Abstract: A light-emitting device comprises a substrate; a first semiconductor layer formed on the substrate; a first patterned layer formed on the first semiconductor layer; and a second semiconductor layer formed on the first semiconductor layer, wherein the second semiconductor layer comprises a core layer comprising a group III or transition metal material formed along the first patterned layer.

Abstract: A board-to-board radio frequency coaxial connector includes an adapter, a clamping socket including a first outer conductor, a first inner conductor, and a first insulator, and a fixed socket including a second outer conductor, a second inner conductor, and a second insulator. The clamping socket and the fixed socket are respectively arranged at two ends of the adaptor. The adapter includes a third outer conductor, a third inner conductor, and two third insulators. The two third insulators are respectively arranged at two ends of the third inner conductors and sleeved on an outside of the third inner conductor. Each of the two third insulators includes a body portion and an auxiliary portion. The body portion includes a second groove recessed inwardly from its outer circumferential surface. Two ends of the third outer conductor are respectively electrically connected to the first and second outer conductors.

Abstract: A board-to-board radio frequency coaxial connector includes an adapter, a clamping socket including a first outer conductor, a first inner conductor, and a first insulator, and a fixed socket including a second outer conductor, a second inner conductor, and a second insulator. The clamping socket and the fixed socket are respectively arranged at two ends of the adaptor. The adapter includes a third outer conductor, a third inner conductor, and two third insulators. The two third insulators are respectively arranged at two ends of the third inner conductors and sleeved on an outside of the third inner conductor. Each of the two third insulators includes a body portion and an auxiliary portion. The body portion includes a second groove recessed inwardly from its outer circumferential surface. Two ends of the third outer conductor are respectively electrically connected to the first and second outer conductors.

Abstract: A light-emitting device comprises a substrate; a first semiconductor layer formed on the substrate; a first patterned layer formed on the first semiconductor layer; and a second semiconductor layer formed on the first semiconductor layer, wherein the second semiconductor layer comprises a core layer comprising a group III or transition metal material formed along the first patterned layer.

Abstract: A method for constructing an metal ion binding motif by identifying an metal ion binding peptide that binds an metal ion with specificity, ascertaining at least a portion of a nucleic acid sequence encoding the metal ion binding peptide, tailoring the nucleic acid sequence encoding the metal ion binding peptide into an metal ion binding site, identifying a host protein and a relevant portion of the nucleic acid sequence of the host protein, operatively linking the tailored nucleic acid sequence encoding the metal ion binding peptide and the host protein nucleic acid sequence into an metal ion binding motif sequence, and expressing metal ion binding motif sequence, in which the nucleic acid sequence encoding the metal ion binding peptide is tailored so as to achieve the metal ion binding motif with a desired specificity for the metal ion. Also, the proteins encoded by the metal ion binding motif sequence as constructed by the method.

Abstract: Memory arrays and reading, programming and erasing methods of the memory arrays are provided. An exemplary memory array includes a plurality of memory columns. Each memory column has a plurality of flash memory cells. The memory columns are divided into at least two blocks. At least one source pull down column is disposed between the two adjacent blocks. Each source pull down column has a plurality of flash memory cells. A source of each flash memory cell in the source pull down column is coupled to sources of the flash memory cells of the plurality memory columns in a same row as the flash memory cell in the source pull down column to pull down a source of a selected flash memory cell to 0 V.

Abstract: A charge pump voltage regulator is provided. The charge pump voltage regulator includes a charge pump circuit, where an output terminal of the charge pump circuit outputs a stable voltage. The charge pump voltage regulator also includes a voltage divider circuit suitable to divide the stable voltage to output a divided voltage and a clock oscillator providing a drive clock signal for the charge pump circuit. In addition, the charge pump voltage regulator includes a first voltage comparator circuit suitable to output at least one of a first comparison result and a second comparison result. Further, the charge pump voltage regulator includes a logic control unit, where, when the charge pump voltage regulator operates in a standby mode, the logic control unit outputs a first control level to the clock oscillator according to the at least one of the first comparison result and the second comparison result.

Abstract: A memory and a reference circuit calibration method are provided. The memory includes: a memory array including a plurality of memory cells; a reference circuit including a reference memory cell and a reference connection terminal, wherein the reference memory cell is a same as the memory cell; a calibration circuit including a calibration connection terminal, and a mirror circuit including a first mirror terminal and a second mirror terminal, wherein the first mirror terminal is connected to the reference connection terminal, and the second mirror terminal is connected to the calibration connection terminal; a clamp circuit, configured to set one of a voltage of the reference connection terminal and a voltage of the calibration connection terminal as a preset voltage and to set the other thereof as a comparison voltage; and a comparison circuit configured to input the comparison voltage and the preset voltage, and to output a comparison result.

Abstract: Memory arrays and reading, programming and erasing methods of the memory arrays are provided. An exemplary memory array includes a plurality of memory columns. Each memory column has a plurality of flash memory cells. The memory columns are divided into at least two blocks. At least one source pull down column is disposed between the two adjacent blocks. Each source pull down column has a plurality of flash memory cells. A source of each flash memory cell in the source pull down column is coupled to sources of the flash memory cells of the plurality memory columns in a same row as the flash memory cell in the source pull down column to pull down a source of a selected flash memory cell to 0 V.

Abstract: A memory and a reference circuit calibration method are provided. The memory includes: a memory array including a plurality of memory cells; a reference circuit including a reference memory cell and a reference connection terminal, wherein the reference memory cell is a same as the memory cell; a calibration circuit including a calibration connection terminal and a mirror circuit including a first mirror terminal and a second mirror terminal, wherein the first mirror terminal is connected to the reference connection terminal, and the second mirror terminal is connected to the calibration connection terminal; a clamp circuit, configured to set one of a voltage of the reference connection terminal and a voltage of the calibration connection terminal as a preset voltage and to set the other thereof as a comparison voltage; and a comparison circuit configured to input the comparison voltage and the preset voltage, and to output a comparison result.

Abstract: A charge pump voltage regulator is provided. The charge pump voltage regulator includes a charge pump circuit, where an output terminal of the charge pump circuit outputs a stable voltage. The charge pump voltage regulator also includes a voltage divider circuit suitable to divide the stable voltage to output a divided voltage and a clock oscillator providing a drive clock signal for the charge pump circuit. In addition, the charge pump voltage regulator includes a first voltage comparator circuit suitable to output at least one of a first comparison result and a second comparison result. Further, the charge pump voltage regulator includes a logic control unit, where, when the charge pump voltage regulator operates in a standby mode, the logic control unit outputs a first control level to the clock oscillator according to the at least one of the first comparison result and the second comparison result.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: A method for constructing an metal ion binding motif by identifying an metal ion binding peptide that binds an metal ion with specificity, ascertaining at least a portion of a nucleic acid sequence encoding the metal ion binding peptide, tailoring the nucleic acid sequence encoding the metal ion binding peptide into an metal ion binding site, identifying a host protein and a relevant portion of the nucleic acid sequence of the host protein, operatively linking the tailored nucleic acid sequence encoding the metal ion binding peptide and the host protein nucleic acid sequence into an metal ion binding motif sequence, and expressing metal ion binding motif sequence, in which the nucleic acid sequence encoding the metal ion binding peptide is tailored so as to achieve the metal ion binding motif with a desired specificity for the metal ion. Also, the proteins encoded by the metal ion binding motif sequence as constructed by the method.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: A cleaner is provided for a filter of a dishwashing appliance. The filter cleaner rotates within the filter and uses nozzles to remove particulates on the filter surface. Energy from fluid flow caused by a pump is used to rotate the filter cleaner. The particulates removed from the filter are pumped away for disposal.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: Analyte sensors, methods for producing and using analyte sensors, methods of detecting and/or measuring analyte activity, detecting pH change, and/or, controlling the concentration of an analyte in a system, are disclosed. Embodiments of the analyte sensors according to the disclosure can provide an accurate and convenient method for characterizing analyte activity, detecting pH change, controlling the concentration of an analyte in a system, and the like, in both in vivo and in vitro environments, in particular in living cell imaging.

Abstract: The present subject matter provides a dishwashing appliance having a flow of air through an air passageway defined between an inner panel and an outer panel of the dishwasher appliance. The inner panel has a condensation surface for assisting in drying dishes in the dishwasher appliance. A dampening baffle causes at least one change of direction in the flow of air through the air flow passageway.