Keith Brian
Keith Brian Blodorn, Menomonee Falls, WI US
Patent application number | Description | Published |
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20120081841 | MOTOR CONTROL CENTER NETWORK CONNECTIVITY METHOD AND SYSTEM - A motor control center comprises a plurality of bays in which switchgear components, circuit protective components, automation components and power electronic components are disposed for driving motors and other loads. Network optical conductors are routed through one or more wireways adjacent to the bays. Distribution nodes are coupled to the conductors and are interconnected with respective network terminals within the bays. Components within individual bays for which EtherNet and/or Internet connectivity is desired are coupled to the network terminals. The conductors may comprise plastic optical fibers and may be designed to operate in the relatively high voltage environment of the motor control center bays. | 04-05-2012 |
20130022357 | MOTOR CONTROL CENTER NETWORK CONNECTIVITY METHOD AND SYSTEM - A motor control center comprises a plurality of bays in which switchgear components, circuit protective components, automation components and power electronic components are disposed for driving motors and other loads. Network optical conductors are routed through one or more wireways adjacent to the bays. Distribution nodes are coupled to the conductors and are interconnected with respective network terminals within the bays. Components within individual bays for which EtherNet and/or Internet connectivity is desired are coupled to the network terminals. The conductors may comprise plastic optical fibers and may be designed to operate in the relatively high voltage environment of the motor control center bays. | 01-24-2013 |
Keith Brian Galocy, Morgan Hill, CA US
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20130067240 | CONTENT PROTECTION VIA ONLINE SERVERS AND CODE EXECUTION IN A SECURE OPERATING SYSTEM - A computer system comprising a processor and a memory for storing instructions, that when executed by the processor performs a copy protection method. The copy protection method comprises executing a software loop of a first software application in a first operating system. A first call is executed in the software loop to a code portion. A decrypted code portion of the first software application is executed in a second operating system in response to the first call. The code portion is decrypted in response to a successful validation of the first software application. | 03-14-2013 |
Keith Brian Kahen, Rochester, NY US
Patent application number | Description | Published |
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20120205586 | INDIUM PHOSPHIDE COLLOIDAL NANOCRYSTALS - A method of making a colloidal solution of indium phosphide semiconductor nanocrystals, includes forming a first solution by combining solvents and ligands; and heating the first solution to a temperature equal to or higher than 290° C. and, while heating, adding to the first solution, a second solution containing trialkylindium, a phosphorus precursor and solvents and ligands so that a reaction takes place that forms a colloidal solution of indium phosphide semiconductor nanocrystals. The method further includes forming core shell indium phosphide semiconductor nanocrystals by forming semiconducting shells on the nanocrystals. | 08-16-2012 |
20130092883 | HIGHLY-CONFINED SEMICONDUCTOR NANOCRYSTALS - A high confinement semiconductor nanocrystal and method for making such nanocrystal are described. The nanocrystal includes a compact homogenous semiconductor region having a first composition in the center area of the nanocrystal, with its diameter being less than 2.0 nm; and a gradient alloy region comprised of a second varying alloy composition which extends from the surface of the compact homogenous semiconductor region to the surface of the nanocrystal. | 04-18-2013 |
20130092886 | METHOD OF MAKING HIGHLY-CONFINED SEMICONDUCTOR NANOCRYSTALS - A method of making a colloidal solution of high confinement semiconductor nanocrystals includes: forming a first solution by combining a solvent, growth ligands, and at most one semiconductor precursor; heating the first solution to the nucleation temperature; and adding to the first solution, a second solution having a solvent, growth ligands, and at least one additional and different precursor than that in the first solution to form a crude solution of nanocrystals having a compact homogenous semiconductor region. The method further includes: waiting 0.5 to 20 seconds and adding to the crude solution a third solution having a solvent, growth ligands, and at least one additional and different precursor than those in the first and second solutions; and lowering the growth temperature to enable the formation of a gradient alloy region around the compact homogenous semiconductor region, resulting in the formation of a colloidal solution of high confinement semiconductor nanocrystals. | 04-18-2013 |
Keith Brian Maddern, Tucson, AZ US
Patent application number | Description | Published |
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20100082282 | REDUCTION OF THE NUMBER OF INTEROPERABILITY TEST CANDIDATES AND THE TIME FOR INTEROPERABILITY TESTING - Provided are a method, system, and article of manufacture wherein a determination is made of a subset of all possible interoperable combinations of components of a computing system, wherein the components comprise selected elements of the computing system. One or more testing criteria are stored, wherein a testing criteria provides indications of characteristics of one or more of the components of the computing system. A selection is made of a number of interoperable combinations of the components from the subset of interoperable combinations of the components, based on the stored one or more testing criteria. The selected interoperable combinations are tested, wherein the selected interoperable combinations are fewer in number than the subset of interoperable combinations. | 04-01-2010 |
20130202922 | POLYMER FUSED BATTERIES - Polymer-fused batteries are provided. The battery includes a casing, an anode coupled to the casing, an electrical source disposed between the casing and the anode, and a fuse over at least a portion of the anode. The polymer fuse comprises an electrically-conductive material formulated to decompose upon contact with a bodily fluid and to provide electrical communication between the anode cap and the electrical source when the polymer fuse is intact. | 08-08-2013 |