Abstract: A system for using free-space optics to interconnect a plurality of computing nodes can include a plurality of node optical transceivers that are electrically coupled to at least some of the plurality of computing nodes. The system can also include a plurality of router optical transceivers that facilitate free-space optical communications with the plurality of node optical transceivers. Each node optical transceiver among the plurality of node optical transceivers can have a corresponding router optical transceiver that is optically coupled to the node optical transceiver. The system can also include a router that is coupled to the plurality of router optical transceivers. The router can be configured to route the free-space optical communications among the plurality of computing nodes.

Abstract: A system for using free-space optics to interconnect a plurality of computing nodes can include a plurality of node optical transceivers that are electrically coupled to at least some of the plurality of computing nodes. The system can also include a plurality of router optical transceivers that facilitate free-space optical communications with the plurality of node optical transceivers. Each node optical transceiver among the plurality of node optical transceivers can have a corresponding router optical transceiver that is optically coupled to the node optical transceiver. The system can also include a router that is coupled to the plurality of router optical transceivers. The router can be configured to route the free-space optical communications among the plurality of computing nodes.

Abstract: A bus architecture for supplying power to loads in a datacenter includes a first DC bus including a first bus conductor and a first plurality of source/load groups. Each of the first plurality of source/load groups includes a first power source and a first plurality of loads, wherein at least one of the first plurality of loads includes a server rack. The first power source in each of the first plurality of source/load groups is sized to supply power to the first plurality of loads for the corresponding one of the first plurality of source/load groups. The first power source in each of the first plurality of source/load groups is also sized to provide excess capacity to be shared by the first plurality of loads corresponding to other ones of the first plurality of source/load groups.

Abstract: Described herein are various technologies pertaining to predicting an amount of electrical power that is to be generated by a power system at a future point in time, wherein the power system utilizes a renewable energy resource to generate electrical power. A camera is positioned to capture an image of sky over a geographic region of interest. The image is analyzed to predict an amount of solar radiation that is to be received by the power source at a future point in time. The predicted solar radiation is used to predict an amount of electrical power that will be output by the power system at the future point in time. A computational resource of a data center that is powered by way of the power source is managed as a function of the predicted amount of power.

Abstract: Superconducting computing system housed in a liquid hydrogen environment and related aspects are described. An example superconducting computing system includes a housing, arranged inside a liquid hydrogen environment, where a lower pressure is maintained inside the housing than a pressure outside the housing. The superconducting computing system further includes a substrate, arranged inside the housing, having a surface, where a plurality of components attached to the surface is configured to provide at least one of a computing or a storage functionality, and the substrate further comprises a plurality of circuit traces for interconnecting at least a subset of the plurality of the components. The housing is configured such that each of the plurality of components is configured to operate at a first temperature, where the first temperature is below 4.2 Kelvin, despite the liquid hydrogen environment having a second temperature greater than 4.2 Kelvin.

Abstract: A method for facilitating increased utilization of a data center includes receiving information about availability of components in a data center's electrical infrastructure and about power consumption of servers in the data center. The method may also include detecting that the power consumption of the servers in the data center exceeds a reduced total capacity of the electrical infrastructure. The reduced total capacity may be caused by unavailability of at least one component in the data center's electrical infrastructure. The method may also include causing power management to be performed to reduce the power consumption of the servers so that the power consumption of the servers does not exceed the reduced total capacity of the electrical infrastructure of the data center.

Abstract: A method described herein includes an act of receiving data that is indicative of predicted weather conditions for a particular geographic region, wherein the particular geographic region has an energy generation system therein, and wherein the energy generation system utilizes at least one renewable energy resource to generate electrical power. The method also includes the act of scheduling a computational workload for at least one computer in a data center based at least in part upon the data that is indicative of the predicted weather conditions for the particular geographic region.

Abstract: Superconducting computing system housed in a liquid hydrogen environment and related aspects are described. An example superconducting computing system includes a housing, arranged inside a liquid hydrogen environment, where a lower pressure is maintained inside the housing than a pressure outside the housing. The superconducting computing system further includes a substrate, arranged inside the housing, having a surface, where a plurality of components attached to the surface is configured to provide at least one of a computing or a storage functionality, and the substrate further comprises a plurality of circuit traces for interconnecting at least a subset of the plurality of the components. The housing is configured such that each of the plurality of components is configured to operate at a first temperature, where the first temperature is below 4.2 Kelvin, despite the liquid hydrogen environment having a second temperature greater than 4.2 Kelvin.

Abstract: A continuously growing physical structure may be generated by identifying a plurality of metrics associated with the physical structure. The plurality of metrics may include at least one of a shape of available physical space, a size of available physical space, a type of soil/earth of a location of the physical structure, a context of use of the physical structure, a climate of the location, or availability of resources associated with the location. The plurality of metrics may be analyzed to determine at least one of a rate of growth of the physical structure or a most suitable shape of the physical structure. Growth of the physical structure may then be generated according to at least one of the determined rate of growth of the physical structure or the determined most suitable shape of the physical structure. The identified plurality of metrics may then be monitored periodically.

Abstract: A method described herein includes an act of receiving data that is indicative of predicted weather conditions for a particular geographic region, wherein the particular geographic region has an energy generation system therein, and wherein the energy generation system utilizes at least one renewable energy resource to generate electrical power. The method also includes the act of scheduling a computational workload for at least one computer in a data center based at least in part upon the data that is indicative of the predicted weather conditions for the particular geographic region.

Abstract: A bus architecture for supplying power to a datacenter. A first DC bus includes a first DC bus conductor, a first power source and a first diode having a cathode connected to the first DC bus conductor. The first DC bus includes a first converter connected to the first power source and to an anode of the first diode. Power output by the first power source via the first converter is supplied at a first voltage level. The first DC bus includes a first plurality of loads and a first plurality of DC/DC converters connecting the first plurality of loads to the first DC bus conductor, respectively. The first DC bus includes a second diode having a cathode connected to the first DC bus conductors. A first uninterruptable power supply is connected to an anode of the second diode and operates at a second voltage level.

Abstract: A bus architecture for supplying power to a datacenter. A first DC bus includes a first DC bus conductor, a first power source and a first diode having a cathode connected to the first DC bus conductor. The first DC bus includes a first converter connected to the first power source and to an anode of the first diode. Power output by the first power source via the first converter is supplied at a first voltage level. The first DC bus includes a first plurality of loads and a first plurality of DC/DC converters connecting the first plurality of loads to the first DC bus conductor, respectively. The first DC bus includes a second diode having a cathode connected to the first DC bus conductors. A first uninterruptable power supply is connected to an anode of the second diode and operates at a second voltage level.

Abstract: A bus architecture for supplying power to loads in a datacenter includes a first DC bus including a first bus conductor and a first plurality of source/load groups. Each of the first plurality of source/load groups includes a first power source and a first plurality of loads, wherein at least one of the first plurality of loads includes a server rack. The first power source in each of the first plurality of source/load groups is sized to supply power to the first plurality of loads for the corresponding one of the first plurality of source/load groups. The first power source in each of the first plurality of source/load groups is also sized to provide excess capacity to be shared by the first plurality of loads corresponding to other ones of the first plurality of source/load groups.

Abstract: Cooling a first device and second device in a fashion to produce water. The method includes collecting environmental air from an environment. The environmental air is used to cool a first device. Cooling the first device generates first device exhaust air produced from the environmental air. The first device exhaust air is provided to a first device portion of a heat exchanger. At a second device portion of the heat exchanger, thermally coupled to the first device portion of the heat exchanger, second device exhaust air generated by cooling a second device is received. At the heat exchanger, the first device exhaust air is used to cool the second device exhaust air to a dew point, causing condensed water to be created from the second device exhaust air. The condensed water is collected.

Abstract: According to some embodiments, a power supply component for a computer server may include a physical input receptacle adapted to receive with of an Alternating Current (“AC”) plug and a Direct Current (“DC”) plug. An AC-to-DC rectifier circuit coupled to the physical input receptacle may convert AC current into DC current when AC current is received via the physical input receptacle. The power supply component may also include a DC-to-DC voltage regulator to reduce voltages swings. The power supply component might be associated with, for example, a computer data center.

Abstract: Described herein are various technologies pertaining to predicting an amount of electrical power that is to be generated by a power system at a future point in time, wherein the power system utilizes a renewable energy resource to generate electrical power. A camera is positioned to capture an image of sky over a geographic region of interest. The image is analyzed to predict an amount of solar radiation that is to be received by the power source at a future point in time. The predicted solar radiation is used to predict an amount of electrical power that will be output by the power system at the future point in time. A computational resource of a data center that is powered by way of the power source is managed as a function of the predicted amount of power.

Abstract: Electrical power is provided to power consuming, heat-exhausting devices by multiple gas-fueled electrical power sources located near such devices. Exhaust heat from such devices is utilized as intake cooling air for the gas-fueled power sources, thereby excluding them from cooling capacity requirements. The gas piping delivering gas to gas-fueled power sources is positioned so as to be within hot aisles comprising exhaust heat. The gas piping is located up high for lighter than air gasses and near the floor for heavier than air gasses, with leak detection located nearby. Additionally, gas piping is externally coated with material that visually indicates a leak. By locating gas piping in the hot aisle, exhausted heat increases temperature and, thereby, pressure of the gas, resulting in more efficient gas distribution through the piping and preventing valve freezing. Furthermore, the gas piping is located after potential ignition sources in the airstream.

Abstract: A continuously growing physical structure may be generated by identifying a plurality of metrics associated with the physical structure. The plurality of metrics may include at least one of a shape of available physical space, a size of available physical space, a type of soil/earth of a location of the physical structure, a context of use of the physical structure, a climate of the location, or availability of resources associated with the location. The plurality of metrics may be analyzed to determine at least one of a rate of growth of the physical structure or a most suitable shape of the physical structure. Growth of the physical structure may then be generated according to at least one of the determined rate of growth of the physical structure or the determined most suitable shape of the physical structure. The identified plurality of metrics may then be monitored periodically.

Abstract: A physical structure is created at least partially utilizing one or more materials from soil of a site upon which the physical structure is to be created. A plurality of metrics associated with the physical structure is identified. The plurality of metrics includes a shape of available physical space, a size of available physical space, materials included within the soil of a location of the physical structure, a context of use of the physical structure, a climate of the location, or availability of resources associated with the location. The plurality of metrics is analyzed to determine a material from the materials included within the soil of the location of the physical structure to be used in creating the physical structure. Growth of the physical structure is generated in a downward direction utilizing the material. Utilizing the determined material comprises using the determined material as a portion of the physical structure.

Abstract: Described herein are various technologies pertaining to predicting an amount of electrical power that is to be generated by a power system at a future point in time, wherein the power system utilizes a renewable energy resource to generate electrical power. A camera is positioned to capture an image of sky over a geographic region of interest. The image is analyzed to predict an amount of solar radiation that is to be received by the power source at a future point in time. The predicted solar radiation is used to predict an amount of electrical power that will be output by the power system at the future point in time. A computational resource of a data center that is powered by way of the power source is managed as a function of the predicted amount of power.