Abstract: A flexible midplane comprises: a printed circuit board including: a middle section and at least one side section; and a flexible region disposed between the middle section and each side section; wherein each flexible region permits the corresponding side section to be bent in relation to the middle section.

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: Various technologies described herein pertain to racking equipment in a data center. A modular equipment rack system can include an upper track, a lower track, a vertical support, a power and network distribution unit, and a tray. The upper track and the lower track can respectively include incrementally spaced mounting locations at which the vertical support and the power and network distribution unit can be attachable. The tray can be attachable to the vertical support and the power and network distribution unit when the vertical support is attached to the upper track at a first upper mounting location and attached to the lower track at a corresponding first lower mounting location, and the power and network distribution unit is attached to the upper track at a second upper mounting location and attached to the lower track at a corresponding second lower mounting location.

Abstract: One or more techniques and/or systems are provided for regulating an amount of power on a power grid using a datacenter. This allows demand to be more closely brought into alignment with supply. For example, when supply exceeds demand by a predetermined level, the datacenter may increase consumption, causing demand to increase, and when demand exceeds supply and/or comes within a predetermined threshold of supply, the datacenter may decrease consumption, causing demand to decrease. In this way, the datacenter can be utilized as a regulatory tool on the grid. It may be appreciated that given the technology used by and/or operations performed by datacenters, datacenters are uniquely situated to achieve these ends as compared to other (large) energy consumers, such as manufacturing facilities that cannot shift around and/or shut-down operations swiftly.

Abstract: A framework that enables a local computing cloud infrastructure for rural (and third world) populations with the ability to connect into the global cloud. The framework include is a low cost architecture of long distance, wireless based, renewable energy powered, and small datacenter (DC) (referred to as a pico-DC) nodes that can fully operate off-grid, both power-wise and Internet connection-wise at a very low cost. Additionally, the framework includes power management and storage techniques that effectively enable low power and efficient power use. Thus, systems are self-sufficient, low maintenance and weather proof with no need for power or data connections.

Abstract: Super capacitor supplemented server power is described. In embodiments, a power system manager is implemented to monitor the capability of one or more power supplies to provide power for a server system. The power system manager can determine that the capability of the power supplies to provide the power is deficient, and then engage one or more super capacitor power modules to provide supplemental power for the server system to mitigate the power deficiency.

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: An exemplary method may comprise thermally coupling a network of cooling lines to each of a plurality of heat exchangers in a cooling system. The method may also comprise providing a first connection from a network of cooling lines to a first fluid source and a second connection from the network of cooling lines to a second fluid source for configuring the network of cooling lines in different states. The method may also comprise delivering cooling fluid through the network of cooling lines to each of the plurality of heat exchangers both when the network of cooling lines is connected only to the first fluid source and when the network of cooling lines is connected to both the first and second fluid sources.

Abstract: One or more techniques and/or systems are provided for regulating an amount of power on a power grid using a datacenter. This allows demand to be more closely brought into alignment with supply. For example, when supply exceeds demand by a predetermined level, the datacenter may increase consumption, causing demand to increase, and when demand exceeds supply and/or comes within a predetermined threshold of supply, the datacenter may decrease consumption, causing demand to decrease. In this way, the datacenter can be utilized as a regulatory tool on the grid. It may be appreciated that given the technology used by and/or operations performed by datacenters, datacenters are uniquely situated to achieve these ends as compared to other (large) energy consumers, such as manufacturing facilities that cannot shift around and/or shut-down operations swiftly.

Abstract: A datacenter may use heat collected from a heat exchanger at the exhaust portion of a cooling system to heat inlet louvers for an atmospheric intake. The louvers may have fluid passages through which heated fluid may pass and cause the louvers to heat up. The heated louvers may operate during periods of snow, rain, high humidity, or other conditions to eliminate condensation, snow and ice buildup, or other problems. In some embodiments, a liquid may be passed through the louvers, while in other embodiments, heated air or other gas may be passed through conductive paths in the louvers. In a heated air system, holes in the louvers may allow the heated air to enter the incoming airstream to regulate the incoming temperature to the datacenter.

Abstract: An exemplary method may include thermally coupling a network of cooling lines to each of a plurality of heat exchangers in a cooling system. The method may also include providing a first connection from a network of cooling lines to a first fluid source and a second connection from the network of cooling lines to a second fluid source for configuring the network of cooling lines in different states. The method may also include delivering cooling fluid through the network of cooling lines to each of the plurality of heat exchangers both when the network of cooling lines is connected only to the first fluid source and when the network of cooling lines is connected to both the first and second fluid sources.

Abstract: A chassis includes a component interconnect board having multiple multi-function slots coupled thereto. Each of the multi-function slots is configured to accept different types of modules, including a battery module and one or more other types of modules, such as server modules or storage modules. The component interconnect board also includes a power bus coupled to receive external power and route the external power to the multiple multi-function slots.

Abstract: A self-powered processing device comprises both a processing device and a power generator that are physically, electrically, and thermally coupled to one another. The power generator can be a fuel cell that can be manufactured from materials that can also support processing circuitry, such as silicon-based materials. A thermal coupling between the power generator and the processing device can include a thermoelectric either generating electrical power from the temperature differential or consuming electrical power to generate a temperature differential. A computing device with self-powered processing devices also includes energy storage devices to store excess energy produced by the self-powered processing device and provide it back during times of need. The self-powered processing device comprises either a wireless or wired network connection, the latter being connectable to a slot on a backplane that can aggregate multiple self-powered processing devices and provide fuel delivery paths for them.

Abstract: A data center system is described which includes multiple data centers powered by multiple power sources, including any combination of renewable power sources and on-grid utility power sources. The data center system also includes a management system for managing execution of computational tasks by moving data components associated with the computational tasks within the data center system, in lieu of, or in addition to, moving power itself. The movement of data components can involve performing pre-computation or delayed computation on data components within any data center, as well as moving data components between data centers. The management system also includes a price determination module for determining prices for performing the computational tasks based on different pricing models. The data center system also includes a “stripped down” architecture to complement its use in the above-summarized data-centric environment.

Abstract: A data center system is described which includes multiple data centers powered by multiple power sources, including any combination of renewable power sources and on-grid utility power sources. The data center system also includes a management system for managing execution of computational tasks by moving data components associated with the computational tasks within the data center system, in lieu of, or in addition to, moving power itself. The movement of data components can involve performing pre-computation or delayed computation on data components within any data center, as well as moving data components between data centers. The management system also includes a price determination module for determining prices for performing the computational tasks based on different pricing models. The data center system also includes a “stripped down” architecture to complement its use in the above-summarized data-centric environment.

Abstract: Pre-computing a portion of forecasted workloads may enable load-balancing of data center workload, which may ultimately reduce capital and operational costs associated with data centers. Computing tasks performed by the data centers may be analyzed to identify computing tasks that are eligible for pre-computing, and may be performed prior to an actual data request from a user or entity. In some aspects, the pre-computing tasks may be performed during a low-volume workload period prior to a high-volume workload period to reduce peaks that typically occur in data center workloads that do not utilize pre-computation. Statistical modeling methods can be used to make predictions about the tasks that can be expected to maximally contribute to bottlenecks at data centers and to guide the speculative computing.

Abstract: An electronic system includes a component that heats up during operation and an acoustic dampening air moving assembly. The acoustic dampening air moving assembly includes air moving blades, a motor, a support structure and a housing. The motor is attached to the air moving blades to rotate the air moving blades. The support structure supports the motor and the air moving blades within the housing. The housing and the support structure at least partially include a material selected for its acoustic dampening characteristics. The acoustic dampening air moving assembly moves air to the component to cool the component. The selected material dampens acoustic vibrations within the electronic system.

Abstract: Resource-based adaptive server loading is described. In embodiments, a current load level can be determined for a resource that is utilized by an adaptive server system to process computer-executable instructions that are a dynamic computational demand on the adaptive server system. The current load level is compared with a target load level for the resource to establish a resource load level comparison. The adaptive server system can then be reconfigured, based on the resource load level comparison, to change the current load level on the resource for resource overload protection.

Abstract: This document describes various techniques for automatically starting servers at low temperatures. A server may be powered on into a heating mode responsive to determining that a temperature of the server is below an operational temperature range. The server may then be restarted when the temperature of the server has increased to a temperature that is within the operational temperature range.

Abstract: A flexible midplane comprises: a printed circuit board including: a middle section and at least one side section; and a flexible region disposed between the middle section and each side section; wherein each flexible region permits the corresponding side section to be bent in relation to the middle section.