Method and device for separating of sound signals

US 20070003074A1
Filed: 01/31/2005
Published: 01/04/2007
Est. Priority Date: 02/06/2004
Status: Active Grant

First Claim

Patent Images

1-9. -9. (canceled)

View all claims

2 Assignments

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

In a method of separating acoustic signals from a plurality of sound sources comprising the following steps:

- disposing two microphones (MIK1, MIK2) at a predefined distance (d) from one another;
- picking up the acoustic signals with both microphones (MIK1, MIK2) and generating associated microphone signals (m1, m2); and
- separating the acoustic signal of one of the sound sources (S1) from the acoustic signals of the other sound sources (S2) on the basis of the microphone output signals (m1, m2), the proposed separation step comprises the following steps:
- applying a Fourier transform to the microphone output signals in order to determine their frequency spectra (M1, M2);
- determining the phase difference (φ) between the two microphone output signals (m1, m2) for every frequency component of their frequency spectra (M1, M2);
- determining the angle of incidence () of every acoustic signal allocated to a frequency of the frequency spectra (M1, M2) on the basis of the relative phase angle (φ) and the frequency;
- generating a signal spectrum (S) of a signal to be output by correlating one of the two frequency spectra (M1, M2) with a filter function (F₀) which is selected so that acoustic signals from an area (γ_3db) around a preferred angle of incidence (₀) are amplified relative to acoustic signals from outside this area (γ_3db); and applying an inverse Fourier transform to the resultant signal spectrum.

Citations

18 Claims

1-9. -9. (canceled)

10. Method of separating acoustic signals from a plurality of sound sources (S1, S2), comprising the following steps:
- disposing two microphones (MIK1, MIK2) at a predefined distance (d) from one another;
  
  picking up the acoustic signals with both microphones (MIK1, MIK2) and generating associated microphone signals (m1, m2); and
  
  separating the acoustic signal of one of the sound sources (S1) from the acoustic signals of the other sound sources (S2) on the basis of the microphone signals (m1, m2), in which the separation step comprises the following steps;
  
  applying a Fourier transform to the microphone signals in order to determine their frequency spectra (M1, M2);
  
  determining the phase difference (φ
  
  ) between the two microphone signals (m1, m2) for every frequency component of their frequency spectra (M1, M2);
  
  determining the angle of incidence () of every acoustic signal allocated to a frequency of the frequency spectra (M1, M2) on the basis of the phase difference (φ
  
  ) and the frequency;
  
  generating a signal spectrum (S) of a signal to be output by correlating one of the two frequency spectra (M1, M2) with a filter function (F₀) which is selected so that acoustic signals from an area (γ
  
  _3db) around a preferred angle of incidence (₀) are amplified relative to acoustic signals from outside this area (γ
  
  _3db); and
  
  applying an inverse Fourier transform to the resultant signal spectrum, characterised in that the filter function (F₀) is dependent on and has a maximum at the preferred angle of incidence (₀) when is varied, and the correlation of the filter function (F₀) with one of the two frequency spectra comprises multiplying the same.
- View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18)
- - 11. Method as claimed in claim 10, characterised in that the filter function (F₀) is expressed as follows:
    - F₀(f,T)=Z(−
      
      ₀)+DΔ
      
      ²_fZ(−
      
      ₀) in which f is the respective frequency T is the instant at which the frequency spectra (M1, M2) are determined Z(−
      
      ₀) is an allocation function with a maximum at ₀D≧
      
      0 is a diffusion constant and Δ
      
      ²_fis a discrete diffusion operator.
  - 12. Method as claimed in claim 11, characterised in that the allocation function (Z) is expressed as follows:
    - $Z (ϑ - ϑ_{0}) = {(\frac{1 + \cos (ϑ - ϑ_{0})}{2})}^{n}$ $where$ $n > 0.$
  - 13. Method as claimed in claim 10, characterised in that the angle of incidence is determined by the equation
    =arc cos(x(f,T))
    with
    x(f,T)=(φ
    - c/2π
      
      fd where φ
      
      is the phase difference between the two microphone signal components (m1, m2) c is the acoustic velocity f is the frequency of the acoustic signal component and d is the predefined distance of the two microphones (MIK1, MIK2).
  - 14. Method as claimed in claim 13, characterised in that it additionally incorporates the following step:
    - limiting the value of x(f,T) to the interval [−
      
      1,1].
  - 15. Method as claimed in claim 14, characterised in that it additionally incorporates the following step:
    - reducing signal components whose value of x(f,T) lay outside of the interval [−
      
      1,1] prior to limitation.
  - 16. Device for implementing the method as claimed in claim 10, comprising:
    - two microphones (MIK1, MIK2);
      
      a sampling and Fourier transform unit (20) connected to the microphones for discretizing and digitising the microphone signals (m1, m2) and applying a Fourier transform to them;
      
      a calculating unit (30) connected to the sampling and Fourier transform unit (20) for calculating the angle of incidence () of every acoustic signal component; and
      
      at least one signal generator (40) connected to the calculating unit (30) for outputting the separated acoustic signal, at least one signal generator (40) having means for multiplying one of the Fourier transformed frequency spectra (M1, M2) by a filter function (F₀) which is dependent on and has a maximum at a preferred angle of incidence (₀) when is varied.
  - 17. Device as claimed in claim 16, characterised in that the distance (d) between the microphones satisfies the equation:
    - d<
      
      c/4f_Awhere c is the acoustic velocity and f_Ais the sampling frequency of the stereo sampling and Fourier transform unit (20).
  - 18. Device as claimed in claim 16, characterised in that the device has a signal generator (40) for every sound source (S1, S2) to be separated.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Analog Devices International Unlimited Company (Analog Devices, Inc.)
Original Assignee
Dietmar Ruwisch
Inventors
Ruwisch, Dietmar

Granted Patent

US 7,327,852 B2
Time in Patent Office

Days
Field of Search
US Class Current

381/92
CPC Class Codes

G10L 2021/02165   Two microphones, one receiv...

G10L 2021/02166   Microphone arrays; Beamforming

G10L 21/02   Speech enhancement, e.g. no...

Method and device for separating of sound signals

First Claim

2 Assignments

0 Petitions

Accused Products

Abstract

Citations

18 Claims

Specification

Solutions

Use Cases

Quick Links

Method and device for separating of sound signals

First Claim

2 Assignments

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

Citations

18 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links