An audio enhancement system for compensating for ambient noise in a listening environment, comprises an audio system that produces an electrical sound signal and generates a sound output from the electrical sound signal. A sensor (e.g., a microphone) senses a total sound signal representative of the
An audio enhancement system for compensating for ambient noise in a listening environment, comprises an audio system that produces an electrical sound signal and generates a sound output from the electrical sound signal. A sensor (e.g., a microphone) senses a total sound signal representative of the total sound level in the listening environment, including the sound output from the audio system and the ambient noise within the listening environment. A processing unit responsive to the total sound signal and the electrical sound signal extracts from the total sound signal an ambient noise signal representative of the ambient noise in the listening environment. A controller responsive to the ambient noise signal performs a linear predictive coding (LPC) analysis and generates a control signal, which is input to an equalizer to adjust the sound output of the audio system in order to compensate for the ambient noise level.
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What is claimed is: 1. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative
What is claimed is: 1. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, wherein the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; and equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level, where the equalizer means comprises a predictor filter. 2. The audio enhancement system of claim 1, where the equalizer means comprises a predictor filter. 3. The audio enhancement system of claim 1, where the predictor filter comprises a lattice ladder all pole filter. 4. The audio enhancement system of claim 1, where the extraction means comprises at least one adaptive filter. 5. The audio enhancement system of claim 4, where the at least one adaptive filter performs a least mean square (LMS) computation. 6. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; and equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level, where the control means comprises a LPC coefficient calculation unit. 7. The audio enhancement system of claim 6, where the control means performs a warped LPC analysis. 8. The audio enhancement system of claim 7, where the control means comprises a warped LPC coefficient calculation unit. 9. The audio enhancement system of claim 6, where the control means performs a gradient adaptive lattice algorithm. 10. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level; and a psycho-acoustic filter that is responsive to the ambient noise signal and generates a weighted ambient noise signal which is supplied to the control means. 11. The audio enhancement system of claim 10, where the psycho-acoustic filter comprises a A-weighting filter. 12. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level; and voice pass means responsive to the sound signal, for extracting a voice signal which is subtracted from the electrical sound signal supplied to the extractor means. 13. The audio enhancement system of claim 12, where the voice pass means comprises a beamformer unit. 14. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level; and voice stop means responsive to the total sound signal, for suppressing a voice signal in the total sound signal supplied to the extractor means. 15. The audio enhancement system of claim 14, where the voice stop means comprises an inverse beamformer unit. 16. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; and equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level; where the ambient noise signal is filtered by spectral voice suppressing means for suppressing a voice signal in the ambient noise signal. 17. The audio enhancement system of claim 16, where the spectral voice suppressing means comprises: time-to-frequency transformation means responsive to the ambient noise signal for generating spectral noise signals therefrom; means for calculating mean spectral noise signals from the spectral noise signals; a voice activity detector that is responsive to the mean spectral noise signals, and suppresses a voice signal in the mean spectral noise signals; and a frequency-to-time transformation means responsive to the mean spectral noise signals having the voice signal suppressed for transforming the mean spectral noise signals having the voice signal suppressed into an ambient noise signal having the voice signal suppressed. 18. The audio enhancement system of claim 17, where the voice activity detector comprises a first mean value calculation unit for calculating the long-term steady state of the ambient noise signal and a second mean value calculation unit that calculates the short-term steady state of the voice signal, and a comparator unit for comparing the long-term steady state of the ambient noise signal and the short-term steady state of the voice signal. 19. An audio enhancement system for compensating for ambient noise in a listening environment, comprising: audio means for producing an electrical sound signal and generating a sound output from the electrical sound signal; sensor means for obtaining a sound signal representative of the total sound level in the listening environment, where the sound level comprises the sound output from the audio means and the ambient noise within the listening environment; extraction means responsive to the sound signal and to the electrical sound signal for extracting an ambient noise signal representative of the ambient noise in the environment from the sound signal; control means responsive to the ambient noise signal for performing a linear predictive coding (LPC) analysis and generating a control signal; and equalizer means responsive to the control signal for adjusting the sound output of the audio means to compensate for the ambient noise level; where the audio means comprises at least two signal paths active in different frequency ranges; and the extraction means comprises a plurality of parallel signal paths active in frequency ranges corresponding to the signal paths of the audio means. 20. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; and adjusting the output from the audio sound signal to compensate for the ambient noise level, where the step of adjusting the output from the audio sound signal comprises prediction filtering. 21. The method of claim 20, where the step of adjusting the output from the audio sound signal comprises warped prediction filtering. 22. The method of claim 20, where the prediction filtering step comprises lattice ladder all pole filtering. 23. The method of claim 20, where filtering the audio sound signal comprises adaptively filtering the audio sound signal. 24. The method of claim 23, where adaptively filtering the audio signal comprises performing a least mean square (LMS) computation. 25. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; and adjusting the output from the audio sound signal to compensate for the ambient noise level; where the linear predictive coding (LPC) analysis comprises performing a LPC coefficient calculation. 26. The method of claim 20, where the linear predictive coding (LPC) analysis comprises performing a warped LPC analysis. 27. The method of claim 26, where the warped LPC analysis comprises performing a warped LPC coefficient calculation. 28. The method of claim 25, where the linear predictive coding (LPC) analysis comprises performing a gradient adaptive lattice algorithm. 29. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; adjusting the output from the audio sound signal to compensate for the ambient noise level; and where in a psycho-acoustic filtering step a weighted ambient noise signal is generated from the ambient noise signal. 30. The method of claim 29, where the psycho-acoustic filtering comprises performing a A-weighting filtering. 31. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; adjusting the output from the audio sound signal to compensate for the ambient noise level; and where in a voice pass step a voice signal is extracted from the total sound signal, and the voice signal is subtracted from the electrical sound signal. 32. The method of claim 31, where the voice pass step comprises performing a beamforming step. 33. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; adjusting the output from the audio sound signal to compensate for the ambient noise level; and where a voice stop step suppresses a voice signal in the total sound signal. 34. The method of claim 33, where the voice stop step comprises performing an inverse beamforming step. 35. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; and adjusting the output from the audio sound signal to compensate for the ambient noise level; where the ambient noise signal is filtered in a spectral voice suppressing step for suppressing a voice signal in the ambient noise signal. 36. The method of claim 35, where the voice suppressing step comprises: a time-to-frequency transforming the ambient noise signal to generate spectral noise signals; calculating mean spectral noise signals from the spectral noise signals; suppressing a voice signal in the mean spectral noise signals; and a frequency-to-time transforming the mean spectral noise signals having the voice signal suppressed into an ambient noise signal. 37. The method of claim 36, where the voice activity detecting step comprises calculating the long term steady state of the ambient noise signal and calculating the short-term steady state of the voice signal, and comparing the long-term steady state of the ambient noise signal and the short-term steady state of the voice signal. 38. A method for enhancing the sound signal produced by an audio system in a listening environment by compensating for ambient sound in the listening environment, comprising the steps of: producing an audio sound signal; measuring the total sound level in the listening environment and generating a signal representative thereof; filtering the audio sound signal and the total sound signal, to extract a signal representing the ambient sound level within the listening environment; comparing the audio sound signal with the signal representing the ambient sound level; performing a linear predictive coding (LPC) analysis to generate a control signal; and adjusting the output from the audio sound signal to compensate for the ambient noise level; where the step of producing an audio sound signal comprises: splitting the audio signal into at least two signals in different frequency ranges; and extracting signals in frequency ranges corresponding to the frequency ranges of the splitting step from the total sound signal.
Doi Kazuhiro (Yokohama JPX) Kinoshita Akio (Fujisawa JPX) Muraoka Kenichiro (Yokohama JPX), Apparatus for reducing noise in space applicable to vehicle compartment.
Gilles Miet FR, Audio processing device, receiver and filtering method for filtering a useful signal and restoring it in the presence of ambient noise.
Takagi Kazunori (Saitama JPX) Sato Shinichi (Saitama JPX) Ito Masahiko (Saitama JPX) Yamamoto Hideo (Saitama JPX), Automatic sound level compensator for a sound reproduction device mounted in a vehicle.
Clough Patrick V. F. (39 Gatton Road Tooting ; London ; SW17 OEX GB2) Lobo Natividade A. (53 Flowers Walk Ealing ; London ; W.5. GB2), Communications systems.
Smith Shawn W. (Santa Barbara CA) Cromack Mark (Santa Ynez CA), Digital automatic gain control with lookahead, adaptive noise floor sensing, and decay boost initialization.
Brewer James E. (Canton MI) Abowd Peter S. (Farmington Hills MI) Raffaeli Frank W. (Parma OH), Digitally controlled audio amplifier with voltage limiting.
Benning Roger David ; Fischer Elliot Andrew ; Greene Patricia Lee ; Sanford Charles ; Schneider Robert Edward, Electronic cancellation of ambient noise in telephone headset.
Jubien, Christopher Michael; Lakoumentas, Constantine; Roden, Brian John; Shpak, Dale John; Sondermeyer, Jeffrey William, Method and apparatus for automatic volume control in an audio system.
Miller Thomas E. (213 S. Walnut Ave. Arlington Heights IL 60005) Kantor Kenneth L. (6501 Valley View Dr. Oakland CA 94611) Barish Jeffrey (61 Pine Tree La. Boulder CO 80304) Wise Duane K. (1850 Folso, Method and apparatus for dynamic sound optimization.
Miller Thomas E. (Arlington Heights IL) Kantor Kenneth L. (Oakland CA) Barish Jeffrey (Boulder CO) Wise Duane K. (Boulder CO), Method and apparatus for dynamic sound optimization.
Pfaff Donald P. (Mount Clemens MI) Kapsokavathis Nick S. (Rochester MI) Parks Natalie A. (Utica MI), Method for actively attenuating engine generated noise.
Op de Beek Franciscus J. (Eindhoven NLX) Kemna Johannes W. (Eindhoven NLX), Noise-dependent volume control having a reduced sensitivity to speech signals.
Ross Colin F. (Stapleford GBX) Eatwell Graham P. (Caldecote GB2 4), Signal processing system for sensing a periodic signal in the presence of another interfering signal.
Zinser ; Jr. Richard L. (Schenectady NY) Silverstein Seth D. (Schenectady NY) Koch Steven R. (Schenectady NY), Two-input crosstalk-resistant adaptive noise canceller.
Master, Paul L.; Smith, Stephen J.; Watson, John, Apparatus, method, system and executable module for configuration and operation of adaptive integrated circuitry having fixed, application specific computational elements.
Eisenberg, Gunnar; Elting, Frank, Method and arrangement for processing audio data, and a corresponding corresponding computer-readable storage medium.
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