KR20070025904A - Method of effective bitstream composition for the spatial parameter band number of a lfe-channel for multi-channel audio coding - Google Patents

Abstract

A method for effective bitstream composition for the parameter band number of an LFE channel in multi-channel audio coding is provided to express the parameter band number applied to the channel conversion module of the LFE channel included in a bitstream by using the parameter band number for whole channels or grouping plural parameter band numbers, thereby improving the efficiency of encoding, transmission, and decoding. A method for encoding multi-channel audio signals comprises the following steps of: downmixing the multi-channel audio signal and extracting spatial information from the multi-channel audio signal(602,603); and generating a core codec bitstream and a spatial information bitstream by using the downmixed audio signal and the spatial information, and generating the spatial information bitstream to make a bit number variable for expressing the parameter band number applied to the LFE(Low Frequency Enhancement) channel(604,608).

Description

FIELD OF EFFECTIVE BITSTREAM COMPOSITION FOR THE SPATIAL PARAMETER BAND NUMBER OF A LFE-CHANNEL FOR MULTI-CHANNEL AUDIO CODING}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram illustrating a method for a human to recognize spatial information about an audio signal in the present invention.

2 is a diagram of a method of coding a multichannel audio signal using a spatial encoder and decoder in the present invention.

3 is a detailed diagram of a step of converting a multichannel audio signal from 2 to 5.1 channels in a spatial decoder according to the present invention;

4A and 4B are diagrams of a syntax and bsFreqRes table in which the number of parameter bands of an LFE channel according to the present invention is used.

5 is a diagram illustrating syntax for the number of parameter bands applied to an LFE channel according to the present invention.

6 is a flowchart of an encoding method according to a first embodiment of the present invention.

FIG. 7A is a diagram of a method of representing a plurality of parameter band number data applied to a plurality of LFE channels according to a second embodiment of the present invention. FIG.

7B is a flowchart of an encoding method according to a second embodiment of the present invention.

8 is a flowchart of an encoding method according to a third embodiment of the present invention.

9 is a flowchart of an encoding method according to a fourth embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

101.Remote sound source 102.Direct sound wave

104. Reflected Sound Wave 201. Multichannel Audio Signal

202. Downmix unit 203. Special parameter extraction unit

204 Spatial Encoder 205 Artistic Downmix Audio Signal

206. Mono or stereo audio signal 207. Special parameters

208.Space Decoder

302.2 Channel Analysis Filter Bank 303.2 Channel Time / Frequency Signal

304.Upmix section 305.6 channel time / frequency signal

306.6-Channel Integrated Filterbank 401.bs FreqRes

402.OttConfig (i) 501.bsOttBands (i)

The present invention relates to a method for constructing a bitstream of a multichannel audio signal, and more particularly, to a method for effectively configuring a bitstream for a number of parameter bands of a low frequency enhancement channel (LFE channel) in multichannel audio coding. It is about.

Recently, various coding techniques and methods for digital audio signals have been developed, and related products have been produced. In addition, coding methods for multi-channel audio signals have been developed using a psychoacoustic model, and standardization thereof has been in progress. The psychoacoustic model is an unnecessary part of the coding process by using a method of recognizing a sound, for example, a small sound following a loud sound, and only a sound corresponding to a frequency of 20 Hz to 20000 Hz. By eliminating the audio signal for, the amount of data needed can be effectively reduced.

Currently, audio standard technologies such as MPEG-1 Audio (MEPG-1 Layer III), MPEG-4 Advanced Audio Coding (AAC), and MPEG-4 High-Efficiency AAC (HE-AAC) have been developed and commercialized. In addition, a method of coding a multichannel audio signal using spatial information has been developed. The multi-channel audio signal coding method uses a compressed audio signal (e.g., stereo or mono audio signal) and a low bit-rate side information (e.g., spatial information) channel. Therefore, the transmission efficiency of the multichannel audio signal is greatly improved.

However, in constructing a bitstream of a multichannel audio signal in the multichannel audio signal coding method, without considering the characteristics of each information included in the bitstream, for example, the number of parameter bands applied to the LFE channel. As a result, a bitstream for the number of parameter bands is configured, and thus the efficiency is not good.

Therefore, the present invention proposed to solve the above problems, in coding a multi-channel audio signal, of each data included in the bitstream (for example, the number of parameter bands applied to the channel conversion module of the LFE channel) It is an object of the present invention to provide an encoding and decoding method capable of improving encoding, transmission and decoding efficiency of a multichannel audio signal by representing a spatial information bitstream in an efficient manner in consideration of characteristics.

In order to achieve the above object, the present invention comprises the steps of downmixing the multichannel audio signal and extracting spatial information from the multichannel audio signal; A core codec bitstream and a spatial information bitstream are generated using the downmixed audio signal and the spatial information, wherein the spatial information bitstream is determined by the number of parameter bands for all channels. And generating a variable number of bits for expressing the number of parameter bands applied to the LFE channel by providing a method of encoding a multi-channel audio signal.

Here, when the number of parameter bands for the entire channel is in the range of 2 ^ (n-1) or more and less than 2 ^ (n) or more than 2 ^ (n-1) and less than 2 ^ (n), the LFE channel is applied. The number of bits for the number of parameter bands may be n, and the number of bits for the number of parameter bands applied to the LFE channel is a function of rounding up to the nearest integer using the number of parameter bands for all channels as a variable (ceil function). Can be expressed.

In addition, to achieve the above object, the present invention comprises the steps of downmixing the multichannel audio signal, and extracting spatial information from the multichannel audio signal; Each frame is composed of a core codec bitstream and a spatial information bitstream using the downmixed audio signal and spatial information, wherein a plurality of LFE channels exist in the spatial information bitstream, and each LFE channel is unique. Determining a number of parameter bands, the number of parameter bands corresponding to the plurality of LFE channels into one or more groups, and determining information indicating the number of parameter bands applied to each LFE channel for each group; A method of encoding a multichannel audio signal is provided.

In addition, to achieve the above object, the present invention comprises the steps of downmixing the multichannel audio signal, and extracting spatial information from the multichannel audio signal; Each frame is composed of a core codec bitstream and a spatial information bitstream using the downmixed audio signal and spatial information, and represents a plurality of parameter bands applied to a plurality of LFE channels included in the spatial information bitstream. The information may be generated by using one or more absolute values and / or a comparison value adaptively selected based on the absolute values. .

Here, the spatial information bitstream may include information for distinguishing between the case where it is represented by the at least one absolute value and the case where it is represented by a comparison value adaptively selected based on the absolute value.

In addition, to achieve the above object, the present invention comprises the steps of downmixing the multichannel audio signal, and extracting spatial information from the multichannel audio signal; Each frame is composed of a core codec bitstream and a spatial information bitstream using the downmixed audio signal and spatial information, and the range of the number of parameter bands applied to the LFE channel included in the spatial information bitstream is determined. Limiting in advance and generating the parameter band to be represented by a limited number of bits; and providing a method of encoding a multi-channel audio signal.

Here, the limited number of bits uses one of 1 to 5 bits, a value corresponding to half of the number of parameter bands for all channels, or the total channel determined according to the number of parameter bands for all channels. You can use a value smaller than the number of parameter bands for.

In addition, to achieve the above object, the present invention includes the steps of receiving a core codec bitstream and spatial information bitstream for the downmixed audio signal; Decoding the core codec bitstream, and including the information about the number of parameter bands applied to channels other than the LFE channel and the information about the number of parameter bands applied to the LFE channel represented by a variable number of bits. It provides a method for decoding a multi-channel audio signal comprising the step of decoding. The decoding of the spatial information bitstream in the present specification may include converting an audio signal included in the core codec bitstream into a multichannel audio signal using information in the spatial information bitstream.

In addition, to achieve the above object, the present invention includes the steps of receiving a core codec bitstream and spatial information bitstream for the downmixed audio signal; Decode the core codec bitstream, and include the spatial information bitstream including information on the number of parameter bands applied to channels other than an LFE channel and information on the number of parameter bands applied to each LFE channel expressed for each group. It provides a method for decoding a multi-channel audio signal comprising the step of decoding.

In addition, to achieve the above object, the present invention includes the steps of receiving a core codec bitstream and spatial information bitstream for the downmixed audio signal; Decode the core codec bitstream and represent information on the number of parameter bands applied to channels other than an LFE channel and at least one absolute value and / or an adaptive value selected adaptively based on the absolute value. And decoding the spatial information bitstream including information on the number of parameter bands of the LFE channel.

In addition, to achieve the above object, the present invention includes the steps of receiving a core codec bitstream and spatial information bitstream for the downmixed audio signal; Decoding the core codec bitstream and decoding the spatial information bitstream including information about the number of parameter bands applied to channels other than an LFE channel and information about the number of parameter bands of an LFE channel expressed by a limited number of bits. It provides a method for decoding a multi-channel audio signal comprising a.

In addition, in order to achieve the above object, the present invention is generated so that an audio signal includes a core codec bitstream and a spatial information bitstream, the spatial information bitstream, for the entire channel included in the spatial information bitstream Provided is a method for generating an audio signal, characterized in that the number of bits for expressing the number of parameter bands applied to the LFE channel is variable using the value of the number of parameter bands.

In addition, in order to achieve the above object, the present invention provides a plurality of LFE channels in which an audio signal is generated to include a core codec bitstream and a spatial information bitstream, wherein the spatial information bitstream is included in the spatial information bitstream. Provides a method for generating an audio signal, characterized in that the number of parameter bands corresponding to are divided into one or more groups, and generated to express information on the number of parameter bands applied to each LFE channel for each group.

In addition, in order to achieve the above object, the present invention is generated to include an audio signal core codec bitstream and a spatial information bitstream, wherein the spatial information bitstream is assigned to a plurality of LFE channels included in the spatial information bitstream. A method of generating an audio signal, characterized in that the information representing the number of parameter bands to be applied is generated to be expressed as one or more absolute values and / or a comparison value adaptively selected based on the absolute value. to provide.

In addition, in order to achieve the above object, the present invention is generated so that an audio signal includes a core codec bitstream and a spatial information bitstream, and the spatial information bitstream is applied to an LFE channel included in the spatial information bitstream. The present invention provides a method of generating an audio signal, wherein the range of the number of parameter bands is limited in advance, and the number of parameter bands is generated to represent a limited number of bits.

Therefore, according to the present invention, by efficiently representing a spatial information bitstream including information on the number of parameter bands applied to the channel conversion module of the LFE channel, compression and transmission efficiency can be improved.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

1 shows a method for a human to recognize spatial information about an audio signal in the present invention. The coding method for a multichannel audio signal is based on the fact that a human perceives the audio signal as a three-dimensional space. I use it. Such parameters, called "spatial parameters" for displaying spatial information of a multi-channel audio signal, include channel level differences (CLD), inter channel coherences (ICC), channel prediction coefficients (CPC), and the like. The CLD denotes an energy difference between two channels, the ICC denotes a correlation between two channels, and the CPC denotes a prediction coefficient used when generating three channels from two channels. .

How a human perceives an audio signal spatially and how the concept of the spatial parameter is generated is shown in FIG. 1. Direct sound wave 103 from a remote sound source 105 reaches the left ear 107 of the human, and another direct sound wave 102 is diffracted around the head and right ear 106 Will be reached. The two sound waves 102 and 103 show a difference in arrival time and energy level, and this difference generates the CLD and CPC parameters.

Also, if the reflected sound waves 104 and 105 reach both ears, or if the sound source 105 is dispersed, sound waves that do not correlate with each other will reach both ears, which will generate the ICC parameter. Spatial parameters generated on the principle as described above are known to enable a strong number of bits in transmitting a multichannel audio signal as a mono or stereo signal and then outputting the multichannel audio signal back to the multichannel.

The present invention proposes a method of representing information about said spatial parameters in a bitstream in a very efficient way.

2 illustrates the principle of coding a multichannel audio signal using a spatial encoder and decoder in the present invention. As shown, the spatial encoder 204 first receives a multichannel audio signal 201. Where N is the number of input channels. The multichannel audio signal 201 is downmixed by the down-mix unit 202 to be a downmix signal 206.

In addition, the spatial information of the multichannel audio signal, that is, the spatial parameter, is extracted from the multichannel audio signal 201 by the spatial parameter extractor 203. In this case, spatial information refers to downmixing a multi-channel (eg, Left, Right, Center, Left surround, Right surround, etc.) audio signal, transmitting the downmix signal 206, and transmitting the transmitted down signal. Information about the audio signal channel used when upmixing a mix signal back to multichannel. Alternatively, the downmix signal 206 may be generated using an externally provided downmix signal, for example, an artistic down-mix signal 205.

The downmix signal 206 is encoded using the core codec (e.g., MP3, AC-3, DTS or AAC) coding method and then compressed and transmitted. Is also sent together. If the user's system can only output the downmix signal 206, the compressed downmixed signal 206 may be decoded and output 209 directly. If the system is capable of outputting a multichannel audio signal, the compressed and transmitted audio signal is decoded and then received spatial information, i.e., spatial parameter 207, of the multichannel audio signal transmitted together by the spatial decoder 208. The multichannel audio signal 210 may be converted into a multichannel audio signal 210 and output.

Instead of transmitting the multichannel audio signal directly, the method of downmixing and transmitting the downmix signal 206 as described above, and transmitting the spatial information of the multichannel audio signal, that is, the spatial parameter 207 together, is compressed and It is very advantageous in terms of transmission efficiency.

According to the present invention, in transmitting the spatial information of the multi-channel audio signal, that is, the spatial parameter 207 together, the spatial parameter 207 can be represented in a more efficient manner to form a bit string to improve compression and transmission efficiency. Can be.

Figure 3 illustrates in detail the steps of converting a multichannel audio signal from two channels to 5.1 channels in the spatial decoder according to an embodiment of the present invention. The present invention can be used to convert the downmix signal to 5.1 channels as shown, and can also be used to convert the downmix signal to multichannels of 5.1 channels or more.

As shown, the two channel to 5.1 channel conversion is generally performed in the time / frequency domain. The process is as follows. First, the two-channel analysis filterbank 302 converts the decoded and transmitted stereo audio signal 301 into two channels of time / frequency domain audio signals 303. Second, the two-channel time / frequency domain audio signal 303 is up-mixed into a six-channel time / frequency audio signal 305 using the spatial information, that is, the spatial parameter. Third, the six channel time / frequency domain audio signal 305 is converted into a 5.1 channel audio signal 307 by a six channel integrated filter bank 306 and output.

The spatial information of a more efficiently generated multichannel audio signal according to the present invention may be used to convert from a two-channel time / frequency audio signal to a six-channel time / frequency domain audio signal in the upmix step.

4A and 4B illustrate a syntax and bsFreqRes table in which the number of parameter bands of an LFE channel according to the present invention is used. The coding method of the multi-channel audio signal may use a plurality of input channels. For example, six input channels, for example, C (Center), L (Left), R (Right), LS (Left Surround), A wide channel of RS (Right Surround) and a Low Frequency Enhancement (LFE) channel providing only low frequency components may be used. The channels may be converted into two channels by one channel or by two channels by three channel conversion modules (eg, Ottbox and Tttbox), or vice versa. have.

As described above, the channel conversion process using the channel conversion module does not need to be performed for the entire frequency band. Therefore, in the channel conversion process, the frequency band to be used is indicated by a parameter band number, and the parameter band number is represented by "bsOttBands".

4A shows a syntax in which information on the number of parameter bands for all channels is displayed, which is indicated through "bsFreqRes" 401. The relationship between the " bsFreqRes " 401 and the number of parameter bands (" numBands ") for all channels is defined in table form in FIG. 4B. As shown, when "numBands" is 40, 28, 20, 14, 10, 7, 5 or 4, the "bsFreqRes" 401 is 0, 1, 2, 3, 4, 5, 6 or It is indicated by 7. That is, when the value of the "bsFreqRes" 401 is 0, it can be seen that the number of parameter bands (ie, "numBands") for all channels is 40. The number of parameter bands for the entire channel can be used for " bsOttBands " applied to the LFE channel, which is represented by " OttConfig (i) "

5 illustrates syntax for the number of parameter bands applied to an LFE channel according to the present invention. As shown, if the channel conversion module is for the LFE channel, since the LFE channel exists only in the low frequency region, information about the number of parameter bands (hereinafter referred to as "bsOttBands") applied to the LFE channel is obtained from the bitstream. Read new. In this case, in the related art, fixed 6 bits are used to indicate “bsOttBands” 501. According to the first embodiment of the present invention, the length of the “bsOttBands” 501 is determined by the number of parameter bands for all channels (ie, , "numBands") can be used to express the variable.

For example, when the "numBands" ranges from 2 ^ (n-1) to less than 2 ^ (n), the length of the "bsOttBands" 501 may be variable n bits. For example, (a) if the "numBands" is 40, the length of the "bsOttBands" 501 is 6 bits, and (b) if the "numBands" is 28 or 20, the "bsOttBands" 501 If the length is 5 bits and (c) if the "numBands" is 14 or 10, the length of the "bsOttBands" 501 is 4 bits and (d) if the "numBands" is 7, 5, or 4, the "bsOttBands" The length of "501" can be 3 bits. The present invention also includes setting the length of the "bsOttBands" 501 to variable n bits when the "numBands" is more than 2 ^ (n-1) and less than 2 ^ (n). For example, (a) if the "numBands" is 40, the length of the "bsOttBands" 501 is 6 bits, and (b) if the "numBands" is 28 or 20, the "bsOttBands" 501 If the length is 5 bits and (c) if the "numBands" is 14 or 10, the length of the "bsOttBands" 501 is 4 bits and (d) if the "numBands" is 7 or 5, the "bsOttBands" 501 ) Length is 3 bits, and (e) when the "numBands" is 4, the length of the "bsOttBands" 501 can be 3 bits.

In addition, the number of bits for the number of parameter bands applied to the LFE channel can be variably expressed using a function (ceil function) that rounds up to the nearest integer using the number of parameter bands for all channels as variables. For example, when the number of parameter bands applied to the channel conversion module of the LFE channel is called "bsOttBands" of the LFE channel, and the number of parameter bands for all the channels is called numBands, the rounding function (ceil function) is I) expressed as ceil (log2 (numBands)) for 0 <bsOttBands≤numBands or 0≤bsOttBands <numBands, or ii) as ceil (log2 (numBands + 1)) for 0≤bsOttBands≤numBands Can be.

In addition, if the value ("numberBands") less than or equal to the number of parameter bands for all the channels is defined to be 올, the rounding function is ⅰ) in the case of 0 <bsOttBands≤numberBands or 0≤bsOttBands <numberBands, ceil (log2). (numberBands)) or ii) in the case of 0 ≦ bsOttBands ≦ numberBands, it may be represented by ceil (log2 (numberBands + 1)).

If there are a plurality of LFE channels (for example, N), a combination of the number of parameter bands applied to the plurality of LFE channels,

It can be expressed as Here, bsOttBands _i means the i-th "bsOttBands". For example, if there are three LFE channels and the "bsOttBands" value (hereinafter, a1, a2, and a3) corresponds to three cases, two bits are used to express the a1, a2, and a3 information, respectively. Is required, so a full 6 bits are required. If the a1, a2, and a3 information are grouped and expressed as a group, 3 * 3 * 3 = 27 cases can be generated, which can be represented by 5 bits smaller than the 6 bits. If "numBands" is 3 and the value read in 5 bits is 15, it can be expressed as 15 = 1x (3 ^ 2) + 2 * (3 ^ 1) + 0 * (3 ^ 0), and the above equation in the decoder By applying vice versa, the information that a1, a2, and a3 are 1, 2, and 0 may be extracted.

In addition, if a value smaller than or equal to the number of parameter bands of all channels (hereinafter referred to as "numberBands") is defined, the combination of the number of parameter bands applied to the channel conversion module of the plurality of LFE channels,

or,

or

It can be expressed as

6 is a flowchart of an encoding method according to a first embodiment of the present invention. To more efficiently express the number of parameter bands applied to the LFE channel, first downmix 602 the audio signal from the multichannel audio signal 601 and generate a core codec bitstream using the downmixed audio signal. (604). The downmixed audio signal may include a mono or stereo signal.

Then, spatial information, e.g., spatial parameters, is extracted from the multi-channel audio signal 601 (603), and if the channel applied to the channel conversion module is an LFE channel (605), the number of parameter bands for all channels Determining the number of bits of the number of parameter bands (" bsOttBands ") applied to the LFE channel using " numBands " (606), and using the information about the number of parameter bands applied to the LFE channel indicated by the determined number of bits. To generate a spatial information bitstream (608). If the channel applied to the channel conversion module is not an LFE channel (605), the spatial information bitstream is generated (608) using the number of parameter bands ("numBands") for all channels (607).

Then, the entire bitstream consisting of the core codec bitstream and the spatial information bitstream generated as described above is transmitted (609).

FIG. 7A illustrates a method of representing a plurality of parameter band number data applied to a plurality of LFE channels according to a second embodiment of the present invention. As shown, in the case of kN + L parameter band number data applied to a plurality of LFE channels, if Q bits are required to display each data (where k and N are arbitrary non-negative integers, L may be an integer satisfying 0 ≦ L <N) and a plurality of parameter bands applied to the plurality of LFE channels as a group.

Specifically, N data may be bundled into one group, and the group may be represented using M bits, and the last group may be formed by using L data and the last group may be represented using P bits. Here, it is preferable that the M bits used for grouping and representing are smaller than the N * Q bits used for representing each group without grouping. It is preferable that the P bits used to represent the last group also be less than or equal to the L * Q bits used when expressing each group without grouping them.

For example, assuming that data b1 and b2 have five values, three bits must be used to represent each of the data. In this case, three values can represent eight values, and since five values are actually required, the data has three redundancies. However, when the data b1 and b2 are grouped and expressed as a group, only 5 bits may be used instead of 3 bits + 3 bits = 6 bits. That is, since all combinations of b1 and b2 are 5 * 5 = 25 types, only 5 bits can be expressed. Although seven redundancies occur in the combination, the redundancy is reduced compared to the case of using 3 bits each.

(a) If the parameter band number data applied to the channel conversion module of the LFE channel has 40 values, N is used as 2, 3, 4, 5, and 6 to form a group, and each of 11, 16, 22, 27, 32 bits can be displayed or a combination of the above cases can be expressed.

(b) If the parameter band number data applied to the channel conversion module of the LFE channel has 28 values, one group may be formed using N as 6 and represented using 29 bits.

(c) If the parameter band number data applied to the channel conversion module of the LFE channel has 20 values, N is used as 2, 3, 4, 5, 6, and 7, respectively, to form a group and 9, 13, 18, 22, 26, and 31 bits can be used for display or a combination of the above cases.

(d) If the parameter band number data applied to the channel conversion module of the LFE channel has 14 values, one group may be formed using N as 6 and represented using 23 bits.

(e) If the parameter band number data applied to the channel conversion module of the LFE channel has 10 values, one group using N as 2, 3, 4, 5, 6, 7, 8, and 9, respectively. It can be expressed using 7,10,14,17,20,24,27,30 bits, respectively, or a combination of the above cases can be expressed.

(f) If the parameter band number data applied to the channel conversion module of the LFE channel has 7 values, N is used as 6, 7, 8, 9, 10 and 11, respectively, to form a group and each 17, 20, 23, 26, 29, 31 bits can be displayed or a combination of the above cases can be expressed.

(g) If the parameter band number data applied to the channel conversion module of the LFE channel has five values, N is 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, respectively. To create a group and display it using 5, 7, 10, 12, 14, 17, 19, 21, 24, 26, 28, and 31 bits, or a combination of the above cases. I can express it.

In addition, the parameter band number data applied to the LFE channel may be expressed as a group as described above, or may be configured to make each of the data into an independent bit string and paste them continuously.

7B is a flowchart of an encoding method according to a second embodiment of the present invention. In order to more efficiently express the number of parameter bands applied to the channel conversion module of the LFE channel, first downmix 702 the audio signal from the multi-channel audio signal 701, and then use the downmixed audio signal to use a core codec. Generate a bitstream (704). The downmixed audio signal may comprise a mono or stereo signal.

Spatial information, e.g., spatial parameters, is then extracted from the multichannel audio signal 701. If the channel applied to the channel conversion module is the LFE channel 705, when the number of parameter bands applied to the plurality of LFE channels is plural, the number of parameter bands corresponding to the plurality of LFE channels is one or more. The information is divided into groups, and represents information indicating the number of parameter bands applied to each LFE channel for each group (706), and generates a spatial information bitstream including the number of parameter bands applied to each LFE channel represented for each group. do. If the channel applied to the channel conversion module is not the LFE channel (705), the spatial information bitstream is generated (708) using the number of parameter bands for the entire channel (707).

Then, the entire bitstream consisting of the core codec bitstream and the spatial information bitstream generated as described above is transmitted (709).

8 is a flowchart of an encoding method according to a third embodiment of the present invention. In order to more efficiently express the number of parameter bands applied to the channel conversion module of the LFE channel, first downmix 802 the audio signal from the multichannel audio signal 801, and then use the downmixed audio signal as a core. A codec bitstream is generated 804. The downmixed audio signal may comprise a mono or stereo signal.

Spatial information, eg, spatial parameters, is then extracted 802 from the multichannel audio signal 801. If the channel applied to the channel conversion module is the LFE channel 805, the information representing the number of parameter bands applied to the plurality of LFE channels included in the spatial information bitstream may include at least one absolute value and / or the In operation 806, a comparison value is adaptively selected based on an absolute value, and a spatial information bitstream including information on the number of parameter bands represented as described above is generated 808. The method of expressing the adaptively selected comparison value may include a method of expressing using a difference value (“differential”) from an ambient value. In this case, the spatial information bitstream may include information for distinguishing between the case where it is represented by the at least one absolute value and the case where it is represented by a comparison value adaptively selected based on the absolute value. If the channel applied to the channel conversion module is not an LFE channel (805), the spatial information bitstream is generated (809) using the number of parameter bands for the entire channel (807).

Next, the entire bitstream including the core codec bitstream and the spatial information bitstream generated as described above is transmitted (910).

9 is a flowchart of an encoding method according to a fourth embodiment of the present invention. In order to more efficiently express the number of parameter bands applied to the channel conversion module of the LFE channel, first downmix 902 the audio signal from the multichannel audio signal 901, and then use the downmixed audio signal as a core. A codec bitstream is generated (904). The downmixed audio signal may comprise a mono or stereo signal.

Spatial information, e.g., spatial parameters, is then extracted 903 from the multichannel audio signal, and if the channel applied to the channel conversion module is an LFE channel 905, it is applied to the channel conversion module of the LFE channel. Spatial information including information on the number of parameter bands applied to the LFE channel represented as described above, limiting the range of the number of parameter bands in advance (906), expressing the value of the number of parameter bands in a limited number of bits (908) Generate a bitstream (908). The limited number of bits is i) using one of 1 to 5 bits, ii) using half of the number of parameter bands for the entire channel, or iii) being determined according to the number of parameter bands for the entire channel. You can use a value smaller than the number of parameter bands for. If the channel applied to the channel conversion module is not an LFE channel (905), the spatial information bitstream is generated (908) using the number of parameter bands for all channels (907).

Next, the entire bitstream including the core codec bitstream and the spatial information bitstream generated as described above is transmitted (910).

The present invention also limits the upper limit of the frequency band to be applied by a method or a special rule (e.g. fixed value) proportional to the sampling frequency of the original signal, and ii) applied to the channel conversion module of the LFE channel. The number of parameter bands may be limited by the above i), and may be represented by a number of bits smaller than the number of parameter bands of the original signal in order to express the number of parameter bands.

Although the present invention has been described in detail with reference to some embodiments, the above embodiments are presented for the purpose of understanding the present invention, and the scope of the present invention is not limited to the above embodiments. Those skilled in the art will understand that various modifications are possible without departing from the scope of the technical idea of the present invention, and the scope of the present invention should be interpreted by the appended claims.

As described above, in coding a multi-channel audio signal according to the present invention, the number of parameter bands applied to the channel conversion module of the LFE channel included in the bitstream is expressed using the number of parameter bands for all channels. By expressing the data in groups, the encoding, transmission and decoding efficiency can be improved.

In addition, the number of parameter bands applied to the channel conversion module of the LFE channel is represented by a comparison value adaptively selected based on an absolute value and the absolute value or by a limited value, thereby improving encoding, transmission and decoding efficiency. It can be effected.

Claims (20)

A method of encoding a multichannel audio signal, (a) downmixing the multichannel audio signal and extracting spatial information from the multichannel audio signal; And (b) generating a core codec bitstream and a spatial information bitstream using the downmixed audio signal and the spatial information, wherein the spatial information bitstream is a parameter for all channels; And generating a variable number of bits for representing the number of parameter bands applied to the LFE channel by the number of bands. The method of claim 1, In step (b), And when the number of parameter bands for the entire channel ranges from 2 ^ (n-1) to less than 2 ^ (n), the number of bits for the number of parameter bands applied to the LFE channel is further included. A method for encoding a multichannel audio signal. The method of claim 1, In step (b), The number of bits for the number of parameter bands applied to the LFE channel is n when the number of parameter bands for the entire channel is within a range of 2 ^ (n-1) and less than 2 ^ (n). A method for encoding a multichannel audio signal. The method of claim 1, In step (b), When there are a plurality (N) of the LFE channels, a combination of the number of parameter bands applied to all LFE channels with respect to the number of parameter bands for all the channels and the number of parameter bands applied to the i-th LFE channel is determined.

The method of claim 1, further comprising the step of represented as. The method of claim 1, In step (b), The number of bits for the number of parameter bands applied to the LFE channel included in the spatial information bitstream is expressed using a function (ceil function) that rounds up to the nearest integer using the number of parameter bands for all channels as variables. A method for encoding a multichannel audio signal, further comprising. The method of claim 5, When the number of parameter bands applied to the LFE channel is bsOttBands and the number of parameter bands for all the channels is numBands, the rounding function (ceil function) is (a) in the case of 0 <bsOttBands≤numBands or 0≤bsOttBands <numBands, expressed as ceil (log ₂ (numBands)), or (b) in the case of 0≤bsOttBands≤numBands, expressed as ceil (log ₂ (numBands + 1)). The method of claim 1, In step (b), The number of bits for the number of parameter bands applied to the LFE channel included in the spatial information bitstream is rounded up to the nearest integer using a value less than or equal to the number of parameter bands for all channels as a variable (ceil function). And generating the multi-channel audio signal. A method of encoding a multichannel audio signal, (a) downmixing the multichannel audio signal and extracting spatial information from the multichannel audio signal; And (b) Each frame is composed of a core codec bitstream and a spatial information bitstream using the downmixed audio signal and spatial information, wherein a plurality of LFE channels exist in the spatial information bitstream, and each LFE channel Determining a number of parameter bands corresponding to the plurality of LFE channels into one or more groups, wherein the information indicating the number of parameter bands applied to each LFE channel for each group is determined; Method for encoding a multi-channel audio signal, characterized in that it comprises a. A method of encoding a multichannel audio signal, (a) downmixing the multichannel audio signal and extracting spatial information from the multichannel audio signal; And (b) a plurality of parameter bands applied to a plurality of LFE channels included in a core codec bitstream and a spatial information bitstream using each of the downmixed audio signals and spatial information; The information representing the number is generated with at least one absolute value and / or a comparison value adaptively selected based on the absolute value. Way. The method of claim 9, In step (b), And having information for distinguishing the case represented by the one or more absolute values and the case represented by the comparison value adaptively selected based on the absolute value. How to encode. A method of encoding a multichannel audio signal, (a) downmixing the multichannel audio signal and extracting spatial information from the multichannel audio signal; And (b) Each frame is composed of a core codec bitstream and a spatial information bitstream using the downmixed audio signal and spatial information, and the range of the number of parameter bands applied to the LFE channel included in the spatial information bitstream is determined. Limiting in advance, and generating the parameter bands to be represented by a limited number of bits. The method of claim 11, wherein The limited number of bits, (a) use one of 1 to 5 bits, or (b) use a value equal to half the number of parameter bands for all channels, or (c) using a value smaller than the number of parameter bands for all channels, determined according to the number of parameter bands for all channels. In the method of decoding a multichannel audio signal, (a) receiving a core codec bitstream and a spatial information bitstream for the downmixed audio signal; And (b) the spatial information including the information about the number of parameter bands applied to the LFE channel represented by a variable number of bits and the information about the number of parameter bands applied to a channel other than the LFE channel after decoding the core codec bitstream. And decoding the bitstream. In the method of decoding a multichannel audio signal, (a) receiving a core codec bitstream and a spatial information bitstream for the downmixed audio signal; And (b) the spatial information including the information about the number of parameter bands applied to each LFE channel expressed for each group and the information about the number of parameter bands applied to channels other than the LFE channel after decoding the core codec bitstream; And decoding the bitstream. In the method of decoding a multichannel audio signal, (a) receiving a core codec bitstream and a spatial information bitstream for the downmixed audio signal; And (b) decode the core codec bitstream and adaptively select a comparison based on information on the number of parameter bands applied to channels other than an LFE channel and one or more absolute values and / or the absolute values; And decoding the spatial information bitstream including information on the number of parameter bands of the LFE channel expressed as a value. In the method of decoding a multichannel audio signal, (a) receiving a core codec bitstream and a spatial information bitstream for the downmixed audio signal; And (b) decoding the core codec bitstream and including the information about the number of parameter bands applied to channels other than the LFE channel and the information about the number of parameter bands of the LFE channel represented by a limited number of bits. Decoding the multi-channel audio signal. In generating an audio signal, The audio signal is generated to include a core codec bitstream and a spatial information bitstream, The spatial information bitstream is generated such that the number of bits for expressing the number of parameter bands applied to the LFE channel is variable using the value of the number of parameter bands for all channels included in the spatial information bitstream. , Audio signal generation method. In generating an audio signal, The audio signal is generated to include a core codec bitstream and a spatial information bitstream, The spatial information bitstream divides the number of parameter bands corresponding to the plurality of LFE channels included in the spatial information bitstream into one or more groups, and includes information on the number of parameter bands applied to each LFE channel for each group. And to generate an audio signal. In generating an audio signal, The audio signal is generated to include a core codec bitstream and a spatial information bitstream, In the spatial information bitstream, information representing a plurality of parameter bands applied to a plurality of LFE channels included in the spatial information bitstream is adaptive based on one or more absolute values and / or the absolute values. Audio signal is generated so as to be represented by a comparison value. In generating an audio signal, The audio signal is generated to include a core codec bitstream and a spatial information bitstream, The spatial information bitstream is generated so as to limit the range of the number of parameter bands applied to the LFE channel included in the spatial information bitstream in advance, and to express the number of parameter bands as a limited number of bits. How to create.

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