of bays positioned vertically above the first layer of bays, the server racks positioned in at least one of the bays of the first or second layers of bays; determining that at least one of the server devices requires a maintenance operation; based on the determination, operating an automated service machine to move to a location in the data center that is adjacent to the data center server device; and performing the maintenance operation on the at least one data center server device with the automated service machine.

Provided is a patch panel, comprising: a circuit board; and an SFP, SFP+, or QSFP+ connector connected to a plurality of radio frequency coaxial (RF coaxial) connections via conductive traces of the circuit board, the RF coaxial connections configured to extend functionality of the SFP, SFP+, or QSFP+ socket of a computing device coupled to the patch panel from a rear end of the computing device to a front end of the computing device.

A rack computer system can provide data indicating electrical power consumption by separate sets of the mass storage devices, including separate individual mass storage devices, of the rack computer system. A power sensor can be electrically coupled to a power transmission line for each mass storage device. The power sensor can be coupled to the power transmission line externally to the mass storage device. The power sensor can be an internal power sensor of the mass storage device, where a mass storage device microcontroller transmits internally-generated data to an external power monitoring system. A microcontroller can transmit the data to a baseboard management controller via a side-band connection between the mass storage device and the controller. The data can be transmitted via an in-band connection between a baseboard management controller and an instance of firmware which accesses internally-generated data from mass storage device microcontrollers.

A two-phase liquid immersion cooling system is described in which heat generating computer components cause a dielectric fluid in its liquid phase to vaporize. The dielectric vapor is then condensed back into a liquid phase and used to cool the computer components. Using a pressure controlled vessel and pressure controller, the disclosed system may be operated at less than ambient pressure. Utilizing robotic arms and slot-in computing components located within chassis, a self-healing computing system may be created.

A modular data center includes a container for housing at least one rack containing an information handling system. A frame is disposed within the container. The frame has several upper cross-members and several lower cross-members. A floor is coupled to the lower cross-members and the at least one rack is disposed on an upper surface of the floor. At least one lower bracket extends between the floor and the first rack and is affixed to the floor and a first rack to couple/secure the first rack to the floor. Several first isolators are mounted between the floor and the lower cross-members. The first isolators protect the first rack from mechanical shock and vibration.

A battery backup unit module is dimensioned to fit on a height of one rack unit of an electronic rack, and one third of a shelf width of the electronic rack. A cell pack of the battery backup unit module has batteries arranged parallel to the front of the electronic rack. There are 14 groups of battery cells. Each group of battery cells has six battery cells connected in parallel. The 14 groups of battery cells are connected in series. The 14 groups are arranged as two groups in width of the cell pack, one group in height of the cell pack, and seven groups in depth of the cell pack. In each group, the six battery cells are arranged as an upper row three cells deep and a lower row three cells deep.

A server node is provided that includes a processor and a network interface controller mounted in a chassis configured to be inserted into a server node slot of a server node grid. The chassis includes a blind-mate connector system on a back side that includes a blind-mate power connector and a blind-mate network connector configured to blind-mate with a corresponding blind-mate power connector and a corresponding blind-mate network connector of the server node slot of the server node grid. As the server node is inserted into the server node slot, the blind-mate power connector is configured to blind-mate with the corresponding blind-mate power connector of the server node slot before the blind-mate network connector blind-mates with the corresponding blind-mate network connector of the server node slot, such that the blind-mate power connector provides alignment guidance for the blind-mate network connector.

An information handling system for identifying equipment in a datacenter establishes a wireless communication link with an element of datacenter equipment, and receives identification information from the element. The identification information distinguishes the element from other elements of the datacenter equipment that are visibly indistinct from the first element. The information handling system further captures image data when the field of view of an imaging system includes the element, displays the image data on a display, matches a portion of the image data with an image object associated with the first and second elements, determines an identity of the element based upon the identification information and the image object, and displays an augmented reality overlay on the display over the image data. The augmented reality overlay co-locates the image object with the portion and includes the identity over the portion.