JPH06335096A - Sound field reproducing device - Google Patents

Abstract

PURPOSE:To simulate the characteristic of a space in accordance with the directivity of a sounding body. CONSTITUTION:A storage part 13 stores the acoustic characteristics of the space in accordance with the directivity of the sounding body. Switching parts 14 and 15 switch the acoustic characteristic, which is stored in the stored part 13, of the space in accordance with the directivity of the sounding body. An arithmetic part 16 performs calculation processing of a musical signal converted to a digital signal by an A/D converter 12 by using the acoustic characteristic, which is supplied from the switching part 14, of the space in accordance with the directivity of the sounding body of the right ear. An arithmetic part 19 performs calculation processing of a musical signal converted to a digital signal by the A/D converter 12 by using the acoustic characteristic, which is supplied from the switching part 15, of the space in accordance with the directivity of the sounding body of the left ear. D/A converters 17 and 20 convert the signals calculated by the arithmetic parts 16 and 19 to analog signals.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sound field reproducing device,
In particular, the present invention relates to a sound field reproducing device that reproduces an input signal by performing arithmetic processing based on acoustic characteristics.

[0002]

2. Description of the Related Art Conventionally, acoustic characteristics of a space such as a hall and a theater, that is, frequency characteristics and reverberation characteristics have been measured as a response to an omnidirectional sound source using an omnidirectional sound source. Therefore, even when simulating the acoustic characteristics of the measured space, it is simulated on the assumption that the sound source is omnidirectional.

[0003]

By the way, musical instruments actually played in spaces such as halls and theaters, voices of singers, etc. have a considerable directivity. Since the omnidirectional sound source is used for the measurement of the acoustic characteristics simulated by the above conventional method, the directivity of the musical instrument, the voice of the singer, etc. is not considered at all.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a sound field reproducing device capable of simulating the acoustic characteristics of a space according to the directivity of each sounding body such as a musical instrument.

[0005]

A sound field reproducing apparatus according to the present invention is a sound field reproducing apparatus for reproducing an inputted musical tone signal by performing arithmetic processing based on the acoustic characteristics of the sound field. And / or storage means for storing acoustic characteristics of the space,
The above-mentioned problem is solved by having an arithmetic means for arithmetically processing the inputted tone signal using the acoustic characteristics stored in the storage means.

Here, the acoustic characteristics stored in the storage means are characteristics considering the directivity characteristics of the sounding body, and characteristics considering the response characteristics to the sounding body having the directivity of the space. Is preferred. Further, the storage means may store the acoustic characteristic of the sound field obtained by synthesizing the acoustic characteristic in consideration of the directivity of the sounding body and the response characteristic of the space.

The response characteristic of the space is that a narrow directional sound source is rotated by 360 ° in the space and a measurement sound generated at every predetermined angle is measured by a dummy head arranged at a predetermined listening position. Sound is collected and measured by sound collecting devices attached to the positions of the right and left ears. In addition, the directional characteristics of the above-mentioned sounding body are different from those of the central instrument by the sound incity method or the like at a plurality of angular positions up to 360 ° at a predetermined angle from a certain reference direction with the instrument placed in the anechoic chamber as the center. The sound level in the radiating direction is measured and calculated.

The acoustic characteristics stored in the storage means are a plurality of acoustic characteristics in consideration of directivity characteristics of a plurality of sounding bodies, and a plurality of acoustic characteristics in consideration of response characteristics of a plurality of spaces. Is preferred. It is preferable that the acoustic characteristic in consideration of the directivity characteristics of the plurality of sounding bodies and the acoustic characteristic in consideration of the response characteristics of the plurality of spaces are switched by the switching unit.

Further, the acoustic characteristics stored in the storage means are a combination of a plurality of acoustic characteristics in consideration of response characteristics of a plurality of spaces and a plurality of acoustic characteristics in consideration of response characteristics of a plurality of spaces. It may be the acoustic characteristics of the obtained plural sound fields. Then, it is preferable that the acoustic characteristics of the plurality of sound fields are switched by the switching unit.

[0010]

With the acoustic characteristics of the sounding body and / or the space stored in the storage means, the musical sound signal inputted by the calculating means is processed, so that the acoustic characteristics of the space according to the directivity of the sounding body are simulated. it can.

[0011]

Embodiments of the sound field reproducing apparatus according to the present invention will be described below with reference to the drawings. In this embodiment, as shown in FIG. 1, the acoustic characteristics of a space (for example, a theater, a hall, etc., which will be described below as a hall) in accordance with the directivity of a sounding body such as a violin, cello and piano are stored. Storage unit 13, switching units 14 and 15 for switching the acoustic characteristics stored in the storage unit 13, and, for example, a violin, cello, or the like input using the acoustic characteristics switched by the switching units 14 and 15. Arithmetic units 16 and 19 for arithmetically processing a musical tone signal of a piano,
An analog / digital (A) which converts the input musical tone signal supplied from the input terminal 11 into a digital musical tone signal and supplies the digital musical tone signal to the arithmetic units 16 and 19
/ D) converter 12 and a digital / analog (D / A) converter 17 for converting a digital musical tone signal which is arithmetically processed by the arithmetic unit 16 using the acoustic characteristics switched by the switching unit 14 into an analog musical tone signal.
And a D / A converter 20 for converting the digital musical tone signal, which has been arithmetically processed using the acoustic characteristics switched by the switching unit 15, into an analog musical tone signal. The analog tone signal from the D / A converter 17 is output to the output terminal 18
And supplied to headphones or the like (not shown) through an amplifier (not shown). Similarly, the analog tone signal from the D / A converter 20 is derived from the output terminal 21 and supplied to a headphone or the like (not shown) via an amplifier (not shown).

Here, the acoustic characteristics stored in the storage unit 13 are the acoustic characteristics in the hall in accordance with the directivity of the violin, cello and piano as described above. That is, in this embodiment, the acoustic characteristic at a predetermined listening position when the piano is played in the B hall, the acoustic characteristic at a predetermined listening position when the cello is played in the A hall, and the violin in the A hall. The storage unit 13 separately stores acoustic characteristics at a predetermined listening position when played as characteristics of the right ear and the left ear.

The acoustic characteristic stored in the storage unit 13, that is, the acoustic characteristic at a predetermined listening position when the musical instrument is played in a hall is obtained by synthesizing the directivity of the musical instrument and the response characteristic of the hall. ing. As the acoustic characteristics, generally, there are a frequency characteristic showing a change in sound level with respect to a change in frequency and a reverberation characteristic showing a change in reverberation time with respect to frequency. Since the frequency characteristic and the reverberation characteristic depend on the directivity of the musical instrument and the response characteristic of the space, in the present embodiment, the acoustic characteristic is combined with the directivity of the musical instrument and the response characteristic of the hall. It has gained.

The specific method will be described below with reference to FIGS. Since the directivity is simple, consider only the two-dimensional direction.

First, as shown in FIG. 2, an instrument (piano in FIG. 2) 31 to be measured is brought into an anechoic chamber 30, and a reference directional position P ₀ centered on the piano 31 is set at an angle of 0 °.
As a twelve-direction position to the 330 ° therefrom 30 ° intervals P _1, and set the P ₂ ··· P _11, in the direction position _{P 0, P 1 ····· P 11} , for example an acoustic Intel The sound level from the piano 31 is measured by the Citi method or the like. That is, the sound level at each radial position with respect to the piano 31 is measured. By carrying out this measurement for a plurality of scales, the positions P ₀ , P _1, ...
The frequency characteristic for each P ₁₁ is obtained as shown in FIG. Note that FIG. 3 shows frequency characteristics at the directional position P ₀ .

Next, in addition to the measurement of the directivity of each musical instrument, the response characteristic in the hall is measured as shown in FIG. First, for example, a sound source 41 having a narrow directivity is placed at a position where the musical instrument is to be played in the hall 40. From this narrow directional sound source 41, a measurement signal such as a TSP (Time Streched Pulse) signal is output. At this time, the narrow directional sound source 41 is rotated, for example, at an angle of 30 °, and a sound collecting device such as a microphone attached to the positions of the right and left ears of the dummy head 42 arranged at a predetermined listening position. Then, the response characteristic of the hole 40 is measured. Here, the measurement signal sound from the narrow directional sound source 41 rotating at an angle of 30 ° is collected and analyzed by the dummy head 42, and the characteristics of the right ear and the left ear are extracted.

That is, in general, unlike the case of measuring the acoustic characteristics of a hall, the directional characteristics at a predetermined listening position are not measured, but the acoustic characteristics of the hall are determined by the response characteristics according to the directivity of the sound source. You should pay attention to what you are looking for.

Then, the directivity characteristic which is the characteristic of the musical instrument and the response characteristic which is the characteristic of the hole obtained by measuring the directivity of the musical instrument are synthesized as shown in FIG.

As shown in FIG. 5, input terminals 51 ₀ , 51
₁ , 51 ₂ ... 51 ₁₁ and the angles 0 °, 30 °, 60 °, ... 330 ° obtained by the method described in FIG.
Data of the directional characteristics of the musical instruments and the input terminals 52 ₀ , 5
2 _1, 52 ₂ ... 52 ₁₁ FIG 4 by the method obtained in the angle 0 ° as described through, 30 °, 60 ° ... 330
° the data of the response characteristics of the holes in the right ear, the multipliers M _0, multiplied respectively by _{M 1, M 2 ··· M 11} , the multiplier _{M 0, M 1, M 2} ··· M 11 It is possible to obtain the acoustic characteristic of the right ear at a predetermined listening position when the musical instrument is played in the hall by adding and synthesizing the multiplication result from the adder A ₀ . Similarly, the acoustic characteristics of the left ear at a predetermined listening position when the musical instrument is played in the hall can be obtained. The storage unit 13 of the present embodiment stores the acoustic characteristics thus obtained.

Returning to FIG. 1, the operation of this embodiment will be described.
The description will be given assuming that the musical tone signal of the piano is supplied from the input terminal 11. In FIG. 1, an analog musical tone signal of, for example, a piano supplied from an input terminal 11 is collected by an instrument-mounted microphone or the like. The digital musical tone signal of the piano output from the A / D converter 12 is divided into two systems, one of which is read from the storage unit 13 and switched by the switching unit 14, and the acoustic characteristics in the B hole of the piano in the right ear. Then, a predetermined operation is performed by the operation unit 16, the analog tone signal is converted by the D / A converter 17, and the analog tone signal is output from the output terminal 18. A above
Similarly, the other signal of the digital tone signals output by the / D converter 12 is read from the storage unit 13 and the acoustic characteristics in the B-hole of the piano in the left ear switched by the switching unit 15 and the arithmetic unit 19 described above. A predetermined calculation is performed, an analog musical tone signal is generated by the D / A converter 20, and the analog musical tone signal is output from the output terminal 21. Output terminals 18, 21
The analog musical tone signal output from is supplied to headphones or the like via an amplifier (not shown) and is given to the right and left ears of the listener.

In the storage section 13, the characteristics of the right and left ears are acoustic characteristics in the B hall of the piano and A of the cello.
The acoustic characteristics in the hall and the acoustic characteristics in the A hall of the violin are stored, and these acoustic characteristics are switched by the switching units 14 and 15 as described above.

The switching section 14 has selected terminals a and b.
And c are provided to supply the acoustic characteristics in the B-hole of the piano, the acoustic characteristics of the A-hole of the cello and the acoustic characteristics of the A-hole of the violin in the right ear. When the changeover switch d of the changeover unit 14 is changed over to the selected terminal a, the arithmetic unit 16 is supplied with the acoustic characteristic in the B hole of the piano in the right ear.

Similarly, the switching section 15 is provided with selected terminals a, b, and c, and the acoustic characteristics of the B-hole of the piano, the acoustic characteristics of the A-hole of the cello, and the acoustics of the A-hole of the violin in the left ear. The property is supplied. When the changeover switch d of the changeover unit 15 is changed over to the selected terminal a, the calculation unit 19 is supplied with the acoustic characteristics in the B-hole of the piano in the left ear, for example.

The changeover switch d is changed over in the changeover sections 14 and 15 in accordance with the musical instrument for generating the tone signal input to the input terminal 11 of the sound field reproducing apparatus.
Switch by user.

Then, in the arithmetic unit 16, the A / D
The digital musical tone signal of the piano supplied from the converter 12 and the acoustic characteristic in the B hole of the piano in the right ear switched by the switching unit 14 are processed.

Similarly, in the arithmetic unit 19, the A / D
The digital musical tone signal of the piano supplied from the converter 12 and the acoustic characteristic in the B hole of the piano in the left ear switched by the switching unit 15 are processed.

The calculation output from the calculation unit 16, that is, the output obtained by calculating the acoustic characteristics of the right ear in the hall B with respect to the musical tone signal of the piano input from the input terminal 11, is D / A.
The analog tone signal is converted by the converter 17 and supplied to the headphones from the output terminal 18 via an amplifier (not shown) or the like, and reaches the right ear of the listener. Further, the calculation output from the calculation unit 19, that is, the output obtained by calculating the acoustic characteristics of the left ear in the hall B to the musical tone signal of the piano input from the input terminal 11, is converted into an analog musical tone signal by the D / A converter 20. Then, it is supplied from the output terminal 21 to the headphones through an amplifier (not shown) or the like, and reaches the left ear of the listener.

As described above, the present embodiment can simulate the acoustic characteristics of the hall in accordance with the directivity of each musical instrument.

The present invention is not limited to the above embodiment, and for example, regarding the input signal, A /
It may be a digital signal input / output without having a D / D / A converter, or may be a combination of analog input / output and an arithmetic part such as an analog delay and a filter. Also, the simulated characteristics are not performed by the dummy head, but by measuring the characteristics in multiple directions with a directional sound collector.
It is also possible to simulate a hall with multiple speakers.

The acoustic characteristics stored in the storage means are not limited to, for example, piano, cello, and violin, but various types such as guitar and drum.

Further, the storage means may store acoustic characteristics relating to human speech, and the acoustic characteristics in a desired space are calculated for the real voice input to the sound field reproducing apparatus. Good.

Furthermore, it is desirable to measure the directional characteristics of the musical instrument and the response characteristics in the hall at a finer angle. Moreover, it is not a two-dimensional direction such as a horizontal direction,
It is more realistic to measure the acoustic characteristics in three dimensions and combine the characteristics.

[0033]

The sound field reproducing device according to the present invention is a sound field reproducing device which reproduces an inputted musical tone signal by performing arithmetic processing on the basis of the acoustic characteristics of the sound field. Since it has storage means for storing acoustic characteristics and operation means for arithmetically processing the inputted musical tone signal using the acoustic characteristics stored in the storage means, a space in accordance with the directivity of each sounding body is provided. The characteristics of can be simulated.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of a present embodiment.

FIG. 2 is a diagram for explaining a method of measuring the directivity of a musical instrument.

FIG. 3 is a diagram showing frequency characteristics obtained by a method of measuring directivity of a musical instrument.

FIG. 4 is a diagram for explaining a method of measuring the response characteristic of a hole.

FIG. 5 is a diagram for explaining a method of synthesizing characteristics to be simulated in a desired space of a musical instrument stored in a storage means.

[Explanation of symbols]

12 ... Analog / Digital (A / D) converter 13 ... Storage unit 14,15 ... Switching unit 16,19 ... Calculation unit 17,20 ... Digital / Analog (D / A) converter

Claims (5)

[Claims] 1. A sound field reproducing apparatus for reproducing an inputted musical tone signal by performing arithmetic processing based on the acoustic characteristic of the sound field, and a storage means for storing acoustic characteristics of a sounding body and / or space. A sound field reproducing apparatus, comprising: an arithmetic unit that arithmetically processes the input musical tone signal by using the acoustic characteristics stored in the storage unit. 2. The sound field reproducing device according to claim 1, wherein the acoustic characteristics stored in the storage means are characteristics in consideration of the directional characteristics of the sounding body. 3. The sound field reproducing apparatus according to claim 1, wherein the acoustic characteristic stored in the storage means is a characteristic in consideration of a response characteristic to a sounding body having a spatial directivity. 4. The storage means stores the acoustic characteristics of a plurality of sounding bodies, and the switching of the acoustic characteristics of the plurality of sounding bodies is performed by a switching means. Sound field playback device. 5. The acoustic characteristics of a plurality of spaces are stored in the storage means, and switching of the acoustic characteristics of the plurality of spaces is performed by the switching means.
The sound field reproducing device described in 2, 3, or 4.