초록 ▼

The perceptual sound quality of desired audio signals (e.g., human voice) captured by an electronic device (e.g., cell phone) are improved by reducing ambient noise according to an algorithm that acts upon audio signals captured from a front and rear direction. More particularly, audio signals captu

The perceptual sound quality of desired audio signals (e.g., human voice) captured by an electronic device (e.g., cell phone) are improved by reducing ambient noise according to an algorithm that acts upon audio signals captured from a front and rear direction. More particularly, audio signals captured by two directional microphones pointing in opposite directions (e.g., a front microphone which receives audio signals from a forward direction and a rear microphone which receives audio signals from a rear direction) are classified and subsequently enhanced (e.g., unwanted signals are suppressed) according to a probability of their source (e.g., front, rear, or noise) thereby providing an improved perceptual sound recording than each microphone individually. The resultant signals provide decreased noise since the contribution of the front and rear microphones are taken into consideration and the signal from the more relevant (e.g., in the direction from which sound is coming) microphone is utilized.

대표청구항 ▼

1. A method for processing audio signals, comprising: capturing a sound at a first microphone oriented in a first direction to generate a first audio signal;capturing the sound at a second microphone oriented in a second direction, different than the first direction, to generate a second audio signa

1. A method for processing audio signals, comprising: capturing a sound at a first microphone oriented in a first direction to generate a first audio signal;capturing the sound at a second microphone oriented in a second direction, different than the first direction, to generate a second audio signal;computing a first probability indicative of a likelihood that the sound was emitted toward the first microphone, comprising: comparing a first feature of the first audio signal to a first feature of the second audio signal to derive a first feature probability, anddetermining a trust level for the first feature probability to determine a contribution of the first feature probability to the first probability;computing a second probability indicative of a likelihood that the sound was emitted toward the second microphone;altering the first audio signal as a function of the first probability to generate a first enhanced audio signal; andaltering the second audio signal as a function of the second probability to generate a second enhanced audio signal, the second audio signal altered in a different manner than the first audio signal such that the second audio signal is suppressed relative to the first audio signal when there is a greater likelihood that the sound was emitted toward the first microphone than toward the second microphone. 2. The method of claim 1, comprising: filtering the first audio signal prior to altering the first audio signal. 3. The method of claim 2, the filtering comprising: filtering the first audio signal as a function of the second audio signal. 4. The method of claim 1, comprising: converting the first audio signal from a time domain to a frequency domain prior to altering the first audio signal. 5. The method of claim 1, comprising: converting the first audio signal from an analog domain to a digital domain prior to altering the first audio signal. 6. The method of claim 1, comprising: amplifying the first enhanced audio signal based at least in part on automatic gain control. 7. The method of claim 1, the capturing a sound at a first microphone and the capturing a sound at a second microphone comprising capturing the sound by a cellular telephone comprising the first microphone and the second microphone. 8. The method of claim 1, the comparing comprising at least one of: comparing an energy of the first audio signal for a frame to an energy of the second audio signal for the frame,comparing a time of arrival of the sound as represented in the first audio signal for the frame to a time of arrival of the sound as represented in the second audio signal for the frame,comparing an energy of the first audio signal for a frequency bin to an energy of the second audio signal for the frequency bin, orcomparing a time of arrival of the sound as represented in the first audio signal for the frequency bin to a time of arrival of the sound as represented in the second audio signal for the frequency bin. 9. The method of claim 1, comprising, mixing the first enhanced audio signal with the second enhanced audio signal to generate an output signal. 10. The method of claim 1, comprising, prior to altering the first audio signal: converting the first audio signal from a time domain to a frequency domain; andfiltering the first audio signal as a function of the second audio signal. 11. A system for processing audio signals, comprising: a first microphone oriented in a first direction and configured to capture a sound emitted by a source;a second microphone oriented in a second direction, different than the first direction, and configured to capture the sound;a feature extractor component configured to: compute a first probability indicative of a likelihood that the sound was emitted toward the first microphone, the computing comprising: comparing a first feature of a first audio signal generated from the sound captured by the first microphone to a first feature of a second audio signal generated from the sound captured by the second microphone to derive a first feature probability, anddetermining a trust level for the first feature probability to determine a contribution of the first feature probability to the first probability;compute a second probability indicative of a likelihood that the sound was emitted toward the second microphone;a first estimator component configured to alter the first audio signal as a function of the first probability to generate a first enhanced audio signal; anda second estimator component configured to alter the second audio signal as a function of the second probability to generate a second enhanced audio signal. 12. The system of claim 11, comprising: a first filter component configured to filter the first audio signal prior to the feature extractor component deriving the first feature probability. 13. The system of claim 12, the first filter component configured to filter the first audio signal as a function of the second audio signal. 14. The system of claim 11, comprising an analog-to-digital converter component configured to at least one of: convert the first audio signal from an analog domain to a digital domain prior to the feature extractor component deriving the first feature probability; orconvert the first audio signal from a time domain to a frequency domain prior to the feature extractor component deriving the first feature probability. 15. The system of claim 11, the feature extractor component configured to: compare a second feature of the first audio signal to a second feature of the second audio signal to derive a second feature probability; anddetermine a trust level for the second feature probability to determine a contribution of the second feature probability to the first probability. 16. The system of claim 15, the first feature of the first audio signal related to an energy of the first audio signal, the first feature of the second audio signal related to an energy of the second audio signal, the second feature of the first audio signal related to a time of arrival of the sound as represented in the first audio signal, and the second feature of the second audio signal related to a time of arrival of the sound as represented in the second audio signal. 17. A computer-readable storage device comprising computer-executable instructions, which when executed at least in part via a processing unit perform a method, comprising: capturing a sound at a first microphone oriented in a first direction to generate a first audio signal;capturing the sound at a second microphone oriented in a second direction, different than the first direction, to generate a second audio signal;computing a first probability indicative of a likelihood that the sound was emitted toward the first microphone, comprising: comparing a first feature of the first audio signal to a first feature of the second audio signal to derive a first feature probability, anddetermining a trust level for the first feature probability to determine a contribution of the first feature probability to the first probability;computing a second probability indicative of a likelihood that the sound was emitted toward the second microphone;altering the first audio signal as a function of the first probability to generate a first enhanced audio signal; andaltering the second audio signal as a function of the second probability to generate a second enhanced audio signal, the second audio signal altered in a different manner than the first audio signal. 18. The computer-readable storage device of claim 17, comprising: mixing the first enhanced audio signal with the second enhanced audio signal. 19. The computer-readable storage device of claim 17, comprising: amplifying the first enhanced audio signal based at least in part on automatic gain control. 20. The computer-readable storage device of claim 17, comprising: converting the first audio signal from a time domain to a frequency domain prior to altering the first audio signal.