Optimal acoustic rake receiver

The invention claimed is: 1. An acoustic processing method for M acoustic receivers comprising the steps of: determining a position of a real acoustic source and K positions of K image sources of the real acoustic source, wherein K is the number of image sources considered, wherein each of the image sources of the real acoustic source corresponds to one path of the acoustic signal between the real acoustic source and one of the M acoustic receivers with at least one reflection; determining a beamforming weight vector with M weights for the M acoustic receivers based on a steering vector of the position of the real acoustic source, on steering vectors of the positions of the image sources of the real acoustic source and on a first matrix, wherein the first matrix depends on a covariance matrix of the noise and/or on a position of an interfering acoustic source; and linearly combining the M acoustic signals received at the M acoustic receivers on the basis of the M weights of the beamforming vector. 2. Method according to claim 1 , comprising determining the position of the interfering acoustic source, wherein said first matrix is calculated on the basis of the determined position of the interfering acoustic source. 3. Method according to claim 2 , comprising determining positions of interfering image sources, wherein said first matrix is calculated on the basis of the position of the interfering source and on the positions of the interfering image sources, wherein each of the interfering image sources corresponds to one path of the interfering signal between the interfering acoustic source and one of the M acoustic receivers with at least one reflection. 4. Method according to claim 3 , wherein said first matrix is calculated based on the sum of the steering vectors of the positions of the interfering acoustic source and the image interfering sources. 5. Method according to claim 4 , wherein said first matrix is calculated based on the sum of the steering vectors of position of the interfering acoustic source and the positions of the image interfering sources multiplied with the adjoint of the sum of the steering vectors of the positions of the interfering acoustic source and the positions of the image interfering sources. 6. Method according to claim 1 , wherein said first matrix comprises a first addend depending on the covariance matrix of the noise and a second addend depending on the position of an interfering acoustic source. 7. Method according to claim 1 , wherein the beamforming weight vector is based on the first matrix and on a second matrix depending on the steering vector of the position of the real acoustic source and on the steering vectors of the positions of the image sources of the real acoustic source. 8. Method according to claim 7 , wherein the second matrix comprises the steering vector of the position of the real acoustic source and the steering vectors of the positions of the image sources of the real acoustic source as columns or rows. 9. Method according to claim 7 , wherein the beamforming weight vector is proportional to diagonal elements of the multiplication of the inverse of said first matrix with the second matrix. 10. Method according to claim 7 , wherein the beamforming weight vector is proportional to the eigenvector of a third matrix corresponding to the largest eigenvalue, wherein the third matrix depends on the first matrix and the second matrix. 11. Method according to claim 10 , wherein the third matrix depends on the inverse of the Cholesky decomposition of the first matrix and on the second matrix. 12. Method according to claim 11 , wherein the third matrix is proportional to (C −1 ) H A s A s H C −1 , with C being the Cholesky decomposition of the first matrix and A s being the second matrix. 13. Method according to claim 1 , wherein the beamforming weight vector is proportional to the inverse of said first matrix multiplied with the sum of the steering vectors of the positions of the image sources of the real acoustic source. 14. An acoustic processing method for M acoustic transmitters comprising the steps of: determining a position of a real acoustic receiver and positions of image receivers, wherein each of the image receivers corresponds to one path of a transmission signal between one of the M transmitters and the real acoustic receiver with at least one reflection; determining a beamforming weight vector with M weights for the M acoustic transmitters based on a steering vector of the position of the real acoustic receiver, on steering vectors of the positions of the image receivers of the real acoustic receiver and on a first matrix calculated on the basis of the covariance matrix of the noise and/or on the basis of a position of another acoustic receiver which is not intended to receive a transmission signal, and beamforming the transmission signal with the M weights for the M acoustic transmitters. 15. An acoustic processing apparatus for M acoustic receivers comprising: a position section for determining a position of a real acoustic source and K positions of K image sources of the real acoustic source, wherein K is the number of image sources considered, wherein each of the image sources of the real acoustic source corresponds to one path of the acoustic signal between the real acoustic source and one of the M acoustic receivers with at least one reflection; a beamforming weights section for determining a beamforming weight vector with M weights for the M acoustic receivers based on a steering vector of the position of the real acoustic source, on steering vectors of the positions of the image sources of the real acoustic source and on a first matrix, wherein the first matrix depends on a covariance matrix of the noise and/or on a position of an interfering acoustic source; and a beamforming section for linearly combining the M acoustic signals received at the M acoustic receivers on the basis of the M weights of the beamforming vector. 16. An acoustic processing apparatus for M acoustic transmitters comprising: a position section for determining a position of a real acoustic receiver and positions of image receivers, wherein each of the image receivers corresponds to one path of a transmission signal between one of the M transmitters and the real acoustic receiver with at least one reflection; a beamforming weights section for determining a beamforming weight vector with M weights for the M acoustic transmitters based on a steering vector of the position of the real acoustic receiver, on steering vectors of the positions of the image receivers of the real acoustic receiver and on a first matrix calculated on the basis of the covariance matrix of the noise and/or on the basis of a position of another acoustic receiver which is not intended to receive a transmission signal, and a beamforming section for beamforming the transmission signal with the M weights for the M acoustic transmitters.