Abstract: An apparatus for managing heat generated by at least one electronic component of a mobile device, the apparatus comprising: a housing for containing the electronic component of the mobile device; and a vapor chamber arranged in the housing, the vapor chamber having a cavity defined by a front wall and a rear wall opposite the rear wall, the front wall for receiving heat generated by the electronic component of the mobile device to evaporate fluid in the cavity into a vapor, the rear wall for receiving the vapor to allow the vapor to condense to liquid thereby cooling the rear wall of the vapor chamber; wherein an outer surface of the housing comprises at least a portion of the rear wall of the vapor chamber.

Abstract: An electronic device includes a housing with a plurality of sides and electronics components in the housing. A porous and thermally conductive material is associated with the housing. The material has a thermal conductively (k), and a porosity between 10% and 70% that results in a specific heat (?) and density (Cp) for the material, such that k*?*Cp is between 0 (J*W)/(m4*K2) and 1,000,000 (J*W)/(m4*K2). The material may be: a glass-based material having a thermal conductivity between 0.5-2 W/m-K, a density between 1000-2500 kg/m3, and a specific heat between 500-1000 J/kg-K; a metal-based material having a thermal conductivity between 300-400 W/m-K, a density between 4000-8000 kg/m3, and a specific heat between 200-300 J/kg-K; and a plastic-based material having a thermal conductivity may be between 0.1-0.4 W/m-K, a density between 400-1000 kg/m3, and a specific heat between 1900-2000 J/kg-K.

Abstract: Various embodiments of methods and systems for thermal energy management in a portable computing device (“PCD”) based on power level calculations are disclosed. An exemplary method includes tracking instantaneous operating temperatures and active power supply levels to one or more components. With an estimate or measurement of ambient temperature, the instantaneous operating temperature values and active power supply level values can be used to calculate an instantaneous thermal resistance value. In the event that thermal energy generation should be managed, a target operating temperature may be used with the ambient temperature and the instantaneous thermal resistance value to solve for an optimum power supply level. The active power supply level may then be adjusted based on the calculated optimum power supply level.

Abstract: Various embodiments of methods and systems for adaptive thermal management techniques implemented in a portable computing device (“PCD”) are disclosed. Notably, in many PCDs, temperature thresholds associated with various components in the PCD such as, but not limited to, die junction temperatures, package on package (“PoP”) memory temperatures and the “touch temperature” of the external surfaces of the device itself limits the extent to which the performance capabilities of the PCD can be exploited. It is an advantage of the various embodiments of methods and systems for adaptive thermal management that, when a temperature threshold is violated, the performance of the PCD is sacrificed only as much and for as long as necessary to clear the violation before authorizing the thermally aggressive processing component(s) to return to a maximum operating power.

Abstract: Various embodiments of methods and systems for thermal energy management in a portable computing device (“PCD”) based on power level calculations are disclosed. An exemplary method includes tracking instantaneous operating temperatures and active power supply levels to one or more components. With an estimate or measurement of ambient temperature, the instantaneous operating temperature values and active power supply level values can be used to calculate an instantaneous thermal resistance value. In the event that thermal energy generation should be managed, a target operating temperature may be used with the ambient temperature and the instantaneous thermal resistance value to solve for an optimum power supply level. The active power supply level may then be adjusted based on the calculated optimum power supply level.

Abstract: Various embodiments of methods and systems for adaptive thermal management techniques implemented in a portable computing device (“PCD”) are disclosed. Notably, in many PCDs, temperature thresholds associated with various components in the PCD such as, but not limited to, die junction temperatures, package on package (“PoP”) memory temperatures and the “touch temperature” of the external surfaces of the device itself limits the extent to which the performance capabilities of the PCD can be exploited. It is an advantage of the various embodiments of methods and systems for adaptive thermal management that, when a temperature threshold is violated, the performance of the PCD is sacrificed only as much and for as long as necessary to clear the violation before authorizing the thermally aggressive processing component(s) to return to a maximum operating power.

Abstract: Various embodiments of methods and systems for idle state optimization in a portable computing device (“PCD”) are disclosed. An exemplary method includes comparing an aggregate power consumption level for all processing cores in the PCD to a power budget and, if there is available headroom in the power budget, transitioning cores operating in a first idle state to a different idle state. In doing so, the latency value associated with bringing the transitioned cores out of an idle state and into an active state, should the need arise, may be reduced. The result is that user experience and QoS may be improved as an otherwise idle core in an idle state with a long latency time may be better positioned to quickly transition to an active state and process a workload.

Abstract: Various embodiments of methods and systems for estimating environmental ambient temperature of a portable computing device (“PCD”) from electrical resistance measurements taken voice coils in a speaker or microphone component are disclosed. In an exemplary embodiment, it may be recognized that the PCD is in an idle state, thus producing little or no thermal energy. Electrical resistance measurements are taken from a voice coil and used to estimate the environmental ambient temperature to which the PCD is exposed. Certain embodiments may simply render the estimated ambient temperature for the benefit of the user or use the estimated ambient temperature as an input to a program or application running on the PCD. It is envisioned that certain embodiments of the systems and methods may use the estimated ambient temperature to adjust temperature thresholds in the PCD against which thermal management policies govern thermally aggressive processing components.

Abstract: An apparatus for managing heat generated by at least one electronic component of a mobile device, the apparatus comprising: a housing for containing the electronic component of the mobile device; and a vapor chamber arranged in the housing, the vapor chamber having a cavity defined by a front wall and a rear wall opposite the rear wall, the front wall for receiving heat generated by the electronic component of the mobile device to evaporate fluid in the cavity into a vapor, the rear wall for receiving the vapor to allow the vapor to condense to liquid thereby cooling the rear wall of the vapor chamber; wherein an outer surface of the housing comprises at least a portion of the rear wall of the vapor chamber.

Abstract: Various embodiments of methods and systems for thermal energy management in a portable computing device (“PCD”) based on power level calculations are disclosed. An exemplary method includes tracking instantaneous operating temperatures and active power supply levels to one or more components. With an estimate or measurement of ambient temperature, the instantaneous operating temperature values and active power supply level values can be used to calculate an instantaneous thermal resistance value. In the event that thermal energy generation should be managed, a target operating temperature may be used with the ambient temperature and the instantaneous thermal resistance value to solve for an optimum power supply level. The active power supply level may then be adjusted based on the calculated optimum power supply level.

Abstract: Various embodiments of methods and systems for tuning a thermal strategy of a portable computing device (“PCD”) based on PCD location information. In an exemplary embodiment, it may be recognized that the PCD is in an active state and producing thermal energy, or that one or more thermally aggressive components of the PCD are operating near temperature thresholds for efficient operation. The PCD location information is used to estimate the environmental ambient temperature to which the PCD is exposed. Certain embodiments may simply render the estimated ambient temperature for the benefit of the user or may use the estimated ambient temperature as an input to a program, application, or algorithm running on the PCD. It is envisioned that certain embodiments of the systems and methods may use the estimated ambient temperature to adjust temperature thresholds in the PCD against which thermal management policies govern thermally aggressive PCD components.

Abstract: Various embodiments of methods and systems for estimating environmental ambient temperature of a portable computing device (“PCD”) from temperature measurements taken within the PCD are disclosed. In an exemplary embodiment, it may be recognized that the PCD is in an idle state, thus producing little or no thermal energy. Temperature measurements are then taken from temperature sensors within the PCD and used to estimate the environmental ambient temperature to which the PCD is exposed. Certain embodiments may simply render the estimated ambient temperature for the benefit of the user or use the estimated ambient temperature as an input to a program or application running on the PCD. It is envisioned that certain embodiments of the systems and methods may use the estimated ambient temperature to adjust temperature thresholds in the PCD against which thermal management policies govern thermally aggressive processing components.

Abstract: The formation of electronic assemblies is described. In one embodiment, an electronic assembly includes a semiconductor die and a plurality of spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a fluid positioned between the spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a endcap covering the plurality of nanotube structures and the fluid, wherein the endcap is positioned to define a gap between the nanotube structures and an interior surface of the endcap. The endcap is also positioned to form a closed chamber including the working fluid, the nanotube structures, and the gap between the nanotube structures and the interior surface of the endcap.

Abstract: Various embodiments of methods and systems for adaptive thermal management techniques implemented in a portable computing device (“PCD”) are disclosed. Notably, in many PCDs, temperature thresholds associated with various components in the PCD such as, but not limited to, die junction temperatures, package on package (“PoP”) memory temperatures and the “touch temperature” of the external surfaces of the device itself limits the extent to which the performance capabilities of the PCD can be exploited. It is an advantage of the various embodiments of methods and systems for adaptive thermal management that, when a temperature threshold is violated, the performance of the PCD is sacrificed only as much and for as long as necessary to clear the violation before authorizing the thermally aggressive processing component(s) to return to a maximum operating power.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A method, apparatus and system with a semiconductor package including a microchimney or thermosiphon using carbon nanotubes to modify the effective thermal conductivity of an integrated circuit die.

Abstract: A method, apparatus and system with a semiconductor package including a microchimney or thermosiphon using carbon nanotubes to modify the effective thermal conductivity of an integrated circuit die.

Abstract: The formation of electronic assemblies is described. In one embodiment, an electronic assembly includes a semiconductor die and a plurality of spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a fluid positioned between the spaced apart nanotube structures on the semiconductor die. The electronic assembly also includes a endcap covering the plurality of nanotube structures and the fluid, wherein the endcap is positioned to define a gap between the nanotube structures and an interior surface of the endcap. The endcap is also positioned to form a closed chamber including the working fluid, the nanotube structures, and the gap between the nanotube structures and the interior surface of the endcap.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.