JP5673070B2 - Conversation sound leakage prevention device - Google Patents

Description

  The present invention relates to a technique for ensuring the confidentiality of conversation using a masking effect.

  Various techniques for securing the confidentiality of conversation using the masking effect have been proposed. The masking effect is that when two types of sound are propagated in the same space, the listener in the space can hear one sound (target sound) and the other sound (masker sound) can interfere. It is a phenomenon to receive. For example, Patent Literature 1 discloses a technique for preventing leakage of conversation between two adjacent spaces across a partition using a masking effect. In the technique disclosed in this document, a directional speaker is fixed to an upper part of a partition separating two spaces, and a reflecting member capable of adjusting a reflection angle is fixed to a position corresponding to the speaker on the ceiling. In this technique, when a speaker talks in one of two adjacent spaces across a partition, the masking sound is emitted from the directional speaker after the reflecting direction of the reflecting member is tilted toward the other space. Let it sound. According to this technique, it is possible to prevent a situation in which a masker sound is heard on the side of a talking speaker and the conversation becomes difficult.

Japanese Patent Laid-Open No. 06-175666

  By the way, in an area where the masking effect needs to be generated in almost all external directions, such as a booth surrounded by partitions on all sides, a plurality of speakers are arranged in the surrounding partitions, and a masker is formed from each. Sound may be emitted. Since the technique of Patent Document 1 needs to fix the reflection member to the ceiling and adjust the reflection angle, it is difficult to apply the technique when using a plurality of speakers. Therefore, in this case, by fixing the plurality of speakers to the partition with each sound emitting surface facing outward, the level of masker sound propagated in the region can be reduced to some extent. However, according to this technical means, the masker sound emitted from each speaker may be affected by the speaker in the area depending on the length of the wavelength of the sound wave included in the masker sound emitted from each speaker around the area. There is a problem in that the sound pressure level is locally increased by being added almost in phase at a certain position, and the speaker is uncomfortable.

  The present invention has been devised under such a background, and while ensuring a sufficient masking effect outside the area surrounded by the partition, it reduces the uncomfortable feeling given to the speakers in the area. For the purpose.

  The present invention provides a plurality of sound emitting means and a masker sound signal, which is a sound signal that makes it difficult to hear a conversation sound generated in a certain area outside the area, through each of the plurality of sound emitting means. A means for emitting sound, wherein the masker sound signal is supplied to some of the plurality of sound emitting means, and the remaining sound emitting means is supplied to the part of the sound emitting means. There is provided a conversation sound leakage prevention apparatus comprising control means for supplying a reverse phase masker sound signal that is opposite in phase to the masker sound signal.

  According to the present invention, masker sounds having opposite phases are emitted from some of the plurality of sound emitting means and the other sound emitting means. When masker sounds that are out of phase with each other are emitted from some of the plurality of sound emitting means and other sound emitting means, even if the sound wave of any wavelength is included in the masker sound, The sound pressure level in the region does not increase locally. Therefore, according to the present invention, it is possible to reduce discomfort given to the speakers in the area while securing the masking effect outside the area.

It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 1st Embodiment of this invention. It is a figure for demonstrating the content of the verification which confirms the effect of the conversational sound leakage prevention apparatus. It is a figure which shows the result of the same verification. It is a figure for demonstrating the content of the verification which confirms the effect of the conversation leakage prevention apparatus which is 1st Embodiment of this invention. It is a figure which shows the result of the same verification. It is a figure which shows the result of the same verification. It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 2nd Embodiment of this invention. It is a figure for demonstrating the content of the verification which confirms the effect of the conversational sound leakage prevention apparatus. It is a figure which shows the result of the same verification. It is a figure which shows the result of the same verification. It is a figure which shows the result of the same verification. It is a figure which shows the result of the same verification. It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 3rd Embodiment of this invention. It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 4th Embodiment of this invention. It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 5th Embodiment of this invention. It is a figure which shows the result of the verification which confirms the effect of the conversational sound leakage prevention apparatus. It is a figure which shows the structure of the conversational sound leakage prevention apparatus which is 6th Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
FIG. 1 is a diagram showing a configuration of a conversation sound leakage preventing apparatus 10 according to the first embodiment of the present invention. The conversation sound leakage prevention apparatus 10 uses the conversation sound between the speakers S1 and S2 in the center of the booth 90 surrounded by the partitions 91F, 91R, 91B, 91L as the target sound T, and uses the target sound T as the booth 90. A masker sound M, which is difficult for the outside listener U to hear, is emitted toward the outside of the booth 90.

  In FIG. 1, the conversation sound leakage preventing apparatus 10 includes a control unit 1, speakers 1-1-m (m = 1-8), and 1-2-m (m = 1-8). The control unit 1 includes a masker sound storage unit 11, a CPU 12, a RAM 14, a ROM 15, D / A conversion units 16-1 and 16-2, and amplifier units 7-1-m (m = 1 to 8), 7-2- m (m = 1 to 8). The role of the control unit 1 will be described later.

  The speakers 1-1-m (m = 1 to 8) and 1-2-m (m = 1 to 8) are devices that serve as sound emitting means for emitting the masker sound M. Each speaker 1-1-m in the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) is connected to the amplifier unit 7-1-m in the control unit 1. ing. Each speaker 1-2-m is connected to an amplifier unit 7-2-m in the control unit 1. The speakers 1-1-m (m = 1 to 8) and 1-2-m (m = 1 to 8) are speakers 1-1 that are supplied with output signals of the amplifier unit 7-1-m. -M and speakers 1-2m to which the output signal of the amplifier unit 7-2-m is supplied are alternately arranged and arranged in each of the partitions 91F, 91R, 91B and 91L. The sound emission surfaces of the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) are directed to the outside of the booth 90.

  There is a gap D1 between the upper ends of the partitions 91F, 91R, 91B and 91L1 and the ceiling (not shown). Most of the sounds emitted from the speakers 1-2m and 1-2m are propagated to spaces outside the partitions 91F, 91R, 91B, and 91L1, but the speakers 1-2m and 1 A part of each sound emitted from −2−m wraps around the gap D1, and is transmitted from the gap D1 into the booth 90 surrounded by the partitions 91F, 91R, 91B, and 91L1.

  Next, the role of the control unit 1 will be described. The control unit 1 is connected to some speakers 1-1-m (m = 1-8) among the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8). A masker sound signal M (k) (k is an index indicating time) is supplied as a signal of the masker sound M, and the remaining masker 1-2m (m = 1 to 8) is connected to the masker sound signal M (k). Supplies a negative phase masker sound signal -M (k).

  More specifically, the masker sound storage unit 11 in the control unit 1 stores masker sound data MD. The masker sound data MD is data generated by performing the following processing on a sound sample train of sound recorded using a microphone (not shown) or the like. First, the sound sample of the voice is written in the memory, and the sound sample in the memory is divided into frames of a predetermined time length. Next, those frames are read out in the reverse direction to the writing, and a series of frames read out in the reverse direction is set as masker sound data MD. The sound indicated by the masker sound data MD generated as described above is not the same as the sound (human voice) but has an acoustic feature similar to that. A sound having such an acoustic feature can generate a high masking effect when sound is emitted in the same space as the sound.

  The CPU 12 executes a masker sound signal generation program stored in the ROM 15 while using the RAM 14 as a work area. The masker sound signal generation program is a program that causes the CPU 12 to realize the functions of the masker sound generation unit 31, the distribution unit 32, and the phase inversion unit 33. The masker sound generation unit 31 acquires sound samples in the masker sound data MD in the masker sound storage unit 11 from the storage unit 11 and outputs these sound samples to the distribution unit 32 as a masker sound signal M (k). repeat.

  The distribution unit 32 branches the output signal M (k) of the masker sound generation unit 31 into masker sound signals M (k) of two channels and outputs them. The phase inverting unit 33 inverts the phase of the sound signal M (k) of one channel out of the two channels of sound signals M (k) output from the distributing unit 32, and the sound signal −M ( k) is output. The output signal −M (k) of the phase inverting unit 33 is input to the D / A conversion unit 16-2. The sound signal M (k) of the other channel output from the distributing unit 32 is input to the D / A converting unit 16-1 as it is without undergoing phase inversion by the phase inverting unit 33. The D / A conversion unit 16-1 converts the sound signal M (k) output from the distribution unit 32 into an analog waveform signal, and outputs the analog waveform signal to the amplifier unit 7-1-m (m = 1 to 8). The analog waveform signal output from the D / A conversion unit 16-1 is amplified by the amplifier unit 7-1-m (m = 1 to 8), and then the speaker 1-1-m (m = 1 to 8). And is emitted as a masker sound M from the speakers 1-1-m (m = 1 to 8). The D / A conversion unit 16-2 converts the sound signal -M (k) output from the phase inverting unit 33 into an analog waveform signal and outputs the analog waveform signal to the amplifier unit 7-2-m (m = 1 to 8). . The analog waveform signal output from the D / A conversion unit 16-2 is amplified by the amplifier unit 7-2-m (m = 1 to 8), and then the speaker 1-2m (m = 1 to 8). And is emitted as a masker sound M from the speaker 1-2m (m = 1 to 8).

  The above is the details of the configuration of the conversation sound leakage prevention apparatus 10 in the present embodiment. According to the present embodiment, while ensuring the masking effect outside the booth 90, which is an area surrounded by the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8). The discomfort given to the speakers S1 and S2 in the booth 90 can be reduced. The reason why such an effect occurs is as follows. As described in the background section, all the masker sounds M emitted from the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) are assumed to be in phase. In this case, when the following two conditions a1 and b1 are satisfied, the maskers emitted from the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) are used. The sound M is added in approximately the same phase at a certain position R in the booth 90, and the sound pressure level at the position R is locally increased, giving discomfort to the speakers S1 and S2 at the position R.

Condition a1. The wavelength λ of the masker sound M is the maximum value DIFF of the difference between each distance from each of the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) to the position R. Longer than _MAX (in the central region in the partition 90, the distance from each of the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) to the central region. (The difference between the two becomes almost zero, and the sound pressure level locally increases regardless of the wavelength of the masker sound M.)
Condition b1. The upper ends of the partitions 91F, 91R, 91B and 91L1 provided with the speakers 1-1-m (m = 1 to 8) and 1-2m (m = 1 to 8) and the speakers 1-1-m and 1 -M is sufficiently smaller than the wavelength of the sound emitted from each speaker 1-1-m and 1-2m, and each speaker 1-1-m and 1-2m The distance from the sound that is emitted from the door is sufficiently small to diffract into the gap D1 and wrap around the booth 90

  On the other hand, in this embodiment, some speakers 1-1-m (m = 1) among the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8). To 8) and the remaining other speaker 1-2m (m = 1 to 8) are supplied with the masker sound signal M and the reverse phase masker sound signal -M, respectively, and the speaker 1-1-m (m = 1 to 1). 8) and 1-2m (m = 1 to 8), masker sounds M having opposite phases are emitted. For this reason, it is assumed that part of the sound emitted from the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) has entered the booth 90 from the gap D1. Among these sounds, the sound emitted from the speaker 1-1-m (m = 1 to 8) and the sound emitted from the speaker 1-2m (m = 1 to 8) are included in the booth 90. In each other. Therefore, in the present embodiment, regardless of the conditions a1 and b1, the phenomenon in which the sound pressure level locally increases in the booth 90 does not occur.

  Moreover, in this embodiment, each speaker 1-1-m of the supply destination of the masker sound signal M in the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) The speakers 1-2m to which the masker sound signal -M is supplied are alternately arranged around the booth 90 one by one. For this reason, the sound pressure level in the booth 90 is almost uniform without being biased, and the local increase in the sound pressure level in the booth 90 can be more reliably prevented.

  Furthermore, in the present embodiment, the speaker 1-1-m (m) is obtained from the geometrical arrangement relationship of the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8). = 1 to 8) and 1-2m (m = 1 to 8), there is no position outside the booth 90 where the sounds emitted from each other cancel each other. 1 to 8) and 1-2m (m = 1 to 8), the same masking effect as when the in-phase masker sound M is emitted can be generated outside the booth 90.

The inventor of the present application performed the following two verifications in order to confirm the effects of the present embodiment described above. In the first verification, the inventor selected one measurement point representative of the inside and outside of the area surrounded by the partition. In addition, the sound between the case where the sound signal M (k) is supplied to all speakers around the area and the case where the sound signals M (k) and -M (k) are supplied to half of the speakers, respectively. The difference in pressure level was calculated for each measurement point. More specifically, as shown in FIG. 2, the inventor adds speakers 5-1-1, 5-2-1 to the partitions 51 F in the four partitions 51 F, 51 R, 51 B, and 51 L surrounding the area 50. , 5-1-2, and 5-2-2, and speakers 5-1-3, 5-2-3, 5-1-4, and 5-2-4 are arranged in the partition 51R. Further, speakers 5-1-5, 5-2-5, 5-1-6, and 5-2-6 are arranged in the partition 51B, and speakers 5-1-7, 5-2-7, and 5-2-7 are arranged in the partition 51L. 5-1-8 and 5-2-8 were arranged. Further, the width WF of the partition 51F, the width WR of the partition 51R, the width WB of the partition 51B, the width WL of the partition 51L, the gap D between the upper ends of the partitions 51F, 51R, 51B and 51L and the ceiling, and the speaker in the partition 51F Arrangement interval IF, speaker arrangement interval IR in partition 51R, speaker arrangement interval IB in partition 51B, speaker arrangement interval IL in partition 51L, and upper ends of partitions 51F, 51R, 51B and 51L. Table 1 below shows the distance DP between each speaker. In addition, a point that is 1100 mm above the floor surface at the center of the floor surface in the region 50 is defined as the first measurement point P11, and is separated from the partition 51B by the same distance between the partition 51B and the measurement point P11. The point was designated as a second measurement point P12.

  And the sound pressure level when the sound signal M (k) is supplied to all of the speakers 5-1 -m (m = 1 to 8) and 5-2 -m (m = 1 to 8) (hereinafter, for convenience, The sound signal M (k) and the sound signal −M (k) are sent to the speakers 5-1 -m (m = 1 to 8) and 5-2-m (m = 1 to 8). The sound pressure level when supplied (hereinafter referred to as the negative phase added sound pressure level) was obtained, and the difference (dB value) between the negative phase added sound pressure level and the common phase added sound pressure level was calculated. FIG. 3 is a diagram showing a difference in sound pressure level for each frequency at each of the measurement points P11 and P12.

  In the graph of FIG. 3, the sound pressure level difference at 125 Hz at the measurement point P12 is −15 dB. In contrast, the 125 Hz sound pressure level difference at the measurement point P11 is -24 dB, which is 9 dB lower than that at the measurement point P12. Further, the sound pressure level difference at 250 Hz at the measurement point P12 is −6 dB. On the other hand, the sound pressure level difference of 250 Hz at the measurement point P11 is −22 dB which is 16 dB lower than that at the measurement point P12. Further, the sound pressure level difference of 500 Hz at the measurement point P12 is −4 dB. On the other hand, the sound pressure level difference at 500 Hz at the measurement point P11 is -16 dB, which is 12 dB lower than that at the measurement point P12. From the above, the value of the difference between the anti-phase added sound pressure level and the in-phase added sound pressure level outside the region 50 is compared with the value of the difference between the anti-phase added sound pressure level and the in-phase added sound pressure level outside the region 50. In particular, it can be seen that there is a marked decrease in the low frequency range (the absolute value of the difference is large). From this, it is understood that local increase in the sound pressure level in the region 50 can be prevented by reproducing the masker sound in reverse phase.

In the second verification, the inventor changed the arrangement of the partition surrounding the area, the arrangement of the speaker on the partition, and the positions of the measurement points inside and outside the area from those of the first verification, and then the speaker surrounding the area. The difference in sound pressure level between the case where the sound signal M (k) is supplied to all of the speakers and the case where the sound signal M (k) and the sound signal −M (k) are respectively supplied to half of the speakers was obtained. . More specifically, as shown in FIG. 4, the inventor puts the speaker 6-1-1 in the partition 61R in the five partitions 61L ′, 61F, 61R, 61B, and 61L spirally surrounding the region 60. 6-2-1, 6-1-2, and 6-2-2. Speakers 6-1-3, 6-2-3, 6-1-4, and 6-2-4 are arranged in the partition 61B, and speakers 6-1-5, 6-2-5, and the partition 61L. 6-1-6 and 6-2-6 were placed. Further, the horizontal width WL ′ of the partition 61L ′, the horizontal width WF of the partition 61F, the horizontal width WR of the partition 61R, the horizontal width WB of the partition 61B, the horizontal width WL of the partition 61, the upper end and the ceiling of the partitions 61L′61F, 61R, 61B, and 61L Is provided below the upper end of the partitions 61R, 61B, and 61L, and the speaker arrangement interval IR of the partition 61B, the speaker arrangement interval IB of the speaker 61L, and the speaker arrangement interval IL of the partition 61L. Table 2 below shows the distance DP between the speakers. In addition, a point 1100 mm above the floor surface at a position 660 mm away from the center point C of the floor surface in the region 60 toward the partition 61B is defined as a first measurement point P21. A point 3700 mm away from the measurement point P21 toward the outside of the partition 61B was taken as a second measurement point P22.

  And the sound pressure level when the sound signal M (k) is supplied to all of the speakers 6-1-n (n = 1 to 6) and 6-2-n (n = 1 to 6) (hereinafter, for convenience, The sound signals M (k) and -M (k) are respectively supplied to the in-phase added sound pressure level and the speakers 6-1-n (n = 1 to 6) and 6-2-n (n = 1 to 6). The sound pressure level (hereinafter referred to as a reverse phase added sound pressure level for convenience) was calculated. FIG. 5 is a diagram in which the in-phase added sound pressure level and the reversed-phase added sound pressure level at the measurement point P22 and an NC (Noise Criteria) curve are overlapped. Here, the NC curve is a group of curves for evaluating room noise having a broadband spectrum. FIG. 6 is a diagram in which the in-phase added sound pressure level and the reversed-phase added sound pressure level at the measurement point P21 and the NC curve are superimposed.

  In the graph of FIG. 5, the 125 Hz in-phase added sound pressure level at the measurement point P22 and the 125 Hz anti-phase added sound pressure level at the measurement point P22 are both slightly below NC25, and there is almost no difference between the two. . The 250 Hz in-phase added sound pressure level at the measurement point P22 is slightly higher than NC35 (46 dB), whereas the 250 Hz in-phase added sound pressure level at the measurement point P22 is slightly higher than NC30 (43 dB). ) And there is not much difference between the two.

  In the graph of FIG. 6, the 125 Hz in-phase added sound pressure level at the measurement point P21 is about NC30 (49 dB). On the other hand, the 125 Hz anti-phase added sound pressure level at the measurement point P21 is reduced to a level lower than NC20 (40 dB). Further, the in-phase added sound pressure level of 250 Hz at the measurement point P22 is about the middle (56 dB) of NC45-50. On the other hand, the anti-phase added sound pressure level of 250 Hz at the measurement point P22 is reduced to a level slightly lower than NC35 (45 dB). From the above, at the measurement point 22 outside the region 60, there is no significant sound pressure level difference between the in-phase addition sound pressure level and the reverse-phase addition sound pressure level, but at the measurement point 21 in the region 60, It can be seen that the reverse phase added sound pressure level can be significantly reduced in the low frequency range from 125 Hz to 250 Hz.

Second Embodiment
FIG. 7 is a diagram showing a configuration of a conversational sound leakage prevention apparatus 10A that is the second embodiment of the present invention. This conversation sound leakage prevention device 10A is obtained by adding a masker sound storage unit 19 and a masker sound generation unit 34 to the control unit 1 of the conversation sound leakage prevention device 10 in the first embodiment. The masker sound storage unit 19 stores masker sound data MD ′. The masker sound data MD ′ is a sound sample string of environmental sounds (for example, a stream sound of Ogawa). The masker sound generation unit 34 acquires sound samples in the masker sound data MD ′ in the masker sound storage unit 19 from the storage unit 19, and uses these sound samples as a masker sound signal M ′ (k). And 20-2 are repeated. In the adder 20-1, the signal M (k) and the signal M ′ (k) are added, and the added signal M (k) + M ′ (k) is input to the D / A converter 16-1. The adder 20-2 adds the signal −M (k) and the signal M ′ (k), and inputs the added signal −M (k) + M ′ (k) to the D / A converter 16-2. .

  The above is the details of the configuration of the conversation sound leakage prevention apparatus 10A in the present embodiment. In the present embodiment, a sound signal having a sound characteristic similar to that of a sound is referred to as a masker sound signal M (k), and an environmental sound signal is referred to as a masker sound signal M ′ (k). Of these two types of sound signals M (k) and M ′ (k), the sound signal M (k) containing a relatively large amount of low-frequency components is output from the speakers 1-1-m and 1-2m. Sounds are emitted as masker sounds M having opposite phases. Further, the sound signal M ′ (k) that hardly contains the low frequency component is emitted as the in-phase masker sound M from the speakers 1-1-m and 1-2m. According to this embodiment, the same effect as that of the first embodiment can be obtained.

The inventor of the present application performed the following third verification in order to confirm the effect of the present embodiment.
In the third verification, the inventor selected three measurement points from inside and outside the area surrounded by the partition having the same arrangement as in the second verification. In addition, the sound signals M (k) + M ′ (k) and −M (k) are supplied to all speakers around the area when the sound signals M (k) + M ′ (k) are supplied to the speakers. The difference in sound pressure level between when + M ′ (k) was supplied was calculated. More specifically, as shown in FIG. 8, the inventor determines the layout and dimensions of the partitions 61L ′, 61F, 61R, 61B, and 61L surrounding the area 60 from those of the second verification (Table 2). Similarly, a point 1100 mm above the floor surface at the center point of the floor surface in the region 60 is defined as a first measurement point P31. A point 660 mm away from the measurement point P31 toward the partition 61B was taken as a second measurement point P32, and a point 340 mm away from the measurement point P31 towards the opposite side of the partition 61B was taken as a third measurement point P33. A point 3700 mm away from the measurement point P32 toward the outside of the partition 61B was taken as a fourth measurement point P34. A point that is approximately 300 mm away from the measurement point P34 in a direction parallel to the partition 61B is defined as a fifth measurement point P35, and a point that is approximately 300 mm away from the measurement point P35 in a direction parallel to the partition 61B is defined as a sixth measurement point P36. It was.

  The sound pressure level when the sound signals M (k) + M ′ (k) are supplied to all of the speakers 6-1-n (n = 1 to 6) and 6-2-n (n = 1 to 6). (Hereinafter referred to as in-phase additive sound pressure level for convenience) and the sound signals M (k) + M ′ (k) to the speakers 6-1-n (n = 1-6) and 6-2-n (n = 1-6). ) And −M (k) + M ′ (k), respectively, were calculated (hereinafter referred to as an anti-phase added sound pressure level for convenience). FIG. 9 is a diagram in which the in-phase added sound pressure levels at the measurement points P34, P35, and P36 and the NC curve are overlapped. FIG. 10 is a diagram in which the anti-phase added sound pressure levels at the measurement points P34, P35, and P36 are overlaid with the NC curve. FIG. 11 is a diagram in which the in-phase added sound pressure levels at the measurement points P31, P32, and P33 are overlaid with the NC curve. FIG. 12 is a diagram in which the respective antiphase added sound pressure levels at the measurement points P31, P32, and P33 are overlaid with the NC curve.

  In the graph of FIG. 9, the 125 Hz in-phase added sound pressure level at the measurement points P34, P35, and P36 is about NC25 (all of the measurement points P34, P35, and P36 are 46 dB), and at the measurement points P34, P35, and P36. The in-phase added sound pressure level of 250 Hz is within the range of NC35 to 40 (measurement point P34: 46 dB, measurement point P35: 49 dB, measurement point P36: 47 dB). On the other hand, in the graph of FIG. 10, the anti-phase added sound pressure level at 125 Hz of the measurement points P34, P35, and P36 is within the range of NC20 to 25 (measurement point P34: 44 dB, measurement point P35: 43 dB, measurement point P36: 44 dB), and the anti-phase added sound pressure level at 250 Hz at the measurement points P34, P35, and P36 is within the range of NC30 to 35 (measurement point P34: 43 dB, measurement point P35: 42 dB, measurement point P36: 42 dB). Comparing the graphs of FIGS. 9 and 10, it can be seen that there is no significant difference between the in-phase added sound pressure level and the reverse-phase added sound pressure level outside the region 60.

  In the graph of FIG. 11, the in-phase added sound pressure level at 125 Hz at the measurement points P31, P32, and P33 is within the range of NC25 to 30 (measurement point P31: 48 dB, measurement point P32: 49 dB, measurement point P33: 46 dB). The in-phase added sound pressure level at 250 Hz at the measurement points P31, P32, and P33 is within the range of NC40 to 50 (measurement point P31: 59 dB, measurement point P32: 58 dB, measurement point P33: 53 dB). On the other hand, in the graph of FIG. 12, the 125 Hz anti-phase added sound pressure level at the measurement points P31, P32, and P33 is within NC20 or less (measurement point P31: 41 dB, measurement point P32: 40 dB, measurement point P33: 41 dB). ), And the 250 Hz reverse phase added sound pressure level at the measurement points P31, P32, and P33 is within the range of NC35 or less (measurement point P31: 45 dB, measurement point P32: 44 dB, measurement point P33: 45 dB). Comparing the graphs of FIGS. 11 and 12, the difference between the in-phase added sound pressure level and the anti-phase added sound pressure level is larger in the region 60 than in the region 60 outside, particularly in the low sound range of 124 Hz to 250 Hz. I understand that.

  From the above, even if the signal supplied to a plurality of speakers around a certain region includes the environmental sound signal M ′ (k), the masker sound emitted from some speakers is reversed. It is proved that the phase reproduction can prevent a local increase in the sound pressure level in the region.

<Third Embodiment>
FIG. 13 is a diagram showing a configuration of a conversation sound leakage prevention apparatus 10B according to the third embodiment of the present invention. This conversation sound leakage prevention apparatus 10B is obtained by replacing the phase inversion unit 33 in the conversation sound leakage prevention apparatus 10 (FIG. 1) of the first embodiment with an APF (All Pass Filter) 35. The APF 35 outputs a sound signal -M (k) in which only the low frequency phase of the sound signal M (k) output from the distributing unit 32 is reversed. More specifically, in the present embodiment, the APF 35 is configured by a first-order IIR (Infinite Impulse Response) filter having a transfer function H expressed by the following equation.
H = (b0 + b1z) / (a0 + a1z) (1)

B0 in the equation (1) is given by the following equation (2). B1 in the formula (1) is given by the following formula (3). A0 in the equation (1) is given by the following equation (3). A1 in the formula (1) is given by the following formula (4). Z in the equation (1) is given by the following equation (5).
b0 = (2πf0−2 / T) (2)
b1 = (2πf0 + 2 / T) (3)
a0 = -b1 (4)
a1 = −b0 (5)
z = exp (−j2πfT) (6)

In Expression (6), exp is an exponential function that calculates the power of e. F0 in the equations (2) and (3) is a cutoff frequency. T in the equations (2), (3), and (6) is given by the following equation (7).
T = 1 / fs (7)
Fs in Equation (7) is a sampling frequency.

  The above is the details of the configuration of the conversation sound leakage prevention apparatus 10B in the present embodiment. In the present embodiment, only the phase of the frequency component in the frequency band that is easily diffracted in the masker sound signal M (k) generated by the masker sound generator 31 is rotated by the APF 35. Thereby, it is possible to reliably prevent a local increase in sound pressure in the region surrounded by the speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8). .

<Fourth embodiment>
FIG. 14 is a diagram showing a configuration of a conversational sound leakage prevention apparatus 10C according to the third embodiment of the present invention. As shown in FIG. 14, in the present embodiment, around the booth 90, seven partitions 92-1-i (assembled so that the intersection angle between the adjacent partitions 92-1-i becomes an obtuse angle. i = 1 to 3), 92-2i (i = 1 to 3), and 92-3. A speaker 2-1-i is fixed to each partition 92-1-i. A speaker 2-2i is fixed to each partition 92-2i. Each speaker 2-1-i is connected to an amplifier unit 8-1-i in the control unit 1. Each speaker 2-2-i is connected to an amplifier unit 8-2-i in the control unit 1. In the present embodiment, the masker sound signal M (k) is supplied from the amplifier unit 8-1-i to the speaker 2-1-i, and the masker sound signal -M (k) is supplied from the amplifier unit 8-2-i to the speaker 2. -2 to i. As a result, maskers with opposite phases are emitted from the adjacent speakers 2-2-i and 2-2-i on the partition 92-1-i. Therefore, the present embodiment can achieve the same effects as those of the first embodiment.

<Fifth Embodiment>
FIG. 15 is a diagram showing a configuration of a conversational sound leakage prevention apparatus 10D according to the fifth embodiment of the present invention. In the present embodiment, the present invention is applied to prevention of leakage of conversational sound in a region not surrounded by partitions. In the example of the present embodiment, the speakers S3 and S4 are not surrounded by partitions, and the speakers S3 and S4 face each other with a substantially linear counter 80 interposed therebetween. Six speakers 3-1-i (i) arranged in parallel with the counter 80 at positions separated from the counter 80 by a distance DA in a direction perpendicular to the extending direction (in the example of FIG. 15, the direction of the speaker S 3). = 1 to 3) and 3-2-i (i = 1 to 3). The sound emission surfaces of the speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) are directed in the direction opposite to the direction in which the counter 80 is located. Speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) are adjacent to each other (speaker 3-1-1 and speaker 3-2-1, speaker 3). -2-1, speaker 3-1-2, speaker 3-1-2, speaker 3-2-2, speaker 3-2-2, speaker 3-1-3, speaker 3-1-3, and speaker 3- 2-3) are separated by the same distance DB. Here, the above-described distance DA is obtained by listening to the conversation sound between the speakers S3 and S4 from these speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3). The distance DC is shorter than the distance DC to the listener U to be blocked.

  Each of the speakers 3-1-i of the speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) is connected to the amplifier unit 9-1-i in the control unit 1. It is connected. Each speaker 3-2-i is connected to an amplifier unit 9-2-i in the control unit 1. In the present embodiment, the masker sound signal M (k) is supplied from the amplifier unit 9-1-i to the speaker 3-1-i, and the masker sound signal -M (k) is supplied from the amplifier unit 9-2-i to the speaker 3. -2 to i. As a result, in this embodiment, each speaker 3-1-i and each speaker 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) are adjacent to each speaker 3-1-i. Masker sounds with opposite phases are emitted from the speaker 3-2-i. Therefore, the present embodiment can achieve the same effects as those of the first embodiment.

The inventor of the present application performed the following fourth verification in order to confirm the effect of the present embodiment.
In the fourth verification, the distance DA between the counter 80 and the speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) in FIG. -1-1 and 3-2-1, between speakers 3-2-1 and 3-1-2, between speakers 3-1-2 and 3-2-2, and speakers 3-2-2 and 3-1. -3, and the distance DB between the speakers 3-1-3 and 3-2-3 was 1000 mm. Then, a position 500 mm away from the midpoint between the speakers 3-1 and 3-2-1 toward the counter 80 (corresponding to the position of the speaker S 3 in FIG. 15) is defined as the first measurement point P 41. A position (corresponding to the position of the listener U in FIG. 15) at a distance of 2000 m from the midpoint between the speakers 3-1-1 and 3-2-1 to the opposite side of the counter 80 was taken as a second measurement point P42. And the sound pressure level when the sound signal M (k) is supplied to all the speakers 3-1-i (i = 1 to 3) and 3-2-i (i = 1 to 3) (hereinafter, for convenience, And the sound pressure level when the sound signals M (k) and -M (k) are supplied to each of them in half (hereinafter referred to as the anti-phase added sound pressure level). The difference (dB value) between the anti-phase added sound pressure level and the in-phase added sound pressure level was calculated. FIG. 16 is a diagram showing a difference in sound pressure level for each frequency at each of the measurement points P41 and P42.

  In the graph of FIG. 16, the sound pressure level difference at 125 Hz at the measurement point P42 is −7 dB. On the other hand, the 125 Hz sound pressure level difference at the measurement point P41 is -12 dB, which is 5 dB lower than that at the measurement point P42. Further, the sound pressure level difference at 250 Hz at the measurement point P42 is 0 dB. On the other hand, the sound pressure level difference of 250 Hz at the measurement point P41 is -11 dB, which is 11 dB lower than that at the measurement point P41. Further, the sound pressure level difference at 500 Hz at the measurement point P42 is −5 dB. On the other hand, the sound pressure level difference of 500 Hz at the measurement point P41 is -14 dB, which is 9 dB lower than that at the measurement point P42. This confirms that the sound pressure level in the vicinity of the seat of the counter 80 can be greatly reduced, particularly in the frequency band from 250 Hz to 1000 Hz.

<Sixth Embodiment>
FIG. 17 is a diagram showing the configuration of a conversational sound leakage prevention apparatus 10E that is the sixth embodiment of the present invention. In the first embodiment, the speaker to which the masker sound signal M is supplied and the speaker to which the masker sound signal -M of the opposite phase is supplied are alternately arranged one by one around the area where the speaker is present. It was. On the other hand, in the present embodiment, a plurality of speakers serving as masker sound signals M and a speaker serving as a reverse-phase masker sound signal -M are provided around the area where the speaker is present (see FIG. 17). 2 in the example) are arranged alternately. More specifically, in the present embodiment, speakers 1-1-m (m = 1-8) and 1-2-m (m = 1-8) are provided in partitions 91F, 91R, 91B, and 91L, respectively. Four are arranged in each. Then, the masker sound signal M (k) is supplied to the speakers 1-1-1 and 1-1-2 in the partition 91F, and the masker sound signal -M is supplied to the speakers 1-2-1 and 1-2-2 in the partition 91F. (K) is supplied. Further, the masker sound signal M (k) is supplied to the speakers 1-1-3 and 1-1-4 in the partition 91R, and the masker sound signal -M is supplied to the speakers 1-2-3 and 1-2-4 in the partition 91R. (K) is supplied. Further, the masker sound signal M (k) is supplied to the speakers 1-1-5 and 1-1-6 in the partition 91B, and the masker sound signal -M is supplied to the speakers 1-2-5 and 1-2-6 in the partition 91B. (K) is supplied. Further, the masker sound signal M (k) is supplied to the speakers 1-1-7 and 1-1-8 in the partition 91L, and the masker sound signal -M is supplied to the speakers 1-2-7 and 1-2-8 in the partition 91L. (K) is supplied. Also according to this embodiment, the same effects as those of the first embodiment can be obtained.

The first to sixth embodiments of the present invention have been described above. However, the present invention may have other embodiments. For example, it is as follows.
(1) In the first embodiment, the masker sound signal M (k) generated by the masker sound generator 31 is distributed to two channels by the distributor 32, and one of the two-channel sound signals M (k) is distributed. The phase was inverted by the signal inverter 33 and then supplied to the speaker 1-2m (m = 1 to 8). However, the means for inverting the phase of the sound signal supplied to the speaker 1-2m (m = 1 to 8) is not limited to this. For example, the positive and negative terminal connections of the cable in the speaker 1-2m (m = 1 to 8) are reversed from the positive and negative terminal connections of the cable in the speaker 1-1-m (m = 1 to 8). May be. Further, masker sound data MD for two channels for normal phase reproduction and reverse phase reproduction are stored in advance in the masker sound storage unit 11, and the sound signal of the masker sound data MD for normal phase reproduction is stored in the same unit 11. Is read out from the unit 12 and supplied to the speaker 1-1-m (m = 1 to 8), and the sound signal of the masked sound data MD for reverse phase reproduction is read out from the same section 12 and the speaker 1-2m (m = 1 to 1). You may make it supply to 8).

(2) In the first to sixth embodiments, the partitions 91F, 91R, 91B, 91L, 92-1-i (i = 1 to 3) and 92-2i (i = 1 to 1) around the booth 90 are provided. 3) was assembled so as to form a rectangle as a whole. However, the partitions inside and outside the booth 90 may be curved, and these partitions may be combined to form a circle or an ellipse as a whole. Further, the partitions may be assembled so as to have a shape other than a circle or an ellipse.

(3) In the first to fourth embodiments and the sixth embodiment, speakers 1-1-m and 1-2m are provided in all of the partitions 91F, 91R, 91B, and 91L that surround the four sides of the booth 90. It was done. However, the speakers 1-1-m and 1-2m may be provided only in some of the partitions 91F, 91R, 91B, and 91L (for example, the partitions 91F and 91R). Moreover, you may provide the speaker 1-1-m and 1-2m in the lower part instead of the upper part of partition 91F, 91R, 91B, 91L. Further, an actuator may be attached to the partitions 91F, 91R, 91B, and 91L1 instead of a speaker, and the masker sound M may be emitted by this actuator.

1, 2, 5, 6 ... Speaker, 7, 8, 9 ... Amplifier, 10, 10A, 10B, 10C, 10D, 10E ... Conversation sound leakage prevention device, 11, 19 ... Masker sound storage, 12 ... CPU, DESCRIPTION OF SYMBOLS 14 ... RAM, 15 ... ROM, 16 ... D / A conversion part, 31,34 ... Masker sound generation part, 32 ... Distribution part, 33 ... Phase inversion part, 90 ... Booth, 91,92 ... Partition.

Claims (3)

A plurality of sound emitting means;
Means for emitting a masker sound signal, which is a sound signal that makes it difficult to hear a conversation sound generated in a certain area outside the area, through each of the plurality of sound emitting means; The masker sound signal is supplied to some of the sound emitting means, and the phase of the masker sound signal supplied to the remaining sound emitting means is supplied to the part of the sound emitting means. Control means for supplying a reverse phase masker sound signal ,
The sound emitting means as the supply destination of the masker sound signal and the sound emission means as the supply destination of the reverse phase masker sound signal are alternately arranged one by one or plural around the area.
Conversation sound leakage prevention device comprising a call. 2. The conversation sound leakage according to claim 1, wherein the control means includes means for supplying a masker sound signal of a type different from the masker sound signal to the plurality of sound emitting means without inverting the phase. Prevention device. The said control means has a filter which inverts the phase of the low frequency component in the said masker sound signal, The output signal of this filter is used as the said anti-phase masker sound signal. 2. The conversation sound leakage prevention apparatus according to 2.

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