Murokh
Alex Murokh, Encino, CA US
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20150338545 | SYSTEM AND METHOD FOR ADAPTIVE X-RAY CARGO INSPECTION - An X-ray based inspection systems providing radiographic imaging for cargo inspection and material discrimination with adaptive control dependent upon characteristics of the cargo under inspection. A packet of X-ray pulses with controllable packet duration is produced that allows multi-energy material discrimination in a single scan line and real-time adjustment of packet duration to adapt to cargo attenuation. In addition, adaptive dynamic adjustment of the operational characteristic of the detector channels increases the effective dynamic range and as a result increases the penetration and range of thicknesses where material discrimination is possible. The material discrimination technique is applied within a single packet of short pulses of several hundred nanoseconds. Feedback from the detection system is used to control the packet duration of each packet of X-ray pulses in order to adapt scan parameters to the object that is being imaged. | 11-26-2015 |
Alex Y. Murokh, Encino, CA US
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20110240888 | METHOD OF TESTING ELECTRONIC COMPONENTS - A method for testing the sensitivity of electronic components and circuits against particle and photon beams using plasma acceleration, in which the flexibility of the multifaceted interaction can produce several types of radiation such as electron, proton, ion, neutron and photon radiation, and combinations of these types of radiation, in a wide range of parameters that are relevant to the use of electronic components in space, such as satellites, at high altitudes or in facilities that work with radioactive substances such as nuclear power plants. Relevant radiation parameter ranges are accessible by this method, which are hardly accessible with conventional accelerator technology. Because of the compactness of the procedure and its versatility, radiation testing can be performed in smaller laboratories at relatively low cost. | 10-06-2011 |
Alex Y. Murokh, Sherman Oaks, CA US
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20110290379 | METHOD AND USE FOR TEXTURED DYSPROSIUM - A method of making a magnetic field concentrator, comprising cold rolling a first metal sample that includes dysprosium to a foil having a thickness of between 20 microns and 60 microns; and further annealing the foil at a temperature of between 1000 and 1300 degrees C., for a period of between 10 minutes and 20 minutes. Preferably, annealing the foil takes place in an oxygen-free chamber, where the chamber is made from a material selected from at least one of molybdenum, tantalum, and titanium. Finally, at least a second sheet of annealed foil is produced, and the first and second foils are laminated together to produce a laminated sheet suitable for use as a magnetic field concentrator. | 12-01-2011 |
Igor Murokh, Santa Monica, CA US
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20120145673 | DIELECTRIC PLASMA CHAMBER APPARATUS AND METHOD WITH EXTERIOR ELECTRODES - A dielectric barrier discharge plasma generator includes a dielectric chamber. The chamber contains or incorporates a solid surface that is to be treated with non-thermal plasma. The chamber can be substantially sealed and confine an atmosphere therein. An atmosphere control system is provided for controlling the atmosphere within the chamber. At least one or two electrodes are located outside of the chamber. When actuated by an appropriate source of plasma generating electrical power the electrodes cause the generation of a solid surface modifying non-thermal plasma in a plasma zone within the chamber. A transport system is provided for moving the electrode and the chamber relative to one another. A plasma zone is confined within the chamber adjacent to the electrodes, and remains substantially stationary relative to the electrodes. The chamber carries the solid surface through the plasma zone. The solid surface remains substantially stationary relative to the chamber. | 06-14-2012 |
20140123601 | Laser Capsule Marking System and Method - A laser capsule marking system and method may comprise at least two indexing wheels, a feeding mechanism, a laser marker, a first inspection system, a rejection subsystem, a reject verification sensor, and a collection device. The wheels are coaxial and have respective circumferential peripheries with multiple open pockets distributed thereabout. Each pocket is configured to releasably receive a pharmaceutical capsule doped with pigment particles reactive to laser light. The indexing wheels are configured to be incrementally rotated in alternating indexing fashion for transporting discrete arrays of respective pockets through a loading zone, an inspection zone, a marking zone, a reject zone, and an unloading zone. An actuatable reject block may be provided to simultaneously blow a rejected capsule from its pocket, and draw it in for transport to a rejection bin. Each circumferential periphery may be comprised of multiple arcuate shoes removably and replaceably secured to their respective indexing wheel. | 05-08-2014 |