Dual path noise detection and isolation for acoustic ambulatory respiration monitoring system
First Claim
1. A method for processing an acoustic signal, comprising the steps of:
- receiving an acoustic signal recording body sounds on a respiration monitoring system;
detecting first noisy portions of the signal based at least in part on cumulative energies in the signal with the system;
detecting second noisy portions of the signal based at least part on peak energies in the signal with the system;
isolating third noisy portions of the signal based at least in part on the first noisy portions and the second noisy portions with the system, including designating, as third noisy portions, intersections between first noisy portions that envelop second noisy portions and second noisy portions that are enveloped by first noisy portions;
calculating a respiration parameter estimate using the signal without resort to the third noisy portions with the system; and
outputting information based at least in part on the respiration parameter estimate on the system.
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Accused Products
Abstract
Dual path noise detection and isolation for an acoustic respiration monitoring system detects noise in an acoustic signal recording lung sounds using two discrete noise detection techniques. A first technique detects portions of the signal that exhibit long-term, moderate amplitude noise by analyzing cumulative energy in the signal. A second technique detects portions of the signal that exhibit short-term, high amplitude noise by analyzing peak energy in the signal. Noisy portions of the signal are isolated using the combined results of the dual path detection. A respiration parameter is estimated using the signal without resort to the noisy portions and information based at least in part on the respiration parameter is outputted.
18 Citations
20 Claims
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1. A method for processing an acoustic signal, comprising the steps of:
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receiving an acoustic signal recording body sounds on a respiration monitoring system; detecting first noisy portions of the signal based at least in part on cumulative energies in the signal with the system; detecting second noisy portions of the signal based at least part on peak energies in the signal with the system; isolating third noisy portions of the signal based at least in part on the first noisy portions and the second noisy portions with the system, including designating, as third noisy portions, intersections between first noisy portions that envelop second noisy portions and second noisy portions that are enveloped by first noisy portions; calculating a respiration parameter estimate using the signal without resort to the third noisy portions with the system; and outputting information based at least in part on the respiration parameter estimate on the system. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A respiration monitoring system, comprising:
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a sound capture system adapted to generate an acoustic signal recording body sounds; an acoustic signal processing system adapted to receive from the sound capture system the signal, detect first noisy portions of the signal based at least in part on cumulative energies in the signal, detect second noisy portions of the signal based at least part on peak energies in the signal, isolate third noisy portions of the signal based at least in part on the first noisy portions and the second noisy portions, including designating, as third noisy portions, intersections between first noisy portions that envelop second noisy portions and second noisy portions that are enveloped by first noisy portions, and calculate a respiration parameter estimate using the signal without resort to the third noisy portions; and a respiration data output system adapted to output information based at least in part on the respiration parameter estimate. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18)
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19. A method for processing an acoustic signal, comprising the steps of:
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receiving an acoustic signal recording body sounds on a respiration monitoring system; detecting first noisy portions of the signal based at least in part on cumulative energies in the signal with the system; detecting second noisy portions of the signal based at least part on peak energies in the signal with the system; isolating third noisy portions of the signal based at least in part on the first noisy portions and the second noisy portions with the system, including designating, as third noisy portions, unions of first noisy portions that do not envelop second noisy portions and second noisy portions that are not enveloped by first noisy portions; calculating a respiration parameter estimate using the signal without resort to the third noisy portions with the system; and outputting information based at least in part on the respiration parameter estimate on the system.
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20. A respiration monitoring system, comprising:
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a sound capture system adapted to generate an acoustic signal recording body sounds; an acoustic signal processing system adapted to receive from the sound capture system the signal, detect first noisy portions of the signal based at least in part on cumulative energies in the signal, detect second noisy portions of the signal based at least part on peak energies in the signal, isolate third noisy portions of the signal based at least in part on the first noisy portions and the second noisy portions, including designating, as third noisy portions, unions of first noisy portions that do not envelop second noisy portions and second noisy portions that are not enveloped by first noisy portions, and calculate a respiration parameter estimate using the signal without resort to the third noisy portions; and a respiration data output system adapted to output information based at least in part on the respiration parameter estimate.
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Specification