Kordon
Arthur Karl Kordon, Lake Jackson, TX US
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20100049340 | Inferential Sensors Developed Using Three-Dimensional Pareto-Front Genetic Programming - A predictive algorithm for predictive at least one output variable based on a plurality of input variables is developed using a genetic programming technique that evolves a population of candidate algorithms through multiple generations. Within each generation, the candidate algorithms are evaluated based on three fitness criteria: (i) an accuracy criterion that evaluates each candidate algorithm's ability to predict historical measurements of the at least one output variable based on corresponding historical measurements of the input variables; (ii) a complexity criterion that evaluates each candidate algorithm's complexity; and (iii) a smoothness criterion that evaluates each candidate algorithm's nonlinearity. The predictive algorithm may be implemented in an inferential sensor that is used to monitor a physical, chemical, or biological process, such as an industrial process in an industrial plant. | 02-25-2010 |
Michael Kordon, Gerstetten DE
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20100199708 | REFRIGERATION DEVICE WITH A HOLDER FOR A SECTION OF A REFRIGERANT LINE - A refrigeration device having a refrigerated chamber, a refrigerant line, and a refrigerant circulation system structured to transfer heat energy from the refrigerated chamber into the refrigerant circulation system via the refrigerant line. In an exemplary embodiment of the invention, the refrigerant line may include a heat-emitting section in heat-conducting contact with a trim strip of the refrigeration device running below the refrigerated chamber. | 08-12-2010 |
Seven Kordon, Wunstorf DE
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20110158326 | METHOD AND APPARATUS FOR GENERATING OR CUTTING OR CHANGING A FRAME BASED BIT STREAM FORMAT FILE INCLUDING AT LEAST ONE HEADER SECTION, AND A CORRESPONDING DATA STRUCTURE - In frame-based bit stream formats the data required for decoding a current frame are usually stored within the data section for that frame. One exception is the mp3 bit stream where data for a current frame is stored in previous frames. If the decoder did not receive the required previous frame, decoding of the current mp3 frame is skipped. The invention can be applied for such bit streams, in an archival mode, a streaming mode and a sample-exact cutting of an archival mode. In the streaming and cutting modes, new headers are established. The number of frames required for initialising the decoder status is signalised in the header, as well as a consistency check value in the streaming mode. These frames are used for decoder initialisation but not for decoding samples or coefficients. For a sample-exact cutting, for the frame at which the cut shall occur, the number of samples or coefficients to be muted is also indicated in the header. The invention can be applied for the hd3 audio file format for lossless extension of an mp3 bit stream. | 06-30-2011 |
Timothy Kordon, Purcelville, VA US
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20120278971 | VISORED CLOTH HEADGEAR - An item of headgear comprised of a visor bill attached to a square piece of cloth along the diagonal of the cloth and slightly below the center of the cloth. The visor bill is encased in a pocket-shaped visor bill cover before it is stitched to the square piece of cloth. The present invention can be worn as a visor, or it can be opened up and wrapped over the top of the head to form the shape of a more traditional hat. | 11-08-2012 |
Ulrich Kordon, Dresden DE
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20120006117 | Method and Apparatus for Locating Cable Faults - An electrical pulse fed into an electrical cable, e.g. a power transmission or distribution cable buried underground, produces an acoustic signal, e.g. an arc-over or discharge noise, at a fault in the cable. This acoustic signal is detected and used to locate the fault. But the acoustic signal has interference noise superimposed on it, which makes it difficult to identify the acoustic signal in the noise-burdened received signal, and thus also makes it difficult or impossible to accurately locate the fault. To minimize or avoid the influence of interference noises, the relevant acoustic signal is identified in the received signal by comparing the received signal with predetermined sample data, such as signal patterns, characteristics or characteristic sets. | 01-12-2012 |