MULTIPLE ACOUSTIC THREAT ASSESSMENT SYSTEM
First Claim
1. An acoustic monitoring system for locating an acoustic event in an environment surrounding the acoustic monitoring system, the acoustic monitoring system comprising:
- (a) an acoustic sensor comprising;
i. a pair of microphones separated by a predetermined distance, the microphones facing each other on a microphone axis MA, the microphone pair generating a signal corresponding to an acoustic intensity and a sound spectra corresponding to the acoustic event arriving at each microphone relative to the microphone axis, the sound spectra received at each microphone as an individual spectra in front of and behind the microphone pair, at a given time and global location;
ii. a microprocessor in communication with the microphone pair;
iii. an absolute clock in communication with the microprocessor and providing a synchronized time to the microprocessor;
iv. a position sensor for detecting an absolute global position of the microphone pair and an absolute axis orientation of the microphone pair; and
(b) a command unit in communication with the microprocessor, wherein the acoustic event received at the microphone pair results in the acoustic sensor transmitting to the command unit a time of arrival, a microphone pair absolute global position, a microphone pair axis orientation, and a signal corresponding to an angle of incidence of the acoustic event relative to the microphone axis MA.
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Accused Products
Abstract
A system is provided for locating and identifying an acoustic event. An acoustic sensor having a pair of concentric opposing microphones at a fixed distance on a microphone axis is used to measure an acoustic intensity, from which a vector incorporating the acoustic event is identified. A second acoustic sensor or movement of the first acoustic sensor is used to provide a second vector incorporating the acoustic event. Combination of the first and the second vector locates the acoustic event in space. A command unit in communication with the acoustic sensors can be used for combining the vectors as well as comparing a signal spectra of the acoustic event to stored identified spectra to provide an identification of acoustic event.
93 Citations
36 Claims
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1. An acoustic monitoring system for locating an acoustic event in an environment surrounding the acoustic monitoring system, the acoustic monitoring system comprising:
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(a) an acoustic sensor comprising; i. a pair of microphones separated by a predetermined distance, the microphones facing each other on a microphone axis MA, the microphone pair generating a signal corresponding to an acoustic intensity and a sound spectra corresponding to the acoustic event arriving at each microphone relative to the microphone axis, the sound spectra received at each microphone as an individual spectra in front of and behind the microphone pair, at a given time and global location; ii. a microprocessor in communication with the microphone pair; iii. an absolute clock in communication with the microprocessor and providing a synchronized time to the microprocessor; iv. a position sensor for detecting an absolute global position of the microphone pair and an absolute axis orientation of the microphone pair; and (b) a command unit in communication with the microprocessor, wherein the acoustic event received at the microphone pair results in the acoustic sensor transmitting to the command unit a time of arrival, a microphone pair absolute global position, a microphone pair axis orientation, and a signal corresponding to an angle of incidence of the acoustic event relative to the microphone axis MA. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17)
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18. A method for locating and identifying an acoustic source producing an acoustic signal, the method comprising:
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(a) spacing a first acoustic sensor and a second acoustic sensor from each other and the acoustic event, each of the first and the second acoustic sensor comprising; i. a microprocessor; ii. a microphone pair connected to the microprocessor, the microphone pair located in an opposing orientation along a microphone axis in the acoustic sensor, the microphone pair presenting to the microprocessor a sound spectra corresponding to the acoustic signal, the microprocessor determining an angle of incidence to the acoustic source and identifying at least one frequency focal point within the sound spectra; iii. an absolute clock in communication with the microprocessor, the absolute clock providing a synchronized time to the microprocessor; iv. a transceiver in communication with the microprocessor for receiving relative clock signals, such that the microprocessor can obtain synchronized time from the relative time clock to match similar sound frequencies received simultaneously at the first and second acoustic sensor; v. a network interface in communication with the microprocessor, the network interface selected to communicate over a network; (b) receiving at the first acoustic sensor the acoustic signal corresponding to the acoustic source; (c) creating at the first acoustic sensor a signal corresponding to an incidence angle between the first acoustic sensor and the acoustic source, with respect to an absolute time and axis position of the first acoustic sensor; (d) transmitting from the first acoustic sensor to a command unit data corresponding to the incidence angle; and (e) transmitting from the command unit to the second acoustic sensor instructions to detect the acoustic source and in response to the acoustic signal, provide an incidence angle between the acoustic source and the second acoustic sensor with respect to the absolute axis of the second acoustic sensor and a global position of the second acoustic sensor. - View Dependent Claims (19, 20, 21, 22, 23)
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24. A system for monitoring an acoustic signal from an acoustic event, the system comprising:
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(a) a movable first acoustic sensor comprising; i. a microphone pair fixed in an opposing orientation along a microphone axis, the microphone pair producing a signal indicative of an incidence angle with respect to an absolute point in time axis position of the first acoustic sensor at a given absolute global position, the microphone pair producing an individual sound spectra from the front and rear of the microphone pair; ii. a microprocessor in communication with the microphone pair, the microprocessor determining an incidence angle with respect to an absolute axis position for each of a plurality of frequency focal points at the given absolute global position; iii. an absolute clock in communication with the microprocessor, the absolute clock providing a synchronized time to the microprocessor to match sequentially received sound frequencies at different absolute global positions of the acoustic sensor; and (b) a command unit in communication with the microprocessor, the command unit configured to receive the incidence angle from the first acoustic sensor. - View Dependent Claims (25, 26, 27)
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28. A method for locating the source of an acoustic event comprising the steps of:
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(a) disposing two acoustic sensors at spaced locations, each acoustic sensor comprising; i. a microphone pair disposed in an opposing orientation a fixed distance apart along a microphone axis; (b) transmitting data from each acoustic sensor to a command unit, the transmitted data including a time of arrival of the acoustic event corresponding to one of a synchronized clock and a relative clock, an incidence angle and corresponding frequency for the time of arrival; and (c) determining at the command unit the location of the acoustic event in response to transmitted data.
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29. A method for determining spatial uncertainty from the presence of a sound transmission path modification of acoustic signals from an acoustic event, the method comprising the steps of:
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(a) receiving the acoustic signals at a first and a second acoustic sensor, each acoustic sensor including a pair of opposing microphones in a fixed spacing on a microphone axis; (b) reducing ambient acoustic interference from the acoustic signals; (c) creating a digital representation of the acoustic signals, each digital representation including one of a frequency peak and a plurality of frequency peaks; (d) transmitting the digital representation and a corresponding time of arrival to a command unit; and (e) associating the time of arrival from the first and the second acoustic sensor, and in response to a non correlation of the time of arrival between the one of the individual frequency peak and the plurality of frequency peaks with the digital representation having the shortest time of arrival, assessing of one of (i) the acoustic signals arrived at the second acoustic sensor by a non-direct path and (ii) a time of arrival representing an error greater than a predetermined level in a calculated triangulation of the acoustic signals.
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30. A method for identifying a detected acoustic event, the method comprising the steps of:
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(a) receiving acoustic signals from the acoustic event at an acoustic sensor; (b) reducing ambient acoustic event interference from the received acoustic signals and converting the received acoustic signals to a digital representation; and (c) correlating the digital representation to a stored spectral distribution to identify the acoustic event. - View Dependent Claims (31)
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32. A method of monitoring a noise source, the method comprising:
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(a) measuring at a pair of spaced locations an incidence angle of the noise source, each location including an acoustic sensor having a pair of concentric opposing microphones at a fixed distance on a microphone axis; and (b) determining a position of the noise source corresponding to the measured incidence angles. - View Dependent Claims (33, 34)
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35. A method of monitoring a noise source, the method comprising:
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(a) measuring at a pair of spaced locations an acoustic intensity of a sound, each location including an acoustic sensor having a pair of concentric opposing microphones at a fixed distance on a microphone axis; and (b) determining a position of the noise source corresponding to the measured acoustic intensities.
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36. An apparatus for monitoring a noise source, the apparatus comprising:
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(a) a first and a second acoustic sensor, each acoustic sensor including a pair of concentric opposing microphones at a fixed distance on a microphone axis; and (b) a command unit in communication with the first and the second acoustic sensor, the command unit selected to determine a location of the noise source relative to at least one of the first and the second acoustic sensors.
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Specification