JP2013003422A - Acoustic system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it difficult for a listener existing in the front of one of electrostatic speakers arrayed in a row, to hear sounds emitted from electrostatic speakers adjacent to the one electrostatic speaker.SOLUTION: When a level of noise in a room where electrostatic speakers 10-k (k=1 to 3) are arrayed is low, a control device 40 emits masker sounds M which hinder listeners from hearing sounds which are emitted from electrostatic speakers adjacent to each of electrostatic speakers 10-k and reach hearing reference points P in the front of the electrostatic speakers 10-k, from respective electrostatic speakers 10-k together with advertisement sounds A. Therefore, a listener H existing in the frontward direction of, for example, the electrostatic speaker 10-2 hardly hears advertisement sounds Aemitted from adjacent electrostatic speakers 10-1 and 10-3.

Description

  The present invention relates to an acoustic system using a flat speaker such as an electrostatic speaker.

A flat speaker called an electrostatic speaker is known. The basic configuration and driving principle of the electrostatic speaker are as follows. As shown in FIG. 4, the electrostatic speaker 80 has one diaphragm 81 and two electrode plates 82F and 82B sandwiching the diaphragm 81 from both sides. The diaphragm 81 and the electrode plates 82F and 82B on both sides are separated by the same distance d. The surface of the diaphragm 81 is coated with a conductive material. The electrode plates 82F and 82B are provided with a plurality of holes for allowing sound waves to pass therethrough. A DC bias voltage V _B is applied to the diaphragm 81. Then, forward and reverse two-phase input audio signals V ₀ and −V ₀ (| V ₀ | <V _B ) are applied to each of the electrode plates 82F and 82B.

Here, the electric field strength F1 between the vibration plate 81 and the electrode plate 82F depends on the potential difference V _B −V ₀ between the vibration plate 81 and the electrode plate 82F, and the electric field strength F2 between the vibration plate 81 and the electrode plate 82B is It depends on the potential difference V _B − (− V ₀ ) between the vibration plate 81 and the electrode plate 82B. Then, the electrostatic speaker 80, a polarity of the input audio signal V ₀ which positive phase positive, when the polarity of the input audio signal -V ₀ reverse phase is negative, V B _-V 0 _{<V Since B} − (− V ₀ ) and F1 <F2, the diaphragm 81 is displaced toward the electrode 82B. Conversely, when the polarity of the positive phase input audio signal V ₀ is negative and the polarity of the negative phase input audio signal −V ₀ is positive, V _B −V ₀ > V _B − (− V ₀ ). Since F1> F2, the vibration plate 81 is displaced toward the electrode 82F side. Thus the diaphragm 81 is displaced to the electrode 82B direction or electrode 82F direction according to the input audio signal _{V 0} and -V _0, the input between each of the diaphragm 81 and the electrode plate 82F and 82B audio signal _{V 0} And a sound wave which is an air density wave corresponding to −V ₀ is generated, and this sound wave penetrates through the holes of the electrode plates 82F and 82B and is radiated to the outside. The above is the basic configuration and driving principle of the electrostatic speaker 80.

  If the direction from diaphragm 81 to electrode plate 82F in this electrostatic speaker 80 is the front direction, and the direction from diaphragm 81 to electrode plate 82B is the back direction, it is generated from diaphragm 81 of electrostatic speaker 80. Most of the sound waves are transmitted in the front direction and the back direction without almost diffusing after passing through the holes of the diaphragms 82F and 82B. Therefore, the sound wave emitted from the electrostatic speaker 80 becomes a plane wave having strong directivity in the front direction and the back direction. As a document disclosing the technology related to the electrostatic speaker 80, there is, for example, Patent Document 1.

JP 2009-232405 A

  By the way, as a system using the above-described electrostatic speaker, as shown in FIGS. 5A and 5B, a plurality of electrostatic speakers 80-m (m = 1, 2,...): In the example of FIGS. 5A and 5B, an acoustic system in which m = 3) are arranged in a horizontal row and different advertising sounds are emitted from the respective electrostatic speakers 80-m can be considered. According to this system, even if the volume level of the advertisement sound emitted from each electrostatic speaker 80-m is set to the same level, the advertisement sound emitted from each electrostatic speaker 80-m is displayed in front of each electrostatic speaker 80-m. The level of the advertisement sound emitted from the adjacent electrostatic speaker 80-m is smaller than the level. For this reason, according to this system, the listener H who is in front of the electrostatic speaker 80-1 is allowed to listen only to the advertisement sound emitted from the electrostatic speaker 80-1, and the adjacent electrostatic speaker 80 is listened to. The listener H who is in front of -2 is allowed to listen only to the advertisement sound emitted from the electrostatic speaker 80-2, so that the advertisement sound to be heard according to the position of the listener H is divided. it can. Therefore, a high advertising effect can be created.

However, this system has the following problems. How clearly the listener H who is in front of the electrostatic speaker 80-m can hear the advertisement sound emitted from the adjacent electrostatic speaker 80-m is determined by the adjacent electrostatic speaker 80-m. Depends on the background noise level BK in the space where the electrostatic speakers 80-m are arranged, as well as the volume level difference of the advertisement sound emitted from each of the above. For example, as shown in FIG. 6 (A), there is a listener H in front of the electrostatic speaker 80-2, the volume level LV ₂ of the advertising sound emitted from the electrostatic speaker 80-2, next to it. If the magnitude relationship between the volume level LV ₃ of the advertisement sound emitted from the electrostatic speaker 80-3 and the volume level LV _BK of the background noise BK is LV ₂ > LV _BK > LV ₃ , the listener H Cannot hear the advertisement sound emitted from the adjacent electrostatic speaker 80-3. On the other hand, as shown in FIG. 6B, when the magnitude relationship is LV ₂ > LV ₃ > LV _BK , the listener H receives the advertisement sound emitted from the adjacent electrostatic speaker 80-3. I can hear it. Therefore, the configuration in which the plurality of electrostatic speakers 80-k are merely arranged in a horizontal row has a problem in that a sufficient effect cannot be exhibited in a quiet space where the level LV _{BK of the} background noise _BK is low.

  The present invention has been devised under such a background, and an adjacent electrostatic speaker is connected to a listener in front of an electrostatic speaker among the electrostatic speakers arranged in a horizontal row. The purpose is to make it difficult to hear the sound emitted from the sound source.

  According to the present invention, a plurality of speakers arranged in substantially the same direction and adjacent to each other and a plurality of audio signals are respectively supplied to the plurality of speakers to emit sound from the plurality of speakers, and next to each speaker. There is provided an acoustic system including control means for emitting from each speaker a masker sound having a volume level that prevents sound from being emitted from the speaker and reaching a listening reference point in front of each speaker.

  According to the present invention, a masker sound is emitted from each of a plurality of speakers, which prevents sound from being emitted from an adjacent speaker and reaching a listening reference point in front of each speaker. Therefore, according to the present invention, it is possible to make it difficult for the listener who is in front of the speaker from which the masker sound is emitted to hear the sound emitted from the adjacent speaker.

It is a figure which shows the structure of the acoustic system which is 1st and 2nd embodiment of this invention. It is a figure which shows the aspect of arrangement | positioning of the electrostatic type speaker in the same system. It is a figure for demonstrating operation | movement of the system. It is a figure which shows the structure of the conventional electrostatic speaker. It is a figure which shows the structural example of the system using two or more electrostatic speakers shown in FIG. It is a figure for demonstrating the problem of the system.

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 an acoustic system according to the first embodiment of the present invention. FIG. 2 is a diagram illustrating an arrangement mode of the electrostatic speakers 10-k (k = 1 to 3) in the system. In this acoustic system, an electrostatic speaker 10-k (k = 1) in which advertisements of respective languages (for example, English, Japanese, and Chinese) are printed on the protective members 3F and 3B forming the outermost shells. 3), a sound source 50 that outputs an audio signal X _k (k = 1 to 3) of advertisement voices A _k (k = 1 to 3) in English, Japanese, and Chinese, a sound source 50, and an electrostatic speaker 10-k (k = 1 to 3), and the control device 20 and the microphone 60 used for collecting the background noise BK. As shown in FIG. 2, in the acoustic speaker 10-k (k = 1 to 3) in this acoustic system, each of the protective members 3F and 3B is directed in the same direction (hereinafter, the direction in which the protective member 3F faces). And the direction in which the protective member 3B faces is the back surface direction). In this acoustic system, the advertisement sound A _k (k = 1 to 3) is emitted from each of the electrostatic speakers 10-k (k = 1 to 3), and the static sound next to each electrostatic speaker 10-k is emitted. A masker sound M (for example, a broadband noise is set as a masker sound M) that prevents the sound from being emitted from the electric speaker and reaching the listening reference point in front of each electrostatic speaker 10-k. Sound is emitted from the type speaker 10-k.

  In FIG. 1, each electrostatic speaker 10-k includes a speaker unit 11-k and input terminals 12-k, 13-k, and 14-k. The speaker unit 11-k includes one diaphragm 1, two electrode plates 2F and 2B that sandwich the diaphragm 1 from the outside, and two protective members 3F and 3B that sandwich both the electrode plates 2F and 2B from the outside. Elastic members inserted between the diaphragm 1 and the electrode plate 2F, between the diaphragm 1 and the electrode plate 2B, between the electrode plate 2F and the printing plate 3F, and between the electrode plate 2B and the printing plate 3B, respectively. 4F, 4B, 5F, and 5B.

  More specifically, the diaphragm 1 is made of a synthetic resin film (insulating layer) having insulating properties and flexibility such as PET (polyethylene terephthalate) or PP (polypropylene: polypropylene) as a base material. It has a sheet-like configuration in which a conductive metal is deposited on one surface to form a conductive film (conductive layer). In the present embodiment, the conductive film of the diaphragm 1 is formed on one surface of the film, but may be formed on both surfaces of the film. Moreover, the film of the diaphragm 1 is not limited to PET or PP, and may be a film made of another synthetic resin obtained by vapor-depositing a conductive metal or applying a conductive paint. Moreover, the diaphragm 1 may have a configuration of a conductive film obtained by rolling a metal having conductivity into a film shape. The electrode plates 2F and 2B are made of a synthetic resin film (insulating layer) having an insulating property such as PET or PP, and a conductive metal is deposited on one surface of the film by depositing a conductive metal. Layer). The electrode plates 2F and 2B are rectangular when viewed from the front (as viewed from the direction of arrow A in FIG. 1), and have a plurality of holes penetrating from the front surface to the back surface, allowing passage of air and sound. It has become. In addition, illustration of this hole is abbreviate | omitted in drawing. The electrode plates 2F and 2B may have a conductive film configuration obtained by rolling a conductive metal into a film shape. In this embodiment, the longitudinal length of the electrode plates 2F and 2B is longer than the longitudinal length of the diaphragm 1, and the lateral length of the electrode plates 2F and 2B is the lateral length of the diaphragm 1. It is longer than that.

  In the present embodiment, the elastic members 4F, 4B, 5F, and 5B are non-woven fabrics formed of fibers, and are capable of passing air and sound, and the shape thereof is viewed from the front (FIG. 1). (As viewed from the direction of arrow A). The elastic members 4F, 4B, 5F, and 5B have elasticity, and are deformed when a force is applied from the outside, and return to the original shape when the force applied from the outside is removed. In the present embodiment, the lengths of the elastic members 4F, 4B, 5F, and 5B in the vertical and horizontal directions are the same as the lengths of the electrode plates 2F and 2B in the vertical and horizontal directions. By being supported with the elastic members 4F and 4B sandwiched therebetween, a certain distance is secured between the diaphragm 1 and the electrode plate 2F and between the diaphragm 1 and the electrode plate 2B.

  The protection members 3F and 3B are insulating cloths. The protective member 60 has a rectangular shape when viewed from the front (viewed from the direction of arrow A in FIG. 1), and allows passage of air and sound. The advertisement described above is printed on the protective member 3F and the protective member 3B. In the present embodiment, the lengths of the protective members 3F and 3B in the vertical direction and the horizontal direction are the same as the lengths of the elastic members 4F, 4B, 5F, and 5B in the vertical direction and the horizontal direction. The input terminal 12-k is connected to the electrode plate 2B. The input terminal 13-k is connected to the electrode plate 2F. The input terminal 14-k is connected to the diaphragm 1.

  The control device 20 includes an input terminal 21-k (k = 1 to 3), an output terminal 22-k (k = 1 to 3), 23-k (k = 1 to 3), and 24-k (k = 1). -3), microphone terminal 25, adder 26-k (k = 1 to 3), power amplifier 27-k (k = 1 to 3), and protective resistor 28-k (k = 1 to 3). 29-k (k = 1 to 3), transformer 30-k (k = 1 to 3), bias power supply 31-k (k = 1 to 3), and protective resistor 32-k (k = 1 to 3). 3) and a control unit 40.

  An input terminal 21-k (k = 1 to 3) in the control device 20 is connected to the sound source 50. Each output terminal 22-k in the output terminal 22-k (k = 1 to 3) is connected to the input terminal 12-k of the electrostatic speaker 10-k. Each output terminal 23-k in the output terminal 23-k (k = 1 to 3) is connected to the input terminal 13-k of the electrostatic speaker 10-k. Each output terminal 24-k in the output terminal 24-k (k = 1 to 3) is connected to the input terminal 14-k of the electrostatic speaker 10-k. The microphone terminal 25 is connected to the microphone 60. The microphone 60 is for collecting the background noise BK in the environment where the acoustic system is installed. The adder 26-k, the power amplifier 27-k, the protective resistors 28-k and 29-k, and the transformer 30-k are inserted in series between the input terminal 21-k and the output terminal 22-k. More specifically, one input terminal of the adder 26-k is connected to the input terminal 22-k, and the output terminal of the adder 26-k is connected to the input terminal of the power amplifier 27-k. Yes. The other input terminal of the adder 26-k is connected to the controller 40. The positive output terminal of the power amplifier 27-k is connected to one end of the input side coil of the transformer 30-k via the protective resistor 28-k. The negative output terminal of the power amplifier 27-k is connected to the other end of the input side coil of the transformer 30-k via the protective resistor 29-k. A midpoint between one end and the other end of the output side coil of the transformer 30-k is connected to the ground via a protective resistor 39-k. One end of the output side coil of the transformer 30-k is connected to the electrode plate 2B of the electrostatic speaker 10-k via the output terminal 22-k and the input terminal 12-k of the electrostatic speaker 10-k. The other end of the output side coil of the transformer 30-k is connected to the electrode plate 2F of the electrostatic speaker 10-k via the output terminal 23-k and the input terminal 13-k of the electrostatic speaker 10-k. .

The bias power supply 31-k and the protective resistor 32-k are interposed between the output terminal 24-k and the ground. A bias power supply 31-k generates a DC bias voltage V _B having the same voltage level as the center point of the output-side coil of the transformer 30-k. The DC bias voltage _{V B} is applied to the diaphragm 1 via a protection resistor 32-k and the terminal 24-k and 14-k. In a state where the bias voltage V _B is applied to the diaphragm 1, if the audio signal X _k is supplied between one end and the other end of the input coil of the transformer 30-k, the input-side coil voltage of the audio signal X _k The voltage V ₀ amplified according to the ratio N1 / N2 of the number of turns N1 and the number of turns N2 of the output side coil from one end of the output side coil of the transformer 30-k through the terminals 22-k and 12-k is an electrode plate 2B. Further, the voltage -V ₀ having a voltage _{V 0} and the opposite phase is applied to the electrode plates 2F via the terminal 23-k and 13-k from the other end of the output coil of the transformer 30-k. Thereby, the magnitude relationship between the electric field strength between the diaphragm 1 and the electrode plate 2F and the electric field strength between the diaphragm 1 and the electrode plate 2B is changed, and the diaphragm 1 vibrates, and the same waveform as that of the audio signal _Xk is obtained. The sound wave which has is emitted toward the front direction and the back direction.

The control unit 40 includes an A / D conversion unit 41, a noise generation source 42, and a microcomputer 43. The control unit 40 uses each point separated by a predetermined distance in the front direction of the electrostatic speaker 10-k (k = 1 to 3) as a listening reference point, and the sound is emitted from each electrostatic speaker 10-k. Ruoto a _k volume level each electrostatic speaker the masking sound M having a large volume level than the volume level at the listening reference points of the sound emitted from small neighboring electrostatic speaker than in listening reference point Sound is emitted from 10-k.

Hereinafter, the operation of the control unit 40 will be specifically described by taking as an example the case where the middle electrostatic speaker 10-2 of the electrostatic speakers 10-k (k = 1 to 3) is the reference speaker. As shown in FIG. 3, in this example, it is assumed that a point away from the center of the protective member 3F of the electrostatic speaker 10-2 by a distance D (D = 5 m) in the front direction is the listening reference point P, and the microphone 60 collects the sound at the reference point P. An A / D conversion unit 41 in the control unit 40 converts the output signal of the microphone 60 into a digital sound signal Y and outputs the sound signal Y. The microcomputer 43 takes in the audio signal _X k (k = _1~3) sound signal Y output is output from the A / D converter 41 immediately before the beginning of the sound source 50 as a sound signal _{Y BK} background noise BK, The volume level LV _BK of the background noise BK is obtained from the sound signal Y _BK . The noise generation source 42 in the control unit 40 generates a sound signal Z of a broadband noise sound.

When the output of the audio signal X _k (k = 1 to 3) from the sound source 50 starts, the microcomputer 43 starts to output the electrostatic speakers 10-1 and 10-3 adjacent to the electrostatic speaker 10-2 that is the reference speaker. The following processing is performed. That is, the microcomputer 43, by multiplying the correction coefficient corresponding to the position relationship between the electrostatic speaker 10-1 and listening reference point P to the audio signal X _1, sound audio signal X ₁ in the listening reference point P A to convert the volume level LV ₁ of _1. The microcomputer 43, by multiplying the correction coefficient corresponding to the position relationship between the electrostatic speaker 10-3 and listening reference point P to the audio signal X _3, sound audio signals X ₃ in the listening reference points P A ₃ of converting the volume level LV _3. Next, the microcomputer 43 obtains the volume level difference _LV 1 _{-LV BK} with volume levels LV ₁ and volume level _{LV BK,} and the volume level difference _LV 3 _{-LV BK} with volume level LV ₃ and volume level _{LV BK.} Next, the microcomputer 43 compares the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK with the threshold value TH, and _{one of} the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK is the threshold value TH. If you have exceeded the to the extent that the listener H who is listening reference point P is thus inaudible emission sound a ₃ release sound a ₁ or electrostatic speaker 10-3 electrostatic speaker 10-1 until it determined that the volume level _{LV BK} of the background noise BK is reduced. Here, as described above, the listener H at the listening reference point P can hear the sounds A ₁ and A ₃ emitted from the speakers 10-1 and 10-3 adjacent to the speaker 10-2 in front of the listener H. Whether or not it is in the state depends on the volume level LV _BK of the background noise BK, the volume levels LV ₁ and LV ₃ of the emitted sounds A ₁ and A ₃ of the adjacent speakers 10-1 and 10-3, and the speaker 10-on the front. 2 depends on the relationship between the volume level LV ₂ release sound _{a 2.} Therefore, the threshold value TH in this determination, taking into account the volume level LV ₂ sound _{A 2} that would be emitted from the speaker 10-2 (estimated value) by the supply to the speaker 10-2 of the audio signal _{X 2} To set. The microcomputer 43 performs the following processing based on the result of comparing the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK with the threshold value TH.

a1. When one or both of the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK are larger than the threshold value TH In this case, the microcomputer 43 selects the speaker 10-from among the electrostatic speakers 10-1 and 10-3. The volume level difference LV _k −LV _B between the volume level LV _k and the volume level LV _BK of the emitted sound A _k of _k is such that the magnitude relationship between the threshold level TH is LV _k −LV _BK > TH (for example, electrostatic type Speaker 10-1). Next, the microcomputer 43 determines the sound pressure level LV ₁ of the sound A ₁ emitted from the electrostatic speaker 10-1 at the listening reference point P and the electrostatic speaker 10 from the amplitudes of the signals X ₁ , X ₂ and Y _BK. sound pressure level LV ₂ release sound _{a 2} -2, and background noise BK volume level _{LV BK + M} magnitude relationship _LV 2 of the energy sum of the volume level LV _M volume levels _{LV BK} and masking sound M _{of> LV BK + M} The target volume level LV _M of the masker sound M such that> LV ₁ is obtained. On top of that, the microcomputer 43 is amplified by a gain R _M corresponding signal Z outputted from the noise source 42 to the target volume level LV _M, supplying the amplified signal Z × R _M to the adder 26-2 To do. The addition unit 26-2, is added to the audio signal _{X 2} and sound signals Z × _{R M,} the addition signal _X 2 + Z × _{R M} is the addition result is output to the power amplifier 27-2. Thus, from the electrostatic speaker 10-2 sounds including the advertising audio A ₂ and the masking sound M (broadband noise) is emitted. This masker sound M enhances the masking effect at the listening reference point P. As a result, the clarity of the sound that is emitted from the adjacent silent speaker 10-1 in the front direction of the electrostatic speaker 10-2 and goes around toward the listening reference point P is lowered.
b2. When both the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK are smaller than the threshold value TH In this case, the microcomputer 43 stops supplying the output signal Z of the noise source 42 to the adding unit 26-2.

The operation of the control unit 40 has been described above by taking the middle electrostatic speaker 10-2 as an example, but the control unit 40 generates similar masker sounds M for the other electrostatic speakers 10-1 and 10-3. Controls mute and volume at occurrence. Here, each of the electrostatic speaker 10-k (k = 1~3) is sometimes performs sound emission of sound at the same volume _A k (k = _1~3), sound different volume _A k ( In some cases, k = 1 to 3) is emitted. In the latter case, the volume level of the sound that is emitted from the electrostatic speaker adjacent to each electrostatic speaker 10-k and reaches the listening reference point P on each front surface is set to each electrostatic speaker 10-k ( k = 1 to 3). For example, when the electrostatic speaker 10-1 emits sound at a large volume and the electrostatic speaker 10-2 emits sound at a low volume, the electrostatic speaker 10-2 emits sound. Although the sound volume level of the sound that reaches the listening reference point in front of the electrostatic speaker 10-1 is reduced, the sound is emitted from the electrostatic speaker 10-1 and the sound level of the front of the electrostatic speaker 10-2 is reduced. The volume level of the sound that reaches the listening reference point increases. In such a case, the control unit 40 emits a high-volume masker sound M from the electrostatic speaker 10-2, but emits a low-volume masker sound M from the electrostatic speaker 10-1. Alternatively, the control of not releasing the masker sound M is performed.

As described above, in this embodiment, the level LV _BK of the background noise BK in the room in which the electrostatic speaker 10-k (k = 1 to 3) is arranged is the sound emitted from the electrostatic speaker 10-k. smaller than the a _k, when it is probable that listening sound arriving sound is emitted from the neighboring electrostatic speaker to the listening reference point P in front of the electrostatic speaker 10-k is performed, Each electrostatic speaker 10-k emits a masker sound M having a volume that prevents listening to sound from the adjacent electrostatic speaker. Therefore, according to this embodiment, it is possible to make it difficult for the listener H who is in front of each electrostatic speaker 10-k to hear the sound emitted from the adjacent electrostatic speaker.

Second Embodiment
Next, a second embodiment of the present invention will be described. In the present embodiment, the frequency of the masker sound M (broadband noise) that causes the microcomputer 43 in the control device 20 of the first embodiment to emit sound from each of the electrostatic speakers 10-k (k = 1 to 3). A function for adjusting the bandwidth is provided. Taking the masking sound M for emitted from an electrostatic speaker 10-2 as an example, in the present embodiment, the frequency components of the sound A ₁ and A _3, which is emitted from an electrostatic speaker 10-1 and 10-3 The masker sound M having a frequency component in the frequency band to which the sound belongs is emitted from the electrostatic speaker 10-2. More specifically, the microcomputer 43 performs the above-described a1. In the process of analyzing the frequency components of the audio signal _{X 1} and _{X 3} which the electrostatic speaker 10-1 and 10-3 and the supply destination. Then, the microcomputer 43 selects only the frequency components in the same band as that contained from the signal Z wideband noise noise source 42 generates the audio signal X ₁ and X _3, only the addition the selected frequency component Supply to the vessel 26-2. The masker sound M emitted from the electrostatic speaker 10-2 has been described above as an example, but the microcomputer 43 also applies the same to each masker sound M emitted from the electrostatic speakers 10-1 and 10-3. Adjust the frequency band. According to the present embodiment, sound is emitted from each adjacent electrostatic speaker while minimizing the uncomfortable feeling given to the listener H in front of each of the electrostatic speakers 10-k (k = 1 to 3). It is possible to make it difficult to hear the generated sound.

The first and second 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 and second embodiments, the microcomputer 43 in the control unit 40 determines that one or both of the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK are larger than the threshold value TH (described above). In the case of a1), a sound signal Z having a predetermined volume level is supplied to the adding unit 26-k regardless of the difference between the volume level differences LV ₁ -LV _BK and LV ₃ -LV _BK and the threshold value TH. You may make it do.

(2) In the first and second embodiments, the number of electrostatic speakers 10-k (k = 1 to 3) is three. However, the number may be two or four. You may do it above. Moreover, it is not necessary to arrange the electrostatic speakers 10-k (k = 1 to 3) in a horizontal row. For example, they may be arranged in a square shape so that the front directions do not overlap.

(3) In the first and second embodiments described above, control of sound emission / stop of the masker sound M and sound volume control are individually performed for each of the electrostatic speakers 10-k (k = 1 to 3). When the measured level LV _{BK of the} background noise B is less than the threshold value, the masker sound M having a constant volume is emitted from all the electrostatic speakers 10-k (k = 1 to 3), and the threshold value is set. In the above case, the sound emission of the masker sound M from all the electrostatic speakers 10-k (k = 1 to 3) may be stopped.

(4) In the first and second embodiments, the electrostatic speaker is used as the planar speaker. However, a speaker other than the electrostatic speaker may be used as long as it can emit a plane sound wave.
(5) In the first and second embodiments, the broadband noise is used as the masker sound M. However, a sound other than the broadband noise, for example, a sound obtained by processing a human voice is used as the masker sound M. Also good. The signal Z ′ obtained by correcting the frequency component of the output signal Z (broadband noise sound signal) of the noise source 42 so as to have a frequency characteristic equivalent to the background noise BK at the listening reference point P may be used as the masker sound M. . In this way, it is possible to efficiently mask the sounds A ₁ and A ₃ emitted from the adjacent silent speakers 10-1 and 10-3 while reducing the noise of the masker sound M itself.

DESCRIPTION OF SYMBOLS 1 ... Vibration plate, 2 ... Electrode plate, 3 ... Protection member, 4, 5 ... Elastic member, 10 ... Electrostatic speaker, 20 ... Control apparatus, 27 ... Power amplifier, 28, 29, 39, 32 ... Protection resistance, DESCRIPTION OF SYMBOLS 30 ... Transformer, 31 ... Bias power supply, 40 ... Control part, 41 ... A / D conversion part, 42 ... Noise generation source, 43 ... Microcomputer, 50 ... Sound source, 60 ... Microphone.

Claims (5)

A plurality of loudspeakers that face substantially the same direction and are arranged next to each other;
A plurality of audio signals are respectively supplied to the plurality of speakers and emitted from the plurality of speakers, and a sound that is emitted from a speaker adjacent to each speaker and reaches a listening reference point in front of each speaker is listened to. And a control means for emitting a masker sound having a volume level to prevent sound from each speaker.   The control means is larger than the volume level of the sound emitted from the speaker adjacent to each speaker and reaching the listening reference point in front of each speaker, and is emitted from each speaker and listened to the listening reference point in front of each speaker. The acoustic system according to claim 1, wherein a masker sound having a volume level smaller than a volume level of a sound reaching the sound is emitted from each speaker.   The control means emits a masker sound when the volume level of sound emitted from a speaker adjacent to each speaker and reaching the listening reference point in front of each speaker is lower than the background level of background noise. The acoustic system according to claim 1, wherein: Sound collecting means for collecting the sound of the listening reference point;
4. The sound system according to claim 3, wherein the control unit obtains a volume level of the background noise from a sound signal output from the sound collecting unit before supply of an audio signal to the speaker is started. 3. The control unit according to claim 1, wherein the control unit causes each speaker to emit a masker sound having a frequency component in a frequency band to which a frequency component of the sound emitted from the speaker adjacent to each speaker belongs. Acoustic system.

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