Abstract: Examples include a computing system for receiving memory class of service parameters; setting performance monitoring configuration parameters, based at least in part on the memory class of service parameters, for use by a performance monitor of a memory controller to generate performance monitoring statistics by monitoring performance of one or more workloads by a plurality of processor cores based at least in part on the performance monitoring configuration parameters; receiving the performance monitoring statistics from the performance monitor; and generating, based at least in part on the performance monitoring statistics, a plurality of memory bandwidth settings to be applied by a memory bandwidth allocator to the plurality of processor cores to dynamically adjust priorities of memory bandwidth allocated for the one or more workloads to be processed by the plurality of processor cores.

Abstract: A method for detecting concentration of iodine in water samples. An arsenite-containing test solution, a tetravalent cerium ion-containing test solution and a series of iodine-containing standard solutions are prepared. The standard solutions are added to primary wells of a microplate, respectively. A water sample is added to a secondary well. The arsenite-containing test solution and the tetravalent cerium ion-containing test solution are sequentially added to the primary wells and the secondary well. Reaction mixture in each well is reacted and then measured for absorbance by a detector. A standard curve is plotted according to the absorbance of each primary well and a concentration of each iodine-containing standard solution. The absorbance of the sample is plugged into the standard curve to obtain an iodine concentration in the sample.

Abstract: Disclosed is a kit for detecting content of fluoride ions in a microsample, including: at least one 96-well plate, reagent A, reagent B, reagent C, reagent D, reagent E and a fluoride standard solution having a concentration of 2.5 mg/L. The kit can be used to effectively overcome the uncertainties in the existing methods for detecting fluoride ions, and also involves rapid and convenient operation. Moreover, this method involves simple and rapid operation, the use of a small amount of a sample and simultaneous detection of multiple samples. This kit provides a more standardized detection to lower the human error, thereby allowing for a more reliable result and for a suitable application in the on-site detection of content of fluoride ions in various environments such as in water quality engineering or in the laboratory.

Abstract: A method for detecting content of fluoride ions in a microsample, including: (1) preparing reagents; (2) preparing a detecting liquid; (3) loading samples; and (4) detecting the content of fluoride ions. The method of the invention can effectively overcome unstable factors in the prior art. Moreover, this method involves simple and rapid operation, the use of a small amount of a sample and simultaneous detection of multiple samples. The steps are standardized to reduce human error, allowing for more reliable results.

Abstract: A method for detecting concentration of iodine in water samples. An arsenite-containing test solution, a tetravalent cerium ion-containing test solution and a series of iodine-containing standard solutions are prepared. The standard solutions are added to primary wells of a microplate, respectively. A water sample is added to a secondary well. The arsenite-containing test solution and the tetravalent cerium ion-containing test solution are sequentially added to the primary wells and the secondary well. Reaction mixture in each well is reacted and then measured for absorbance by a detector. A standard curve is plotted according to the absorbance of each primary well and a concentration of each iodine-containing standard solution. The absorbance of the sample is plugged into the standard curve to obtain an iodine concentration in the sample.

Abstract: Examples include a computing system for receiving memory class of service parameters; setting performance monitoring configuration parameters, based at least in part on the memory class of service parameters, for use by a performance monitor of a memory controller to generate performance monitoring statistics by monitoring performance of one or more workloads by a plurality of processor cores based at least in part on the performance monitoring configuration parameters; receiving the performance monitoring statistics from the performance monitor; and generating, based at least in part on the performance monitoring statistics, a plurality of memory bandwidth settings to be applied by a memory bandwidth allocator to the plurality of processor cores to dynamically adjust priorities of memory bandwidth allocated for the one or more workloads to be processed by the plurality of processor cores.

Abstract: Disclosed is a kit for detecting content of fluoride ions in a microsample, including: at least one 96-well plate, reagent A, reagent B, reagent C, reagent D, reagent E and a fluoride standard solution having a concentration of 2.5 mg/L. The kit can be used to effectively overcome the uncertainties in the existing methods for detecting fluoride ions, and also involves rapid and convenient operation. Moreover, this method involves simple and rapid operation, the use of a small amount of a sample and simultaneous detection of multiple samples. This kit provides a more standardized detection to lower the human error, thereby allowing for a more reliable result and for a suitable application in the on-site detection of content of fluoride ions in various environments such as in water quality engineering or in the laboratory.

Abstract: A method for detecting content of fluoride ions in a microsample, including: (1) preparing reagents; (2) preparing a detecting liquid; (3) loading samples; and (4) detecting the content of fluoride ions. The method of the invention can effectively overcome unstable factors in the prior art. Moreover, this method involves simple and rapid operation, the use of a small amount of a sample and simultaneous detection of multiple samples. The steps are standardized to reduce human error, allowing for more reliable results.