Patent application number | Description | Published |
20090045142 | METHOD AND APPARATUS FOR COLLECTING POLLUTANTS IN A BODY OF WATER - During collection of pollutants having a density lower than that of water and carried by a surface layer of a body of water, water of the surface layer is caused to flow into and through a collection vessel having a separation compartment with a top wall, pollutants entrained by the inflowing surface layer water are allowed to collect gravimetrically as a supernatant layer carried beneath the top wall of the separation compartment on water in the separation compartment, and changes of the weight of the collection vessel in the body of water are monitored. Intake and discharge phases may be initiated and terminated to in response to the said weight reaching predetermined values. | 02-19-2009 |
20090311656 | STATE SPACE MODEL OF A HEART - A state space model (SSM), being a computer-calculated model, adapted to represent the pumping and controlling functions of a heart that have been determined by a heart cluster state machine simulating the heart, and optionally the circulatory system, of an individual. The state space model includes two groups of separate interacting state machines, the heart muscle cell state machines and the displacement pump state machines. | 12-17-2009 |
20100281413 | STATE MACHINE USER AND VALIDATION INTERFACE SYSTEM - State machine interface system, comprising state machine algorithms and a graphical user interface, adapted to receive signals from at least one sensor device, that are related to physiological activities of the heart and/or the circulatory system of a living being. The state machine algorithms are adapted to determine phases of heart cycles based upon said signals. The different phases of the heart cycle are determined by said state machine algorithms in a heart cluster state machine simulating the heart, and optionally the circulatory system, achieved by fusions of finite heart muscle cell state machines to form a ΔV-pump state machine. The determined heart cycle phases are evaluated by determining their respective local state diagram based upon said signal such that the respective correct time duration is determined for each heart cycle phase, and then determining the most representative global state diagram. The determined local and global state diagrams are presented at the graphical user interface such that the temporal relations between the different phases are illustrated. | 11-04-2010 |
Patent application number | Description | Published |
20090284325 | Phased-Array Antenna Filter and Diplexer for a Super Economical Broadcast System - A phased-array antenna filter and diplexer for a super economical broadcast system are provided. The filter and diplexer includes a signal divider tee diplexer, a receive filter and a transmit filter. The diplexer includes a tee branch point, an antenna port, a transmit port and a receive port. The receive filter includes a flat, multi-pole bandpass filter, an input port and an output port, where the input port is coupled to the diplexer receive port to define a receive signal path, from the tee branch point to the receive input port, that has a length of approximately one quarter receive wavelength. The transmit filter includes a folded, multi-pole bandpass filter, an input port and an output port, where the output port is coupled to the diplexer transmit port to define a transmit signal path, from the tee branch point to the transmit output port, that has a length of approximately one quarter transmit wavelength. | 11-19-2009 |
20090305710 | Super Economical Broadcast System and Method - A super economical broadcast system and method are provided. The system includes a plurality of base transceiver stations that define a plurality of respective cells, each base transceiver station includes a phased-array antenna having a plurality of sectors, each sector has a plurality of vertically-arranged antenna panels, and each antenna panel has a plurality of vertically-arranged radiators disposed in at least two staggered columns. The method includes forming a horizontally and vertically shaped beam using a plurality of vertically-arranged antenna panels, in which each antenna panel has a plurality of vertically-arranged radiators disposed in at least two staggered columns, and transmitting a power distribution that has an essentially uniform field strength over a near zone, a middle zone and at least a portion of a far zone. | 12-10-2009 |
20100134374 | Phased-Array Antenna Panel for a Super Economical Broadcast System - A phased-array antenna panel for a super economical broadcast system is provided. The phased-array antenna panel system includes an antenna panel support member, a first pair of striplines and a second pair of striplines. The antenna panel support member includes a front reflector surface to support first and second columns of constantly-spaced, crossed-dipole radiators, a first pair of signal ground cavities disposed beneath the first column of crossed-dipole radiators, a second pair of signal ground cavities disposed beneath the second column of crossed-dipole radiators, and a rear surface including first and second pairs of signal distribution cable connectors. The first pair of striplines are respectively disposed within the first pair of signal ground cavities and are coupled to the first pair of signal distribution connectors and the first column of crossed-dipole radiators. The second pair of striplines are respectively disposed within the second pair of signal ground cavities and are coupled to the second pair of signal distribution connectors and the second column of crossed-dipole radiators. | 06-03-2010 |
20120220339 | Base Station for a Cellular Communication System - A base station for a cellular communication system is provided. The base station includes a transceiver and a phased-array antenna. The phased-array antenna includes a plurality of sectors, each of which includes a plurality of vertically-arranged antenna panels, each of which includes a plurality of radiators arranged in columns. The vertical spacing between the radiators in each column is a predetermined value, and the vertical spacing between the radiators in adjacent columns is one-half of the predetermined value. | 08-30-2012 |