Abstract: A method for manufacturing a photovoltaic device. The method comprises fabricating a first photovoltaic device portion with a first photoactive layer having a first face comprising a first perovskite precursor material; fabricating a second photovoltaic device portion with a second photoactive layer having a second face comprising a second perovskite material or a second perovskite precursor material; arranging the first photovoltaic device portion and the second photovoltaic device portion such that the first face is in contact with the second face; and compressing the first photovoltaic device portion and the second photovoltaic device portion at a pressure sufficient to fuse the first perovskite precursor material to the second perovskite material or the second perovskite precursor material.

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device, the method comprises: determining a target sound level for the multi-processor computing device; determining one or more candidate fan speed combinations for a first fan associated with a first temperature-controlled device included in the multi-processor computing device and a second fan associated with a second temperature-controlled device included in the multi-processor computing device based on the target sound level; determining a temperature error for one of the first temperature-controlled device, the second temperature-controlled device, or a third temperature-controlled device included in the multi-processor computing device based on the one or more candidate fan speed combinations and a measured temperature value for one of the first temperature-controlled device, the second temperature-controlled device, or the third temperature-controlled device; determining a value for a first power setting asso

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device comprises determining a first value for a first power setting associated with a first processor based on a sound level generated by the multi-processor computing device; determining a second value for the first power setting based on a power consumption level of the multi-processor computing device; comparing the first value to the second value; and causing the first processor to perform one or more operations based on the lesser of the first value and the second value.

Abstract: Various embodiments include techniques for controlling temperature and fan speed in a computing system. Conventional computing systems present the user with a very limited set of three or four curated performance mode presets, which can impose substantial trade-offs in performance, acoustic noise, and/or case temperature that the user may find to be unacceptable. By contrast, the disclosed techniques allow the user to precisely position the operation of the computing system anywhere in the two-dimensional space of fan speed (which determines acoustic noise) versus case temperature that suits the preference of the user. The disclosed techniques further provide a closed-loop feedback control system for controlling the case temperature. This closed-loop feedback control system operates in conjunction with the adjustable case temperature target to determine individual power limits for certain components, such as a CPU power limit, a GPU power limit, and/or the like.

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device comprises: determining whether a first processor is operating in a high-power regime or a low-power regime; selecting a first set of control rules that includes a first subset of control rules that apply when the first processor is operating in the high-power regime and a second subset of control rules that apply when the first processor is operating in the low-power regime; determining one or more power settings for the first processor based on the first set of control rules; and causing the first processor to perform one or more operations based on the one or more power settings.

Abstract: A method for manufacturing a photovoltaic device. The method comprises fabricating a first photovoltaic device portion with a first photoactive layer having a first face comprising a first perovskite precursor material; fabricating a second photovoltaic device portion with a second photoactive layer having a second face comprising a second perovskite material or a second perovskite precursor material; arranging the first photovoltaic device portion and the second photovoltaic device portion such that the first face is in contact with the second face; and compressing the first photovoltaic device portion and the second photovoltaic device portion at a pressure sufficient to fuse the first perovskite precursor material to the second perovskite material or the second perovskite precursor material.

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device comprises: determining whether a first processor is operating in a high-power regime or a low-power regime; selecting a first set of control rules that includes a first subset of control rules that apply when the first processor is operating in the high-power regime and a second subset of control rules that apply when the first processor is operating in the low-power regime; determining one or more power settings for the first processor based on the first set of control rules; and causing the first processor to perform one or more operations based on the one or more power settings.

Abstract: A method for manufacturing a photovoltaic device. The method comprises fabricating a first photovoltaic device portion with a first photoactive layer having a first face comprising a first perovskite precursor material; fabricating a second photovoltaic device portion with a second photoactive layer having a second face comprising a second perovskite material or a second perovskite precursor material; arranging the first photovoltaic device portion and the second photovoltaic device portion such that the first face is in contact with the second face; and compressing the first photovoltaic device portion and the second photovoltaic device portion at a pressure sufficient to fuse the first perovskite precursor material to the second perovskite material or the second perovskite precursor material.

Abstract: A method for forming a nickel oxide layer is disclosed herein. In some embodiments, a method includes depositing a nickel oxide precursor ink on a substrate, wherein the nickel oxide precursor ink comprises a solvent comprising diols, alcohol amines, and water, Ni(NO3)2·6H2O, and at least one metal acetate selected from the group consisting of Ni(CH3CO2)2·4H2O and Cu(CH3CO2)2·1H2O, annealing the nickel oxide precursor ink at a temperature between 250° to 400° Celsius for between 10 minutes and 6 hours to form a nickel oxide layer, and cooling the nickel oxide layer.

Abstract: A method for preparing a nickel oxide precursor ink comprising: preparing a solvent comprising diols and alcohol amines; adding nickel nitrate into the solvent to form a nickel nitrate containing solution; adding at least one metal acetate into the nickel nitrate containing solution to form a nickel nitrate and metal acetate containing solution; adding water to the nickel nitrate and metal acetate containing solution to form a nickel oxide precursor mixture; heating the nickel oxide precursor mixture to 60 to 75 Celsius; and cooling the nickel oxide precursor mixture to form the nickel oxide precursor ink.

Abstract: A method for manufacturing a photovoltaic device. The method comprises fabricating a first photovoltaic device portion with a first photoactive layer having a first face comprising a first perovskite precursor material; fabricating a second photovoltaic device portion with a second photoactive layer having a second face comprising a second perovskite material or a second perovskite precursor material; arranging the first photovoltaic device portion and the second photovoltaic device portion such that the first face is in contact with the second face; and compressing the first photovoltaic device portion and the second photovoltaic device portion at a pressure sufficient to fuse the first perovskite precursor material to the second perovskite material or the second perovskite precursor material.

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device, the method comprises: determining a target sound level for the multi-processor computing device; determining one or more candidate fan speed combinations for a first fan associated with a first temperature-controlled device included in the multi-processor computing device and a second fan associated with a second temperature-controlled device included in the multi-processor computing device based on the target sound level; determining a temperature error for one of the first temperature-controlled device, the second temperature-controlled device, or a third temperature-controlled device included in the multi-processor computing device based on the one or more candidate fan speed combinations and a measured temperature value for one of the first temperature-controlled device, the second temperature-controlled device, or the third temperature-controlled device; determining a value for a first power setting asso

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device comprises determining a first value for a first power setting associated with a first processor based on a sound level generated by the multi-processor computing device; determining a second value for the first power setting based on a power consumption level of the multi-processor computing device; comparing the first value to the second value; and causing the first processor to perform one or more operations based on the lesser of the first value and the second value.

Abstract: A computer-implemented method of controlling power consumption in a multi-processor computing device comprises: determining whether a first processor is operating in a high-power regime or a low-power regime; selecting a first set of control rules that includes a first subset of control rules that apply when the first processor is operating in the high-power regime and a second subset of control rules that apply when the first processor is operating in the low-power regime; determining one or more power settings for the first processor based on the first set of control rules; and causing the first processor to perform one or more operations based on the one or more power settings.

Abstract: A method for manufacturing a photovoltaic device includes fabricating a first photovoltaic device portion with a first perovskite material layer having a first face, and fabricating a second photovoltaic device portion with a second perovskite material layer having a second face. Then first photovoltaic device portion and the second photovoltaic device portion are arranged such that the first face is in contact with the second face. Finally, the first photovoltaic device portion and second photovoltaic device portion are compressed at a pressure sufficient to fuse the first perovskite material to the second perovskite material.

Abstract: A method for manufacturing a photovoltaic device. The method comprises fabricating a first photovoltaic device portion with a first photoactive layer having a first face comprising a first perovskite precursor material; fabricating a second photovoltaic device portion with a second photoactive layer having a second face comprising a second perovskite material or a second perovskite precursor material; arranging the first photovoltaic device portion and the second photovoltaic device portion such that the first face is in contact with the second face; and compressing the first photovoltaic device portion and the second photovoltaic device portion at a pressure sufficient to fuse the first perovskite precursor material to the second perovskite material or the second perovskite precursor material.

Abstract: A method for manufacturing a photovoltaic device includes fabricating a first photovoltaic device portion with a first perovskite material layer having a first face, and fabricating a second photovoltaic device portion with a second perovskite material layer having a second face. Then first photovoltaic device portion and the second photovoltaic device portion are arranged such that the first face is in contact with the second face. Finally, the first photovoltaic device portion and second photovoltaic device portion are compressed at a pressure sufficient to fuse the first perovskite material to the second perovskite material.

Abstract: A connection device is provided for operatively connecting a temperature control for an electrical appliance to a power source. The connection device includes first and second connection surfaces projecting from the temperature control that partially define a cavity. Each connection surface includes a corresponding depression formed therein. A power cord housing supports a first end of a power cord. The power cord housing includes a forward end that is receivable in the cavity. The connection device further includes first and second detent elements that are movable between first extended positions wherein the detent elements project from the power cord housing and are receivable in corresponding depressions and second retracted positions. Biasing structure is provided for urging the first and second detent elements toward their extended positions.