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A system applicable to acoustic, seismic, electromagnetic, hydrodynamic, and shock waves utilizing a map between signal time series and signal vectors defining the mathematical wave field model characterizing the signal's wave field. This map is developed from wave models relating field values to th

A system applicable to acoustic, seismic, electromagnetic, hydrodynamic, and shock waves utilizing a map between signal time series and signal vectors defining the mathematical wave field model characterizing the signal's wave field. This map is developed from wave models relating field values to those on surfaces and corresponding uniqueness theorems. The system should allow for improved resolving power in bearing and elevation for discrimination of sources; detection and direction finding for signals below the average background level; detection based upon resolving power and signal vector characteristics rather than signal to noise ratio; reconstruction of signals of resolved sources for their transmitted information content; and multiple modes of operation. Adaptive incorporation of known undesired signals into the noise background and/or treatment of asymmetric background noise fields is permitted through use of a noise metric-based map yielding signal direction in the presence of diffraction effects.

대표청구항 ▼

What is claimed is: 1. An apparatus for determining selected information from fluctuations of a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the apparatus comprising: at least one antenna having a neighborhoo

What is claimed is: 1. An apparatus for determining selected information from fluctuations of a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the apparatus comprising: at least one antenna having a neighborhood; said antenna being capable of generating output signals representative of the physical wave field in said neighborhood; said output signals being sufficient to define a signal vector characterizing the physical wave field in said neighborhood; means for converting said output signals to said signal vector; and means for determining the selected information from said signal vector. 2. A method of determining selected information from signals contributing to a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: providing an antenna having a neighborhood; creating a signal vector representative of the physical wave field in said neighborhood; creating a mathematical model of the physical wave field in said neighborhood from said signal vector; and determining the selected information from said mathematical model. 3. A method for determining within a background environment the presence of a source of a signal contributing to a physical wave field, the properties of the physical wave field being detectable over tree spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing a mathematical model of the physical wave field; providing a library of library signal vectors characterizing physical wave fields with known properties; determining background signal vectors characterizing the background environment; and determining the presence of the source using at least one of said background signal vectors, at least one of said library signal vectors, and said physical wave field signal vector. 4. A method of determining the directions of a multiple sources contributing to a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing a mathematical model of the physical wave field; providing a library of library signal vectors having library elements whose properties represent potential physical wave fields; using at least one of said library signal vectors and said physical wave field signal vector to determine probable detections; resolving at least one of the multiple sources using said probable detections; associating at least one of said library signal vectors with each of said resolved sources; and determining the direction of each said resolved source using said at least one library signal vector associated with each said resolved source. 5. A method of determining selected information from a physical wave field containing background interference from at least one source contributing to a physical wave field, the wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing a mathematical model of the physical wave field; providing a library of library signal vectors characterizing physical wave fields with known properties; determining background signal vectors characterizing the background interference; and determining the selected information using at least one of said background signal vectors, at least one of said library signal vectors, and said physical wave field signal vector. 6. A method of determining the direction of at least one source contributing to the physical wave field containing background interference from a source contributing to a physical wave field, the wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing a mathematical model of the physical wave field; providing a library of library signal vectors characterizing physical wave fields with known properties; determining background signal vectors characterizing the background interference; and determining the direction of the source using at least one of said background signal vectors, at least one of said library signal vectors, and said physical wave field signal vector. 7. The method as defined in claim 6, further comprising: providing a directional map using said library signal vectors and said background signal vectors; and using said map in said determining of the direction of the source. 8. A method of constructing the signals of resolvable sources contributing to a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing a mathematical model of the physical wave field; providing a library of library signal vectors having library elements representing physical wave fields with known properties including that of direction and frequency; using said library and said physical wave field signal vector to assign directions to said resolvable sources and weights to said library elements associated with at least one of said resolvable sources; and constructing the signal of said at least one resolvable source using said library elements and said weights. 9. The method as defined in claim 8, further comprising: summing Fourier transforms of said library elements and producing a time series for said at least one resolvable source; and manipulating said time series to obtain selected information. 10. A method of calibrating a detection, tracking, and reconstruction system for signals contained in a physical wave field, the method comprising: providing an antenna having multiple transducer defined channels; providing a library of library signal vectors having library elements representing physical wave fields with known properties including that of direction and frequency; providing signal conditioners associated with said channels; providing reversible transducers that each provide a signal output and a calibrating signal input; driving said reversible transducers with a common electrical signal input, determining the relative amplitude and phase of said signal output of each of said channels; and modifying said signal vector library elements to compensate for amplitude and phase difference variations between said channels in said signal conditioners and said outputs of said transducers. 11. An antenna for use in an apparatus for determining selected information from fluctuations of a physical wave field, the antenna having a neighborhood associated therewith and a structure portion, the antenna comprising: transducers that convert the fluctuations of the physical wave field into electrical signals representative of the fluctuations at predetermined positions; means for sampling said transducers according to Nyquist criteria; and said transducers being configured to allow sampling of said electrical signals sufficient to construct a mathematical model of the physical wave field in said neighborhood. 12. A method for predicting the signal output of a transducer positioned in the neighborhood of an antenna, wherein the antenna includes transducers sampled and positioned for compliance with temporal and spatial Nyquist criteria applied to a sampled physical wave field, the method comprising: characterizing the physical wave field by a physical wave field signal vector representing the physical wave field; providing a library of library signal vectors having library elements representing physical wave fields with known properties; constructing a time series at the transducer positions using said physical wave, field signal vector and at least one library signal vector; generating a mathematical model for said time series solution in the neighborhood of the antenna; and using said mathematical model to determine the signal to be detected by a transducer placed at a location in the neighborhood of the antenna. 13. A method of determining selected information from signals contained in a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field modeling vector specifying a mathematical model of the physical wave field; and determining the selected information from said physical wave field modeling vector. 14. A method of determining the presence of a signal belonging to a source contributing to a physical wave field, properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: characterizing the physical wave field by a physical wave field modeling vector specifying a mathematical model of the physical wave field; and determining the presence of a source using said physical wave field a modeling vector. 15. An apparatus for determining selected information from temporal fluctuations of a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the apparatus comprising: at least one antenna capable of generating output signals representative of the physical wave field; said output signals being sufficient to define a physical wave field modeling vector characterizing the physical wave field; means for converting said output signals into at least one physical wave field modeling vector; and means for determining the selected information from said at least one physical wave field modeling vector. 16. A method of determining selected information from signals contained in a physical wave field, the properties of the physical wave field being detectable over three spatial dimensions and a temporal dimension, the method comprising: creating a physical wave field modeling vector representative of the physical wave field; creating a mathematical model of the physical wave field from said physical wave field modeling vector; and determining the selected information from said mathematical model. 17. A method for constructing an antenna structure for use in determining selected information from a physical wave field, the antenna structure having transducers, and the antenna structure having a neighborhood associated therewith, the method comprising: providing a mathematical model sufficient to substantially account for the effects of the antenna structure on propagation of the physical wave field in the neighborhood of the antenna structure, said model being sufficient to indicate placement of transducers on the antenna structure in compliance with Nyquist sampling criteria for the physical wave field in the neighborhood of the antenna structure; and using said model to determine placement of the transducers on the antenna structure. 18. A method of providing signal vectors representing physical wave fields in the neighborhood of an antenna structure, the method comprising: providing a mathematical model sufficient to substantially account for the effects of the antenna structure on propagation of the physical wave fields in the neighborhood of the antenna structure, said model being sufficient to indicate placement of transducers on the antenna structure in compliance with Nyquist sampling criteria for the physical wave fields in the neighborhood of the antenna structure; and using said model to obtain sufficient information to construct signal vectors representing the physical wave fields in the neighborhood of the antenna structure.