Abstract: A method of forming metallic pillars between a fluid inlet and outlet for two-phase fluid cooling. The method may include; forming an arrangement of metallic pillars between two structures, the metallic pillars are electrically connected to metallic connecting lines that run through each of the two structures, the arrangement of metallic pillars located between a fluid inlet and a fluid channel, the fluid channel having channel walls running between arrangements of the metallic pillars and a fluid outlet, whereby a fluid passes through the arrangement of metallic pillars to flow into the fluid channel.

Abstract: A system for identifying and reporting traffic events is presented. Position and motion data from two or more vehicles are uploaded to a data center. The system identifies an accident between first and second vehicles by correlating the motion and position information of the first vehicle with the motion and position information of the second vehicle.

Abstract: A method of forming metallic pillars between a fluid inlet and outlet for two-phase fluid cooling. The method may include; forming an arrangement of metallic pillars between two structures, the metallic pillars are electrically connected to metallic connecting lines that run through each of the two structures, the arrangement of metallic pillars located between a fluid inlet and a fluid channel, the fluid channel having channel walls running between arrangements of the metallic pillars and a fluid outlet, whereby a fluid passes through the arrangement of metallic pillars to flow into the fluid channel.

Abstract: A Personal Food Database (PFD) that resides on a consumer's mobile device is presented. The PFD maintains an inventory that keeps track of amount of available food items. The mobile device operating the PFD has sensors for measuring the activities or biometric data of the user. The PFD uses the sensor data to assess the nutrition need of the user and to recommend recipes accordingly.

Abstract: A method of forming metallic pillars between a fluid inlet and outlet for two-phase fluid cooling. The method may include; forming an arrangement of metallic pillars between two structures, the metallic pillars are electrically connected to metallic connecting lines that run through each of the two structures, the arrangement of metallic pillars located between a fluid inlet and a fluid channel, the fluid channel having channel walls running between arrangements of the metallic pillars and a fluid outlet, whereby a fluid passes through the arrangement of metallic pillars to flow into the fluid channel.

Abstract: An apparatus comprises a storage controller coupled to at least one multi-region storage device. The at least one multi-region storage device comprises two or more storage regions, the two or more storage regions comprising a first storage region associated with a first set of failure characteristics and at least a second storage region associated with a second set of failure characteristics different than the first set of failure characteristics. The storage controller is configured to replicate in the second storage region at least a portion of data that is stored in the first storage region.

Abstract: Systems and methods for cooling include one or more computing structure, an inter-structure liquid cooling system that includes valves configured to selectively provide liquid coolant to the one or more computing structures; a heat rejection system that includes one or more heat rejection units configured to cool liquid coolant; and one or more liquid-to-liquid heat exchangers that include valves configured to selectively transfer heat from liquid coolant in the inter-structure liquid cooling system to liquid coolant in the heat rejection system. Each computing structure further includes one or more liquid-cooled servers; and an intra-structure liquid cooling system that has valves configured to selectively provide liquid coolant to the one or more liquid-cooled servers.

Abstract: A manifold for cooling electronic equipment, the manifold including a facility side coolant supply line, a facility side coolant return line, liquid-to-liquid heat exchangers, and pumps. The liquid-to-liquid heat exchangers are connected in parallel to the facility side coolant supply line. Each of the pumps is coupled to a liquid-to-liquid heat exchanger and regulates coolant flow through the coupled liquid-to-liquid heat exchangers.

Abstract: An apparatus comprises a storage controller coupled to at least one multi-region storage device. The at least one multi-region storage device comprises two or more storage regions, the two or more storage regions comprising a first storage region associated with a first set of failure characteristics and at least a second storage region associated with a second set of failure characteristics different than the first set of failure characteristics. The storage controller is configured to replicate in the second storage region at least a portion of data that is stored in the first storage region.

Abstract: An integrated circuit (IC) can be cooled by using a structure that includes two elements, such as integrated circuits (ICs) or electronic packages, in a stacked arrangement, with the elements having surfaces that face each other. The structure also includes a pair of fluidic channel boundaries, between the facing surfaces, where each fluidic channel boundary is formed by an arrangement of adjacent discrete connecting structures. The primary and secondary fluidic channel boundaries and the facing surfaces define a fluidic channel that is useful for promoting boiling of and directing the flow of a refrigerant between the two surfaces.

Abstract: A method of forming metallic pillars between a fluid inlet and outlet for two-phase fluid cooling. The method may include; forming an arrangement of metallic pillars between two structures, the metallic pillars are electrically connected to metallic connecting lines that run through each of the two structures, the arrangement of metallic pillars located between a fluid inlet and a fluid channel, the fluid channel having channel walls running between arrangements of the metallic pillars and a fluid outlet, whereby a fluid passes through the arrangement of metallic pillars to flow into the fluid channel.

Abstract: A system, method, and computer product for cooling a server center without the use of vapor compression refrigeration. An example embodiment involves using outdoor ambient air to cool first server components directly and to cool heat exchanges containing liquid used to cool second server components.

Abstract: A system for identifying hazardous driving behaviors is presented. Position and motion data from a plurality of vehicles are uploaded to a data center. For each vehicle, the system computes a set of hazard metric for identifying hazardous driving behaviors based on the position and motion information received from the plurality of vehicles. A hazardous vehicle is identified based on the computed hazard metric for the plurality of vehicles. The system reports a set of information regarding the hazardous vehicle to an agency.

Abstract: An apparatus comprises a first die, a thermal cooler formed over at least a portion of the first die, a second die formed over at least a portion of the thermal cooler, and a plurality of through-silicon vias providing electrical connections between the first die and the second die. The thermal cooler comprises a plurality of fluid channels for fluid cooling of the first die and the second die, the plurality of fluid channels being formed horizontally through the thermal cooler. The plurality of through-silicon vias are formed vertically through the first die, the thermal cooler and the second die.

Abstract: A data center cooling system is operated in a first mode, and has an indoor portion wherein heat is absorbed from components in the data center by a heat transfer fluid, and an outdoor heat exchanger portion and a geothermal heat exchanger portion. The first mode includes ambient air cooling of the heat transfer fluid in the outdoor heat exchanger portion and/or geothermal cooling of the heat transfer fluid in the geothermal heat exchanger portion. Based on an appropriate metric, a determination is made that a switch should be made from the first mode to a second mode; and, in response, the data center cooling system is switched to the second mode. The second mode is different than the first mode.

Abstract: An electric potential is applied to first and second electrodes on opposite sides of a gap between an electronic component and a heat spreader. At least one of a thermal interface material in the gap, the electronic component and the heat spreader is subjected to a changing physical condition. The capacitance is monitored. Such a method can be practiced using an array of components sharing a common heat spreader. An assembly for testing thermal interfaces includes a printed circuit board, a plurality of electronic components mounted to and operatively associated with the printed circuit board, a heat spreader positioned for absorbing heat generated by the electronic components, a first electrode associated with the heat spreader, a plurality of second electrodes associated, respectively, with the electronic component, and a device for monitoring electrical capacitances. The technique may be employed for monitoring physical changes in electronic devices.

Abstract: A system, method, and computer product for cooling a server center without the use of vapor compression refrigeration. An example embodiment involves using outdoor ambient air to cool first server components directly and to cool heat exchanges containing liquid used to cool second server components.

Abstract: A cooling system includes a device to be cooled and a cooling device integrated with the device to be cooled. A cooling volume has cavities and active coolant flow controls configured to adjust coolant flow through the cavities. A reservoir is in fluid communication with the cavities and has a liquid outlet and an inlet for a gas or gas-liquid mixture. A two-phase coolant is in the reservoir and cavities. The two-phase coolant has a phase transition temperature between an ambient temperature and an expected device temperature. A capacitance sensor is configured to determine a coolant capacitance in the cavities. A control module is configured to determine a vapor quality and void fraction of the coolant based on the measured capacitance and to increase coolant flow if the determined vapor quality and void fraction indicate a dry-out condition. A secondary cooling line removes heat from the cooling device.

Abstract: An electronic component to be encapsulated is introduced into a mold cavity. The mold cavity includes at least first and second halves, and at least one of the halves is formed with a negative of a thermal-interface-material engaging pattern thereon. An encapsulating material, which encapsulates the electronic component and engages the negative of the thermal-interface-material engaging pattern, is introduced into the mold cavity. The encapsulating material is allowed to solidify such that a thermal-interface-material engaging surface of the encapsulant solidifies with the thermal-interface-material engaging pattern thereon. During subsequent assembly, the thermal-interface-material engaging pattern engages thermal interface material to resist lateral motion of the thermal interface material.

Abstract: Cooling control methods and systems include measuring a temperature of air provided to one or more nodes by an air-to-liquid heat exchanger; measuring a temperature of at least one component of the one or more nodes and finding a maximum component temperature across all such nodes; comparing the maximum component temperature to a first and second component threshold and comparing the air temperature to a first and second air threshold; and controlling a proportion of coolant flow and a coolant flow rate to the air-to-liquid heat exchanger and the one or more nodes based on the comparisons.