Abstract: A method and apparatus are provided for detecting and recovering from a damaged signal line in a communication cable. Signals are transmitted over a first plurality of signal lines within the cable from a first end, signals are transmitted over a second plurality of signal lines within the cable from the second end, and the quality of signals received on each of the first plurality of signal lines at the second end of the cable are monitored. A first one of the first plurality of signal lines that is not providing a signal of a predetermined minimum quality is identified, the identified first signal line is automatically switched out for a first spare signal line within the cable, and one of the second plurality of signal lines that is logically associated with the identified first signal line is automatically switched out for a second spare signal line within the cable.

Abstract: Water is circulated through a cooling system within a compute node to remove heat from a heat-generating component within the compute node. Water leakage from the cooling system is collected into a containment reservoir within the compute node. A rate of the water leakage is measured, a temperature of the compute node is measured, a rate of water evaporation from the containment reservoir is determined based upon the measured temperature, and the rate of water leakage is compared to the rate of water evaporation to determine whether water is accumulating in the containment reservoir. A period of time before the containment reservoir reaches a critical level may also be determined.

Abstract: Predictive block allocation in a flash device, where the flash device includes a plurality of blocks may include: receiving a request to store data to the flash device; determining, in dependence upon one or more characteristics of the data, a usage prediction value for the data; determining, in dependence upon the usage prediction value for the data and upon wear levels for the plurality of blocks, a block from among the plurality of blocks; and; and storing the data in the block of the plurality of blocks.

Abstract: A method includes, for each of a plurality of configured switch ports, identifying switch port settings being used by the configured switch port and device parameters of an installed device connected to the configured switch port. The method further includes correlating one or more of the device parameters to one or more of the switch port settings. In response to an additional device being connected to an additional switch port, the method obtains device parameters of the additional device and automatically configures the additional switch port to use the one or more of the switch port settings that are correlated to one or more of the device parameters matching the device parameters of the additional device.

Abstract: Management of power consumption in large computing clusters is disclosed herein. According to an aspect, a method includes using a power manager to receive, via a communication interface, information associated with the cluster of computing nodes. The method includes determining whether a switch is coupled to an inactive computing node of the cluster of computing nodes based on the received information. Further, the method includes communicating a command to the switch to remove power supplied to a switch port of the switch coupled to the inactive computing node in response to determining that the switch is coupled to an inactive computing node of the cluster of computing nodes.

Abstract: Automatically cooling computer system components for safe servicing includes: determining that a target component of a plurality of components is to be serviced; and reducing temperature of one or more components of said plurality of components if such one or more components exceeds a threshold temperature and such one or more components are within a predefined area of the target component.

Abstract: An electronic device has a number of ports that have the same physical form factor and that are receptive to cable insertion. The electronic device also has visual indicators corresponding to the ports. Each visual indicator indicates at least link establishment when a cable has been inserted into its corresponding port and a link has been established. When a cable is removed from a port, the electronic device controls its corresponding visual indicator to identify the port as one from which cable removal has recently occurred.

Abstract: Management of power consumption in large computing clusters is disclosed herein. According to an aspect, a computing device comprising a power manager may be configured to receive, via a communication interface, information associated with the cluster of computing nodes. The power manager of the computing device may also be configured to determine whether a switch is coupled to an inactive computing node of the cluster of computing nodes based on the received information. Further, the power manager of the computing device may be configured to communicate a command to the switch to remove power supplied to a switch port of the switch coupled to the inactive computing node in response to determining that the switch is coupled to an inactive computing node of the cluster of computing nodes.

Abstract: A method and apparatus are provided for detecting and recovering from a damaged signal line in a communication cable. Signals are transmitted over a first plurality of signal lines within the cable from a first end, signals are transmitted over a second plurality of signal lines within the cable from the second end, and the quality of signals received on each of the first plurality of signal lines at the second end of the cable are monitored. A first one of the first plurality of signal lines that is not providing a signal of a predetermined minimum quality is identified, the identified first signal line is automatically switched out for a first spare signal line within the cable, and one of the second plurality of signal lines that is logically associated with the identified first signal line is automatically switched out for a second spare signal line within the cable.

Abstract: A method includes a first optical transmitter generating a first data signal at a first end of a fiber optic cable, wherein the first optical transmitter and a first photodetector are included in a first optical transceiver. The method further includes a second photodetector receiving a second data signal at a second end of the fiber optic cable. The second photodetector and the a second optical transmitter are included in a second optical transceiver, and the second data signal is the result of the first data signal passing from the first optical transmitter through the fiber optic cable to the second photodetector. A bit error rate in the second data signal is determined and, in response to the bit error rate exceeding a setpoint, the second optical transmitter sends a message to the first photodetector. The power output of the first optical transmitter is increased responsive to the message.

Abstract: A system includes an electronic device including a baseboard management controller (BMC), a power supply unit (PSU), and an external connector, wherein the BMC controls a serial communication bus, and the external connector includes AC voltage contacts and serial communication bus contacts. A power distribution unit (PDU) includes multiple outlets, a management entity, a radio frequency identification (RFID) tag reader, and a visual indicator. A power cable includes a first plug end for coupling to the external connector, a second plug end for coupling to one of the outlets, AC voltage wires extending end-to-end, a read/write RFID tag in the second plug end, and communication wires extending from the first plug end to the read/write RFID tag. Coupling the first plug end to the external connector connects the AC voltage and connects the serial communication bus such that the BMC is in serial communication with the read/write RFID tag.

Abstract: An apparatus for workload management includes a thermal relationship module, a thermal effect module, and a resource allocation module. The thermal relationship module determines a plurality of thermal relationships among components of an electronic device. Each thermal relationship quantifies a thermal impact on one of the components of utilizing another of the components. The thermal effect module determines one or more potential thermal effects of a workload on the components based on the thermal relationships. The one or more potential thermal effects correspond to one or more possible allocations of resources of at least a portion of the components to run the workload.

Abstract: A system includes an electronic device including a baseboard management controller (BMC), a power supply unit (PSU), and an external connector, wherein the BMC controls a serial communication bus, and the external connector includes AC voltage contacts and serial communication bus contacts. A power distribution unit (PDU) includes multiple outlets, a management entity, a radio frequency identification (RFID) tag reader, and a visual indicator. A power cable includes a first plug end for coupling to the external connector, a second plug end for coupling to one of the outlets, AC voltage wires extending end-to-end, a read/write RFID tag in the second plug end, and communication wires extending from the first plug end to the read/write RFID tag. Coupling the first plug end to the external connector connects the AC voltage and connects the serial communication bus such that the BMC is in serial communication with the read/write RFID tag.

Abstract: Processing visual cues to improve understanding of an input is described herein, including receiving a visual cue, the visual cue including visual media of a target; storing a list of words representing the target; and updating a probable words dictionary to include the list of words.

Abstract: The embodiments relate to a computer system, and management of an operating mode of a general-purpose computing on graphics processing unit (GPGPU) adapter. A tool is provided to control the function of the GPGPU adapter. The tool includes an input/output (I/O) interface operatively coupled to the GPGPU adapter. The tool further includes basic input/output system (BIOS) to determine presence of the GPGPU adapter and to interrogate the GPGPU adapter to automatically set an operating mode of the GPGPU adapter. At least two modes of the GPGPU adapter are provided. The GPGPU adapter is set to a first mode in response to determining that the GPGPU adapter is in communication with the visual display, and set to the second mode in response to determining that the GPGPU is not in communication with a visual display.

Abstract: A method includes supplying power to a physical server from a plurality of power supplies, wherein operation of all hardware components of the server requires more power than any one of the power supplies can provide. A plurality of jobs are run on the server while the plurality of power supplies are supplying power to the physical server. The method further comprises identifying an amount of power required by each of the components, and identifying one or more components that are not required by one or more of the jobs that are running on the server. The method detects a loss of power from one of the power supplies and then selectively removes power from hardware components identified as not required so that at least a central processing unit and a memory device can continue running at least one job using power available from the operational power supplies.

Abstract: An electronic device has a number of ports that have the same physical form factor and that are receptive to cable insertion. The electronic device also has visual indicators corresponding to the ports. Each visual indicator indicates at least link establishment when a cable has been inserted into its corresponding port and a link has been established. When a cable is removed from a port, the electronic device controls its corresponding visual indicator to identify the port as one from which cable removal has recently occurred.

Abstract: A method includes, for each of a plurality of configured switch ports, identifying switch port settings being used by the configured switch port and device parameters of an installed device connected to the configured switch port. The method further includes correlating one or more of the device parameters to one or more of the switch port settings. In response to an additional device being connected to an additional switch port, the method obtains device parameters of the additional device and automatically configures the additional switch port to use the one or more of the switch port settings that are correlated to one or more of the device parameters matching the device parameters of the additional device.

Abstract: A method comprising flowing a liquid through supply pipe couplings to a fin tube assembly of an air-to-liquid heat exchanger and through the fin tube assembly to return pipe couplings, wherein the fin tube assembly forms a central air flow pathway. The method further comprises passing air through components within a rack secured to the rear door heat exchanger and through the fin tube assembly and detecting an operating condition within the rack. The method then automatically moves the fin tube assembly from a retracted position to an extended position in response to the operating condition, wherein the retracted position directs substantially all of the air to exit the rack through the central air flow pathway, and wherein the extended position allows the air to exit through the central air flow pathway and also through first and second side air flow pathways.

Abstract: Method of cooperative reduced power mode suspension for high input/output (‘I/O’) workloads, including: determining, by a transfer monitoring module, a size of a file to be transferred to a recipient, wherein the recipient includes a central processing unit (‘CPU’) operating in a reduced power mode; determining, by the transfer monitoring module, a desired transfer rate for transferring the file to the recipient; calculating, by the transfer monitoring module, an expected transfer completion time in dependence upon the size of the file and the desired transfer rate; and sending, by the transfer monitoring module, a message to the recipient requesting that the CPU suspend the reduced power mode in dependence upon the expected transfer completion time.