JP5761259B2 - Conversation leakage prevention device - Google Patents

Description

  The present invention relates to a technique for preventing leakage of conversation.

  Some conversation leakage prevention devices that prevent leakage of conversation sound from the room to the outside use a masking effect. The masking effect is that when two types of sounds are emitted within a certain area, one target sound (target sound) that is the target of the listener within that area is concealed by the other sound (masker sound). This is a phenomenon in which the minimum audible value of the target sound (target sound) increases and the listener's ability to listen to the target sound (target sound) decreases. As a document disclosing a technique related to this type of conversation leakage prevention apparatus, there is Patent Document 1. The system disclosed in this document uses, as a target sound, a transmitted sound that passes through a wall from a room RA of two adjacent rooms RA and RB through a wall, and the sound pressure level of the target sound and the room RB. The sound pressure level of background noise is calculated. When the sound pressure level of the target sound is higher than the sound pressure level of background noise in the room RB, this system uses a band noise sound having a frequency spectrum similar to that of the conversation sound as a masker sound from the speaker in the room RB. Sound is emitted. When a masker sound is emitted into the room RB, the masking effect increases the ambiguity of the target sound in the room RB, making it difficult to hear the target sound.

JP 2008-233671 A

In this type of conversation leakage prevention device, the masker sound emitted to increase the ambiguity of the target sound is often uncomfortable and uncomfortable. For this reason, there is a case where a speaker who uses the conversation leakage prevention apparatus has a desire to make the volume level of the masker sound as low as possible.
However, the ambiguity of the target sound depends on the sound pressure level ratio between the target sound and the masker sound. Therefore, there is a problem that when the volume level of the masker sound is lowered, unless the speaker's voice is reduced in accordance with it, sufficient ambiguity of the target sound of the voice cannot be secured.
The present invention has been devised under such a background, and provides a mechanism that encourages the speaker to suppress the loudness of the voice when the volume of the masker sound is lowered. Objective.

  A conversation leakage prevention apparatus according to a preferred aspect of the present invention includes a sound collecting unit that collects sound, an operation unit, and a second region different from the first region from the first region where the sound is collected. A masker sound generating means for emitting a masker sound for reducing the intelligibility of the target sound propagated to the area to the second area; and when the first operation mode is selected by the operating means, the operating means When the second operation mode is selected by the operation means, the intelligibility of the target sound in the second region is kept below a specified level when the volume of the masker sound is controlled according to the operation of Control means for controlling the volume of the masker sound in accordance with the volume of the sound collected by the sound collection means.

  In the present invention, the speaker can control the volume of the masker sound emitted to the second area by operating the operation means such as the volume, and by selecting the second operation mode, The volume of the masker sound can be automatically controlled according to the volume of the sound picked up by the sound pickup means so that the intelligibility of the target sound in the region is below the specified level.

It is the figure which showed typically the room in which the conversation leakage prevention equipment which is embodiment of this invention is installed. It is a block diagram which shows the structure of the conversation leakage prevention apparatus. It is a figure which shows the correspondence of the intelligibility and sound pressure level ratio in the table memorize | stored in the table memory of the conversation leakage prevention apparatus.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram schematically showing rooms 91 and 92 in which a conversation leakage prevention apparatus 10 according to an embodiment of the present invention is installed. FIG. 2 is a block diagram showing the configuration of the conversation leakage prevention apparatus 10. As shown in FIG. 1, the conversation leakage prevention apparatus 10 is placed in one of the two rooms 91, 92 constituting the first and second areas, and the speaker 97 and the cable 93 in the other room 92. Connected by In the room 91, the conversation leakage prevention device 10 may be placed at a position about 1 m away from the speaker in the room 91.

  When a speaker in the room 91 generates the voice S, the voice S passes through the wall 90 and the sound that has passed through the wall 90 propagates into the room 92 as the target sound R. The conversation leakage prevention apparatus 10 plays a first role of emitting a masker sound M from the speaker 97 in the room 92 to increase the ambiguity of the target sound R in the room 92, and each of the green, yellow, and red notification lights 96. (G), 96 (Y), and 96 (R) are devices that play a second role of notifying the speaker of the degree of ambiguity of the target sound R in the room 92 through lighting. The outline of the operation of the conversation leakage prevention apparatus 10 will be described with attention to these two roles as follows.

The ambiguity of the target sound R when the masker sound M is emitted in the room 92 depends on the following two factors. The first element is the frequency spectrum of the masker sound M. The second element is the volume level ratio TM between the volume level LR (dB) of the target sound R in the room 92 and the volume level (LM + LMa) ^* (dB) of the masker sound M and background noise Ma in the room 92. (TM = LR- (LM + LMa) ^* (dB)). Here, the volume level (LM + LMa) ^* is obtained by converting each of the volume level LM (dB) of the masker sound M and the volume level LMa (dB) of the background noise Ma into a true number and adding the result, and converting the addition result into a logarithm. ((LM + LMa) ^* = 10 log (10 ** (LM / 10) +10 ** (LMa / 10))).
For example, when the volume spectrum LM of the masker sound M is kept constant and the frequency spectrum thereof is changed, the ambiguity of the target sound R increases as the frequency spectrum of the masker sound M and the target sound R is similar. When the volume level LM is changed without changing the frequency spectrum of the masker sound M, the ambiguity of the target sound R increases as the volume level LM of the masker sound M increases.

Therefore, in the first role, the conversation leakage prevention apparatus 10 emits a sound of the type selected by the speaker from the following three types of sound as a masker sound M from the speaker 97 in the room 92, and the masker sound. The volume level LM of M is adjusted according to the speaker's specification.
a1. Sound containing only noise (hereinafter referred to as “noise”)
b1. A sound that is a mixture of noise and human voice (hereinafter referred to as “mixed sound”)
c1. Sounds that contain only human voice (hereinafter “human voice”)

以上が、会話漏洩防止装置１０の動作の概要である。 Then, in the second role, the conversation leakage prevention apparatus 10 collects the speech S in the room 91 with the microphone 95, and an index value representing the degree of ambiguity of the target sound R in the room 92 from the speech S. The intelligibility WIS (Word Intelligibility Score: 0.000 ≦ WIS ≦ 1.000) is calculated, and the intelligibility among the three intelligibility ranks “A”, “B”, and “C” shown in Table 1 below. A notification lamp 96 of a color associated with the intelligibility rank to which the WIS belongs is turned on.

The above is the outline of the operation of the conversation leakage prevention apparatus 10.

Next, the structure of each part which comprises the conversation leakage prevention apparatus 10 is explained in full detail.
In FIG. 2, a masker sound memory 11 is a memory that stores masker sound data M-data of each of noise sound, mixed sound, and human voice sound. The masker sound data M-data is data indicating the sound waveform of each of the noise sound, the mixed sound, and the human voice sound.

  The background noise memory 12 is a memory that stores background noise data Ma-data. The background noise data Ma-data is data indicating the sound waveform of the background noise Ma previously collected in the room 92 adjacent to the room 91 in which the conversation leakage prevention apparatus 10 is installed.

The intelligibility memory 14 is a memory that stores tables tbl-n, tbl-m, and tbl-v.
The table tbl-n shows the volume level ratio TM (TM = RM) between the target sound R and the masker sound M and the intelligibility WIS of the target sound R in the room 92 when the masker sound M is a noise sound. It is a table to associate.
The table tbl-m shows the volume level ratio TM (TM = RM) between the target sound R and the masker sound M and the intelligibility WIS of the target sound R in the room 92 when the masker sound M is a mixed sound. It is a table to associate.
The table tbl-v shows the volume level ratio TM (TM = RM) between the target sound R and the masker sound M and the intelligibility WIS of the target sound R in the room 92 when the masker sound M is a human voice. It is a table to associate.

  FIG. 3 shows the correspondence relationship between the intelligibility WIS and the volume level ratio TM in the three tables tbl-n, tbl-m, and tbl-v in a coordinate system having the intelligibility WIS as the vertical axis and the volume level ratio TM as the horizontal axis. Is a stack of As shown in FIG. 3, the intelligibility WIS when the volume level ratio TM is the same decreases in the order of noise sound → mixed sound → human voice.

The operation unit 20 includes a volume adjustment volume 21 for instructing a volume level LM of the masker sound M, and various switch groups 22 for performing the following three types of selection operations.
a2. Masker selection operation This is an operation of selecting one of a noise sound, a mixed sound, and a human voice as a masker sound M to be emitted into the room 92.
b2. Sound insulation class selection operation This is because the room 91 where the conversation leakage prevention apparatus 10 is installed and the adjacent room 92 among the sound insulation classes i (i = 10, 15, 20,...) Defined in JIS A 1419-1. Is the operation of selecting the sound insulation grade i of the wall 90 that separates.
c2. Mode selection operation This is an operation for selecting one of mode A and mode B, which is the operation mode of the conversation leakage prevention apparatus 10. Mode A is a mode in which the volume level LM of the masker sound M is manually adjusted according to the operation of the volume adjustment volume 21, and mode B is an upper limit value in which the intelligibility WIS of the target sound R in the room 92 is designated in advance. In this mode, the volume level LM of the masker sound M is automatically adjusted so as to be kept below WIS _LIMIT (for example, WIS _LIMIT = 0.010).

The microphone 95 outputs an electrical signal indicating the voice S collected in the room 91.
The masker sound generator 30 is a means for emitting a masker sound M from the speaker 97 to the room 92. The masker sound generation unit 30 includes a reproduction unit 31, an equalizer 32, a main amplifier 33, a mode A amplifier 34, a mode B amplifier 35, and a D / A conversion unit 36. The operation content of each unit in the masker sound generation unit 30 is as follows. The playback unit 31 uses the masker sound data M-data of the sound selected by the masker selection operation among the three types of masker sound data M-data stored in the masker sound memory 11 as a playback target. The process of outputting the masker sound data M-data as the signal M (k) is repeated.

The output signal M (k) from the reproduction unit 31 is input to the D / A conversion unit 36 after being equalized by the equalizer 32 and then amplified by the main amplifier 33, the mode A amplifier 34, and the mode B amplifier 35. .
The equalizer 32 adjusts the frequency characteristic of the output signal M (k) of the reproducing unit 31 to a frequency characteristic equivalent to that transmitted through the wall 90 according to the parameter Para-E set by the control unit 70. Details of the setting of the parameter Para-E by the control unit 70 will be described later.
The main amplifier 33, the mode A amplifier 34, and the mode B amplifier 35 are amplifiers whose gains g-33, g-34, and g-35 are variable.
In the main amplifier 33, every time the type of the masker sound M is switched by the masker selection operation, a gain g-33 associated with the type after switching is set by the control unit 70. The gain g-33 of the main amplifier 33 in each of noise sound, mixed sound, and human voice sound is set so that the reproduction sound level of the signal multiplied by the gain g-33 becomes the reproduction sound level shown in Table 2 below. Yes.

モードＡ用アンプ３４は、モードＡにおけるマスカ音Ｍの音量レベルＬＭのマニュアル調整のためのアンプであり、モードＢ用アンプ３５は、モードＢにおけるマスカ音Ｍの音量レベルＬＭの自動調整のためのアンプである。制御部７０は、モードＡでは、音量調整ボリューム２１の操作に応じてモードＡ用アンプ３４の利得ｇ−３４と報知部４０内の収音信号用アンプ４２（後述）の利得ｇ−４２とを連動して変化させ、モードＢでは、報知部４０内の判定部４７（後述）による支援の下、ターゲット音Ｒの了解度ＷＩＳが上限値ＷＩＳ_LIMIT（ＷＩＳ_LIMIT＝０．０１０）以下に保たれるようにモードＢ用アンプ３５の利得ｇ−３５を変化させる。詳しくは、後述する。

The mode A amplifier 34 is an amplifier for manual adjustment of the volume level LM of the masker sound M in mode A, and the mode B amplifier 35 is for automatic adjustment of the volume level LM of the masker sound M in mode B. It is an amplifier. In the mode A, the control unit 70 sets the gain g-34 of the mode A amplifier 34 and the gain g-42 of the collected sound signal amplifier 42 (described later) in the notification unit 40 in accordance with the operation of the volume adjustment volume 21. In mode B, the intelligibility WIS of the target sound R is kept below the upper limit value WIS _LIMIT (WIS _LIMIT = 0.010) with the assistance of a determination unit 47 (described later) in the notification unit 40. Thus, the gain g-35 of the mode B amplifier 35 is changed. Details will be described later.

  The signal M (k) input to the D / A conversion unit 36 is converted into an analog electrical signal by the D / A conversion unit 36, and this electrical signal is reproduced from the speaker 97 as a masker sound M in the room 92. . The output signal M (k) of the equalizer 32 is also given to the determination unit 47 in the notification unit 40 and is used for the determination process in the determination unit 47. Details will be described later.

  The notification unit 40 is a means for lighting the notification lamp 96 associated with the intelligibility rank to which the intelligibility WIS of the target sound R in the room 92 belongs to notify the speaker in the room 91 of the intelligibility rank. The notification unit 40 includes an A / D conversion unit 41, a sound pickup signal amplifier 42, an A characteristic filter 43, a wall characteristic filter 44, an RMS (Root Mean Square) processing unit 45, a background noise generation unit 46, and a determination unit 47. Have The operation content of each unit in the notification unit 40 is as follows. The A / D converter 41 converts the electrical signal of the voice S given from the microphone 95 into a digital format and outputs it as a signal S (k).

  The output signal S (k) of the A / D converter 41 is amplified by the sound pickup signal amplifier 42, passes through the A characteristic filter 43 and the wall characteristic filter 44, and is heard by the listener in the room 92. The signal is input to the RMS processing unit 45 as a signal R (k) indicating the wax target sound R. The A characteristic filter 43 is set with an A characteristic which is a frequency characteristic of human hearing. The wall characteristic filter 44 adjusts the frequency characteristic of the output signal S (k) of the A characteristic filter 43 to a frequency characteristic equivalent to that transmitted through the wall 90 according to the parameter Para-F set by the control unit 70, Output as R (k). Details of setting of the parameter Para-F by the control unit 70 will be described later.

The RMS processing unit 45 converts the output signal R (k) of the wall characteristic filter 44 into an effective value signal R ′ (k) that is an average square root for a fixed time length in the past and outputs the result.
The background noise generator 46 repeats the process of outputting the background noise data Ma-data stored in the background noise memory 12 as the signal Ma (k). The output signal Ma (k) of the background noise generation unit 46 is input to the determination unit 47.

  The determination unit 47 performs a determination process. The determination process is performed based on the output signal R ′ (k) of the RMS processing unit 45, the output signal Ma (k) of the background noise generation unit 46, and the output signal M (k) of the equalizer 32 in the masker sound generation unit 30. The intelligibility WIS of the target sound R is obtained, and the color notification lamp 96 associated with the notification rank to which the intelligibility WIS belongs is turned on. The specific processing contents of the determination processing are as follows.

First, the determination unit 47 performs the masking sound M indicated by the signal M (k) and the effective sound level (LM + LMa) ^* (dB) of the background noise Ma indicated by the signal Ma (k) and the target sound indicated by the signal R ′ (k). The volume level ratio TM (dB) is obtained by substituting the effective volume level LR ′ (dB) of R into the following equation (2). Here, the effective volume level (LM + LMa) ^* is obtained by converting each of the effective volume level LM (dB) of the masker sound M and the effective volume level LMa (dB) of the background noise Ma into a true number and adding the result. The value converted to logarithm.
TM = LR ′ − ((LM + LMa) ^{* −} LMx) (2)
In this equation (2), LMx is a correction coefficient for correcting a difference in masking effect (numerical value of intelligibility WIS) due to a difference in the type of masker sound. The values of LMx in each of noise sound, mixed sound, and human voice sound are as shown in Table 3 below.

  Further, each time the volume level ratio TM is obtained by the above equation (2), the determination unit 47 determines the masker among the three types of tables tbl-n, tbl-m, and tbl-v stored in the intelligibility memory 14. Using the sound table tbl selected by the selection operation as a reference destination, the intelligibility WIS associated with the latest volume level ratio TM is acquired from the reference table tbl. The determination unit 47 turns on the green notification lamp 96 (G) while the intelligibility WIS is 0.010 or less, and yellow while the intelligibility WIS is greater than 0.010 and less than or equal to 0.200. The notification lamp 96 (Y) is turned on, and the red notification lamp 96 (R) is turned on while the intelligibility WIS is greater than 0.200.

  The control unit 70 performs masker sound switching processing and wall characteristic setting processing that are processing common to modes A and B, gain manual adjustment processing that is processing unique to mode A, and automatic gain adjustment that is processing unique to mode B. Four types of processing are performed. The contents of the four types of processing are as follows.

a3. Masker Sound Switching Process In the masker sound switching process, the control unit 70 determines the sound type signal M-kind indicating the type of sound after switching as the playback unit 31 every time the type of masker sound M is switched by a masker selection operation. To the unit 47. The reproduction unit 31 switches the masker sound data M-data to be reproduced according to the sound type signal M-kind supplied from the control unit 70, and the determination unit 47 refers to the reference destination according to the sound type signal M-kind supplied from the control unit 70. The table tbl is switched.

b3. Wall Characteristic Setting Process In the wall characteristic setting process, the control unit 70 sets the parameter Para-E of the equalizer 32 and the parameter Para-F of the wall characteristic filter 44 according to the sound insulation class i selected by the sound insulation class selection operation. More specifically, the control unit 70 transmits the transmission loss characteristics of the wall 90 having the sound insulation grade i selected by the sound insulation grade selection operation (specifically, the wall 90 for each octave band from 125 Hz to 4 kHz). The parameter Para-E is set in the equalizer 32 so that the amplitude characteristics of the equalizer 32 are the same as those of the sound volume level ratio before and after the transmission: A parameter Para-F is set in the wall characteristic filter 44 so that the amplitude characteristics of 44 are the same.

c3. Gain Manual Adjustment Process In the gain manual adjustment process, the control unit 70 adjusts the gain g−34 of the mode A amplifier 34 according to the operation of the volume adjustment volume 21. In addition, when the gain g-34 of the mode A amplifier 34 is increased by this adjustment, the control unit 70 decreases the gain g-42 of the sound pickup signal amplifier 42 in conjunction with the gain G-34. When the gain g-34 is reduced, the gain g-42 of the collected sound signal amplifier 42 is increased in conjunction with the gain g-34. That is, every time the gain g-34 of the mode A amplifier 34 is adjusted, the control unit 70 has the same absolute value as the adjustment (dB value) of the gain g-34 of the mode A amplifier 34, and the sign is inverted. The gain g-42 of the sound signal amplifier 42 is adjusted so that the adjustment value (dB value) of the gain g-42 of the sound pickup signal amplifier 42 matches.

d3. Automatic Gain Adjustment Process In the automatic gain adjustment process, the control unit 70 receives data indicating the intelligibility WIS obtained in the determination process from the determination unit 47. Then, when the intelligibility WIS indicated by the data supplied from the determination unit 47 exceeds the upper limit value WIS _LIMIT (WIS _LIMIT = 0.010), the control unit 70 sets the intelligibility WIS to be equal to or lower than the upper limit value WIS _LIMIT. The insufficient volume level of the necessary masker sound M is calculated, and the gain g-35 of the mode B amplifier 35 is controlled according to the insufficient volume level.

  As described above, when the gain g-34 of the mode A amplifier 34 is small in the gain manual adjustment process, which is a process unique to mode A, the conversation leakage prevention apparatus 10 is linked to the sound collection signal. The gain g−42 of the amplifier 42 is increased, and the intelligibility WIS is calculated on the assumption that the volume level LS of the voice S collected by the microphone 95 is apparently increased. Therefore, in mode A, when the volume level LM of the masker sound M emitted by the speaker into the room 92 is reduced, the notification lamps 96 (Y), 96 (96) having higher intelligibility levels such as “B” and “C”. R) is easily lit, and the speaker can be prompted to suppress the loudness of the speech S.

  Further, the conversation leakage prevention apparatus 10 keeps the intelligibility WIS of the target sound R in the room 92 below the specified level in the mode A in which the volume level LM of the masker sound M is manually adjusted according to the operation of the volume adjustment volume 21. The operation is performed in one mode selected by the operation unit 20 in the mode B in which the volume level LM of the masker sound M is automatically adjusted so as to be leaned. By adopting a configuration that operates in two modes, mode A and mode B, the following problems that have not been solved so far can be solved. That is, this type of conversation leakage prevention device so far has been able to manually adjust the volume level LM of the masker sound M emitted to the adjacent room 92 by an operator such as a volume. The volume level LM of the masker sound M is not automatically adjusted so that the intelligibility WIS of the target sound R is equal to or lower than the desired intelligibility WIS. For this reason, this type of conversation leakage prevention device is not convenient for a speaker who feels annoyed by suppressing the size of his / her speech S or manually adjusting the volume level LM of the masker sound M. On the other hand, according to the conversation leakage prevention apparatus 10 according to the embodiment of the present invention, a speaker can speak his own voice S according to the lighting state of the notification lamps 96 (G), 96 (Y), 96 (R). If you do not feel bothered to reduce the size of the sound or adjust the volume level LM of the masker sound M, select Mode A, and ensure that a certain masking effect is guaranteed without paying attention to such matters. It is possible to change the usage of the conversation leakage prevention apparatus 10 according to its own requirements and preferences, such as selecting mode B when speaking.

Although one embodiment of the present invention has been described above, the present invention may have other embodiments. For example, it is as follows.
(1) In the above embodiment, the table tbl represents a function indicating the relationship between the volume level RL of the target sound R, the volume level ratio TM between the various masker sounds M and the volume level LM, and the intelligibility WIS of the target sound R in the room 92. Alternatively, the intelligibility WIS may be obtained using this function.

(2) In the above embodiment, in the gain manual adjustment process, the control unit 70 changes the gain g-42 of the collected sound signal amplifier 42 in conjunction with the change of the gain g-34 of the mode A amplifier 34. . However, the upper limit value and the lower limit value of the corresponding range of the intelligibility rank in Table 1 may be moved up and down in conjunction with the gain g-34 of the mode A amplifier 34. In this aspect, for example, when the gain g-34 of the mode A amplifier 34 is changed, the control unit 70 notifies the determination unit 47 of the changed gain g-34. When the gain g-34 notified from the control unit 70 exceeds the reference gain, the determination unit 47 lowers the upper limit value and the lower limit value of the corresponding range of each intelligibility rank by an amount that exceeds the reference gain. Determine the degree rank. Further, when the gain g-34 notified from the control unit 70 is lower than the reference gain, the determination unit 47 increases the upper limit value and the lower limit value of the corresponding range of each intelligibility rank by an amount that is lower than the reference gain. Determine the intelligibility rank with.

(3) In the above embodiment, the output signal S (k) of the A / D converter 41 is divided into a plurality of bands (for example, a band for each octave or a band for each 1/3 octave), and for each divided band. Are used to obtain a volume level ratio TM _m (m = 1, 2...) For each band using each of the signals S (k) _m (m = 1, 2,..., M is an index indicating the band). The intelligibility WIS corresponding to the total value of the ratio TM _m (m = 1, 2,...) May be acquired from the table tbl.

(4) In the above embodiment, sound waveform data having a standard frequency spectrum of background noise in the room may be stored in the background noise memory 12 as background noise data Ma-data. In this case, the reproducing unit 31 may output the signal M (k) indicated by the background noise data Ma-data after adjusting the level according to the effective noise level (dBA) of the background noise Ma in the room 92. . The effective noise level (dBA) of the background noise Ma may be obtained from an actually measured value in the room 92 or may be obtained by calculation.

(5) In the above embodiment, when the operation mode is switched from mode B to mode A, the control unit 70 sets the mode B amplifier 35 immediately before switching to mode A in mode B. The gain g-35 that has been set is used as the initial value of the gain g-34 of the mode A amplifier 34 in mode A, and in the subsequent gain manual adjustment processing, the gain g-34 set as the initial value is used to operate the volume adjustment volume 21. It may be controlled according to According to this embodiment, a speaker unfamiliar with volume adjustment first finds a volume level LM of masker sound M in mode B that ensures sufficient ambiguity of the target sound R, and then mode A And further fine adjustment of the volume level LM of the masker sound M can be performed. In the above embodiment, when the operation mode is switched from mode A to mode B, the control unit 70 sets the mode A amplifier 34 immediately before switching to mode B in mode A. The gain g-34 is set as the initial value of the gain g-35 of the mode B amplifier 35 in mode B, and the gain g-35 set as the initial value is stored in the microphone 95 in the room 90 in the subsequent automatic gain adjustment processing. You may control according to the intelligibility WIS calculated | required from the sound produced | generated.

(6) In the above embodiment, the controller 70 accepts an operation for designating the upper limit value WIS _LIMIT -A of the intelligibility WIS at the time of operation in the mode A, and the control unit 70 sets the upper limit of the intelligibility WIS while operating in the mode A. When the value WIS _LIMIT -A is reached, the volume level LM of the masker sound M may be controlled so that the intelligibility WIS does not exceed the upper limit value WIS _LIMIT -A. According to this embodiment, when the volume level LR of the target sound R suddenly increases, the control unit 70 adjusts the volume when the intelligibility WIS increases until it reaches the upper limit value WIS _LIMIT -A. Regardless of the operation of the volume 21, the volume level LM of the masker sound M is increased to prevent further increase in the intelligibility WIS. Therefore, according to the present embodiment, even if the speaker in the room 91 does not perform an operation of adjusting the volume level LM of the masker sound M, the intelligibility WIS deteriorates beyond the preset upper limit value WIS _LIMIT -A. Nothing will happen.

(7) In the above embodiment, an operation for designating the upper limit value LM _LIMIT -B of the volume level LM of the masker sound M at the time of operation in mode B is accepted, and the control unit 70 performs the masker operation while operating in mode B. If the volume level LM of the sound M has reached the upper limit value LM _lIMIT -B, it may be volume level LM controls the upper limit WIS _lIMIT intelligibility WIS so as not to exceed the upper limit value LM _lIMIT -B . According to this embodiment, when the volume level LR of the target sound R suddenly increases, the control unit 70 increases the volume level LM of the masker sound M until it reaches the upper limit value LM _LIMIT -B. Overlooks that the intelligibility WIS exceeds the upper limit value WIS _LIMIT, and in exchange, suppresses the volume level LM of the target sound R to the upper limit value LM _LIMIT -B or less. Therefore, according to the present embodiment, it is possible to prevent the inconvenience that the volume level LM of the masker sound M becomes too large and the person in the room 92 feels a noise.

(8) In the above embodiment, the conversation leakage prevention apparatus 10 is installed in one of the two rooms 91 and 92 adjacent to each other with the wall 90 interposed therebetween, and the conversation leakage prevention apparatus 10 is connected to the speaker of the other room 92. 97. However, the conversation leakage prevention device 10 and the speaker 97 may be installed in each of the first and second regions partitioned with a screen having a height lower than that of the wall.

(9) In the above embodiment, instead of the notification lights 96 (G), 96 (Y), 96 (R) of the colors associated with the intelligibility ranks “A”, “B”, “C”, a display ( Display means), and the intelligibility WIS calculated by the control unit 70 may be displayed on the display (display means).

(10) In the above embodiment, the reproduction sound level of various masker sounds shown in Table 2 and the correction coefficient LMx of various masker sounds shown in Table 3 are merely examples, and the values described in these tables Different playback sound levels and correction coefficients LMx may be employed. In addition, in the tables tbl-n, tbl-m, and tbl-v, the intelligibility WIS and the volume level ratio TM may have a different relationship from that in FIG.

DESCRIPTION OF SYMBOLS 10 ... Conversation leak prevention apparatus, 11 ... Masker sound memory, 12 ... Background noise memory, 14 ... Comprehension memory, 20 ... Operation part, 21 ... Volume adjustment volume, 22 ... Switch group, 30 ... Masker sound generation part, 31 ... Playback unit 32 ... Equalizer 33 ... Main amplifier 34 ... Mode A amplifier 35 ... Mode B amplifier 36 ... D / A conversion unit 40 ... Notification unit 41 ... A / D conversion unit 42 ... Accumulation Sound signal amplifier, 43 ... A characteristic filter, 44 ... wall characteristic filter, 45 ... RMS processing unit, 46 ... dark noise generation unit, 47 ... determination unit, 70 ... control unit, 90 ... wall, 91, 92 ... room, 93 ... Cable, 95 ... Microphone, 96 ... Notification light, 97 ... Speaker.

Claims (2)

Sound collection means for collecting sound;
Operation means;
Masker sound that emits to the second area a masker sound that reduces the intelligibility of the target sound propagated from the first area where the sound is collected to a second area different from the first area Generating means;
Calculating means for calculating the intelligibility of the target sound in the second region from the sound collected by the sound collecting means;
When the first operation mode is selected by the operation means, the volume of the masker sound is controlled according to the operation of the operation means, and when the second operation mode is selected by the operation means, the calculation means Control means for controlling the volume of the masker sound according to the volume of the sound picked up by the sound pickup means so that the intelligibility calculated by is kept below a predetermined upper limit value. Conversation leakage prevention device.   The control means switches the volume of the masker sound immediately before switching in the operation mode before switching when switching from one of the first operation mode and the second operation mode to the other is performed. It is set as an initial value of the volume of the masker sound in a later operation mode, and thereafter, the volume set as the initial value is controlled according to the operation of the operation means or the volume of the sound collected by the sound collection means. The conversation leakage prevention apparatus according to claim 1.

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