JP2007057584A - Audio apparatus and sound effect setting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shorten a muting time when rewriting data by shortening a rewriting time of sound effect data in the case that the sound effect data is changed due to variation in encode setting of an audio signal. <P>SOLUTION: When the sound effect is changed by user operation, a setting means 44 makes a sound effect data storage means 32 store two or more sound effect data therein, which are sound effect data specifying characteristics of the changed sound effect and correspond to two or more predetermined encode settings. Then, a sound effect means 31 provides the audio signal with the sound effect based on the sound effect data in accordance with the encode setting of the audio signal detected by the encode setting means 11, 12, among the two or more sound effect data in the sound effect data storage means 32. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an audio device and a sound effect setting method.

  There is SPDIF (Sony / Philips Digital Interface Format) as an interface between digital audio devices. There are several sampling frequencies such as 32 kHz and 44.1 kHz, and several audio channels such as 2 channels and 5.1 channels in the encoding setting of audio signals transmitted and received as SPDIF signals in SPDIF. Then, digital audio signals compressed by various encoding methods such as AC3 (Audio Code number 3) and dts (digital theater system) are carried. The SPDIF signal is transmitted and received between a DIT (Digital Interface Transmitter) and a DIR (Digital Interface Receiver). A digital audio signal compressed by various methods included in the SPDIF signal is decoded by a multi-channel reproduction device, and a PCM (Pulse Code Modulation) audio signal of each channel is reproduced.

  FIG. 10 is a block diagram showing a configuration of a multi-channel playback device as a conventional audio device. In the apparatus shown in FIG. 10, the SPDIF signal is received by the DIR 201 as an input signal. The DIR 201 extracts a clock and data (encoded digital audio signal) from the SPDIF signal and outputs them. Next, the multi-channel decoder 202 decodes the data and reproduces the PCM audio signal. At that time, if the encoded digital audio signal includes an audio signal of two channels, PCM audio signals for two channels of L (Left) channel and R (Right) channel are reproduced and encoded digital audio. When a 5.1 channel audio signal is included in the signal, there are 6 channels of L channel, R channel, Ls (Surround Left) channel, Rs (Surround Right) channel, C (Center) channel and LFE (Low Frequency) channel. PCM audio signals are reproduced.

  The digital signal processor (DSP) 203 performs sound effect processing on the PCM audio signals of a plurality of channels reproduced by the multi-channel decoder 202, and outputs the processed PCM audio signal. In the DSP 203, the sound effect processing is performed by the sound effect unit 231 with the filter characteristics based on the coefficient values stored in the coefficient RAM 232.

  The coefficient value of the coefficient RAM 232 is set by the control unit 204 configured by, for example, a microcomputer. In the control unit 204, the sampling frequency acquiring unit 241 acquires the sampling frequency of the audio signal detected by the sampling frequency detecting unit 211 of the DIR 201, and the audio channel number acquiring unit 242 is the audio channel number output unit of the multichannel decoder 202. 221 acquires the number of audio channels of the audio signal detected by the H.221, the UI unit 243 specifies the acoustic effect to be applied by the DSP 203 based on a user operation on an operation unit (not shown), and the coefficient setting unit 244 uses the UI unit 243. A coefficient value for designating the specified acoustic effect, a coefficient value corresponding to the sampling frequency acquired by the sampling frequency acquisition unit 241 or a coefficient value corresponding to the number of audio channels acquired by the audio channel number acquisition unit 242 Select and engage the DSP 203 Set to RAM232.

  Therefore, when the switching of the sound effect by the user operation is detected by the UI unit 243, and the change of the sampling frequency of the audio signal is detected by the sampling frequency acquisition unit 241, or the change of the number of audio channels of the audio signal is acquired. When detected by the unit 242, the coefficient setting unit 244 of the control unit 204 selects a new coefficient value each time, writes it in the coefficient RAM 232 of the DSP 203, and updates the coefficient value in the DSP 203. In the DSP 203, when the coefficient value in the coefficient RAM 232 is updated, the sound effect unit 231 applies the sound effect to the audio signal with the updated coefficient value. During the rewriting of the coefficient values in the DSP 203, since a certain acoustic effect cannot be obtained, the output of the DSP 203 is muted.

  In this way, the coefficient value of the acoustic effect in the DSP 203 is updated according to the user operation and the audio signal encoding setting.

  In FIG. 10, for simplicity of explanation, only one acoustic effect unit 231 and one coefficient RAM 232 are shown, but the DSP 203 is often provided with a plurality of acoustic effect units. FIG. 11 is a block diagram showing a DSP 203 having a plurality of sound effect units 231-1 to 231 -N.

  In the DSP 203 shown in FIG. 11, a plurality of sound effect units 231-1 to 231 -N are connected in cascade, and a coefficient RAM 232-i for each sound effect unit 231-i (i = 1,..., N). The interface unit 233 transmits and receives coefficient values to and from the control unit 204.

  When the DSP 203 includes a plurality of sound effect units 231-1 to 231 -N as shown in FIG. 11, when the coefficient value of the sound effect in the DSP 203 is changed due to a user operation, 1 or Only the coefficient values of the coefficient RAM 232-i corresponding to the plurality of sound effect units 231-i are rewritten by the control unit 204, and the coefficient value of the sound effect in the DSP 203 is changed due to the change in the encoding setting of the audio signal. Sometimes, the coefficient values of the coefficient RAMs 232-1 to 232-N corresponding to all the sound effect units 231-1 to 231-N are rewritten by the control unit 204. When the coefficient value of the acoustic effect in the DSP 203 is changed due to a change in the encoding setting of the audio signal, the filter configuration of the acoustic effect unit 231-i changes for each sampling frequency and the number of audio channels. It is necessary to rewrite the coefficient values of the coefficient RAMs 232-1 to 232-N.

  An example of an equalizer using a DSP and an example in which the characteristics of the equalizer of the DSP are changed by a CPU or the like are disclosed in Patent Documents 1 and 2, for example.

JP-A-62-179211 (Detailed description of the invention) JP-A-3-28899 (Example column)

  When the coefficient value of the sound effect in the DSP is changed due to a user operation, only the coefficient value of the coefficient RAM corresponding to one or a plurality of sound effect parts related to the change is rewritten. The mute time is not long. Also, since muting occurs due to user operations, it is difficult for the user to feel uncomfortable with muting.

  On the other hand, when the coefficient value of the acoustic effect in the DSP is changed due to a change in the encoding setting of the audio signal, it is necessary to rewrite the coefficient value of the coefficient RAM corresponding to all the acoustic effect units. Mute time during rewriting becomes longer. In this case, since the mute is not caused by a user operation, the user is likely to feel uncomfortable with the mute. Furthermore, when the output device (for example, a DVD player) that outputs the SPDIF signal and the multi-channel playback device shown in FIG. 10 are separate devices, the output device determines whether the multi-channel playback device performs the mute period. It is difficult to wait for signal output, and an unintended mute is applied to the start of music.

  The present invention has been made in view of the above problems, and the rewriting time of sound effect data when sound effect data (for example, the above-described coefficient value) is changed due to a change in the encoding setting of an audio signal. It is an object of the present invention to obtain an audio device and a sound effect setting method that can be shortened to shorten the mute time at the time of data rewriting.

  In order to solve the above problems, the present invention is configured as follows.

  An audio apparatus according to the present invention includes an acoustic effect data storage unit that stores a plurality of acoustic effect data that specifies characteristics of an acoustic effect to be applied to an audio signal, and a user operation detection unit that detects a user operation on a predetermined operation unit. When the sound effect is changed by the user operation detected by the user operation detecting means, the sound effect data for specifying the characteristic of the sound effect after the change, and a plurality of predetermined encoding settings that can be set for the audio signal Among the plurality of sound effect data in the sound effect data storage means, the setting means for storing the sound effect data corresponding to the sound effect data storage means, the encoding setting detection means for detecting the encoding setting of the audio signal, Sound according to the encoding setting of the audio signal detected by the encoding setting detection means Based on the effect data, and a sound effect means for applying sound effects to the audio signal.

  In addition to the above audio device, the audio device according to the present invention may be configured as follows. That is, in this case, when the sound effect is changed by the user operation detected by the user operation detection unit, the setting unit is sound effect data that specifies the characteristic of the sound effect after the change, and is set for the audio signal. A plurality of sound effect data corresponding to a plurality of possible predetermined sampling frequencies are stored in the sound effect data storage means. The encoding setting detection means detects the sampling frequency of the audio signal. The sound effect means applies the sound effect to the audio signal based on the sound effect data corresponding to the sampling frequency detected by the encoding setting detection means among the plurality of sound effect data in the sound effect data storage means.

  The audio apparatus according to the present invention may be as follows in addition to any of the above audio apparatuses. That is, in this case, when the sound effect is changed by the user operation detected by the user operation detection unit, the setting unit is sound effect data that specifies the characteristic of the sound effect after the change, and is set for the audio signal. A plurality of sound effect data corresponding to a predetermined number of possible sound channels is stored in the sound effect data storage means. The encoding setting detection means detects the number of audio channels of the audio signal. The sound effect means applies the sound effect to the audio signal based on the sound effect data corresponding to the number of sound channels detected by the encoding setting detection means among the plurality of sound effect data in the sound effect data storage means.

  The audio apparatus according to the present invention may be as follows in addition to any of the above audio apparatuses. That is, in that case, the sound effect means corresponds to the changed encoding setting of the plurality of sound effect data in the sound effect data storage means when the encoding setting of the audio signal detected by the encoding setting detection means changes. The sound effect is applied to the audio signal based on the sound effect data.

  The audio apparatus according to the present invention may be as follows in addition to any of the above audio apparatuses. That is, in that case, the sound effect means has a plurality of sound effect sections that apply a plurality of sound effects to the same audio signal, and the sound effect data storage means is provided corresponding to the plurality of sound effect sections, respectively. A plurality of memories for storing sound effect data corresponding to. In addition, when the sound effect is changed by the user operation detected by the user operation detection unit, the setting unit may store a predetermined number of memories only in a part of the memory corresponding to the sound effect unit that needs to change the sound effect data. A plurality of sound effect data corresponding to the encoding setting is stored. Then, all the sound effect units of the sound effect means perform audio based on the sound effect data corresponding to the encoding setting of the audio signal detected by the encoding setting detection means among the plurality of sound effect data in the memory corresponding to the sound effect means. Apply an acoustic effect to the signal.

  The audio apparatus according to the present invention may be as follows in addition to any of the above audio apparatuses. That is, in this case, the sound effect data storage means is a memory in a certain digital signal processor, and the sound effect means is an arithmetic processing unit in the digital signal processor. The digital signal processor has an interface for receiving sound effect data from an external setting means.

  The audio apparatus according to the present invention may be as follows in addition to any of the above audio apparatuses. That is, in that case, the sound effect data storage means stores a plurality of sound effect data in a series of storage areas. Then, the sound effect means specifies the offset value of the address according to the encoding setting of the audio signal detected by the encode setting detection means, and the sound effect data is obtained from the address obtained by adding the offset value to the start address of the series of storage areas. Read out and apply an acoustic effect to the audio signal.

  The sound effect setting method according to the present invention includes a step of detecting a user operation on a predetermined operation unit, and sound effect data for designating characteristics of the sound effect after the change when the sound effect is changed by the detected user operation. A step of storing a plurality of sound effect data corresponding to a plurality of predetermined encoding settings that can be set for the audio signal in a predetermined sound effect data storage means, a step of detecting the encoding setting of the audio signal, a predetermined Selecting sound effect data corresponding to the detected audio signal encoding setting from a plurality of sound effect data in the sound effect data storage means, and applying a sound effect to the audio signal based on the selected sound effect data Prepare.

  According to the present invention, it is possible to shorten the mute time at the time of data rewriting by shortening the rewriting time of the sound effect data when the sound effect data is changed due to the change in the encoding setting of the audio signal.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of a multi-channel playback device as an audio device according to Embodiment 1 of the present invention. In FIG. 1, DIR1 is a receiving device that receives an SPDIF signal, extracts a digital audio signal encoded from the SPDIF signal and a clock, and outputs the extracted signal. The sampling frequency detection unit 11 in the DIR 1 is a part that functions as an encoding setting detection unit that detects the sampling frequency of the PCM audio signal included in the SPDIF signal.

  The multi-channel decoder 2 is a device that decodes an audio signal encoded by a predetermined method such as AC3 or dts, and outputs a PCM audio signal having the number of audio channels corresponding to the method. The audio channel number detection unit 21 in the multi-channel decoder 2 is a part that functions as an encoding setting detection unit that detects the number of audio channels of the PCM audio signal to be decoded. The audio channel number output unit 22 is a part for outputting the audio channel number as audio channel information.

  The DSP 3 is a processing device that applies a sound effect to a PCM audio signal having a predetermined number of audio channels by filtering.

  The sound effect unit 31 in the DSP 3 sets the audio signal encoding setting (sampling frequency or number of sound channels) detected by the sampling frequency detection unit 11 or the sound channel number detection unit 21 among the plurality of sound effect data in the coefficient RAM 32. It is a processing unit that functions as sound effect means for applying sound effects to audio signals based on the corresponding sound effect data. In the first embodiment, the sound effect unit 31 includes a digital filter, and uses a set of coefficient values of the filter as sound effect data.

  The coefficient RAM 32 in the DSP 3 is a memory that functions as a sound effect data storage unit that stores a plurality of sound effect data for designating characteristics of sound effects to be applied to the audio signal. In the first embodiment, the coefficient RAM 32 stores a set of filter coefficient values of the digital filter of the sound effect unit 31 as sound effect data.

  The coefficient selection unit 33 in the DSP 3 is a processing unit that selects one of a plurality of sound effect data stored in the coefficient RAM 32 as sound effect data used by the sound effect unit 31.

  The sound effect unit 31 and the coefficient selection unit 33 are realized by an arithmetic processor (not shown) in the DSP 3.

  The control unit 4 is a device that writes coefficient values as sound effect data in the coefficient RAM 32 of the DSP 3. The control unit 4 is composed of a recording medium such as a ROM storing a microcomputer and a program executed by the microcomputer. Various functions of the control unit 4 (a sampling frequency acquisition unit 41, a sampling frequency output unit 42, a UI unit 43, a coefficient setting unit 44, etc., which will be described later) are realized by the microcomputer executing the program in the recording medium. .

  The sampling frequency acquisition unit 41 in the control unit 4 is a processing unit that acquires the sampling frequency of the audio signal detected by the sampling frequency detection unit 11 of the DIR1, and the sampling frequency output unit 42 in the control unit 4 is a sampling frequency acquisition unit. 41 is a processing unit that outputs the sampling frequency acquired by 41.

  The UI unit 43 in the control unit 4 is a processing unit that functions as a user operation detection unit that electrically detects a user operation on a predetermined operation unit (key switch, remote controller, etc.) (not shown). Further, the UI unit 43 determines whether or not the detected user operation is an operation for selecting or switching sound effects.

  The coefficient setting unit 44 in the control unit 4 is acoustic effect data that specifies the characteristics of the changed acoustic effect when the acoustic effect is changed by a user operation detected by the UI unit 43, and is an audio signal. Is a processing unit as setting means for storing a plurality of sound effect data (here, a plurality of coefficient value sets) corresponding to a plurality of predetermined encoding settings that can be set for the coefficient RAM 32.

  FIG. 2 is a block diagram showing in detail the DSP 3 in the first embodiment. In FIG. 1, one acoustic effect unit 31, one coefficient RAM 32, and one coefficient selection unit 33 are shown. However, as shown in FIG. 2, there may be a plurality of acoustic effect units 31, coefficient RAM 32, and coefficient selection units 33. .

  The acoustic effect unit 31-i (i = 1,..., N, N ≧ 1) is the same as the above-described acoustic effect unit 31 and provides a certain acoustic effect. The N sound effect units 31-1 to 31-N are connected in cascade, and apply N types of sound effects to the same audio signal.

  The coefficient RAM 32-i (i = 1,..., N, N ≧ 1) is provided in association with the sound effect unit 31-i, and a plurality of sound effects used for the sound effect unit 31-i. A memory for storing data. Each sound effect data is stored in one coefficient storage unit 61. In the first embodiment, one sound effect data is a set of filter coefficient values. The N coefficient RAMs 32-1 to 32-N may be N storage areas provided in one memory element, or may be N memory elements. Various RAMs are used as such memory elements. Each coefficient storage unit 61 is realized as a predetermined storage area of the coefficient RAM 32-i.

  Further, the coefficient selection unit 33-i (i = 1,..., N, N ≧ 1) converts one of the plurality of sound effect data stored in the coefficient RAM 32-i into the sound effect unit 31. -I is a processing unit that is selected as sound effect data used by i. The coefficient selection unit 33-i selects one of the acoustic effect data for the acoustic effect unit 31-i based on the audio channel information 71 or the sampling frequency information 72 in the encoding setting information storage unit 35.

  The interface unit 34 is a communication processing unit as an interface for receiving sound effect data from the external control unit 4.

  The encoding setting information storage unit 35 is a memory that stores audio channel information 71 and sampling frequency information 72 supplied from the outside via the interface unit 34. The encode setting information storage unit 35 may be a single memory element or a storage area in the same memory element as the coefficient RAM 32-i. Various RAMs are used as such memory elements.

  Next, the operation of the above apparatus will be described.

  First, the operation of the apparatus when a change in acoustic effect by a user operation occurs will be described. FIG. 3 is a flowchart for explaining the operation of the apparatus when a change in acoustic effect by a user operation occurs in the first embodiment.

  When the UI unit 43 of the control unit 4 electrically detects a user operation on a predetermined operation unit and determines that the detected user operation is a selection or switching operation of the acoustic effect, the selection or switching of the acoustic effect occurs. The notification indicating that it has been performed and the sound effect type information indicating the type of sound effect designated by the user operation are supplied to the coefficient setting unit 44 (step S1).

  The coefficient setting unit 44 of the control unit 4 includes a plurality of sound effect data (here, coefficient value sets) for each sound setting stored in advance in a non-volatile storage unit such as a ROM (not shown) for each sound effect. A plurality of sound effect data for each encoding setting corresponding to the sound effect type information supplied from the UI unit 43 is selected, and a sound effect unit 31-i that is not used in the DSP 3 or a sound effect unit 31-i that is not used after switching. Are written into a part of the coefficient RAMs 32-i corresponding to 1 through the interface unit 34 (step S2). Each acoustic effect data is stored in one coefficient storage unit 61. The coefficient setting unit 44 stores information on the correspondence between the sound effect unit 31-i and the coefficient RAM 32-i of the DSP 3 and the types of sound effects assigned to the sound effect unit 31-i and the coefficient RAM 32-i. Based on the stored information, the coefficient RAM 32-i for writing the sound effect data is specified.

  Thereafter, when an audio signal is supplied to the device as an SPDIF signal, it is received by DIR1. At that time, the sampling frequency detection unit 11 of the DIR 1 detects the sampling frequency of the audio signal and supplies it to the DSP 3 via the sampling frequency acquisition unit 41 and the sampling frequency output unit 42 of the control unit 4 (step S3). In the DSP 3, the sampling frequency information 72 is stored in the encoding setting information storage unit 35.

  A digital audio signal of a predetermined system output from the DIR 1 is decoded into a PCM audio signal by the multi-channel decoder 2. At that time, the number of audio channels of the audio signal is detected by the audio channel number detection unit 21 of the multi-channel decoder 2 and supplied to the DSP 3 by the audio channel number output unit 22. In the DSP 3, the audio channel information 71 is stored in the encoding setting information storage unit 35 (step S3).

  The DSP 3 applies an acoustic effect to the PCM audio signal. At that time, each coefficient selection unit 33-i refers to the audio channel information 71 and / or sampling frequency information 72 in the encoding setting information storage unit 35, and the sound corresponding to the audio channel information 71 and / or sampling frequency information 72. The effect data, that is, the coefficient storage unit 61 is selected (step S4). Each sound effect unit 31-i applies a sound effect to the PCM audio signal based on the sound effect data in the coefficient storage unit 61 selected by the coefficient selection unit 33-i. This acoustic effect includes sound field effects such as a surround effect in addition to equalization of frequency characteristics.

  As described above, when the sound effect is changed by the user operation, the sound effect data for all the encoding settings in a part of the coefficient RAMs 32-i is rewritten by the control unit 4, and then the encoding setting of the audio signal is performed. The corresponding sound effect data is selected, and the sound effect is applied with the sound effect data.

  Next, the operation of the apparatus when the audio signal encoding setting is changed will be described. FIG. 4 is a flowchart for explaining the operation of the apparatus when the audio signal encoding setting is changed in the first embodiment.

  Each coefficient selection unit 33-i of the DSP 3 refers to the audio channel information 71 and / or the sampling frequency information 72 supplied from the DIR1 and the multichannel decoder 2, and monitors the number of audio channels and / or the sampling frequency (step S11). ).

  And each coefficient selection part 33-i will switch the acoustic effect data used by the acoustic effect part 31-i, if the change of the number of audio channels and / or a sampling frequency is detected (step S12).

  As described above, when the sound effect is changed by the user operation as described above, the sound effect data in the coefficient RAM 32-i is rewritten by the control unit 4, but when the encoding setting of the audio signal is changed. The acoustic effect data used by the acoustic effect unit 31-i is switched by the coefficient selection unit 33-i in the DSP 3 without rewriting the acoustic effect data in the coefficient RAM 32-i by the control unit 4.

  As described above, according to the first embodiment, when the sound effect is changed by the user operation detected by the UI unit 43, the coefficient setting unit 44 of the control unit 4 changes the characteristics of the sound effect after the change. And a plurality of sound effect data corresponding to a plurality of predetermined encoding settings that can be set for the audio signal are stored in the coefficient RAMs 32 and 32-i of the DSP 3. The sound effect units 31 and 31-i of the DSP 3 encode the audio signals detected by the sampling frequency detection unit 11 and the audio channel number detection unit 21 among the plurality of sound effect data in the coefficient RAMs 32 and 32-i. The sound effect is applied to the audio signal based on the sound effect data corresponding to the setting.

  As a result, when the sound effect is changed by a user operation, a plurality of sound effect data corresponding to all the encoding settings that can be supported by the processing unit preceding the DSP 3 such as the multi-channel decoder 2 are collectively rewritten, and the audio When the signal encoding setting changes, it is only necessary to select the appropriate sound effect data without rewriting the sound effect data, so the sound effect data changes due to the change in the audio signal encoding setting. In this case, the sound effect data rewriting time can be shortened to shorten the mute time during data rewriting.

  Further, according to the first embodiment, the plurality of sound effect units 31-1 to 31-N apply the plurality of sound effects to the same audio signal. The plurality of coefficient RAMs 32-1 to 32-N are provided corresponding to the plurality of sound effect units 31-1 to 31-N, and store sound effect data corresponding to each. The coefficient setting unit 44 of the control unit 4 is a part corresponding to the sound effect unit 31-i that needs to change the sound effect data when the sound effect is changed by the user operation detected by the UI unit 43. A plurality of sound effect data corresponding to a plurality of predetermined encoding settings are written only in the coefficient RAM 32-i. All the sound effect units 31-i encode the audio signals detected by the sampling frequency detection unit 11 and the sound channel number detection unit 21 among the plurality of sound effect data in the coefficient RAM 32-i corresponding to the sound effect units 31-i. The sound effect is applied to the audio signal based on the sound effect data corresponding to the setting.

  Thereby, since the acoustic effect data used by the plurality of acoustic effect units 31-1 to 31-N can be switched without rewriting the acoustic effect data, particularly when there are a plurality of acoustic effect units. The rewriting time of the sound effect data can be shortened.

Embodiment 2. FIG.
The multi-channel playback device as an audio device according to Embodiment 2 of the present invention is the same as the multi-channel playback device of Embodiment 1, except that the coefficient values are stored in the coefficient storage unit 61 of the coefficient RAMs 32-1 to 32-N. The switching of the sound effect data by the coefficient selectors 33-1 to 33-N is performed as follows.

  Note that the configuration and operation of the apparatus according to the second embodiment are basically the same as the configuration and operation of the apparatus according to the first embodiment, and a description thereof will be omitted. However, the coefficient RAMs 32-1 to 32-N and the coefficient selectors 33-1 to 33-N function as follows.

  FIG. 5 is a diagram illustrating an example of a method of storing a plurality of coefficient value sets in one coefficient RAM 32-p (p = 1,..., N) in the second embodiment. As shown in FIG. 5, one coefficient value set is stored in one coefficient storage unit 61. This coefficient value set has L coefficient values for coefficients # 1 to #L. In the second embodiment, one coefficient value is stored in a one-word storage area, and the storage area for one coefficient value set, that is, the size of one coefficient storage unit 61 is L words. In FIG. 5, a coefficient value set for audio signals with a sampling frequency of 32 kHz is stored in a storage area (a coefficient storage unit 61) of addresses A to A + L, and the relationship for audio signals with a sampling frequency of 44.1 kHz is stored. The numerical value set is stored in the storage area (another coefficient storage unit 61) of addresses B to B + L.

  FIG. 6 is a diagram illustrating an example of a method of storing a plurality of coefficient value sets in one coefficient RAM 32-q (q = 1,..., N) in the second embodiment. As shown in FIG. 6, one coefficient value set is stored in one coefficient storage unit 61. This coefficient value set has M coefficient values for coefficients # 1 to #M. In the second embodiment, one coefficient value is stored in a 1-word storage area, and the storage area for one coefficient value set, that is, the size of one coefficient storage unit 61 is M words. In FIG. 6, a coefficient value set for an audio signal having two audio channels is stored in a storage area (a certain coefficient storage unit 61) of addresses X to X + M, and for an audio signal having an audio channel of 5.1 channels. Are stored in a storage area (another coefficient storage unit 61) at addresses Y to Y + M.

  Next, the operation of the above apparatus will be described.

  FIG. 7 is a flowchart for explaining the operation of the coefficient selection unit 33-p when the coefficient value set is switched according to the sampling frequency in the second embodiment. As shown in FIG. 5, the coefficient selection unit 33-p corresponding to the coefficient RAM 32-p in which the coefficient value set is stored first specifies the head address (fixed address) of the head coefficient storage unit 61 in the coefficient RAM 32-p. When the sampling frequency information 72 is updated (step S21), the sampling frequency information 72 is acquired (step S22), and an address offset value corresponding to the sampling frequency of the audio signal is specified (step S23). Then, the coefficient selection unit 33-p indicates the address obtained by adding the address offset value to the head address of the head coefficient storage unit 61, and indicates the head address of the coefficient value set corresponding to the changed sampling frequency. The coefficient head address is set (step S24).

  For example, when the coefficient set is stored in the coefficient RAM 32-p as shown in FIG. 5, the leading address of the leading coefficient storage unit 61 is specified as “A”, and the changed sampling frequency is 44.1 kHz. In this case, (B−A) is selected as the address offset value, and the coefficient head address is “B”. The correspondence relationship between the sampling frequency and the address offset value is stored in advance in the DSP 3 as a table or the like and is referred to by the coefficient selection unit 33-p.

  Then, the sound effect unit 31-p reads out the L coefficient values in order from the coefficient head address set by the coefficient selection unit 33-p, and outputs the sound to the PCM audio signal using a digital filter based on the L coefficient values. Apply effect.

  FIG. 8 is a flowchart for explaining the operation of the coefficient selector 33-q when the coefficient value set is switched according to the number of audio channels in the second embodiment. As shown in FIG. 6, the coefficient selection unit 33-q corresponding to the coefficient RAM 32-q in which the coefficient value set is stored first identifies the head address (fixed address) of the head coefficient storage unit 61 in the coefficient RAM 32-q. When the audio channel information 71 is updated (step S31), the audio channel information 71 is acquired (step S32), and an address offset value corresponding to the number of audio channels of the audio signal is specified (step S33). Then, the coefficient selection unit 33-q uses the address obtained by adding the address offset value to the head address of the head coefficient storage unit 61, and the head address of the coefficient value set corresponding to the number of audio channels after the change. The coefficient start address shown is set (step S34).

  For example, when the coefficient set is stored in the coefficient RAM 32-q as shown in FIG. 6, the leading address of the leading coefficient storage unit 61 is specified as “X”, and the changed sampling frequency is 5.1 channels. If there is, (Y−X) is selected as the address offset value, and the coefficient head address is “Y”. The correspondence relationship between the number of audio channels and the address offset value is stored in advance in the DSP 3 as a table or the like and is referred to by the coefficient selection unit 33-q.

  Then, the sound effect unit 31-q reads out the M coefficient values in order from the coefficient head address set by the coefficient selection unit 33-q, and outputs the sound to the PCM audio signal using a digital filter based on the M coefficient values. Apply effect.

  As described above, according to the second embodiment, the coefficient RAMs 32-p and 32-q store a plurality of sound effect data in the series of coefficient storage units 61. Then, the acoustic effect units 31-p and 31-q specify an address offset according to the encoding setting of the audio signal detected by the sampling frequency detection unit 11 and the audio channel number detection unit 21, and the leading coefficient storage unit The sound effect data is read from the address obtained by adding the offset to the head address of 61, and the sound effect is applied to the audio signal.

  As a result, the sound effect data used for the sound effect can be switched by simply calculating the address from which the sound effect data (coefficient value set) is read out. The effect data can be switched in a short time.

Embodiment 3 FIG.
A multi-channel playback device as an audio device according to Embodiment 3 of the present invention is a case where the input audio signal is not a SPDIF signal but a data stream of a digital audio signal of a predetermined encoding method.

  FIG. 9 is a block diagram showing a configuration of a multi-channel playback device as an audio device according to Embodiment 3 of the present invention. In FIG. 9, a multi-channel decoder 101 receives a data stream of a digital audio signal encoded by a predetermined method such as AC3, dts, etc., decodes the audio signal, and PCM audio having the number of audio channels corresponding to the method. It is a device that outputs a signal.

  The sampling frequency detection unit 111 in the multi-channel decoder 101 is a part that functions as an encoding setting detection unit that detects the sampling frequency of the audio signal included in the data stream. The sampling frequency output unit 112 is a part that outputs the sampling frequency as sampling frequency information.

  The audio channel number detection unit 113 in the multi-channel decoder 101 is a part that functions as an encoding setting detection unit that detects the number of audio channels of the PCM audio signal to be decoded. The audio channel number output unit 114 is a part that outputs the number of audio channels as audio channel information.

  Similar to the control unit 4, the control unit 102 is a device that writes coefficient values as sound effect data in the coefficient RAM 32 of the DSP 3. The control unit 102 includes a microcomputer and a recording medium such as a ROM that stores a program executed by the microcomputer. And various functions (UI part 121, coefficient setting part 122, etc.) of control part 102 are realized by a microcomputer running a program in the recording medium. The UI unit 121 and the coefficient setting unit 122 in the control unit 4 are processing units similar to the UI unit 43 and the coefficient setting unit 44 in the first embodiment.

  The DSP 3 is the same as that of the first embodiment (FIGS. 1 and 2), and the description thereof is omitted. In the third embodiment, the sampling frequency information and the audio channel information are directly supplied from the multichannel decoder 101 to the DSP 3.

  Next, the operation of the above apparatus will be described.

  First, the operation of the apparatus when a change in acoustic effect by a user operation occurs will be described.

  In Embodiment 3, when the UI unit 121 of the control unit 102 determines that the detected user operation is a selection or switching operation of the acoustic effect, the notification and the acoustic effect indicating that the selection or switching of the acoustic effect has occurred The type information is supplied to the coefficient setting unit 122.

  The coefficient setting unit 122 of the control unit 102 includes a plurality of sound effect data (here, coefficient value sets) for each sound setting stored in advance in a non-volatile storage unit such as a ROM (not shown) for each sound effect. A plurality of sound effect data for each encoding setting corresponding to the sound effect type information supplied from the UI unit 121 is selected, and a sound effect unit 31-i that is not used in the DSP 3 or a sound effect unit 31-i that is not used after switching. Are written into a part of the coefficient RAMs 32-i through the interface unit 34. Each sound effect data is stored in the coefficient storage unit 61.

  Thereafter, when a digital audio signal of a predetermined system is supplied to this apparatus, it is received by the multi-channel decoder 101 and decoded into a PCM audio signal. At that time, the sampling frequency detection unit 111 detects the sampling frequency of the audio signal, the audio channel number detection unit 113 detects the number of audio channels of the audio signal, and these are supplied to the DSP 3. In the DSP 3, the sampling frequency information 72 and the audio channel information 71 are stored in the encoding setting information storage unit 35.

  The DSP 3 selects sound effect data according to the encoding setting, and applies the sound effect to the PCM audio signal with the selected sound effect data.

  As described above, when the sound effect is changed by the user operation, the sound effect data for all the encoding settings in a part of the coefficient RAMs 32-i is rewritten by the control unit 102, and then the encoding setting of the audio signal is performed. The corresponding sound effect data is selected, and the sound effect is applied with the sound effect data.

  Note that the operation of the apparatus when the audio signal encoding setting is changed is the same as in the first or second embodiment, and a description thereof will be omitted.

  As described above, according to the third embodiment, the sound effect data is rewritten when the sound effect data is changed due to the change in the encoding setting of the audio signal, as in the first embodiment. It is possible to shorten the mute time when rewriting data by shortening the time.

  Each embodiment described above is a preferred example of the present invention, but the present invention is not limited to these, and various modifications and changes can be made without departing from the scope of the present invention. It is.

  For example, in each embodiment, as the audio signal encoding setting, the sampling frequency and the number of audio channels are detected, and the sound effect data is switched according to the sampling frequency and / or the number of audio channels. You may make it switch acoustic effect data according to information.

  In the second embodiment, a plurality of sound effect data corresponding to a change in the encoding setting for any one of the sampling frequency and the number of audio channels is stored in one coefficient RAM 32-i. A plurality of sound effect data corresponding to fluctuations in the two encoding settings of the number of channels may be stored in one coefficient RAM 32-i.

  The present invention is applicable to, for example, a multi-channel playback device.

It is a block diagram which shows the structure of the multichannel reproducing | regenerating apparatus as an audio apparatus which concerns on Embodiment 1 of this invention. FIG. 3 is a block diagram showing in detail a DSP in the first embodiment. 3 is a flowchart for explaining the operation of the apparatus when a change in acoustic effect by a user operation occurs in the first embodiment. 6 is a flowchart for explaining the operation of the apparatus when the audio signal encoding setting changes in the first embodiment. FIG. 11 is a diagram illustrating an example of a method for storing a plurality of coefficient value sets in one coefficient RAM in the second embodiment. FIG. 11 is a diagram illustrating an example of a method for storing a plurality of coefficient value sets in one coefficient RAM in the second embodiment. In Embodiment 2, it is a flowchart explaining operation | movement of the coefficient selection part in the case of switching a coefficient value set according to a sampling frequency. 10 is a flowchart for explaining the operation of the coefficient selection unit when the coefficient value set is switched according to the number of audio channels in the second embodiment. It is a block diagram which shows the structure of the multichannel reproducing | regenerating apparatus as an audio apparatus which concerns on Embodiment 3 of this invention. It is a block diagram which shows the structure of the multichannel reproducing | regenerating apparatus as the conventional audio apparatus. It is a block diagram which shows DSP which has a some acoustic effect part.

Explanation of symbols

3 DSP (Digital Signal Processor)
11, 111 Sampling frequency detector (encoding setting detector)
21, 113 Audio channel number detection section (encoding setting detection means)
31, 31-1 to 31-N Sound effect section (sound effect means)
32,32-1 to 32-N coefficient RAM (acoustic effect data storage means)
34 Interface section (interface)
43, 121 UI unit (user operation detection means)
44, 122 Coefficient setting unit (setting means)

Claims (8)

Sound effect data storage means for storing a plurality of sound effect data for designating characteristics of sound effects to be applied to the audio signal;
User operation detection means for detecting a user operation on a predetermined operation unit;
When the sound effect is changed by the user operation detected by the user operation detection means, the sound effect data for specifying the characteristic of the sound effect after the change, and a plurality of predetermined encodings that can be set for the audio signal Setting means for storing a plurality of sound effect data corresponding to the setting in the sound effect data storage means;
Encoding setting detection means for detecting the encoding setting of the audio signal;
A sound for applying a sound effect to the audio signal based on the sound effect data according to the encoding setting of the audio signal detected by the encoding setting detection means among the plurality of sound effect data in the sound effect data storage means. Effect means,
An audio device comprising: The setting means is sound effect data for specifying the characteristics of the changed sound effect when the sound effect is changed by a user operation detected by the user operation detection means, and can be set for the audio signal Storing a plurality of sound effect data corresponding to a plurality of predetermined sampling frequencies in the sound effect data storage means;
The encoding setting detection means detects a sampling frequency of the audio signal,
The sound effect means outputs sound effects to the audio signal based on the sound effect data corresponding to the sampling frequency detected by the encoding setting detection means among the plurality of sound effect data in the sound effect data storage means. Applying,
The audio apparatus according to claim 1. The setting means is sound effect data for specifying the characteristics of the changed sound effect when the sound effect is changed by a user operation detected by the user operation detection means, and can be set for the audio signal A plurality of sound effect data corresponding to a predetermined number of sound channels is stored in the sound effect data storage means;
The encoding setting detection means detects the number of audio channels of the audio signal,
The sound effect means is configured to add sound effects to the audio signal based on the sound effect data according to the number of sound channels detected by the encoding setting detection means among a plurality of sound effect data in the sound effect data storage means. Applying
The audio apparatus according to claim 1.   The sound effect means corresponds to the changed encoding setting of the plurality of sound effect data in the sound effect data storage means when the encoding setting of the audio signal detected by the encoding setting detection means changes. The audio apparatus according to claim 1, wherein a sound effect is applied to the audio signal based on the sound effect data. The sound effect means has a plurality of sound effect units that apply a plurality of sound effects to the same audio signal,
The sound effect data storage means is provided corresponding to the plurality of sound effect units, and has a plurality of memories for storing sound effect data corresponding to each of the sound effect portions,
In the case where the sound effect is changed by the user operation detected by the user operation detection unit, the setting unit is only in a part of the memory corresponding to the sound effect unit that needs to change the sound effect data. Storing a plurality of sound effect data corresponding to the predetermined plurality of encoding settings;
All the sound effect units of the sound effect means have the sound effect according to the encode setting of the audio signal detected by the encode setting detection means among a plurality of sound effect data in the memory corresponding to the sound effect means. Applying an acoustic effect to the audio signal based on the data;
The audio apparatus according to claim 1. The sound effect data storage means is a memory in a digital signal processor,
The sound effect means is an arithmetic processor in the digital signal processor,
The digital signal processor has an interface for receiving the sound effect data from the external setting means;
The audio apparatus according to claim 1, wherein: The sound effect data storage means stores a plurality of the sound effect data in a series of storage areas,
The sound effect means specifies an offset value of an address according to the encoding setting of the audio signal detected by the encoding setting detection means, and starts from the address obtained by adding the offset value to the start address of the series of storage areas. Reading out sound effect data and applying sound effects to the audio signal;
The audio apparatus according to claim 6. Detecting a user operation on a predetermined operation unit;
A plurality of sound effects corresponding to a plurality of predetermined encoding settings that can be set for an audio signal, the sound effect data specifying the characteristics of the sound effect after the change when the sound effect is changed by the detected user operation Storing the data in a predetermined acoustic effect data storage means;
Detecting the encoding setting of the audio signal;
Selecting the sound effect data according to the detected encoding setting of the audio signal from a plurality of sound effect data in the predetermined sound effect data storage means;
Applying a sound effect to the audio signal based on the selected sound effect data;
A sound effect setting method comprising:

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