A method and apparatus are provided for detecting objects of interest using sounds. Sounds are monitored for using a sensor array. A number of beams are formed. Each beam in the number of beams is formed for a selected direction in which the selected direction for each beam is relative to a line of
A method and apparatus are provided for detecting objects of interest using sounds. Sounds are monitored for using a sensor array. A number of beams are formed. Each beam in the number of beams is formed for a selected direction in which the selected direction for each beam is relative to a line of sight for the sensor array. A presence of a number of objects of interest is identified using the number of beams and the sounds detected by the sensor array.
대표청구항▼
1. A method for detecting objects of interest using sounds, the method comprising: monitoring for the sounds using a sensor array of a plurality of microphones arranged in a uniform hexagonal array pattern;forming a number of beams, wherein each beam in the number of beams is formed for a selected d
1. A method for detecting objects of interest using sounds, the method comprising: monitoring for the sounds using a sensor array of a plurality of microphones arranged in a uniform hexagonal array pattern;forming a number of beams, wherein each beam in the number of beams is formed for a selected direction in which the selected direction for the each beam is relative to a line of sight for the sensor array; andidentifying a presence of a number of objects of interest using the number of beams and the sounds detected by the sensor array. 2. The method of claim 1 further comprising: identifying a direction relative to the line of sight for the sensor array in which the number of objects of interest is present using the number of beams. 3. The method of claim 1, wherein the plurality of microphones being configured to generate electrical signals in response to detecting the sounds, and wherein the step of forming the number of beams comprises: identifying the selected direction for the each beam in the number of beams; andforming the each beam in the number of beams using a responsivity for each microphone in the plurality of microphones and the selected direction for the each beam, wherein the each beam in the number of beams is formed for the selected direction in which the selected direction for the each beam is relative to the line of sight for the sensor array. 4. The method of claim 3, wherein the step of forming the each beam in the number of beams using the responsivity for the each microphone in the plurality of microphones and the selected direction for the each beam, wherein the each beam in the number of beams is pointed in the selected direction in which the selected direction for the each beam is relative to the line of sight for the sensor array comprises: identifying a number of sets of time delays for the electrical signals generated by the plurality of microphones based on the selected direction for the each beam in the number of beams, wherein each set of time delays in the number of sets of time delays corresponds to a beam in the number of beams; andapplying the number of sets of time delays to the electrical signals generated by the plurality of microphones. 5. The method of claim 4 further comprising: generating a number of outputs for the number of beams. 6. The method of claim 5, wherein the step of generating the number of outputs for the number of beams comprises: summing the electrical signals after a set of time delays in the number of sets of time delays corresponding to the beam in the number of beams is applied to the electrical signals to generate an output in the number of outputs for the beam. 7. The method of claim 6, wherein the step of identifying the presence of the number of objects of interest using the number of beams and the sounds detected by the sensor array comprises: identifying the presence of the number of objects of interest using the output for the each beam in the number of beams, the sounds detected by the sensor array, and a policy. 8. The method of claim 2, wherein the direction and the selected direction comprise an elevation angle and an azimuth angle relative to the line of sight for the sensor array. 9. The method of claim 1, wherein the microphones are selected from a group comprising an omnidirectional microphone, a piezoelectric microphone, a semiconductor-type microphone, and a unidirectional microphone. 10. The method of claim 1 further comprising: changing the selected direction for the each beam in the number of beams. 11. The method of claim 2 further comprising: responsive to identifying the direction relative to the line of sight for the sensor array in which the number of objects is present using the number of beams, changing the selected direction for the each beam in at least a portion of the number of beams such that the selected direction is substantially the same as the direction relative to the line of sight for the sensor array in which the number of objects is present. 12. The method of claim 2 further comprising: tracking movement of the number of objects of interest generating the sounds using the number of beams. 13. An apparatus comprising: a sensor array configured to monitor for sounds, the sensor array including a plurality of microphones arranged in a uniform hexagonal array pattern; anda computer system associated with the sensor array and configured to form a number of beams, wherein each beam in the number of beams is formed for a selected direction in which the selected direction for the each beam is relative to a line of sight for the sensor array, andidentify a presence of a number of objects of interest using the number of beams and the sounds detected by the sensor array. 14. The apparatus of claim 13, wherein the computer system is further configured to identify a direction relative to the line of sight for the sensor array in which the number of objects of interest is present using the number of beams. 15. The apparatus of claim 13, wherein the plurality of microphones being configured to generate electrical signals in response to detecting the sounds, and wherein in being configured to form the number of beams, the computer system is configured to identify the selected direction for the each beam in the number of beams; and the plurality of microphones form the each beam in the number of beams using a responsivity for each microphone in the plurality of microphones and the selected direction for the each beam, wherein the each beam in the number of beams is formed for the selected direction in which the selected direction for the each beam is relative to the line of sight for the sensor array. 16. The apparatus of claim 15, wherein in being configured to form the each beam in the number of beams using the responsivity for the each microphone in the plurality of microphones and the selected direction for the each beam, wherein the each beam in the number of beams is pointed in the selected direction in which the selected direction for the each beam is relative to the line of sight for the sensor array, the computer system is configured to identify a number of sets of time delays for the electrical signals generated by the plurality of microphones based on the selected direction for the each beam in the number of beams, wherein each set of time delays in the number of sets of time delays corresponds to a beam in the number of beams; and apply the number of sets of time delays to the electrical signals generated by the plurality of microphones. 17. The apparatus of claim 16, wherein the computer system is further configured to generate a number of outputs for the number of beams. 18. The apparatus of claim 17, wherein in being configured to generate the number of outputs for the number of beams, the computer system is configured to sum the electrical signals after a set of time delays in the number of sets of time delays corresponding to the beam in the number of beams is applied to the electrical signals to generate an output in the number of outputs for the beam. 19. The apparatus of claim 16, wherein in being configured to identify the presence of the number of objects of interest using the number of beams and the sounds detected by the sensor array, the computer system is configured to identify the presence of the number of objects of interest using the output for the each beam in the number of beams, the sounds detected by the sensor array, and a policy. 20. The apparatus of claim 14, wherein the direction and the selected direction comprise an elevation angle and an azimuth angle relative to the line of sight for the sensor array. 21. The apparatus of claim 13, wherein the computer system is further configured to change the selected direction for the each beam in the number of beams. 22. The apparatus of claim 14, wherein the computer system is further configured to responsive to identifying the direction relative to the line of sight for the sensor array in which the number of objects is present using the number of beams, change the selected direction for the each beam in at least a portion of the number of beams such that the selected direction is substantially the same as the direction relative to the line of sight for the sensor array in which the number of objects is present.
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