KR102033071B1 - System and method for compatible multi channel audio - Google Patents

Abstract

Disclosed are a multi-channel audio conversion method and system. The multi-channel audio conversion system includes an output position checking unit for checking an output position for each channel of an output multichannel audio signal and an input multichannel audio signal; A signal allocating unit for allocating a channel signal of the input channel to the output channel when there are an input channel and an output channel having output channels of the same channel among the output multichannel audio signal and the input multichannel audio signal; A signal distribution unit for distributing a channel signal of the input multichannel audio signal to two channels of an output multichannel audio signal closest to a channel of the input multichannel audio signal; And a channel signal calculator configured to calculate a channel-specific signal of the output multichannel audio signal based on a channel signal allocated to each channel of the output multichannel audio signal or a distributed channel signal.

Description

Multi-channel audio compatible system and method {SYSTEM AND METHOD FOR COMPATIBLE MULTI CHANNEL AUDIO}

The present invention relates to a multi-channel audio conversion system and method, and more particularly to a system and method for converting a 10.2 channel audio signal to another multi-channel audio signal.

Multichannel audio playback technology has been extended to 5.1 and 7.1 channels starting with two-channel stereo, and recently 22.2 channel audio playback systems using three layers have been developed.

However, the 22.2 channel audio system has a high sound field reproduction performance but requires too many speakers, so it is difficult to apply to an environment where it is difficult to secure enough space such as a home.

Therefore, it is compatible with new multichannels that can provide a sound field similar to 22.2 channels using fewer speakers than 22.2 channels, as well as 2.0 / 5.1 / 7.1 channels that are currently using the new multichannels, and 22.2 channels that are newly standardized. There is a need for a way to have a.

The present invention provides a system and method capable of converting a 10.2 channel audio signal into another multi-channel audio signal that can provide a sound field similar to the 22.2 channel using fewer speakers than 22.2 channels.

Multi-channel audio conversion system according to an embodiment of the present invention includes an output position check unit for checking the output position for each channel of the output multi-channel audio signal and the input multi-channel audio signal; A signal allocating unit for allocating a channel signal of the input channel to the output channel when there are an input channel and an output channel having output channels of the same channel among the output multichannel audio signal and the input multichannel audio signal; A signal distribution unit for distributing a channel signal of the input multichannel audio signal to two channels of an output multichannel audio signal closest to a channel of the input multichannel audio signal; And a channel signal calculator configured to calculate a channel-specific signal of the output multichannel audio signal based on a channel signal allocated to each channel of the output multichannel audio signal or a distributed channel signal.

When the input multichannel audio signal is a 22.2 channel audio signal, the channel signal calculator of the multichannel audio conversion system according to an embodiment of the present invention may provide a specific constant for each of an upper layer, a middle layer, a bottom layer, and a subwoofer channel. Multiply by to adjust the overall sound level of the output multichannel audio signal.

The channel signal calculator of the multi-channel audio conversion system according to an exemplary embodiment of the present invention, when the input multi-channel audio signal is a 10.2 channel audio signal, channels located on a plane, channels having the height, and a subwoofer Each channel can be multiplied by a certain constant to adjust the overall sound level of the output multichannel audio signal.

Multi-channel audio conversion method according to an embodiment of the present invention comprises the steps of identifying the output position for each channel of the output multi-channel audio signal and the input multi-channel audio signal; Checking whether there are an input channel and an output channel having output channels of the same channel among the output multichannel audio signal and the input multichannel audio signal; Allocating a channel signal of the input channel to the output channel when there is an input channel and an output channel in which the output positions for each channel are the same among the output multichannel audio signal and the input multichannel audio signal; When there is no channel having the same output position for each channel among the output multichannel audio signal and the input multichannel audio signal, the two channels of the output multichannel audio signal closest to the channel of the input multichannel audio signal are connected to the input multichannel audio signal. Distributing channel signals; And calculating a channel-specific signal of the output multichannel audio signal based on a channel signal allocated to each channel of the output multichannel audio signal or a distributed channel signal.

The present invention can increase the compatibility of the 10.2 channel audio signal by converting the 10.2 channel audio signal, which can provide a sound field similar to the 22.2 channel using less speakers than the 22.2 channel, to another multi-channel audio signal.

1 is a block diagram showing the configuration of a multi-channel audio conversion system according to an embodiment of the present invention.
2 is a diagram illustrating an example of a layout of a conventional 22.2 channel audio signal.
3 shows an example of the layout of a 10.2 channel audio signal according to the present invention.
4 illustrates an example of matching between a 22.2 channel audio signal and an L channel signal of a 10.2 channel multichannel audio signal according to an embodiment of the present invention.
FIG. 5 illustrates an example of matching between a 22.2 channel audio signal and a C channel signal of a 10.2 channel multichannel audio signal according to an embodiment of the present invention.
6 is a diagram illustrating an example of matching between a 22.2 channel audio signal and an LH channel signal of a 10.2 channel multichannel audio signal according to an embodiment of the present invention.
FIG. 7 illustrates an example of matching between a 22.2 channel audio signal and an LS channel signal of a 10.2 channel multichannel audio signal according to an embodiment of the present invention.
8 illustrates an example of matching between a 22.2 channel audio signal and an LB channel signal of a 10.2 channel multichannel audio signal according to an embodiment of the present invention.
FIG. 9 illustrates an example of matching between an L channel signal of a 10.2 channel audio signal and a 7.1 channel multichannel audio signal according to an embodiment of the present invention.
FIG. 10 illustrates an example of matching between a LB channel signal of a 10.2 channel audio signal and a 7.1 channel multichannel audio signal according to an embodiment of the present invention.
FIG. 11 illustrates an example of matching between an LS channel signal of a 10.2 channel audio signal and a 5.1 channel multichannel audio signal according to an embodiment of the present invention.
12 illustrates an example of matching between an L channel signal of a 10.2 channel audio signal and a 2.0 channel multichannel audio signal according to an embodiment of the present invention.
13 is a flowchart illustrating a multi-channel audio conversion method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The multichannel audio conversion method according to an embodiment of the present invention may be performed by a multichannel audio conversion system.

1 is a block diagram showing the configuration of a multi-channel audio conversion system according to an embodiment of the present invention.

The multi-channel audio conversion system according to an embodiment of the present invention converts a 10.2 channel audio signal into another multi-channel audio signal that can provide a sound field effect similar to that of the 22.2 channel audio signal by using fewer channels than the 22.2 channel audio signal. I can convert it.

Referring to FIG. 1, the multi-channel audio conversion system may include an output position determiner 110, a signal allocator 120, a signal distributor 130, and a channel signal calculator 140.

The output position checking unit 110 may check the output position for each channel of the output multichannel audio signal generated by converting the output position for each channel of the input multichannel audio signal received from the user and the input multichannel audio signal.

In this case, the input multichannel audio signal may be a 22.2 channel audio signal as shown in FIG. 2. In this case, the 22.2 channel audio signal has a location where the channel signal of each channel is output as 210, and each channel has an upper layer 221, a middle layer 222, and a bottom layer ( bottom layer) 223.

The upper layer 221 includes a channel output at a high position based on the user, the middle layer 222 includes channels output at the same height as the user, and the bottom layer includes a channel output at a low position based on the user. Output channels or subwoofer channels may be included.

In addition, the 10.2 channel audio signal according to the present invention sets the output position of the seven channels on a plane of the same height with respect to the user as shown in Figure 3, and the three channels having a high height relative to the user It sets the output position and can provide two subwoofer channels.

150° 위치에 출력 위치가 배치된 LB/RB(Left Back/Right Back)채널을 포함할 수 있다.Specifically, the seven channels on the plane include a center (C) channel at which the output position is located at the front center of the user, a left / right (L / R) channel at which the output position is disposed at a ± 30 ° position at the front of the user, Left Side / Right Side (LS / RS) channel with output position at user's ± 90 ° position, and user's

It may include a Left Back / Right Back (LB / RB) channel with an output location at 150 °.

In addition, the three channels having a high height, the LH / RH (Left Height / Right Height) channel having the output position is disposed in the 30 to 45 ° position of the upper side of the L / R channel, and the output position is located above the user It may include a disposed top center (TC) channel.

When the input multichannel audio signal is a 10.2 channel audio signal, the multi-channel audio conversion system uses a multi-channel audio output device that uses fewer than 10.2 channels, such as a 7.1 channel audio signal, a 5.1 channel audio signal, and a 2.0 channel audio signal. The channel audio signal can be used as an output multichannel audio signal.

The signal allocator 120 may allocate a channel signal of the input channel to the output channel when there are an input channel and an output channel having the same output position for each channel among the output multichannel audio signal and the input multichannel audio signal. have.

For example, when the output positions of the 22: 2 channel SiL channel and the 10.2 channel LS channel are the same, the signal allocator 120 allocates the channel signal of the SiL channel to the LS channel, thereby outputting an audio output device corresponding to the LS channel. Can reproduce the channel signal of the SiL channel.

씩 나누어 분배할 수 있다.The signal distribution unit 130 provides the channel signal of the input multichannel audio signal to two channels of the output multichannel audio signal closest to the channel of the input multichannel audio signal.

You can divide by one.

TpFc 채널 신호를 분배할 수 있다.For example, in the case of a TpFc (Top forword center) channel output to an output device located at a high center of a 22: 2 channel, the signal distribution unit 130 is respectively provided to the LH channel and the RH channel at the same height.

TpFc channel signal can be distributed.

The channel signal calculator 140 may calculate a channel-specific signal of the output multichannel audio signal based on a channel signal allocated to each channel of the output multichannel audio signal or a distributed channel signal.

For example, when the channel signal calculator 140 converts the 22.2 channel audio signal into a 10.2 channel audio signal, the channel signal calculator 140 multiplies a specific constant for each of the upper layer, the middle layer, the bottom layer, and the subwoofer channel to output the multichannel audio signal. You can adjust the overall sound level.

In the case of converting a 22.2 channel audio signal into a 10.2 channel audio signal, a process of the channel signal calculator 140 calculating a signal for each channel will be described in detail with reference to FIGS. 4 to 8.

In another example, when the channel signal calculator 140 converts a 10.2 channel audio signal into a channel audio signal having less than 10.2 channels, the channel signal calculator 140 may set a specific constant for each channel and subwoofer channel having a height and a channel on a plane. Multiplication can also be used to adjust the overall sound level of the output multichannel audio signal.

When converting a 10.2 channel audio signal into an output multi-audio signal using less than 10.2 channels, the process of the channel signal calculating unit 140 calculating a signal for each channel will be described in detail with reference to FIGS. 9 to 12. do.

When the multi-channel audio conversion system according to an embodiment of the present invention converts the input 22.2 channel audio signal into a 10.2 channel audio signal, the channel signal calculation unit 140 uses a table 1 signal for each channel of the 10.2 channel. Can be calculated.

For example, as shown in Table 1 and FIG. 4, the channel signal calculator 140 may include a FL (Forword Left) channel, a FLC (Forword Left center) channel, and BtFL (Bottom Forword Left) of the 22.2 channel audio signals 410. The channel signal of the L channel of the 10.2 channel output multichannel audio signal 420 may be calculated based on the channel signal of the channel. At this time, the FL channel and the BtFL channel have the same output position as the L channel, and the FLc channel is a channel between the L channel and the C channel.

을 곱한 값에 각각 미들 레이어로 설정된 상수 m을 곱하고, 보텀 레이어인 BtFL 채널의 채널 신호에 보텀 레이어로 설정된 상수 b를 곱한 다음 상기 결과 값들을 더하여 L 채널의 최종 채널 신호를 계산할 수 있다.In more detail, the channel signal calculator 140 may apply the channel signal of the FL channel, which is the middle layer, and the channel signal of the FLc channel.

The multiplying value may be multiplied by a constant m set as the middle layer, and the channel signal of the bottom layer BtFL channel is multiplied by the constant b set as the bottom layer, and the resultant values are added to calculate the final channel signal of the L channel.

In addition, since the output position of the R channel is symmetrical with the L channel, the channel signal calculation unit 140 is a channel in which the output position is symmetrically with the channels used in the L channel, and is a FR (Forword Right) channel and FRc (Forword Right center). The channel signal of the R channel may be calculated using the channel signal of the) channel and the bottom forward right channel.

In another example, the channel signal calculator 140 may include a FC, a FLc channel, an FRc channel, and a BtFC channel of the 22.2 channel audio signals 510 as shown in Table 1 and FIG. 5. The channel signal of the C channel of the 10.2 channel output multi-channel audio signal 520 may be calculated based on the channel signal of. At this time, the FC channel and the BtFC channel have the same output position as the C channel, the FLc channel is a channel between the L channel and the C channel, and the FRc channel is a channel between the R channel and the C channel.

을 곱한 값, FRc 채널의 채널 신호에

을 곱한 값 에 각각 미들 레이어로 설정된 상수 m을 곱하고, 보텀 레이어인 BtFC 채널에 보텀 레이어로 설정된 상수 b를 곱한 다음, 상기 결과 값들을 더하여 C 채널의 최종 채널 신호를 계산할 수 있다.In more detail, the channel signal calculator 140 is configured for channel signals of the middle channel FC channel and channel signals of the FLc channel.

Times the channel signal of the FRc channel

The multiplying value may be multiplied by a constant m set as a middle layer, multiplied by a constant b set as a bottom layer by a bottom layer BtFC channel, and the final channel signal of the C channel may be calculated by adding the result values.

As another example, the channel signal calculator 140 may convert the channel signals of the TpFL (top Forword Left) channel and the TpFC (top Forword center) channel among the 22.2 channel audio signals 610 as shown in Table 1 and FIG. 6. A channel signal of the LH channel of the 10.2 channel output multichannel audio signal 620 may be calculated based on the result. At this time, the channel signal of the TpFL channel is a channel having the same output position as the LH channel, and the TpFC channel is a channel between the LH channel and the RH channel.

을 곱한 값에 각각 어퍼 레이어로 설정된 상수 t을 곱한 다음, 상기 결과 값들을 더하여 LH 채널의 최종 채널 신호를 계산할 수 있다.In detail, the channel signal calculator 140 is configured to transmit the channel signal of the upper layer TpFL channel and the channel signal of the TpFC channel.

The multiplying value may be multiplied by a constant t set as an upper layer, and the resultant values may be added to calculate the final channel signal of the LH channel.

In addition, since the output position of the RH channel is symmetrical with respect to the L channel, the channel signal calculator 140 is a channel of the TpFR (top forward right) channel and the TpFC channel, which are symmetrical with the channels used for the LH channel. The signal may also be used to calculate the channel signal of the RH channel.

As another example, the channel signal calculator 140 may generate a 10.2 channel output multichannel audio signal based on the TpSiL channel and the channel signal of the SiL channel of the 22.2 channel audio signal 710 as shown in Table 1 and FIG. 7. The channel signal of the LS channel of 720 may be calculated. At this time, the TpSiL channel and the SiL channel are the same channel as the LS channel and the output position.

In detail, the channel signal calculator 140 multiplies the channel signal of the SiL channel, which is the middle layer, by the constant m set as the middle layer, and multiplies the channel signal of the TpSiL channel, which is the upper layer, by the constant t set as the upper layer, and then the result value. In addition, the final channel signal of the LS channel may be calculated.

In addition, since the RS channel is symmetrical with the LS channel, the channel signal calculator 140 uses the TpSiR channel, which is a channel in which the output position is symmetrical with the channels used in the LS channel, and a channel signal of the SiR channel. The channel signal of the RS channel may be calculated.

In another example, the channel signal calculator 140 may include a TopBackwordLeft (TpBL) channel, a TopBackwordCenter (TPpBC) channel, a WordCenter (BC) channel, and a BL of the 22.2 channel audio signals 810 as shown in Table 1 and FIG. 8. A channel signal of the LB channel of the 10.2 channel output multichannel audio signal 820 may be calculated based on the channel signal of the (BackwordLeft) channel. At this time, the TpBL channel and the BL channel are channels having the same output position as the LB channel, and the TpBC channel and the BC channel are channels between the LB channel and the RB channel.

을 곱한 값에 각각 미들 레이어로 설정된 상수 m을 곱하고, 어퍼 레이어인 TpBL 채널의 채널 신호와 TpBC 채널의 채널 신호에

을 곱한 값에 각각 어퍼 레이어로 설정된 상수 t를 곱한 다음, 상기 결과 값들을 더하여 LB 채널의 최종 채널 신호를 계산할 수 있다.In more detail, the channel signal calculator 140 may apply the channel signal of the BL channel, which is the middle layer, and the channel signal of the BC channel.

Multiply the value by and multiply the constant m set by the middle layer, respectively, and the channel signal of the upper layer TpBL channel and the channel signal of the TpBC channel.

The multiplying value may be multiplied by a constant t set as an upper layer, and then the resultant values may be added to calculate the final channel signal of the LB channel.

In addition, since the output position of the RB channel is symmetrical with the L channel, the channel signal calculation unit 140 is a channel in which the output position is symmetrical with the channels used for the LB channel, and a TpBR (TopBackwordRight) channel and a TpBC (TopBackwordCenter) channel The channel signals of the RB channel may be calculated using the channel signals of the BC (BackwordCenter) channel and the BR (BackwordRight) channel.

When the multi-channel audio conversion system according to an embodiment of the present invention converts the input 10.2 channel audio signal into a 7.1 channel audio signal, the channel signal calculation unit 140 uses the signal of each channel of the 7.1 channel using Table 2. Can be calculated.

For example, the channel signal calculator 140 may display the L channel of the 7.1 channel audio signal 920 based on the L and LH channel signals of the 10.2 channel audio signals 910 as shown in Table 1 and FIG. 9. The channel signal of can be calculated. In this case, the L channel and the LH channel of the 10.2 channel audio signal 910 are the same output positions as the L channel of the 7.1 channel audio signal 920. In addition, the channel signal calculator 140 may set a constant a to a channel located on a plane and a constant c to a channel having a height.

In detail, the channel signal calculator 140 multiplies the L channel of the 10.2 channel audio signal 910, which is a channel located on the same plane as the user, by a predetermined constant a, and multiplies the preset constant c by the LH channel, which is a channel having a height. After the multiplication, the result values may be added to calculate the final channel signal of the L channel of the 7.1 channel audio signal 920.

In addition, since the output position of the R channel is symmetrically with respect to the L channel, the channel signal calculation unit 140 performs the R channel and the RH of the 10.2 channel audio signal 910, which is a channel where the output position is symmetrically with the channels used for the L channel. The channel signal of the R channel of the 7.1 channel audio signal 420 may be calculated using the channel signal of the channel.

As another example, the channel signal calculator 140 may perform the LB of the 7.1-channel audio signal 1020 based on the LB channel and TC channel channel signals of the 10.2 channel audio signals 1010 as shown in Table 1 and FIG. 10. The channel signal of the channel can be calculated. In this case, the LB channel of the 10.2 channel audio signal 920 has the same output position as the LB channel of the 7.1 channel audio signal 1020, and the TC channel is a channel between the LB channel and the RB channel of the 7.1 channel audio signal 1020. to be.

을 곱한 값에 기 설정된 상수 c를 곱한 다음 상기 결과 값들을 더하여 7.1채널 오디오 신호(420)의 LB 채널의 최종 채널 신호를 계산할 수 있다.In detail, the channel signal calculator 140 multiplies the LB channel of the 10.2 channel audio signal 910, which is a channel located on the same plane as the user, by a predetermined constant a, and has a height between the LB channel and the RB channel. To the channel signal of the TC channel

The final channel signal of the LB channel of the 7.1 channel audio signal 420 may be calculated by multiplying the multiplied value by a predetermined constant c and then adding the resultant values.

In addition, since the output position of the RB channel is symmetrical with respect to the LB channel, the channel signal calculation unit 140 performs the RB channel and TC of the 10.2 channel audio signal 910 which is a channel in which the output position is symmetrical with the channels used for the LB channel. The channel signal of the RB channel of the 7.1 channel audio signal 420 may be calculated using the channel signal of the channel.

When the multi-channel audio conversion system according to an embodiment of the present invention converts the input 10.2 channel audio signal into a 5.1 channel audio signal, the channel signal calculation unit 140 uses a table 3 signal for each channel of the 5.1 channel. Can be calculated.

For example, the channel signal calculator 140 may perform the 7.1-channel audio signal 1120 based on the LS signals, the LB channels, and the TC channels of the 10.2 channel audio signals 1110 as shown in Table 1 and FIG. 11. The channel signal of the LS channel can be calculated. In this case, the TC channel of the 10.2 channel audio signal 1110 is a channel located between the LS channel and the RS channel of the 7.1 channel audio signal 920.

을 곱한 값에 기 설정된 상수 c를 곱한 다음 상기 결과 값들을 더하여 7.1채널 오디오 신호(420)의 LS 채널의 최종 채널 신호를 계산할 수 있다. 이때, 10.2채널의 LS채널은 5.1채널의 L채널과 LS채널의 중간에 위치하고 있으나, 10.2채널의 LS채널은 후면으로 판단되는 사이드 채널이므로 채널 신호 계산부(140)는 10.2채널의 LS채널를 L채널에 분배하지 않고, 5.1 채널의 후면에 위치한 LS채널로만 인가할 수 있다.In detail, the channel signal calculator 140 multiplies the LS channel of the 10.2 channel audio signal 910, which is a channel located on the same plane as the user, and the LB channel by a predetermined constant a, and has a height and is an LS channel and an RS channel. To the channel signal of the TC channel, which is the channel between

The final channel signal of the LS channel of the 7.1 channel audio signal 420 may be calculated by multiplying the multiplied value by a predetermined constant c and then adding the resultant values. At this time, the LS channel of the 10.2 channel is located between the L channel of the 5.1 channel and the LS channel. However, since the LS channel of the 10.2 channel is a side channel determined to be the rear side, the channel signal calculator 140 converts the LS channel of the 10.2 channel into the L channel. It can be applied only to the LS channel located at the rear of the 5.1 channel without distributing to.

In addition, since the RS channel has a symmetrical output position with respect to the LS channel, the channel signal calculation unit 140 performs the RS channel and the RB of the 10.2 channel audio signal 1110, which is a channel in which the output positions are symmetrical with the channels used for the LB channel. The channel signal of the RS channel of the 7.1 channel audio signal 420 may be calculated using the channel signals of the channel and the TC channel.

When the multi-channel audio conversion system according to an embodiment of the present invention converts the input 10.2 channel audio signal into a 2.0 channel audio signal, the channel signal calculation unit 140 uses a signal for each channel of the 2.0 channel using Table 4 Can be calculated.

For example, as shown in Table 1 and FIG. 12, the channel signal calculator 140 may convert channel signals of L, C, LH, LS, LB, and TC channels among the 10.2 channel audio signals 1110. The channel signal of the L channel of the 7.1 channel audio signal 1120 may be calculated on the basis of this. In this case, the channel signal calculator 140 may forward the sound of the rear channel as compared to the magnitude of the output of which the sound of the front channel is mapped to the front. The channel signal can be calculated such that the size of the output mapped to is small.

13 is a flowchart illustrating a multi-channel audio conversion method according to an embodiment of the present invention.

In operation S1310, the output position checking unit 110 may check an output position for each channel of the output multichannel audio signal and the input multichannel audio signal.

In operation S1320, the output position checking unit 110 may determine whether there is a channel having the same output position for each channel among the output multichannel audio signal and the input multichannel audio signal. In this case, a channel of an input multi-audio signal having the same output position for each channel may be referred to as an input channel, and a channel of an output multi-audio signal having the same output position for each channel may be referred to as an output channel. If there is no channel having the same output position for each channel among the output multichannel audio signal and the input multichannel audio signal, in step S1330, the signal allocator 120 allocates the channel signal of the input channel to the channel at the same position. Can be. That is, when there is an input channel and an output channel among the output multichannel audio signal and the input multichannel audio signal, the signal allocator 120 may allocate a channel signal of the input channel to the output channel in step S1330. On the contrary, if there is no channel having the same output position for each channel among the output multichannel audio signal and the input multichannel audio signal, in step S1340, the signal distributor 130 outputs the closest to the channel of the corresponding input multichannel audio signal. Two channels of a multichannel audio signal can be identified.

In operation S1350, the signal distributor 130 may distribute a channel signal of the corresponding input multichannel audio signal to the adjacent channels identified in operation S1340.

In operation S1360, the channel signal calculator 140 may calculate an output for each channel of the output audio signal based on the channel signal allocated in operation S1330 or the channel signal distributed in operation S1350.

In detail, the channel signal calculator 140 may calculate an output for each channel of the output audio signal using Tables 1 to 4.

The present invention can increase the compatibility of the 10.2 channel audio signal by converting the 10.2 channel audio signal, which can provide a sound field similar to the 22.2 channel using less speakers than the 22.2 channel, to another multi-channel audio signal.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

110: channel positioning unit
120: signal allocation unit
130: signal distribution unit
140: channel signal calculator

Claims (16)

An output position checking unit for checking an output position for each channel of the output multichannel audio signal and the input multichannel audio signal;
Channel signal calculator to calculate the channel-specific signal of the output multi-channel audio signal
Including,
One of the input multichannel audio signal or output multichannel audio signal corresponds to a speaker configuration of a 10.2 channel audio signal,
The 10.2 channel audio signal,
The speaker is provided through a speaker corresponding to an upper layer, a speaker corresponding to a middle layer, and a speaker corresponding to a bottom layer.
The upper layer,
LH, Left Height / Right Height (RH) channel disposed between 30 ° to 45 °, including a Top Center (TC) channel above the user,
The middle layer,
The C / Center channel in the front center of the user, the L / R (Left / Right) channel in which the output position is disposed at the front ± 30 ° position of the user, and the LS / in which the output position is disposed at the ± 90 ° position of the user. A Left Side / Right Side (RS) channel, and a Left Back / Right Back (LB / RB) channel with an output location at a user's 150 ° position,
The bottom layer includes two LFE channels,
When the input multi-channel audio signal is 22.2 channels, a forward left (FL) channel, a forward left center (FLc) channel, a bottom forward left (BtFL) channel, a forward right center (FR) channel, a forward right center (FRc) channel, Bottom Forward Right (BtFR), Forward Center (FC) Channel, Forward Left Center (FLc) Channel, Bottom Forword Center (BtFC) Top Forword Left (TpFL) and Top Forword Center (TPp) Channel, Top Forword Right (TpFR) ) Channel, TpSiL Channel, SiL Channel, TpSiR Channel, SiR Channel, TopBackwardLeft Channel A multi-channel audio conversion system for outputting a 10.2-channel output multichannel audio signal based on. delete delete delete delete The method of claim 1,
The channel signal calculator,
When the input multi-channel audio signal is a 22.2 channel audio signal, the overall sound level of the output multi-channel audio signal is adjusted by multiplying a specific constant for each of the upper layer, the middle layer, the bottom layer, and the subwoofer channel. Multi channel audio conversion system. The method of claim 1,
The channel signal calculator,
When the input multi-channel audio signal is a 10.2 channel audio signal, adjusting the overall sound level of the output multi-channel audio signal by multiplying a predetermined constant for each channel and subwoofer channel having a height on a plane, a channel having a height, and a subwoofer channel. A multi-channel audio conversion system. delete Identifying an output position for each channel of the output multichannel audio signal and the input multichannel audio signal;
Computing the channel-specific signal of the output multichannel audio signal
Including,
One of the input multichannel audio signal or output multichannel audio signal corresponds to a speaker configuration of a 10.2 channel audio signal,
The 10.2 channel audio signal,
The speaker is provided through a speaker corresponding to an upper layer, a speaker corresponding to a middle layer, and a speaker corresponding to a bottom layer.
The upper layer,
LH, Left Height / Right Height (RH) channel disposed between 30 ° to 45 °, including a Top Center (TC) channel above the user,
The middle layer,
The C / Center channel in the front center of the user, the L / R (Left / Right) channel in which the output position is respectively disposed at a ± 30 ° position in front of the user, and the LS / having the output position at a ± 90 ° position in the user. A Left Side / Right Side (RS) channel, and a Left Back / Right Back (LB / RB) channel with an output location at a user's 150 ° position,
The bottom layer includes two LFE channels,
When the input multi-channel audio signal is 22.2 channels, a forward left (FL) channel, a forward left center (FLc) channel, a bottom forward left (BtFL) channel, a forward right center (FR) channel, a forward right center (FRc) channel, Bottom Forward Right (BtFR), Forward Center (FC) Channel, Forward Left Center (FLc) Channel, Bottom Forword Center (BtFC) Top Forword Left (TpFL) and Top Forword Center (TPp) Channel, Top Forword Right (TpFR) ) Channel, TpSiL Channel, SiL Channel, TpSiR Channel, SiR Channel, TopBackwardLeft Channel A multi-channel audio conversion method for outputting a 10.2-channel output multichannel audio signal based on. delete delete delete delete The method of claim 9,
Computing the signal for each channel,
When the input multi-channel audio signal is a 22.2 channel audio signal, the overall sound level of the output multi-channel audio signal is adjusted by multiplying a specific constant for each of the upper layer, the middle layer, the bottom layer, and the subwoofer channel. Multi channel audio conversion method. The method of claim 9,
Computing the signal for each channel,
When the input multi-channel audio signal is a 10.2 channel audio signal, adjusting the overall sound level of the output multi-channel audio signal by multiplying a predetermined constant for each channel and subwoofer channel having a height on a plane, a channel having a height, and a subwoofer channel. A multi-channel audio conversion method. delete

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