JP5685173B2 - Loudspeaker system - Google Patents

Description

  The present invention relates to a loudspeaker system, and more particularly to an improvement of a loudspeaker system that controls the directivity of a plurality of line array speakers.

  The line array speaker is a speaker device for emitting sound waves as a linear sound source, and includes a plurality of speaker units arranged in a substantially straight line. In recent years, there is a need to adapt to various acoustic spaces, and line array speakers are desired to change the directivity. The directivity characteristics of the line array speaker can be achieved, for example, by adjusting the mounting angle when the line array speaker is installed or by adjusting the direction of each speaker unit in the line array speaker. For example, by arranging the speaker units in the same direction, it is possible to obtain directivity characteristics with suppressed sound diffusion in the arrangement direction.

  However, in the method of adjusting the mounting angle of the line array speaker, in the case of a system in which a plurality of line array speakers are connected to the audio signal source via the transmission line, the mounting angle is individually adjusted for each line array speaker. There is a problem that the adjustment work is very troublesome. Further, the method of adjusting the orientation of each speaker unit has a problem that the directivity characteristics cannot be changed for each line array speaker.

  Therefore, a line array speaker is proposed in which a delay circuit is provided for each speaker unit, and an arbitrary directivity characteristic can be obtained by adjusting the delay time of the audio signal for each speaker unit (for example, Patent Document 1). And 2).

  FIG. 9 is a diagram showing a conventional loudspeaker system 200 including a plurality of line array speakers 203. The loudspeaker system 200 is a system in which a plurality of line array speakers 203 are connected to an audio signal source 201 via a transmission line 202. The audio signal output from the audio signal source 201 is input to each line array speaker 203 via the transmission line 202.

  The line array speaker 203 includes a plurality of built-in speakers 213, an amplifier 212 provided for each built-in speaker 213, and a DSP (Digital Signal Processor) 211 that controls the delay time of an audio signal for each built-in speaker 213. It is a steerable array speaker. The built-in speaker 213 is a speaker unit that converts the sound signal amplified by the amplifier 212 into a sound wave and emits it. The DSP 211 includes a plurality of delay circuits 214 provided for each built-in speaker 213, and the same audio signal input from the transmission line 202 is processed in each delay circuit 214. The amplifier 212 amplifies the audio signal after adjusting the delay time by the delay circuit 214 and outputs the amplified audio signal to the built-in speaker 213.

  In such a loudspeaker system 200, the delay time of the audio signal must be set for each built-in speaker 213 for each line array speaker 203, and there is a problem that the setting work is extremely troublesome. Further, since an expensive DSP is used for the delay circuit 214 provided for each built-in speaker 213, there is a problem that the manufacturing cost of the line array speaker 203 increases.

Japanese Patent Laid-Open No. 7-87590 JP 2007-74255 A

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a loudspeaker system capable of easily setting the directivity of a plurality of line array speakers. In particular, an object of the present invention is to provide a loudspeaker system capable of facilitating setting work for setting a delay time of an audio signal for each built-in speaker in a line array speaker.

  Another object of the present invention is to provide a loudspeaker system that simplifies the configuration of line array speakers and can suppress an increase in system manufacturing cost when the number of line array speakers increases. .

A loudspeaker system according to a first aspect of the present invention comprises: three or more line array speakers; and a directivity controller that connects the line array speakers via two or more transmission lines and controls the directivity of the line array speakers. A loudspeaker system comprising: two or more delay time control means for generating a speaker drive signal by causing the directivity controller to perform a delay time control on the same audio input signal; and the speaker drive signal respectively. Two or more amplifiers that amplify and output to the transmission lines different from each other, and the line array speaker includes two or more built-in speakers arranged in a substantially straight line, and is generated in each delay time control means Speaker drive signals are output to the different transmission lines, and the same speaker drive signal The signal is input to two or more built-in speakers belonging to different line array speakers via the transmission line . Each line array speaker is a speaker device in which the built-in speakers are arranged in individual housings, and is arranged apart from each other .

  In this loudspeaker system, the directivity of the plurality of line array speakers is controlled by the directivity controller, so that the line array speakers can be compared with the conventional system in which the delay time of each built-in speaker is set for each line array speaker. Directivity can be set easily. Further, the configuration of the line array speaker can be simplified as compared with a conventional line array speaker having a delay circuit and an amplifier for each built-in speaker. For this reason, when the number of line array speakers increases, it can suppress that the manufacturing cost of a system increases.

In addition to the above configuration, the loudspeaker system according to the second aspect of the present invention is configured such that two or more line array speakers have different numbers of the built-in speakers .

A loudspeaker system according to a third aspect of the present invention includes two or more line array speakers, and a directivity controller that connects the line array speakers via two or more transmission lines and controls the directivity of the line array speakers. A loudspeaker system comprising: two or more delay time control means for generating a speaker drive signal by causing the directivity controller to perform a delay time control on the same audio input signal; and the speaker drive signal respectively. Two or more amplifiers that amplify and output to the transmission lines different from each other, and the line array speaker includes two or more built-in speakers arranged in a substantially straight line, and is generated in each delay time control means Speaker drive signals are output to the different transmission lines, and the same speaker drive signal The two or more built-in speakers belonging to the line array speakers different from each other are input via the transmission line. The two or more line array speakers are the first line array speakers and the number of the built-in speakers is the first line. Including the second line array speakers fewer than the array speakers, and the built-in speakers in the second line array speakers are associated with the same number of the built-in speakers arranged continuously in the first line array speaker. The built-in speakers corresponding to each other are configured to be connected to the same transmission line.

  According to such a configuration, directivity can be easily set even in a loudspeaker system to which line array speakers having different numbers of built-in speakers are connected. Moreover, directivity can be made different between line array speakers having different numbers of built-in speakers. For example, a directional characteristic sound field obtained by cutting out a part of the first line array speaker can be formed by the second line array speaker.

A loudspeaker system according to a fourth aspect of the present invention comprises: two or more line array speakers; and a directivity controller that connects the line array speakers via two or more transmission lines and controls the directivity of the line array speakers. A loudspeaker system comprising: two or more delay time control means for generating a speaker drive signal by causing the directivity controller to perform a delay time control on the same audio input signal; and the speaker drive signal respectively. Two or more amplifiers that amplify and output to the transmission lines different from each other, and the line array speaker includes two or more built-in speakers arranged in a substantially straight line, and is generated in each delay time control means Speaker drive signals are output to the different transmission lines, and the same speaker drive signal The two or more built-in speakers belonging to the line array speakers different from each other are input via the transmission line. The two or more line array speakers are the first line array speakers and the number of the built-in speakers is the first line. Including the second line array speakers fewer than the array speakers, and the built-in speakers in the second line array speakers are associated with the same number of the built-in speakers arranged intermittently in the first line array speakers. The built-in speakers corresponding to each other are configured to be connected to the same transmission line.

  According to such a configuration, directivity can be easily set even in a loudspeaker system to which line array speakers having different numbers of built-in speakers are connected. Moreover, directivity can be made different between line array speakers having different numbers of built-in speakers. For example, a sound field having a directional characteristic obtained by reducing a part of the first line array speaker can be formed by the second line array speaker.

  In the loudspeaker system according to the present invention, the directivity of a plurality of line array speakers can be easily set.

  Further, in the loudspeaker system according to the present invention, the configuration of the line array speaker can be simplified as compared with a conventional line array speaker having a delay circuit and an amplifier for each built-in speaker. Therefore, when the number of line array speakers increases, it is possible to suppress an increase in system manufacturing cost.

1 is a system diagram showing an example of a schematic configuration of a loudspeaker system 100 according to Embodiment 1 of the present invention. It is sectional drawing which showed an example of operation | movement of the line array speaker 20 of FIG. 1, and the mode that the directivity direction 3 and the spreading | diffusion condition of reproduced sound are controlled is shown. It is the figure which showed the example of 1 structure of the directivity controller 10 of FIG. It is the figure which showed the example of 1 structure of the line array speaker 20 of FIG. 2 is a diagram showing an example in which a plurality of line array speakers 20 having the same number of built-in speakers 21 are connected to a directivity controller 10. FIG. It is the figure which showed the structural example of the loudspeaker system 100 by Embodiment 2 of this invention, and the case where the line array speaker 20 from which the number of speakers differs is shown is shown. FIG. 6 is a diagram illustrating another example when a plurality of line array speakers 20 having different numbers of built-in speakers 21 are connected to the directivity controller 10. It is the figure which showed the structural example of the loudspeaker system 100 by Embodiment 3 of this invention. 1 is a diagram showing a conventional loudspeaker system 200 including a plurality of line array speakers 203. FIG.

Embodiment 1 FIG.
<Sound system 100>
FIG. 1 is a system diagram showing an example of a schematic configuration of a loudspeaker system 100 according to Embodiment 1 of the present invention. The loudspeaker system 100 includes a plurality of line array speakers 20, a directivity controller 10 that controls the directivity of the line array speakers 20, and the high impedance transmission path 2. The high impedance transmission line 2 includes a plurality of high impedance transmission lines 2a and a common potential line 2b, and the line array speakers 20 are connected in parallel.

  The loudspeaker system 100 is a system that changes the directivity of the line array speaker 20 by adjusting the delay time of the audio signal for each high impedance transmission line 2a.

  The directivity controller 10 is a delay time control device that controls the delay time of an audio input signal input from the audio signal source 1 such as a microphone. Each line array speaker 20 is connected via the high impedance transmission line 2. Yes. The delay time control of the audio input signal is performed by adjusting the delay time for each high impedance transmission line 2a, and a plurality of speaker drive signals having different delay times are generated. Each speaker drive signal is transmitted via different high impedance transmission lines 2a.

  The high-impedance transmission line 2 is a transmission line that connects the directivity controller 10 and each line array speaker 20 with high impedance, and since the signal is transmitted at a high voltage, the speaker drive is compared with the transmission line that is connected with low impedance. There is little power loss at the time of signal transmission, and the wiring length can be increased.

  The line array speaker 20 includes a plurality of built-in speakers 21 and is a speaker array unit in which these built-in speakers 21 are arranged in a substantially straight line. The delay time of the audio signal (speaker drive signal) output from each built-in speaker 21. The desired directivity can be obtained by the control. In this example, each of the built-in speakers 21 is disposed on the front surface of the casing 22 which is an elongated rectangle.

  Such a line array speaker 20 is installed, for example, on a floor or a wall surface in a state where the arrangement direction of the built-in speakers 21 is vertical. In this case, each of the built-in speakers 21 is directed in the same direction in the horizontal direction, and the directing direction and spread of the reproduced sound can be controlled in the vertical direction by controlling the delay time of the speaker drive signal. When the line array speaker 20 is installed on the ceiling or the like, the line array speaker 20 is installed in a tilted state so that the arrangement direction of the built-in speakers 21 is horizontal. In this case, each built-in speaker 21 faces the same direction in the vertical direction.

  Here, an audio system that can individually control the delay time is called a channel. In the directivity controller 10, a plurality of channels of speaker drive signals are generated and input to the line array speaker 20 via different high impedance transmission lines 2a. Each line array speaker 20 receives a plurality of channels of speaker drive signals. With such a configuration, the directivity of the line array speaker 20 can be controlled by the directivity controller 10.

  Further, the same speaker drive signal is input to the plurality of built-in speakers 21 belonging to different line array speakers 20 via the same high impedance transmission line 2a. Since such built-in speakers 21 exist, it is not necessary to individually set the delay time of the audio signal for these built-in speakers 21, and thus the directivity of the plurality of line array speakers 20 can be set easily. Can do.

  FIG. 2 is a cross-sectional view showing an example of the operation of the line array speaker 20 of FIG. 1, and shows a cut surface when the line array speaker 20 is cut along a vertical plane parallel to the direction of the built-in speaker 21. . In this figure, a line array speaker 20 is shown in which eight built-in speakers 21 are arranged at regular intervals on the front surface of the housing 22. In general, the directivity of reproduced sound is controlled by the delay time difference between adjacent built-in speakers 21, and the sound pressure distribution in a plane including the arrangement direction of the built-in speakers 21 can be controlled.

  (A) in the figure shows a state in which the directivity direction 3 of the reproduced sound is controlled. Here, the order of arrangement of the built-in speakers 21 in the line array speaker 20 is referred to as the first place, the second place,..., The eighth place from the top, and the built-in k-th place (k = 1 to 8). The speaker 21 will be referred to as the kth speaker.

  For the built-in speakers 21 from the first speaker to the eighth speaker, if the delay amount of the speaker drive signal is increased by a certain time in this order, a sharp directivity in which the reproduced sound propagates without being diffused can be obtained. The directivity direction 3 can be directed downward. On the other hand, for the built-in speakers 21 from the first speaker to the eighth speaker, if the delay amount of the speaker drive signal is shortened by a certain time in this order, the reproduction sound directing direction 3 can be directed upward.

  (B) in the figure shows how the region where the reproduced sound propagates is narrowed or widened. By inputting a speaker drive signal with the same delay amount to the built-in speakers 21 from the first speaker to the eighth speaker, the reproduction sound can be propagated without spreading in the vertical direction, and the propagation region can be narrowed. . For this reason, sharp directivity is obtained, and the directivity direction 3 of the reproduced sound can be concentrated forward.

  On the other hand, a loudspeaker drive signal having a delay amount gradually longer than that of the middle speaker is input to the upper speaker including the first speaker, and the lower speaker including the eighth speaker is more than the middle speaker. By inputting a speaker drive signal with a gradually shortened delay amount, the reproduced sound is diffused and propagated in the vertical direction, and the propagation area can be expanded. In this way, the directivity of the reproduced sound can be controlled by adjusting the delay time difference of the reproduced sound between the adjacent built-in speakers 21.

<Directivity controller 10>
FIG. 3 is a diagram showing a configuration example of the directivity controller 10 of FIG. This directivity controller 10 includes one DSP 11, N (N is an integer of 2 or more) power amplifiers 12, N matching transformers 13, and output terminals 14, and outputs N-channel speaker drive signals. Generate.

  The directivity controller 10 is connected to a high impedance transmission line 2 including a plurality of high impedance transmission lines 2a provided for each channel and a common potential line 2b. The DSP 11 is a delay time control circuit including N delay time adjustment circuits 111 for adjusting the delay time of the audio input signal for each channel, and adjusts the delay time for each channel by rewriting the setting parameter. Can do. The delay time adjustment circuit 111 is a delay circuit that adjusts the delay time of the audio input signal and generates a speaker drive signal, and is provided for each channel.

  The power amplifier 12 is an amplifier for amplifying the speaker drive signal input from the DSP 11 and outputting the amplified signal to the matching transformer 13, and is provided for each channel. The matching transformer 13 is a transformer that converts the impedance of the speaker drive signal amplified by the power amplifier 12 and outputs the converted signal to the output terminal 14. The primary side and the secondary side are insulated.

  The primary side of the matching transformer 13 is connected to the power amplifier 12, and one end of the primary side winding is grounded. On the other hand, one end of the secondary winding of the matching transformer 13 is connected to the common potential line 2 b and the other end is connected to the output terminal 14. The output terminal 14 includes a plurality of output terminals for high impedance transmission lines and an output terminal for common potential lines. The output terminal for the high impedance transmission line is provided for each channel.

  In this directivity controller 10, speaker driving signals of the first to Nth channels are generated from the same audio input signal, amplified for each channel, converted in impedance, and then each high impedance transmission line 2 a via the output terminal 14. Is output. The common potential line 2b is a transmission line for transmitting the reference potential of each speaker drive signal.

  Further, the speaker drive signals generated in each delay time adjustment circuit 111 are output to different high impedance transmission lines 2a. Furthermore, the same speaker drive signal is input to a plurality of built-in speakers 21 belonging to different line array speakers 20 via the same high impedance transmission line 2a.

<Line array speaker 20>
FIG. 4 is a diagram showing a configuration example of the line array speaker 20 of FIG. The line array speaker 20 includes N built-in speakers 21, N matching transformers 23, and an input terminal 24, and reproduces N-channel speaker drive signals.

  The input terminal 24 includes a plurality of input terminals for high impedance transmission lines and an input terminal for common potential lines. An input terminal for a high impedance transmission line is provided for each channel. In the line array speaker 20, a plurality of high impedance transmission lines 2 a and a common potential line 2 b are respectively connected to the input terminal 24.

  The matching transformer 23 is a transformer for impedance-converting a speaker drive signal input from the high impedance transmission line 2a via the input terminal 24 and outputting the converted signal to the built-in speaker 21, and is provided for each channel. Further, each matching transformer 23 in the line array speaker 20 outputs the speaker drive signal subjected to impedance conversion to different built-in speakers 21.

  The primary side of the matching transformer 23 is connected to the high impedance transmission line 2, one end of the primary side winding is connected to the common potential line 2b, and the other end is connected to the high impedance transmission line 2a. On the other hand, the secondary side of the matching transformer 23 is connected to the built-in speaker 21. Each matching transformer 23 has a fixed winding ratio.

  The built-in speaker 21 is a speaker unit that outputs a speaker drive signal input from the matching transformer 23 as a sound wave, and is provided for each channel. The built-in speaker 21 includes, for example, a diaphragm and a voice coil that vibrates the diaphragm based on a speaker drive signal.

  In this line array speaker 20, an input terminal 24, a matching transformer 23, and a built-in speaker 21 are provided for each channel, and a speaker drive signal input through the input terminal 24 is supplied to the built-in speaker 21 through the matching transformer 23. Is done.

<Connection Mode of Line Array Speaker 20>
FIG. 5 is a diagram showing an example in which a plurality of line array speakers 20 having the same number of built-in speakers 21 are connected to the directivity controller 10. This figure shows an example of a connection mode between three line array speakers 20a each having eight built-in speakers 21 and the high impedance transmission line 2a. 5 to 8, the directivity controller 10 and the common potential line 2b are omitted.

  When transmitting the first to eighth channel speaker drive signals using the eight high-impedance transmission lines 2a, the delay time of the speaker drive signals is individually controlled for the eight built-in speakers 21 in the line array speaker 20a. can do.

  In each line array speaker 20a, built-in speakers 21 from the first speaker to the eighth speaker are connected to the high impedance transmission lines 2a of the first channel to the eighth channel, respectively. That is, for all the built-in speakers 21 in the line array speaker 20a, the same speaker drive signal is input to the three built-in speakers 21 belonging to different line array speakers 20a via the same high impedance transmission line 2a. .

  For the built-in speakers 21 in each line array speaker 20a, the built-in speakers 21 having the same rank in the order of arrangement of the built-in speakers 21 are connected to the same high impedance transmission line 2a. In other words, the k-th speakers of each line array speaker 20a are connected to each other via the k-th channel high impedance transmission line 2a. In such a connection mode, the loudspeaker system 100 having the same number of built-in speakers 21 and having a plurality of line array speakers 20a having the same directivity can be realized at low cost.

  According to the present embodiment, the directivity of the plurality of line array speakers 20 is controlled by one directivity controller 10, so that the delay time of each built-in speaker is set for each line array speaker as compared with the conventional system. The directivity setting operation can be simplified. In particular, since the same speaker drive signal is input to the plurality of built-in speakers 21 belonging to the different line array speakers 20 via the same high impedance transmission line 2a, the audio signal delays for these built-in speakers 21. It is not necessary to set the time individually.

  Further, the configuration of the line array speaker 20 can be simplified as compared with a conventional steerable array speaker having a delay circuit and an amplifier for each built-in speaker 21. For this reason, when the number of line array speakers 20 increases, it can suppress that the manufacturing cost of the loudspeaker system 100 increases. Further, by outputting the speaker drive signals generated in the respective delay time adjustment circuits 111 to the different high impedance transmission lines 2a, it is possible to input the speaker drive signals having different delay times to the respective built-in speakers 21.

Embodiment 2. FIG.
In the first embodiment, an example in which a plurality of line array speakers 20 having the same number of built-in speakers 21 are connected to the directivity controller 10 has been described. In contrast, in the present embodiment, a case will be described in which a plurality of line array speakers 20 having different numbers of built-in speakers 21 are connected to the directivity controller 10.

  FIG. 6 is a diagram illustrating a configuration example of the loudspeaker system 100 according to the second embodiment of the present invention, and an example in which a plurality of line array speakers 20 having different numbers of built-in speakers 21 are connected to the directivity controller 10. It is shown. In this figure, a line array speaker 20a having eight built-in speakers 21, a line array speaker 20b having six built-in speakers 21, a line array speaker 20c having four built-in speakers 21, An example of a connection mode with the high impedance transmission line 2a is shown.

  The built-in speakers 21 in the line array speakers 20b and 20c are associated with the same number of built-in speakers 21 arranged continuously in the line array speaker 20a, and the built-in speakers 21 corresponding to each other are connected to the same high impedance transmission line. 2a. That is, the built-in speaker 21 in the line array speaker 20b is associated with higher-order speakers including the first speaker in the line array speaker 20a. Specifically, the first to sixth speakers in the line array speaker 20b are respectively associated with the first to sixth speakers in the line array speaker 20a, and the high impedance transmission lines 2a of the first to sixth channels are connected. Are connected to each other.

  The built-in speaker 21 in the line array speaker 20c is associated with lower speakers including the eighth speaker in the line array speaker 20a. Specifically, the first to fourth speakers in the line array speaker 20c are respectively associated with the fifth to eighth speakers in the line array speaker 20a, and the high impedance transmission lines 2a of the fifth to eighth channels are connected. Are connected to each other. In such a connection mode, a sound field having a directional characteristic obtained by cutting out a part of the line array speaker 20a can be formed by the line array speakers 20b and 20c.

  FIG. 7 is a diagram illustrating another example in which a plurality of line array speakers 20 having different numbers of built-in speakers 21 are connected to the directivity controller 10. This figure shows a connection mode of one line array speaker 20d having twelve built-in speakers 21, two line array speakers 20b having six built-in speakers 21, and a high impedance transmission line 2a. An example is shown.

  When transmitting the first to twelfth channel speaker drive signals using the 12 high-impedance transmission lines 2a, the delay time of the speaker drive signals is individually controlled for the 12 built-in speakers 21 in the line array speaker 20d. can do. In the line array speaker 20d, built-in speakers 21 from the first speaker to the twelfth speaker are connected to the high impedance transmission lines 2a of the first channel to the twelfth channel, respectively.

  The built-in speakers 21 in the line array speaker 20b are associated with the same or less number of built-in speakers 21 that are intermittently arranged in the line array speaker 20d, and the built-in speakers 21 that correspond to each other have the same high impedance transmission. It is connected to the line 2a. That is, in one line array speaker 20b, the first to sixth speakers are associated with the first, third, fifth, seventh, ninth, and twelfth speakers in the line array speaker 20d, respectively. ,..., 9th and 12th channels are connected via high impedance transmission lines 2a. In such a connection mode, a sound field having a directional characteristic in which a part of the line array speaker 20d is reduced can be formed by the line array speaker 20b. That is, the line array speaker 20b can be given a directivity with a greater downward angle than the line array speaker 20d.

  In the other line array speaker 20b, the first to third speakers are all associated with the first speaker in the line array speaker 20d and are connected via the high impedance transmission line 2a of the first channel. In addition, the fourth to sixth speakers are respectively associated with the fourth, seventh and tenth speakers in the line array speaker 20d, and are respectively connected via the high impedance transmission lines 2a of the fourth, seventh and tenth channels. It is connected. In such a connection mode, it is possible to give the fourth to sixth speakers directivity with a large swing angle while giving the first to third speakers directivity in the horizontal direction.

Embodiment 3 FIG.
In the first and second embodiments, the example in which the high impedance transmission line 2a for each channel is connected to one of the line array speakers 20 has been described. In contrast, in the present embodiment, a case where a plurality of line array speakers 20 having a smaller number of built-in speakers 21 than the number of channels is connected to the directivity controller 10 will be described.

  FIG. 8 is a diagram showing a configuration example of the loudspeaker system 100 according to the third embodiment of the present invention. A plurality of line array speakers 20 having a smaller number of built-in speakers 21 than the number of channels are connected to the directivity controller 10. An example is shown where this is done. This figure shows an example of a connection mode between the two line array speakers 20c and the high impedance transmission line 2a.

  The built-in speaker 21 in one line array speaker 20c is associated with the middle speaker in the line array speaker 20a. Specifically, the first to fourth speakers in the line array speaker 20c are respectively associated with the third to sixth speakers in the line array speaker 20a, and the high impedance transmission lines 2a of the third to sixth channels are connected. Are connected to each other.

  The built-in speakers 21 in the other line array speaker 20c are associated with the same number of built-in speakers 21 arranged intermittently in the line array speaker 20a. Specifically, the first to fourth speakers in the line array speaker 20c are associated with the first, third, fifth, and seventh speakers in the line array speaker 20a, respectively. The fifth and seventh channels are connected via high-impedance transmission lines 2a.

  In such a connection mode, a directional characteristic sound field obtained by cutting out a part of the line array speaker 20a and a directional characteristic sound field obtained by reducing a part of the line array speaker 20a can be simultaneously formed by each line array speaker 20c. it can.

  In the first to third embodiments, an example in which a transformer having a fixed winding turns ratio is used as the matching transformer 23 in the line array speaker 20 has been described. However, the present invention is not limited to this. For example, a configuration in which a transformer with a tap with a variable winding ratio is used as the matching transformer 23 may be used. If such a matching transformer 23 is used, the volume of each built-in speaker 21 can be increased by switching the taps of a plurality of built-in speakers 21 connected to the same high impedance transmission line 2a and belonging to different line array speakers 20. It can be adjusted easily.

  In the first embodiment, an example in which the power amplifier 12 is provided for each channel has been described. However, the present invention does not limit the configuration of the amplifier that amplifies the speaker drive signal before transmission. For example, in a case where the number of built-in speakers 21 connected to the power amplifier 12 differs between channels, it is conceivable that a channel exceeding the capacity of the power amplifier 12 is generated. In such a case, the power amplifier 12 may be added to the channel.

  Moreover, although Embodiment 1-3 demonstrated the example in case the directivity controller 10 and each line array speaker 20 are connected via the high impedance transmission line 2, this invention is the structure of a transmission line. However, the present invention is not limited to this. Any environment in which a plurality of speakers can be connected in parallel to the same transmission path is acceptable, and what is connected via a so-called low impedance transmission path can also be included in the present invention.

100 loudspeaker system 1 audio signal source 2 high impedance transmission line 2a high impedance transmission line 2b common potential line 10 directivity controller 11 DSP
111 Delay Time Adjustment Circuit 12 Power Amplifier 13 Matching Transformer 14 Output Terminal 20 Line Array Speaker 21 Built-in Speaker 22 Case 23 Matching Transformer 24 Input Terminal

Claims (4)

A loudspeaker system including three or more line array speakers, and a directivity controller that controls the directivity of the line array speakers by connecting these line array speakers via two or more transmission lines,
The directivity controller includes two or more delay time control units that respectively generate a speaker drive signal by performing delay time control on the same audio input signal, and amplifies the speaker drive signal, and transmits the different transmissions. With two or more amplifiers that output to the line,
The line array speaker includes two or more built-in speakers arranged substantially linearly,
The speaker driving signals generated in each delay time control means are output to different transmission lines,
The same speaker driving signal is input to two or more built-in speakers belonging to different line array speakers via the same transmission line ,
Each of the line array speakers is a speaker device in which the built-in speakers are arranged in separate housings, and is arranged apart from each other . 2. The loudspeaker system according to claim 1, wherein the two or more line array speakers have different numbers of the built-in speakers . A loudspeaker system including two or more line array speakers, and a directivity controller for controlling the directivity of the line array speakers, wherein the line array speakers are connected via two or more transmission lines.
The directivity controller includes two or more delay time control units that respectively generate a speaker drive signal by performing delay time control on the same audio input signal, and amplifies the speaker drive signal, and transmits the different transmissions. With two or more amplifiers that output to the line,
The line array speaker includes two or more built-in speakers arranged substantially linearly,
The speaker driving signals generated in each delay time control means are output to different transmission lines,
The same speaker driving signal is input to two or more built-in speakers belonging to different line array speakers via the same transmission line,
The two or more line array speakers include a first line array speaker and a second line array speaker in which the number of the built-in speakers is smaller than that of the first line array speaker,
The built-in speakers in the second line array speaker are associated with the same number of the built-in speakers arranged continuously in the first line array speaker, and the built-in speakers corresponding to each other are connected to the same transmission line. expanding voice system that characterized by being connected to. A loudspeaker system including two or more line array speakers, and a directivity controller for controlling the directivity of the line array speakers, wherein the line array speakers are connected via two or more transmission lines.
The directivity controller includes two or more delay time control units that respectively generate a speaker drive signal by performing delay time control on the same audio input signal, and amplifies the speaker drive signal, and transmits the different transmissions. With two or more amplifiers that output to the line,
The line array speaker includes two or more built-in speakers arranged substantially linearly,
The speaker driving signals generated in each delay time control means are output to different transmission lines,
The same speaker driving signal is input to two or more built-in speakers belonging to different line array speakers via the same transmission line,
The two or more line array speakers include a first line array speaker and a second line array speaker in which the number of the built-in speakers is smaller than that of the first line array speaker,
The built-in speakers in the second line array speaker are associated with the same number of the built-in speakers arranged intermittently in the first line array speaker, and the built-in speakers corresponding to each other are connected to the same transmission line. expanding voice system that characterized by being connected to.

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