JP2018055136A - Acoustic device, missing band estimation device, signal processing method, and frequency band estimation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To output high-quality sound whose high-frequency band has been interpolated with a simple structure.SOLUTION: In high-frequency interpolation, a harmonic generation unit first generates a harmonic signal of an input compressed sound signal CAD. Concurrently with generation of this harmonic signal, an HPF unit 121having a cutoff frequency Fextracts a high-frequency component of the compressed sound signal CAD. In addition, an HPF unit 121having a cutoff frequency F(>F) extracts a high-frequency component of the compressed sound signal CAD. An estimation unit 124 estimates a missing band of the compressed sound signal CAD on the basis of the ratio between the signal level of a difference signal SBD obtained by subtracting an output signal HPDof the HPF unit 121from an output signal HPDof the HPF unit 121and the signal level of the signal HPD. Then, on the basis of the estimated missing band, the estimation unit 124 controls a cutoff frequency of a variable HPF unit 130 that extracts a signal component for high-frequency interpolation from the harmonic signal.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an acoustic device, a missing band estimation device, a signal processing method and a signal processing program, a recording medium on which the signal processing program is recorded, and a frequency band estimation device.

In recent years, audio apparatuses that reproduce audio content recorded in a digital format have become widespread. In many cases, such audio content data is digitally compressed by a method such as MP3 (MPEG (Moving Picture Expert Group) Audio Layer-3) in order to reduce the file size. Compressed audio signal according digital compression is achieved by decompressing the compressed audio data generated being performed, from the band limited by the sampling frequency employed in obtaining audio data before compression (F _S) In addition, the audio signal has a higher treble band. The treble band limited by the compression process becomes wider as the bit rate is lower (that is, the compression rate is higher) if the compression process is performed by the same method.

  For this reason, a technique for interpolating a high frequency band corresponding to a bit rate, that is, a signal component that has been lost due to compression processing corresponding to a compression ratio has been proposed (see Patent Document 1 below). "Conventional example"). In this conventional technique, the discriminating means reads information such as a bit rate that is separated from the compressed audio signal obtained by decompressing the compressed audio data. Subsequently, the discriminating means sets the cutoff frequency of the high-pass filter that allows the harmonic signal generated by the harmonic generating means to pass based on the read bit rate or the like. The signal that has passed through the high-pass filter in which the cutoff frequency is set in this way is synthesized with the compressed audio signal, so that the signal component in the high frequency band is interpolated.

JP 2004-317622 A

  In the conventional technique described above, the discrimination means separates from the compressed audio data in order to appropriately set the cutoff frequency of the high-pass filter that performs high-pass filtering on the harmonic signal generated by the harmonic generation means. Information such as the bit rate is read. That is, in the conventional technique, the determination unit can access a storage device in which information such as compressed audio data and bit rate is stored.

  In recent years, information such as compressed audio data and bit rate is often downloaded from a server on a network as acoustic content by a small portable terminal device. For this reason, a compressed audio signal generated by a small portable terminal device is sent to another audio device, and is output as a high-quality audio signal subjected to high-frequency band interpolation by the audio device. There is.

  In such a case, when applying the technique of the conventional example, it is necessary to transmit information such as a bit rate from the portable terminal device to another acoustic device via a route different from the route of the compressed audio signal. Therefore, it is necessary to add a function in the mobile terminal device, and it is difficult to output high-quality sound with high-frequency band interpolation with a simple configuration.

  For this reason, there is a need for a technique that can output a high-quality sound with high-frequency band interpolation with a simple configuration. Meeting this requirement is one of the problems to be solved by the present invention.

  From a first aspect, the present invention provides a harmonic generation unit that generates harmonics of an input audio signal; a high-frequency range of the harmonics that has a variable cutoff frequency and is generated by the harmonic generation unit A variable high-pass filter unit that extracts a component; a first high-pass filter unit that has a first cutoff frequency and extracts a high-frequency component of the input audio signal; and more than the first cutoff frequency A second high-pass filter unit that has a high second cutoff frequency and extracts a high-frequency component of the input audio signal; a level of an output signal of the first high-pass filter unit; and the second high-pass filter unit And a control unit that controls a cutoff frequency of the variable high-pass filter unit based on a level of an output signal of the high-pass filter unit.

  According to a second aspect of the present invention, there is provided a first high-pass filter unit that has a first cutoff frequency and extracts a high frequency component of an input audio signal; and more than the first cutoff frequency. A second high-pass filter unit that has a high second cutoff frequency and extracts a high-frequency component of the input audio signal; a level of an output signal of the first high-pass filter unit; and the second high-pass filter unit And a estimator that estimates a high frequency band in which a signal component is missing in the input audio signal based on the level of the output signal of the high-pass filter unit.

  From a third aspect, the present invention provides a harmonic generation unit that generates harmonics of an input audio signal; a cutoff frequency is variable, and the high frequency range of the harmonics generated by the harmonic generation unit A variable high-pass filter unit that extracts a component; a first high-pass filter unit that has a first cutoff frequency and extracts a high-frequency component of the input audio signal; and more than the first cutoff frequency A signal processing method for use in an acoustic device comprising: a second high-pass filter unit that has a high second cutoff frequency and extracts a high-frequency component of the input audio signal; An acquisition step of acquiring the level of the output signal of the high-pass filter unit and the level of the output signal of the second high-pass filter unit; based on the acquisition result in the acquisition step; A signal processing method characterized by comprising a; and a control step of controlling the cut-off frequency of the filter unit.

  From a fourth aspect, the present invention is a signal processing program that causes a computer included in an audio device to execute the signal processing method of the present invention.

  From a fifth aspect, the present invention is a recording medium on which the signal processing program of the present invention is recorded so as to be readable by a computer included in the audio device.

  According to a sixth aspect of the present invention, there is provided a first high-pass filter unit that has a first cutoff frequency and extracts a high-frequency component of an input audio signal; A second high-pass filter unit that has a high second cutoff frequency and extracts a high-frequency component of the input audio signal; a level of an output signal of the first high-pass filter unit; and the second high-pass filter unit An estimation unit that estimates a frequency band of the input voice signal based on a level of an output signal of a high-pass filter unit.

1 is a block diagram schematically showing a configuration of an audio device according to an embodiment of the present invention. It is a figure which shows the average spectrum of the compression audio | voice signal for every bit rate input into the audio equipment of FIG. It is a block diagram which shows the structure of the missing band estimation apparatus of FIG. It is a figure for demonstrating the filtering characteristic of two types of high-pass filters (HPF) part of FIG. It is a figure for demonstrating the signal component corresponding to the detection object of two types of level detection parts of FIG. 3 for every three bit rates. It is a block diagram for demonstrating the structure of the synthetic | combination part of FIG. It is a figure for demonstrating the high region interpolation by the apparatus of FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. In the drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

[Constitution]
FIG. 1 is a block diagram illustrating a schematic configuration of an audio device 100 according to an embodiment. As shown in FIG. 1, the acoustic device 100 is connected to a compressed speech decompression device (CADD) 200 and a sound output device 300.

  Here, the compressed audio decompression apparatus 200 decompresses the compressed audio data generated in accordance with a predetermined standard such as the MP3 standard, and generates a compressed audio signal (audio signal) CAD. The compressed audio signal CAD generated in this way is sent to the acoustic device 100.

  In the present embodiment, the compressed audio signal CAD is a compressed audio signal corresponding to one of the three bit rates of “BR1”, “BR2 (> BR1)”, and “BR3 (> BR2)”. Yes.

  Further, the sound output device 300 is configured to include the speaker SP. The sound output device 300 receives the high-frequency interpolated signal HID sent from the acoustic device 100. And the sound output device 300 outputs the sound according to the signal HID after the high frequency interpolation from the speaker SP.

<Configuration of acoustic device 100>
The acoustic device 100 includes a harmonic generation unit (HMG) 110 and a missing band estimation device (MBE) 120. In addition, the acoustic device 100 includes a variable high-pass filter (HPF) unit 130 and a synthesis unit 140.

The harmonic generation unit 110 receives the compressed audio signal CAD sent from the compressed audio decompression device 200. Subsequently, the harmonic generation unit 110 generates first to Nth harmonics of a component of a predetermined frequency band (0 to F _H ) of the compressed audio signal CAD. Of the generated harmonics, a component equal to or lower than the maximum frequency F _MAX (= F _S / 2) of the pre-compression voice band determined by the sample frequency F _S is sent to the variable HPF unit 130 as a signal HMD.

  The missing band estimation device 120 receives the compressed audio signal CAD sent from the compressed audio decompression device 200. Subsequently, the missing band estimation device 120 estimates a treble band (hereinafter, also referred to as “missing band”) in which a signal component is missing in the compressed audio signal CAD based on the compressed audio signal CAD. Missing band estimation apparatus 120 then sends cut-off frequency designation HPC designating the estimated minimum frequency of the missing band to variable HPF unit 130.

  Here, estimating the missing band in the compressed audio signal CAD is nothing other than estimating the frequency band of the compressed audio signal CAD. For this reason, it can be said that the missing band estimation apparatus 120 also has a function as a frequency band estimation apparatus that estimates the frequency band of the compressed audio signal CAD.

  Details of the configuration of the missing band estimation device 120 will be described later.

  The variable HPF unit 130 receives the signal HMD sent from the harmonic generation unit 110. The variable HPF unit 130 receives the cut-off frequency designation HPC sent from the missing band estimation device 120. Then, the variable HPF unit 130 performs a high-pass filtering process on the signal HMD using the frequency specified by the cutoff frequency specifying HPC as a cutoff frequency. The result of the high-pass filtering process is sent to the synthesis unit 140 as a signal HBD.

  The synthesizing unit 140 receives the compressed audio signal CAD sent from the compressed audio decompressing device 200. The synthesizing unit 140 receives the signal HBD sent from the variable HPF unit 130. Then, the synthesizer 140 synthesizes the compressed audio signal CAD and the signal HBD to generate a signal HID after high-frequency interpolation. The high-frequency interpolated signal HID generated in this way is sent to the sound output device 300.

  Details of the configuration of the combining unit 140 will be described later.

Here, the relationship between the bit rate and the compressed audio band will be described. FIG. 2A schematically shows an average spectrum of the uncompressed sound corresponding to the digital music sound generated by sampling at the sample frequency F _S. As shown in FIG. 2A, the upper limit frequency of the pre-compression voice band is the maximum frequency F _MAX (= F _S / 2).

2 (B) to 2 (D) show signal bands of compressed audio obtained by decompressing the compressed audio data of the above-described bit rates BR1 to BR3 obtained by compressing such uncompressed audio data. Here, FIG. 2B shows the signal band of the compressed audio having the bit rate BR1. As shown in FIG. 2 (B), the compressed audio of the bit rate BR1 has an upper limit frequency of the signal band of the frequency F _BR1 and the frequency band (F _{BR1 to} F _MAX ) is higher than that of the audio before compression. This is a missing band of signal components.

FIG. 2C shows the signal band of the compressed audio with the bit rate BR2 (> BR1). As shown in FIG. 2C, the compressed audio of the bit rate BR2 has an upper limit frequency of the signal band of the frequency F _BR2 (> F _BR1 ), and the frequency band (F _{BR2 to} F _MAX ) is before compression. Compared to voice, the signal component has a missing band.

Further, FIG. 2D shows a signal band of compressed audio with a bit rate BR3 (> BR2). As shown in FIG. 2D, in the compressed audio of the bit rate BR3, the upper limit frequency of the signal band is the frequency F _BR3 (> F _BR2 ), and the frequency band (F _{BR3 to} F _MAX ) is before compression. Compared to voice, the signal component has a missing band.

(Configuration of missing band estimation device 120)
Next, the configuration of the missing band estimation device 120 will be described.

As shown in FIG. 3, the missing band estimation device 120 includes bypass filter (HPF) units 121 ₁ and 121 ₂ and a subtraction unit 122. Further, the missing band estimation device 120 includes level detection units 123 ₁ and 123 ₂ and an estimation unit 124.

The HPF unit 121 ₁ performs a high-pass filtering process at the cutoff frequency F _C1 . The HPF unit 121 ₁ receives the compressed audio signal CAD sent from the compressed audio decompressing device 200. Then, the HPF unit 121 ₁ performs high-pass filtering processing of the cutoff frequency F _C1 on the compressed audio signal CAD. The result of this high-pass filtering process is sent to the subtraction unit 122 as the signal HPD ₁ .

The HPF unit 121 ₂ performs a high-pass filtering process at the cutoff frequency F _C2 (> F _C1 ). The HPF unit 121 ₂ receives the compressed audio signal CAD sent from the compressed audio decompression device 200. Then, the HPF unit 121 ₂ performs high-pass filtering processing of the cutoff frequency F _C2 on the compressed audio signal CAD. The result of this high-pass filtering process is sent to the subtraction unit 122 and the level detection unit 123 ₂ as the signal HPD ₂ .

The subtraction unit 122 receives the signal HPD ₁ sent from the HPF unit 121 ₁ . The subtractor 122 receives the signal HPD ₂ sent from the HPF unit 121 ₂ . Then, the subtracting unit 122 subtracts the signal HPD ₂ from the signal HPD ₁ . The result calculated in this way is sent to the level detection unit 123 ₁ as a signal SBD.

The level detection unit 123 ₁ receives the signal SBD sent from the subtraction unit 122. Then, the level detector 123 ₁ detects the power level of the signal SBD. The detection result by the level detection unit 123 ₁ is sent to the estimation unit 124 as the detection level DL ₁ .

The level detection unit 123 ₂ receives the signal HPD ₂ sent from the HPF unit 121 ₂ . Then, the level detector 123 ₂ detects the power level of the signal HPD ₂ . The detection result by the level detection unit 123 ₂ is sent to the estimation unit 124 as the detection level DL ₂ .

The estimation unit 124 receives the detection level DL ₁ sent from the level detection unit 123 ₁ . Further, the estimation unit 124 receives the detection level DL ₂ sent from the level detection unit 123 ₂ . Then, the estimation unit 124 estimates a missing band in the compressed audio signal CAD based on the ratio R (= DL ₁ / DL ₂ ) between the detection level DL ₁ and the detection level DL ₂ .

  Subsequently, the estimation unit 124 generates a cutoff frequency designation HPC that designates the estimated lower limit frequency of the missing band. The cut-off frequency designation HPC generated in this way is sent to the variable HPF unit 130.

An example of filtering characteristics of the HPF unit 121 ₁ and the HPF unit 121 ₂ is shown in FIG. Here, FIG. 4A shows an example of filtering characteristics of the HPF unit 121 ₁ . FIG. 4B shows an example of filtering characteristics of the HPF unit 121 ₂ .

Here, the filtering characteristic of the HPF unit 121 ₂ is that the division resource in the estimation unit 124 does not overflow when calculating the ratio R, regardless of the bit rate of “BR1”, “BR2”, and “BR3”. Is set as follows.

Further, signal components corresponding to detection targets of the HPF unit 121 ₁ and the HPF unit 121 ₂ are schematically shown in FIG. In FIG. 5, the signal component corresponding to the detection target of the HPF unit 121 ₁ is indicated by a horizontal line hatch, and the signal component corresponding to the detection target of the HPF unit 121 ₂ is indicated by a vertical line hatch.

Here, FIG. 5A schematically shows signal components corresponding to detection targets of the HPF unit 121 ₁ and the HPF unit 121 ₂ in the case of the bit rate BR1. FIG. 5B schematically shows signal components corresponding to detection targets of the HPF unit 121 ₁ and the HPF unit 121 ₂ in the case of the bit rate BR2. FIG. 5C schematically shows signal components corresponding to detection targets of the HPF unit 121 ₁ and the HPF unit 121 ₂ in the case of the bit rate BR3.

  As can be seen by comparing FIGS. 5A to 5C, the calculated ratio R is different when the bit rate is different. For this reason, since the missing area in the compressed audio signal CAD can be estimated based on the calculated ratio R, if the missing band with respect to the bit rate is uniquely determined, the estimation unit 124 The bit rate can be estimated.

(Configuration of composition unit 140)
Next, the configuration of the synthesis unit 140 will be described.

As shown in FIG. 6, the synthesis unit 140 includes a delay unit 141 and multiplication units 142 ₁ and 142 ₂ . In addition, the synthesis unit 140 includes an addition unit 143.

The delay unit 141 receives the compressed audio signal CAD (= D ₀ (T) (T: time)) sent from the compressed audio decompression device 200. Then, the delay unit 141 generates a signal DLD (= D (T)) obtained by delaying the compressed audio signal CAD by a time T _DL corresponding to the phase delay in the harmonic generation unit 110 and the variable HPF unit 130. Here, the relationship between the signal D (T) and the compressed audio signal D ₀ (T) is expressed by the following equation (1).
D (T) = D ₀ (T−T _DL ) (1)

As a result, the signal DLD and the signal HBD output from the variable HPF unit 130 described above are synchronized. Signal DLD thus generated is sent to the multiplying unit 142 _1.

The multiplication unit 142 ₁ receives the signal DLD sent from the delay unit 141. Then, the multiplier 142 ₁ multiplies the signal DLD by K ₁ to generate a signal MLD. The signal MLD generated in this way is sent to the adder 143.

The multiplication unit 142 ₂ receives the signal HBD sent from the variable HPF unit 130. Then, the multiplier 142 ₂ multiplies the signal HBD by K ₂ to generate a signal MHD. The signal MHD generated in this way is sent to the adding unit 143.

The ratio between the value K ₁ and the value K ₂ is determined in advance based on experiments, simulations, experiences, and the like from the viewpoint of appropriate high-frequency interpolation.

The adder 143 receives the signal MLD sent from the multiplier 142 ₁ . Adder 143 receives signal MHD sent from multiplier 142 ₂ . Then, the adding unit 143 adds the signal MLD and the signal MHD to generate a signal HID after high-frequency interpolation. The high-frequency interpolated signal HID generated in this way is sent to the sound output device 300.

The spectrum of the signal MHD generated as described above is shown in FIG. Here, in FIG. 7A, the spectrum of the signal MHD generated corresponding to the compressed audio signal CAD of the bit rate BR1 is indicated by a broken line. In FIG. 7B, the spectrum of the signal MHD generated corresponding to the compressed audio signal CAD at the bit rate BR2 is indicated by a broken line. Further, in FIG. 7C, the spectrum of the signal MHD generated corresponding to the compressed audio signal CAD at the bit rate BR3 is indicated by a broken line. In FIG. 7 (A) ~ (C) , the spectrum of the signal DLD the K ₁ × signal MLD (thus, the compressed audio signal CAD to ₁ × K signals) are shown by a solid line.

  As shown in FIGS. 7A to 7C, the signal HMD is a signal that appropriately interpolates the missing band of the signal component in the compressed audio signal CAD.

[Operation]
Next, the operation of the acoustic device 100 configured as described above will be described mainly focusing on the generation processing of the signal HBD (see FIG. 1) based on the compressed audio signal CAD.

  When the compressed speech decompression apparatus 200 starts supplying the compressed speech signal CAD, in the acoustic device 100, the harmonic generation unit 110 and the missing band estimation device 120 receive the compressed speech signal CAD. In the acoustic device 100, the synthesis unit 140 receives the compressed audio signal CAD (see FIG. 1).

Upon receiving the compressed audio signal CAD, the harmonic generation unit 110 generates a harmonic of a component in a predetermined frequency band of the compressed audio signal CAD. Then, the harmonic generation unit 110 transmits, to the variable HPF unit 130, a signal having a frequency equal to or lower than the maximum frequency F _MAX of the pre-compression voice band determined by the sample frequency F _S among the generated harmonics as a signal HMD (see FIG. 1).

On the other hand, when receiving the compressed audio signal CAD, the missing band estimation device 120 estimates the missing band in the compressed audio signal CAD based on the compressed audio signal CAD in parallel with the generation of high frequency by the harmonic generation unit 110 described above. . When estimating the missing band, in the missing band estimation apparatus 120, the HPF unit 121 ₁ that has received the compressed audio signal CAD performs a high-pass filtering process on the cut-off frequency F _C1 on the compressed audio signal CAD. Then, the HPF unit 121 ₁ sends the result of the high-pass filtering process to the subtraction unit 122 as the signal HPD ₁ (see FIG. 3).

Upon receiving the compressed audio signal CAD, the HPF unit 121 ₂ performs a high-pass filtering process on the cut-off frequency F _C2 on the compressed audio signal CAD in parallel with the high-pass filtering process performed by the HPF unit 121 ₁ described above. Then, the HPF unit 121 ₂ sends the result of the high-pass filtering process to the subtraction unit 122 and the level detection unit 123 ₂ as a signal HPD ₂ (see FIG. 3).

When receiving the signal HPD ₁ sent from the HPF unit 121 ₁ and the signal HPD ₂ sent from the HPF unit 121 ₂ , the subtracting unit 122 calculates the difference between the signal HPD ₁ and the signal HPD ₂ . The subtraction unit 122 sends the calculated difference, the level detecting unit 123 ₁ as the signal SBD (see FIG. 3).

When receiving the signal SBD sent from the subtractor 122, the level detector 123 ₁ detects the power level of the signal SBD. Then, the level detection unit 123 ₁ sends the detection result to the estimation unit 124 as the detection level DL ₁ (see FIG. 3).

When receiving the signal HPD ₂ sent from the HPF unit 121 ₂ , the level detection unit 123 ₂ detects the power level of the signal HPD ₂ . Then, the level detection unit 123 ₂ sends the detection result to the estimation unit 124 as the detection level DL ₂ (see FIG. 3).

Detection level DL ₁ sent from the level detection unit 123 _1, and receives a detection level DL ₂ sent from the level detection unit 123 _2, estimating unit 124, based on the detection level DL ₁ and the detection level DL ₂ Then, a cutoff frequency designation HPC is generated. When generating such cutoff frequency designation HPC, the estimation unit 124 first calculates the ratio R (= DL ₁ / DL ₂ ) between the detection level DL ₁ and the detection level DL ₂ .

  Subsequently, the estimation unit 124 estimates the missing band of the compressed audio signal based on the calculated ratio R.

  Next, the estimation unit 124 generates a cutoff frequency designation HPC that designates the estimated lower limit frequency of the missing band. Then, the estimation unit 124 sends the generated cutoff frequency designation HPC to the variable HPF unit 130 (see FIG. 3).

  When the cutoff frequency designation HPC sent from the missing band estimation device 120 (more specifically, the estimation unit 124) is received, the variable HPF unit 130 uses the frequency designated by the cutoff frequency designation HPC as a cutoff frequency. The filtering process is performed on the signal HMD sent from the harmonic generation unit 110 to generate the signal HBD. Then, the variable HPF unit 130 sends the generated signal HBD to the synthesis unit 140 (see FIG. 1).

Upon receiving the signal HBD sent from the variable HPF unit 130, the synthesis unit 140 synthesizes the signal HBD and the compressed audio signal CAD sent from the compressed audio decompression device 200. In the synthesis, in the synthesis unit 140, the delay unit 141 delays the compressed audio signal CAD by a time T _DL corresponding to the phase delay in the harmonic generation unit 110 and the variable HPF unit 130, and synchronization with the signal HBD is performed. Generated signal DLD. The delay unit 141 sends the generated signal DLD to the multiplying unit 142 ₁ (see FIG. 6).

When receiving the signal DLD sent from the delay unit 141, the multiplication unit 142 ₁ multiplies the signal DLD by K ₁ to generate a signal MLD. Then, the multiplier 142 ₁ sends the generated signal MLD to the adder 143 (see FIG. 6).

On the other hand, the multiplication unit 142 ₂ multiplies the signal HBD by K ₂ to generate the signal MHD. Then, the multiplication unit 142 ₂ sends the generated signal MHD to the addition unit 143 (see FIG. 6).

Upon receiving the signal MLD sent from the multiplication unit 142 ₁ and the signal MHD sent from the multiplication unit 142 ₂ , the addition unit 143 adds the signal MLD and the signal MHD, and has undergone high-frequency interpolation. Generate an HID. Then, the adding unit 143 sends the generated signal HID after high frequency interpolation to the sound output device 300 (see FIG. 6).

  That is, the synthesizing unit 140 synchronizes the signal HBD and the compressed audio signal CAD, and then performs weighted addition with a mixing ratio that enables appropriate high-frequency interpolation to synthesize the signal HBD and the compressed audio signal CAD. . The high-frequency interpolated signal HID generated as a result of the synthesis is sent to the sound output device 300.

  Upon receiving the high-frequency interpolated signal HID sent from the audio device 100 (more specifically, the synthesizing unit 140), the sound output device 300 outputs a sound according to the high-frequency interpolated signal HID from the speaker SP. . As a result, the sound output device 300 outputs high-quality sound that has been appropriately subjected to high-frequency interpolation in accordance with the bit rate of the compressed sound signal CAD.

  As described above, in the present embodiment, at the time of high-frequency interpolation, first, the harmonic generation unit 110 generates harmonics of the input compressed audio signal CAD. In parallel with the generation of such harmonics, the missing band estimation device 120 estimates the missing band in the compressed audio signal CAD.

When estimating the missing band, in the missing band estimation apparatus 120, the high-pass filter unit 121 ₁ having the cutoff frequency F _C1 extracts a high-frequency component of the compressed audio signal CAD and also uses the cutoff frequency F _C2 (> F _C1 ) Has a high-pass filter section 121 ₂ that extracts a high-frequency component of the compressed audio signal CAD. Subsequently, in the missing band estimation device 120, the estimation unit 124 outputs the signal HPD ₁ output from the high-pass filter unit 121 ₁ (first high-pass filter unit) to the high-pass filter unit 121 ₂ (second high-pass filter unit). the level of the difference signal SBD obtained by subtracting the signal HPD ₂ that is, for calculating the ratio R between the level of the signal HPD _2. Note that the filtering characteristics of the high-pass filter sections 121 ₁ and 121 ₂ are set so that the ratio R is different when the bit rate of the compressed audio signal CAD is different.

  Next, the estimation unit 124 estimates the missing band of the compressed audio signal CAD based on the calculated ratio R. Then, the estimation unit 124 controls the high-pass filtering process by the variable HPF unit 130 by sending a cutoff frequency designation HPC designating the estimated lower limit frequency of the missing band to the variable HPF unit 130.

  Under such control, the variable HPF unit 130 performs a high-pass filtering process using the frequency specified by the cutoff frequency specifying HPC as a cutoff frequency on the signal HMD sent from the harmonic generation unit 110, A signal HBD is generated. Then, the synthesis unit 140 synthesizes the compressed audio signal CAD and the signal HBD.

  Therefore, according to the present embodiment, it is possible to output a high-quality sound in which high-frequency band interpolation is appropriately performed with a simple configuration.

[Modification of Embodiment]
The present invention is not limited to the above-described embodiment, and various modifications are possible.

  For example, in the above embodiment, the level of the difference signal obtained by subtracting the signal output from the second high-pass filter unit from the signal output from the first high-pass filter unit and the signal output from the second high-pass filter unit The missing band of the input compressed audio signal is estimated based on the ratio to the signal level. In contrast, the frequency band of the input compressed audio signal is estimated based on the ratio between the level of the signal output from the first high-pass filter unit and the level of the signal output from the second high-pass filter unit. You may make it do. Then, the cutoff frequency designation specifying the estimated upper limit frequency of the frequency band may be performed on the variable HPF unit.

  If the ratio of the level of the signal output from the first high-pass filter unit and the level of the signal output from the second high-pass filter unit is different when the bit rate of the compressed audio signal is different, You may employ | adopt the high pass filter part which has filtering characteristics other than the characteristic of the high pass filter part illustrated in the embodiment.

  In the above embodiment, the present invention is applied to high frequency interpolation of a compressed audio signal. However, the present invention may be applied to high frequency interpolation of an audio signal other than the compressed audio signal.

  Moreover, in said embodiment, it was set as the structure by which a compression audio | voice decompression | decompression apparatus and a sound output device are arrange | positioned as an apparatus different from an acoustic apparatus. On the other hand, the acoustic device may have a function of a compressed voice decompression device, or the acoustic device may have a function of a sound output device.

  The acoustic device of the above embodiment is configured as a computer as a calculation means including a DSP (Digital Signal Processor) and the like, and a program prepared in advance is executed by the computer, whereby the processing in the above embodiment is performed. A part or all of the above may be executed. This program may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form of delivery via a network such as the Internet. .

DESCRIPTION OF SYMBOLS 100 ... Acoustic apparatus 110 ... Harmonic generation part 120 ... Missing band estimation apparatus (frequency band estimation apparatus)
121 ₁ ... High-pass filter (first high-pass filter)
121 ₂ ... High-pass filter (second high-pass filter)
124 ... estimation unit (control unit)
130 ... Variable high-pass filter section 140 ... Composition section

Claims (1)

A first high-pass filter unit having a first cutoff frequency and extracting a high-frequency component of the audio signal;
A second high-pass filter unit having a second cutoff frequency higher than the first cutoff frequency and extracting a high-frequency component of the audio signal;
An estimation unit that estimates a high frequency band in which a signal component is missing in the audio signal based on a level of an output signal of the first high-pass filter unit and a level of an output signal of the second high-pass filter unit; ;
A missing band estimation apparatus comprising:

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