JP2617990B2 - Audio signal recording medium and reproducing apparatus therefor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Overview] Reverberation information is also recorded on an audio signal recording medium on which a digitized audio signal is recorded, and during reproduction, the reverberation information is read out before reading out the audio signal. By adjusting the sound field characteristics accordingly, a realistic sound field is reproduced.

[Industrial applications]

The present invention relates to an audio signal recording medium and a reproducing device therefor.

In recent years, recording methods for digitizing and recording audio signals, such as compact discs (CD), laser discs (LD), digital audio tapes (DAT), and the like, have been put into practical use, and their recording media and playback devices have become commercially available. became. In these, as an additional benefit of digitizing and recording the audio signal, it is possible to record information other than the audio signal on the same recording medium. It is one of. The present invention refers to such an audio signal recording medium and its playback device.

[Conventional technology]

As a sound field control device for enhancing the sense of reality perceived by a listener of a sound reproduced by an audio reproducing device, that is, for approximating the feeling of directly listening to the sound at the venue where the sound was recorded, there is a conventional sound field control device. In some devices, a certain reverberation sound is added on the playback device side.

[Problems to be solved by the invention]

As described above, if a certain amount of reverberation is unilaterally added on the playback device side, the reverberation may become too harsh or inadequate depending on recording conditions. To compensate for this, the listener needs to adjust the amount of reverberation or the reverberation time based on the listener's own perception. This operation is complicated, and there is a problem that it is difficult to reproduce an ideal sound field.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an audio signal recording medium capable of always reproducing a sound field with ideal sound field characteristics without complicated operations, and a reproducing apparatus therefor.

[Means for solving the problem]

FIG. 1 is a principle diagram of an audio signal recording medium of the present invention and a reproducing apparatus therefor. Explaining with reference to this figure, the audio signal recording medium 13 of the present invention includes a recording area 11 for digitized audio signals and a recording area 12 for reverberation information relating to the degree of reverberation. The reverberation information is obtained by, for example, digitizing information on the spatial size of the performance hall or an impulse response measured at the performance hall. Further, the information on the size includes information on the size of the room in which the audio signal is actually recorded, and information on the size of the room suitable for the music.

The playback device of the audio signal recording medium 13 of the present invention includes:
In addition to the conventional audio signal reading means 22 for reading and reproducing the audio signal and the amplifying means 24 for amplifying the reproduced audio signal and sounding the speaker 29, a reverberation information reading means 21 for reading the above-described reverberation information, A first sound field correction constant calculating means for calculating a first sound field correction constant based on the output reverberation information; and a sound field characteristic of the audio signal using the calculated first sound field correction constant. And first sound field characteristic adjusting means 23 for adjusting.

In addition to the above-described reproducing apparatus, the reproducing apparatus of the present invention further includes a reproducing environment characteristic measuring means 26 for measuring the sound field characteristics of the reproducing environment, and a second reproducing apparatus based on the measured sound field characteristics of the reproducing environment. Second sound field correction constant calculating means 28 for calculating a sound field correction constant, and second sound field characteristic adjusting means 27 for adjusting the sound field characteristics of the audio signal using the calculated second sound field correction constant. Is provided.

(Operation)

The above-mentioned first sound field correction constant calculating means 25 calculates the sound field correction constant so that the longer the reverberation time indicated by the reverberation information is, the longer the reverberation time of the audio signal is. The sound field correction constant may be calculated such that the longer the reverberation time indicated by, the shorter the reverberation time of the audio signal. In the former, the recording of the audio signal is preferably performed in an anechoic room that does not cause reverberation,
If reverberation information about a performance site suitable for the sound is recorded as reverberation information, an ideal sound field is formed by adding reverberation of the performance site suitable for the sound to an audio signal having no reverberation component.

In the latter case, reverberation information is stored for the room in which the sound was recorded, and during playback, the reverberation during recording is temporarily canceled based on this reverberation information, and a certain reverberation characteristic is newly added. By doing so, an ideal sound field can be formed irrespective of the reverberation characteristics of the recorded room.

The second sound field correction constant calculating means 28 calculates a sound field correction constant which cancels the sound field characteristic according to the actually measured sound field characteristic of the reproduction environment. An ideal sound field can be formed excluding the influence of the reflection of light.

〔Example〕

FIG. 2 shows a compact disc (CD) on which reverberation information is recorded, which is an example of the audio signal recording medium of the present invention. The recording medium is not limited to the CD, but can be applied to a laser disk (LD) or a digital audio tape (DAT).

As described above, the reverberation information is, for example, information relating to the spatial size of the performance hall or a digitized impulse response measured at the performance hall, and either of them is recorded on the CD. The areas 120 and 110 are recording areas composed of a large number of tracks formed along the circumference of the concentric circle, and the area near the area 120 is read sequentially to an outer track as a read start area. Each track in the recording areas 120 and 110 is divided into frames each consisting of several hundred bits of information, and in each frame, in addition to the code of the digitized audio signal, information other than the audio signal is called a subcode. Can be recorded. When recording information about the spatial size of a performance hall as reverberation information, for example, the internal volume of a room is expressed as m ³
A numerical value represented by a unit or a code representing a large / medium / small size of a room is written in the subcode area. When recording a digitized impulse response as reverberation information, the impulse response is sampled at regular intervals in a recording area 120, which is a readout start area, in the same manner as recording of an ordinary audio signal, and analog-to-analog. After digital conversion, EFM (Eight to Fourteen Moduratio)
n) Perform modulation and add a correction signal for recording.

FIG. 3 is a diagram for explaining a method of collecting impulse response data. 15 width from impulse sound source 300
A pulse-like sound wave of about 30 μsec is output, and an impulse response is collected from the microphone 302 within a certain period after the sound wave is generated. This impulse response corresponds to the sound field characteristics in the performance hall 304. The impulse response obtained by collecting the sound from the microphone 302 is processed based on the normal CD recording method as described above, and is recorded in the area 120 (FIG. 2). An audio signal from a general music source is recorded in the other area 130 in the same manner.

FIG. 4 is a block diagram of a reproducing apparatus for reproducing the CD shown in FIG. CD player 200, DSP (digital signal processor) 201, DA converter 202, low-pass filter 203, amplifier 204, speaker 205, operation switch 20
The system composed of the control microcomputer 207 and the control microcomputer 207 has the same configuration as a general CD reproducing apparatus in terms of hardware.

The DSP201 is a microcontroller suitable for real-time digital audio signal processing, such as being able to perform product-sum operations at high speeds of the order of nsec (nanoseconds), which are required for processing of digitized audio signals, such as filtering. A processor, generally a CD player, is responsible for sound quality of audio signals, volume processing, and the like. On the other hand, the control microcomputer 207 is a general microcomputer, which controls the CD player 200 by inputting the state of the operation switch 206 and serves to give a constant for audio signal processing to the DSP 201. The audio signal reading means 22 shown in FIG. 1 is realized by software in the control microcomputer 207 and the CD player 200.

As described above, the DSP 201 can perform the product-sum operation at a high speed, but the control microcomputer 207 is suitable for executing a relatively large-scale and complicated process under relatively moderate time constraints. Therefore, the first sound field correction constant calculating means 25 (FIG. 1) is software in the control microcomputer 207,
It is desirable that the sound field characteristic adjusting means 23 be realized by software in the DSP 201.

The dashed line in FIG. 4 indicates the reproduction environment characteristic measuring means in FIG.
26, the microphone 211 and the amplifier 21
0, a low-pass filter 209, and an AD converter 208. For the same reason as described above, it is desirable that the second sound field correction constant calculating means 28 be realized by software in the control microcomputer 207 and the second sound field characteristic adjusting means 27 be realized by software in the DSP 201.

Next, a specific method of calculating the sound field correction constant from the impulse response data will be described.

The impulse response recorded by the method shown in FIG. 3 has a form as shown in FIG. 5 as an example. Figure T ₀ is the initial delay time, a time from the direct user input in a microphone 302 to the first reflected sound is input. FIG. 6 (2) shows a simplified form of the signal in the form of a discrete signal (a discontinuous signal obtained by sampling a continuous signal at a constant period), and FIG. This is shown in column (1).
The time until the initial delay time elapses on the time axis in column (2) is excluded. When an impulse response as shown in FIG. 6 (2) is obtained, the difference equation corresponding to the impulse response is as follows.

y _k = x _k + 0x _kN + 0.5x _kN-1 -0.25x _kN-2 + 0.2x _kN-3 + 0.1x _kN-4 -0.05x _kN-5 (1) where N represents the sampling interval as a unit. It is an initial lag time. FIG. 7 shows a signal diagram corresponding to such a difference equation.

By performing an operation such as equation (1) on the input x (k) using the coefficients obtained from the impulse response data in this way, an FIR filter as shown in FIG. It becomes equivalent to the measured sound field characteristics of the performance hall 304. In FIG. 7, reference numeral 401 denotes a retarder for delaying by a sampling period T, 402 denotes a multiplier, and 403 denotes an adder.
Such an operation can be realized within the sampling synchronization T in the DSP 201 as long as the number of coefficients is within the limit. In order to keep the number of coefficients within the limit, the operation is performed only on points representing typical characteristics in the results obtained by sampling the impulse response at a period T as shown in FIG. Alternatively, there is a method of performing a filter operation in the form of a recursive filter.

When the spatial size of the venue is used as the reverberation information, the typical characteristics of the above-described format are stored in the memory of the control microcomputer 207 or the DSP 201, and are continuously calculated based on the information on the size. The sound field characteristics are changed by changing the initial delay time stepwise or stepwise.

The above is a method of calculating a constant based on the reverberation information so that the longer the reverberation time indicated by the reverberation information is, the longer the reverberation time of the audio signal is. A method for canceling the characteristics will be described. (1) generalizing equation And z-transform both sides Becomes Here, X (z) and Y (z) are the z-transforms of the input and output signals x _n and y _n , respectively. here, Putting a, H (z) is a function called a transfer function in the discrete system, the input y _n of z-transform Y (z) is represented by Y (z) = H (z ) · X (z) (5) . Therefore, the reciprocal of H (z), H (z) ⁻¹
Is a filter that cancels the sound field characteristics of the system of the transfer function H (z).

In the example of the equation (1), H (z) = 1 + 0.5z- ^N-1 -0.25z- ^N-2 + 0.2z- ^N-3 + 0.1z- ^N- 4-0.05z- ^N-5 (6 ) H (z) ^-1 = 1 / (1 + 0.5z ^-N-1 -0.25z ^-N-2 + 0.2z ^-N-3 + 0.1z ^-N-4 -0.05z ^-N-5 ) (7) Is obtained, and (7) is converted into a homogeneous equation according to the method of dividing the homogeneous equation, and each coefficient is used as a coefficient of a difference equation such as the equation (1).

FIGS. 8A, 8B and 8C illustrate processing of an example of a reproducing apparatus that reads reverberation information and an audio signal from an audio signal recording medium according to the present invention and reproduces a sound field based on the principle described above. It is a flowchart. It should be noted that the processing shown in this figure corresponds to the reproduction environment characteristic measuring means 26, the second sound field correction constant calculating means 28 and the second sound field characteristic adjusting means 27 shown in FIG. 1 (FIG. 8A).
, But these are not necessarily essential elements.

Hereinafter, the processing of the playback apparatus of the present invention will be described with reference to FIGS. 8A, 8B and 8C. When this system is used for the first time after installation, the processing is started from the processing in FIG. 8A. First,
An impulse signal is output from the speaker 205 (step a), the response is collected from the microphone 211 (step b), and data is obtained by performing AD conversion. So far
The acquired data is transferred in the DSP to the control microcomputer. The next control microcomputer side, calculates the transfer function h ₁ of the listening room (step c), determining the inverse (step d). The processing so far is performed by an impulse response measurement program in the DSP. This process needs to be performed only once after the system is installed. The transfer coefficient data calculated in this way is conversely transferred to the DSP side. Then enter the normal routine, the CD130 is attached to CDP200, reads an impulse response from CD130 (step f), and transferred to the control microcomputer, it calculates the h ₀ in the microcomputer (step f). Next, the calculated transfer function coefficient is transferred to the DSP side. When the reproduction SW is pressed, data is normally read from the source, and an operation is performed in the DSP based on the difference equation corresponding to 1 / h ₁ and h ₀ (step h). However the only calculation of h ₀ when not in calculating the h _1. The result y _i of the operation is output (step i), and the processing of steps g to i is repeated until the end of the music (step j).

The above is the processing when the reverberation information is an impulse response.If the reverberation information is information relating to the size of a room, standard coefficient data registered in advance is selected by the method described above. The reproduction may be performed according to FIGS. 8A to 8C.

Further, when adding a new ideal sound field characteristic by canceling the sound field characteristic when sound pickup is set to 1 / h ₀ instead of h _0, ideal, which had been previously measured calculated What is necessary is just to correct using the coefficient in a sound field characteristic.

〔The invention's effect〕

As described above, according to the audio signal recording medium and the reproducing apparatus of the present invention, it is possible to always reproduce a sound field based on ideal sound field characteristics without performing complicated operations. Become.

[Brief description of the drawings]

1 is a diagram illustrating the principle of the present invention, FIG. 2 is a diagram illustrating an example of an audio signal recording medium according to the present invention, FIG. 3 is a diagram illustrating a method for collecting impulse responses, and FIG. FIG. 5 is a block diagram showing an example of an impulse response, FIG. 6 is a diagram showing an impulse signal and an impulse response in a discrete system, and FIG. 7 is a signal of an FIR filter used in the reproducing apparatus of the present invention. FIG. 8A is a diagram showing an example of an initial process of the reproducing apparatus of the present invention; FIG. 8B is a diagram showing a process immediately after a CD is loaded in the reproducing device of the present invention; The figure shows the process at the time of reproduction. In the figure, 11 ... an audio signal recording area, 12 ... a reverberation information recording area, 13 ... an audio signal recording medium.

 ──────────────────────────────────────────────────続 き Continuing from the front page (72) Inventor Shoji Fujimoto 1-2-28, Goshodori, Hyogo-ku, Kobe City, Hyogo Prefecture Inside Fujitsu Ten Co., Ltd. No. 28 No. 28 Inside Fujitsu Ten Limited (56) References JP-A-63-183495 (JP, A) JP-A-58-18696 (JP, A) JP-A-58-68400 (JP, A)

Claims (2)

(57) [Claims] 1. An audio signal recording medium reproducing apparatus having a recording area for reverberation information related to a performance hall,
A reproducing apparatus comprising: an audio signal reading unit for reading a recording area of the audio signal; and an amplifying unit for amplifying the audio signal and sounding a speaker. First sound field correction constant calculation means for calculating a first sound field correction constant based on information; reproduction environment characteristic measurement means for measuring a sound field characteristic of a reproduction environment; and a sound field characteristic of the reproduction environment. Second sound field correction constant calculating means for calculating a second sound field correction constant by using the first sound field correction constant and the second sound field correction constant. An audio signal recording medium reproducing apparatus, comprising: a sound field characteristic adjusting means for adjusting. 2. The first sound field correction constant is related to a transfer function (h ₀ ) in the performance hall, and the second sound field correction constant is a transfer function (h ₁ ) in a listening room. The sound field characteristic adjusting means is related to a reciprocal (1 / h ₁ ), and the reciprocal (1 / h) of a transfer function (h ₀ ) in the performance hall and a transfer function (h ₁ ) in the listening room. _2. The audio signal recording medium reproducing apparatus according to claim 1, wherein the sound field characteristics of the audio signal are adjusted from the above ₁ ).