RU2008137596A

RU2008137596A - AUDIO CODING AND DECODING

Info

Publication number: RU2008137596A
Application number: RU2008137596/09A
Authority: RU
Inventors: Дирк Й. БРЕБАРТ (NL); Дирк Й. БРЕБАРТ; Эрик Г.П. СУЙЕРС (NL); Эрик Г.П. СУЙЕРС; Арнольдус В.Й. ОМЕН (NL); Арнольдус В.Й. ОМЕН
Original assignee: Конинклейке Филипс Электроникс Н.В. (Nl); Конинклейке Филипс Электроникс Н.В.
Priority date: 2006-02-21
Filing date: 2007-02-13
Publication date: 2010-03-27
Also published as: RU2427978C2

Abstract

1. Кодировщик аудиосигнала, содержащий ! средство для приема (401) M-канального аудиосигнала, где M>2; ! средство (403) понижающего микширования для понижающего микширования M-канального аудиосигнала в первый стереосигнал и связанные параметрические данные; ! средство (407) формирования для модифицирования первого стереосигнала, чтобы формировать второй стереосигнал, в ответ на связанные параметрические данные и данные пространственных параметров, указывающие передаточную функцию бинаурального восприятия, второй стереосигнал является бинауральным сигналом; ! средство для кодирования (411) второго стереосигнала, чтобы формировать кодированные данные; и ! средство (413) вывода для формирования выходного потока данных, содержащего кодированные данные и связанные параметрические данные. ! 2. Кодировщик по п.1, в котором средство (407) формирования выполнено с возможностью формировать второй стереосигнал посредством расчета значений данных поддиапазона для второго стереосигнала в ответ на связанные параметрические данные, данные пространственных параметров и значения данных поддиапазона для первого стереосигнала. ! 3. Кодировщик по п.2, в котором средство (407) формирования выполнено с возможностью формировать значения поддиапазона для первого поддиапазона второго стереосигнала в ответ на умножение соответствующих стереозначений поддиапазона для первого стереосигнала на матрицу первого поддиапазона; средство (407) формирования дополнительно содержит средство параметров для определения значений данных для матрицы первого поддиапазона в ответ на связанные параметрические данные и данные пространственных параметров д1. An audio encoder containing! means for receiving (401) an M-channel audio signal, where M> 2; ! downmix means (403) for downmixing the M-channel audio signal into a first stereo signal and related parametric data; ! generating means (407) for modifying the first stereo signal to generate a second stereo signal, in response to related parametric data and spatial parameter data indicating a binaural perception transfer function, the second stereo signal is a binaural signal; ! means for encoding (411) the second stereo signal to generate encoded data; and! output means (413) for generating an output data stream containing encoded data and associated parametric data. ! 2. The encoder according to claim 1, wherein the generating means (407) is configured to generate a second stereo signal by calculating subband data values for the second stereo signal in response to associated parametric data, spatial parameter data, and subband data values for the first stereo signal. ! 3. The encoder according to claim 2, wherein the generating means (407) is configured to generate subband values for the first subband of the second stereo signal in response to multiplying the corresponding stereo values of the subband for the first stereo signal by the matrix of the first subband; the means (407) of formation further comprises a parameter means for determining data values for the matrix of the first subband in response to the associated parametric data and spatial parameter data

Claims

1. An audio encoder comprising

means for receiving (401) an M-channel audio signal, where M> 2;

downmix means (403) for downmixing the M-channel audio signal into a first stereo signal and related parametric data;

generating means (407) for modifying the first stereo signal to generate a second stereo signal, in response to related parametric data and spatial parameter data indicating a binaural perception transfer function, the second stereo signal is a binaural signal;

means for encoding (411) the second stereo signal to generate encoded data; and

output means (413) for generating an output data stream containing encoded data and associated parametric data.

2. The encoder according to claim 1, wherein the generating means (407) is configured to generate a second stereo signal by calculating subband data values for the second stereo signal in response to associated parametric data, spatial parameter data, and subband data values for the first stereo signal.

3. The encoder according to claim 2, wherein the generating means (407) is configured to generate subband values for the first subband of the second stereo signal in response to multiplying the corresponding stereo values of the subband for the first stereo signal by the matrix of the first subband; the generating means (407) further comprises parameter means for determining data values for the matrix of the first subband in response to the associated parametric data and spatial parameter data for the first subband.

4. The encoder according to claim 3, wherein the generating means (407) further comprises means for converting the data value of at least one of the first stereo signal, related parametric data and spatial parameter data associated with a subband containing a frequency interval other than the interval of the first subband into the corresponding data value for the first subband.

5. The encoder according to claim 3, in which the means (407) of the formation is configured to determine the stereo values L _B , R _{B of the} subband for the first subband of the second stereo signal essentially as:

,

wherein L ₀ , R ₀ are the corresponding values of the subband of the first stereo signal, and the parameter tool is configured to determine the data values of the multiplication matrix essentially as:

h ₁₁ = m ₁₁ H _L ( L ) + m ₂₁ H _L ( R ) + m ₃₁ H _L ( C )

h ₁₂ = m ₁₂ H _L ( L ) + m ₂₂ H _L ( R ) + m ₃₂ H _L ( C )

h ₂₁ = m ₁₁ H _R ( L ) + m ₂₁ H _R ( R ) + m ₃₁ H _R ( C )

h ₂₂ = m ₁₂ H _R ( L ) + m ₂₂ H _R ( R ) + m ₃₂ H _R ( C ),

where m _{k, l} are parameters determined in response to the associated parametric data for downmixing by means of downmixing channels L, R and C into the first stereo signal; and H _J (X) is determined in response to the spatial parameter data for channel X with respect to the output channel J of the second stereo signal.

6. The encoder according to claim 5, in which at least one of the channels L and R corresponds to the down-mix of at least two down-mix channels, and the parameter means is configured to determine H _J (X) in response to a weighted combination of spatial parameter data for at least two downmixed channels.

7. The encoder according to claim 6, in which the parameter means is configured to determine the weighting of the spatial parameter data for at least two down-mixed channels in response to a relative measure of energy for at least two down-mixed channels.

8. The encoder according to claim 1, in which the data of the spatial parameters include at least one parameter selected from the group consisting of

sub-range mid-range parameter;

parameter of average time of receipt;

phase of at least one stereo channel;

time reference parameter;

group delay parameter;

phases between stereo channels; and

channel cross-correlation parameter.

9. The encoder according to claim 1, wherein the output means (413) is configured to include location data of the sound source in the output stream.

10. The encoder according to claim 1, wherein the output means (413) is configured to include at least some spatial parameter data in the output stream.

11. The encoder according to claim 1, further comprising means (409) for determining the spatial parameter data in response to the desired locations of the audio signal.

12. An audio decoder comprising

means for receiving (701, 703) input data containing the first stereo signal and parametric data associated with the down-mixed stereo signal of the M-channel audio signal, where M> 2, the first stereo signal is a binaural signal corresponding to the M-channel audio signal;

generating means (705) for modifying the first stereo signal to produce a down-mixed stereo signal, in response to the parametric data and the first spatial parameter data indicating the binaural perception transfer function, the first spatial parameter data is associated with the first stereo signal.

13. The decoder of claim 12, further comprising means for generating (709) the M-channel audio signal in response to the down-mixed stereo signal and parametric data.

14. The decoder according to claim 12, wherein the generating means (705) is configured to generate the down-mixed stereo signal by calculating the sub-band data values for the down-mixed stereo signal in response to the associated parametric data, the first spatial parameter data and the sub-band data values for the first stereo signal.

15. The decoder of claim 14, wherein the generating means (705) is configured to generate subband values for a first subband of the stereo down-mixed stereo signal in response to multiplying respective stereo subband values for the first stereo signal by a first subband matrix; the forming means (705) further comprises parameter means for determining the values of the matrix data of the first subband in response to the parametric data and parameter data of the binaural perception transfer function for the first subband.

16. The decoder of claim 12, wherein the input data comprises at least some of the first spatial parameter data.

17. The decoder according to claim 12, in which the input data contains the location data of the sound source, and the decoder comprises means (707) for determining the first spatial parameter data in response to the location data of the sound source.

18. The decoder of claim 12, further comprising

a spatial decoder unit (709, 801) for generating a pair of binaural output channels by modifying the first stereo signal in response to the associated parametric data and the second spatial parameter data indicating the second binaural perception transfer function, the second spatial parameter data is different than the first spatial parameter data.

19. The decoder of claim 18, wherein the spatial decoder unit (709, 801) comprises

a parameter converting unit (903) for converting parametric data into binaural synthesis parameters using second spatial parameter data, and

spatial synthesis unit (901) for synthesizing a pair of binaural channels using binaural synthesis parameters and a first stereo signal.

20. The decoder according to claim 19, in which the binaural synthesis parameters contain matrix coefficients for a 2 by 2 matrix that determines the ratio of stereo samples of the stereo-down-mixed stereo signal to stereo samples of a pair of binaural output channels.

21. The decoder according to claim 19, in which the binaural synthesis parameters comprise matrix coefficients for a 2 by 2 matrix defining the ratio of stereo samples of the sound of the first stereo subband to stereo samples of a pair of binaural output channels.

22. A method of encoding an audio signal, wherein the method is that

receive (1001) an M-channel audio signal, where M> 2;

down-mixing the (1003) M-channel audio signal into a first stereo signal and associated parametric data;

modifying (1005) the first stereo signal to generate a second stereo signal, in response to the associated parametric data and spatial parameter data for the binaural perception transfer function, the second stereo signal is a binaural signal;

encode (1007) a second stereo signal to generate encoded data;

and generating (1009) an output data stream containing encoded data and associated parametric data.

23. A method of decoding an audio signal, comprising

receiving (1101) input data containing the first stereo signal and parametric data associated with the down-mixed stereo signal of the M-channel audio signal, where M> 2, the first stereo signal is a binaural signal corresponding to the M-channel audio signal; and

modifying (1103) the first stereo signal to produce a down-mixed stereo signal, in response to parametric data and spatial parameter data for the binaural perception transfer function, the spatial parameter data is associated with the first stereo signal.

24. A receiver for receiving an audio signal comprising an audio signal decoder according to claim 12.

25. A transmitter (1101) for transmitting an output data stream, the transmitter comprises an audio encoder according to claim 1 and means for transmitting (311) an output data stream.

26. A transmission system for transmitting an audio signal, a transmission system comprising a transmitter according to claim 25, a receiver comprising means for receiving (701, 703) the output data stream and means for modifying (705) the second stereo signal to produce a first stereo signal in response to the associated parametric data and spatial parameter data.

27. The method of receiving an audio signal, consisting in the fact that perform the method according to item 23.

28. The method of transmitting the output audio data stream, which consists in performing the method according to item 22 and transmitting the output audio data stream.

29. The method of transmitting and receiving an audio signal, which consists in performing the method of claim 28 and receiving (1101) the output audio data stream and modifying (1103) the second stereo signal to generate the first stereo signal in response to parametric data and spatial parameter data.

30. A computer program product for performing the method according to any one of paragraphs.22, 23, 27, 28 or 29.

31. An audio recording device comprising an encoder (309) according to claim 1.

32. An audio reproducing apparatus comprising a decoder (315) according to claim 12.

33. An audio data stream for an audio signal comprising a first stereo signal and parametric data associated with a down-mixed stereo signal of an M-channel audio signal, where M> 2, wherein the first stereo signal is a binaural signal corresponding to the M-channel audio signal.

34. A computer-readable medium comprising the audio data stream stored therein according to claim 33.