SELF CALIBRATING MULTI-ELEMENT DIPOLE MICROPHONE

US 20120269356A1
Filed: 04/20/2011
Published: 10/25/2012
Est. Priority Date: 04/20/2011
Status: Active Grant

First Claim

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1. A microphone comprising:

a first acoustic sensor having a first output;

a second acoustic sensor separated by a distance from the first acoustic sensor and having a second output;

a sound source acoustically coupled to the first and second acoustic sensors, the sound source including an input;

a processor electrically coupled to the input, the first output, and the second output, the processor being configured to activate the sound source to produce an acoustic calibration signal, and further configured to receive a first output and a second output from the respective acoustic sensors in response to the acoustic calibration signal; and

the processor configured for determining one or more correction factors based on the received first and second outputs.

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Abstract

A self calibrating dipole microphone formed from two omni-directional acoustic sensors. The microphone includes a sound source acoustically coupled to the acoustic sensors and a processor. The sound source is excited with a test signal, exposing the acoustic sensors to acoustic calibration signals. The responses of the acoustic sensors to the calibration signals are compared by the processor, and one or more correction factors determined. Digital filter coefficients are calculated based on the one or more correction factors, and applied to the output signals of the acoustic sensors to compensate for differences in the sensitivities of the acoustic sensors. The filtered signals provide acoustic sensor outputs having matching responses, which are subtractively combined to form the dipole microphone output.

134 Citations

24 Claims

1. A microphone comprising:
- a first acoustic sensor having a first output;
  
  a second acoustic sensor separated by a distance from the first acoustic sensor and having a second output;
  
  a sound source acoustically coupled to the first and second acoustic sensors, the sound source including an input;
  
  a processor electrically coupled to the input, the first output, and the second output, the processor being configured to activate the sound source to produce an acoustic calibration signal, and further configured to receive a first output and a second output from the respective acoustic sensors in response to the acoustic calibration signal; and
  
  the processor configured for determining one or more correction factors based on the received first and second outputs.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
- - 2. The microphone of claim 1, further comprising:
    - a first channel having a proximal end interfacing with the sound source, and a distal end terminating near the first acoustic sensor, the first channel configured to convey a portion of the acoustic calibration signal from the sound source to the first acoustic sensor; and
      
      a second channel having a proximal end interfacing with the sound source, and a distal end terminating near the second acoustic sensor, the second channel configured to convey a portion of the acoustic calibration signal from the sound source to the second acoustic sensor.
  - 3. The microphone of claim 2, wherein the first and second channels are configured so that the conveyed portions of the acoustic calibration signal have substantially the same phase and amplitude at the first and second acoustic sensors.
  - 4. The microphone of claim 2, further comprising:
    - a housing including a first acoustic opening configured to admit sound to the first acoustic sensor, and a second acoustic opening configured to admit sound to the second acoustic sensor;
      
      the first channel further configured so that the distal end terminates at a point between the first acoustic opening and the first acoustic sensor; and
      
      the second channel further configured so that the distal end terminates at a point between the second acoustic opening and the second acoustic sensor.
  - 5. The microphone of claim 2, wherein the proximal end of the first channel and the proximal end of the second channel terminate at the same point.
  - 6. The microphone of claim 1, wherein the first and second acoustic sensors are equidistant from the sound source.
  - 7. The microphone of claim 1, wherein the sound source is coupled to a boom attaching the first and second acoustic sensors to a headset.
  - 8. The dipole microphone of claim 1, the processor further configured to filter the first and second acoustic sensor outputs and subtractively combine the filtered outputs to generate a composite output signal having the characteristics of a dipole microphone.
  - 9. The dipole microphone of claim 8, the processor further configured to determine filter coefficients based on the one more correction factors, wherein the filter coefficients are used to filter the first and second acoustic sensor outputs.

10. A headset comprising:
- a first acoustic sensor having a first output;
  
  a second acoustic sensor separated by a distance from the first acoustic sensor and having a second output;
  
  a boom configured to hold the first acoustic sensor and the second acoustic sensor along an axis;
  
  a sound source acoustically coupled to the first and second acoustic sensors, the sound source including an input; and
  
  a processor electrically coupled to the input, the first output, and the second output, the processor being configured to activate the sound source to produce an acoustic calibration signal, and further configured to receive a first output and a second output from the respective acoustic sensors in response to the acoustic calibration signal; and
  
  the processor configured for determining one or more correction factors based on the received first and second outputs.
- View Dependent Claims (11, 12, 13, 14)
- - 11. The headset of claim 10, wherein the sound source is integrated with the boom.
  - 12. The headset of claim 11, the boom further including:
    - a first acoustic opening configured to admit sound to the first acoustic sensor;
      
      a second acoustic opening configured to admit sound to the second acoustic sensor;
      
      a first channel having a proximal end interfacing with the sound source, and a distal end terminating at a point between the first acoustic opening and the first acoustic sensor, so that a portion of the acoustic calibration signal is conveyed from the sound source to the first acoustic sensor; and
      
      a second channel having a proximal end interfacing with the sound source, and a distal end terminating at a point between the second acoustic opening and the second acoustic sensor, so that a portion of the acoustic calibration signal is conveyed from the sound source to the second acoustic sensor.
  - 13. The headset of claim 10, the processor further configured to filter the first and second acoustic sensor outputs and subtractively combine the filtered outputs to generate a composite output signal having the characteristics of a dipole microphone.
  - 14. The headset of claim 13, the processor further configured to determine filter coefficients based on the one more correction factors, wherein the filter coefficients are used to filter the first and second acoustic sensor outputs.

15. A method of matching a pair of acoustic sensors forming a dipole microphone, the method comprising:
- generating an acoustic calibration signal;
  
  measuring a response of a first acoustic sensor to the acoustic calibration signal;
  
  measuring a response of a second acoustic sensor to the acoustic calibration signal;
  
  determining one or more correction factors based on the responses of the first and second acoustic sensors to the acoustic calibration signal; and
  
  applying the one or more correction factors to signals produced by the first and second sensors so that the responses of the first and second sensors are matched.
- View Dependent Claims (16, 17, 18, 19, 20, 21, 22, 23, 24)
- - 16. The method of claim 15, wherein the acoustic calibration signal includes a plurality of frequencies.
  - 17. The method of claim 16, wherein only one frequency of the plurality of frequencies is provided at a time.
  - 18. The method of claim 15, the step of applying the one or more correction factors to the output of the first and second sensors including:
    - calculating one or more digital filter coefficients based on the one or more correction factors; and
      
      filtering the signals produced by the first and second acoustic sensors using the one or more digital filter coefficients.
  - 19. The method of claim 15, wherein the acoustic calibration signal is produced by a sound source located in the dipole microphone.
  - 20. The method of claim 15, further comprising:
    - inverting the phase of one of either the first acoustic sensor output or the second acoustic sensor output;
      
      summing the inverted acoustic sensor output with the non-inverted acoustic sensor output to generate a summed output;
      
      comparing the summed output level to a threshold;
      
      in response to the amplitude of the sum being at or below the threshold, making a determination that the acoustic sensors are calibrated; and
      
      in response to the amplitude of the sum being above the threshold, making a determination that the acoustic sensors are not calibrated.
  - 21. The method of claim 20, further comprising generating an error signal if a determination is made that the acoustic sensors are not calibrated.
  - 22. The method of claim 21, further comprising communicating the error signal to a central computer system.
  - 23. The method of claim 21, further comprising activating an indicator on the microphone when the error signal is generated.
  - 24. The method of claim 21, further comprising alerting a user of the microphone that the acoustic sensors are not calibrated.

Specification

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Current Assignee
Vocollect, Inc. (Honeywell International Inc.)
Original Assignee
Vocollect, Inc. (Honeywell International Inc.)
Inventors
Sheerin, John, Shope, Matthew, Sharbaugh, Rich

Granted Patent

US 8,824,692 B2
Time in Patent Office

Days
Field of Search
US Class Current

381/58
CPC Class Codes

H04R 1/1083   Reduction of ambient noise ...

H04R 29/004   for microphones H04R29/007 ...

H04R 3/005   for combining the signals o...

SELF CALIBRATING MULTI-ELEMENT DIPOLE MICROPHONE

First Claim

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Abstract

134 Citations

24 Claims

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SELF CALIBRATING MULTI-ELEMENT DIPOLE MICROPHONE

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

134 Citations

24 Claims

Specification

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Solutions

Use Cases

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