The present invention relates to a sound reproduction technique using a speaker.
In configuring a speaker array using a plurality of speakers, problems relating to speaker reproduction bands and spatial aliasing may occur.
A large speaker is required to reproduce low-frequency sounds. In such a case, as illustrated in
Here, spatial aliasing refers to an effect where, in order to satisfy the sampling theorem in a spatial direction, a sound source interval d needs to be equal to or less than a half wavelength of the highest frequency component, and if the sampling theorem is not satisfied, the desired directivity cannot be obtained (see NPL 1 and NPL 2, for example).
[NPL 1] Hiroshi Saruwatari, Shoichi Koyama (2016, Oct. 24 (searched on 2020, Mar. 27)). “Advanced Signal Processing No. 5 (10/25)”, online. Retrieved from http://www.sp.ipc.i.u-tokyo.ac.jp/˜saruwatari/SP-Grad2016_04.pdf
[NPL 2] Futoshi Asano (2016, Oct. 24 (searched on 2020, Mar. 27)). “Chapter 2: Sound Source Separation”, online. The Institute of Electronics, Information and Communication Engineers, Forest of Knowledge, Group 2, part 6, chapter 2. Retrieved from http://www.ieice-hbkb.org/files/02/02gun_06hen_02.pdf
An object of the present invention is to provide a speaker array capable of eliminating spatial aliasing for high-frequency components that is caused due to speaker size restrictions, to control sound radiation characteristics (directional characteristics) up to high frequencies by using a plurality of speakers.
A speaker array according to one aspect of the present invention is a speaker array including a first speaker, a second speaker, and a local sound emission structure, wherein the local sound emission structure is arranged in a direction of directional control with respect to the first speaker and the second speaker and is provided with a first transmission portion for transmitting an acoustic signal radiated from the first speaker, a second transmission portion for transmitting an acoustic signal radiated from the second speaker, and a non-transmission portion for interrupting the transmission of the acoustic signals radiated from the first speaker and the second speaker, the first transmission portion and the second transmission portion being arranged in such a manner that a distance between a center position of the first transmission portion and a center position of the second transmission portion is smaller than a distance between a center position of the first speaker and a center position of the second speaker, in order to generate sound sources that are arranged at an interval narrower than an interval between the first speaker and the second speaker.
A speaker array according to one aspect of the present invention is a speaker array including a plurality of speakers and a local sound emission structure, wherein the local sound emission structure is arranged in a direction of directional control with respect to the plurality of speakers and is provided with a plurality of transmission portions for transmitting acoustic signals radiated from the plurality of speakers, respectively, and a non-transmission portion for interrupting the transmission of the acoustic signals radiated from the plurality of speakers, the plurality of transmission portions being arranged in such a manner that an interval between the plurality of transmission portions is narrower than an interval between the plurality of speakers, in order to generate sound sources that are arranged at an interval narrower than the interval between the plurality of speakers.
By using a local sound emission structure 3 provided with the plurality of transmission portions having an interval D1 narrower than an interval D2 of the plurality of speakers, the speaker interval can be narrowed artificially. This enables control of the radiation characteristics up to high frequencies.
Embodiments of the present invention are now described hereinafter in detail. Note that components with the same function are denoted by the same reference numerals in the diagrams; overlapping explanations are omitted accordingly.
As illustrated in
The local sound emission structure 3 is arranged in a direction of directional control with respect to the first speaker 1 and the second speaker 2. For example, as illustrated in
The material of the local sound emission structure 3 may be any material as long as it can interrupt the transmission of acoustic signals. Examples of the material of the local sound emission structure 3 include plastic, metal, and wood.
The local sound emission structure 3 is provided with a first transmission portion 311 for transmitting an acoustic signal radiated from the first speaker 1, a second transmission portion 312 for transmitting an acoustic signal radiated from the second speaker 2, and a non-transmission portion 32 for interrupting the transmission of the acoustic signals emitted from the first speaker 1 and the second speaker 2.
In the example illustrated in
In order to generate sound sources that are arranged at an interval narrower than the interval between the first speaker 1 and the second speaker 2, the first transmission portion 311 and the second transmission portion 312 are arranged in such a manner that a distance D1 between the center position of the first transmission portion 311 and the center position of the second transmission portion 312 is smaller than a distance D2 between the center position of the first speaker 1 and the center position of the second speaker 2.
The acoustic signals radiated from the first speaker 1 and the second speaker 2 are radiated from the first transmission portion 311 and the second transmission portion 312, respectively. Therefore, the center positions as the sound sources are the centers of the holes which are the first transmission portion 311 and the second transmission portion 312.
Since the diameters of the first speaker 1 and the second speaker 2 can be made large enough to reproduce low frequencies, sounds in a low frequency region can be reproduced.
By using the local sound emission structure 3 provided with the plurality of transmission portions having the interval D1 narrower than the interval D2 between the plurality of speakers, the speaker interval can be narrowed artificially. In other words, the interval between the sound sources can be narrowed artificially so as to satisfy the spatial sampling theorem within the used frequency band. This enables control of the radiation characteristics up to high frequencies.
Normally, the diameter of a speaker is the minimum value of a speaker interval, and the center of a spherical wave is the center of the speaker. On the other hand, when the local sound emission structure 3 and the transmission portions are used, the center of the spherical wave becomes the center of the corresponding transmission portion, and the sound sources having an interval narrower than the speaker diameter can be artificially produced.
The shape of the first transmission portion 311 and the second transmission portion 312 may not be a circle but may be other shapes such as a semicircle and a rectangle, as illustrated in
The size of the transmission portions such as the first transmission portion 311 and the second transmission portion 312 may be smaller than the diameter of the speakers.
When utilizing acoustic signals that are output from the rear surfaces of the speakers and have a phase opposite to that of acoustic signals output from the front surfaces of the speakers, a sound insulation board may be mounted on the rear surfaces of the speakers so that the sound wave is balanced with the front surfaces.
An example of utilizing acoustic signals having a phase opposite to that of acoustic signals output from the front surfaces is now described below. Acoustic signals having a phase opposite to that of acoustic signals output from the front surfaces of the speakers are emitted from the rear surfaces of the speakers. Normally, a speaker box or the like is installed in order to prevent the emitted sound signals of the opposite phase from diffracting to the front surfaces and canceling the acoustic signals emitted from the front surfaces. However, in some cases, a configuration is employed in which the time lapse from the emission of the sound signals to the diffraction thereof is used to prevent the cancellation of only the acoustic signals very close to the speakers. When the acoustic signals of opposite phase are used in this manner, a sound insulation board or both a sound insulation board and transmission portions may be arranged on the rear surfaces of the speakers, as will be described hereinafter. By such arrangement, the acoustic signals emitted from the rear surfaces of the speakers are configured to diffract so that the acoustic signals that have passed through the transmission portions arranged in front of the speakers are not canceled at a short distance from the transmission portions but are canceled at a distant region.
In other words, the speaker array may further include a reverse local sound emission structure that is arranged in the direction opposite to the direction of directional control with respect to the first speaker 1 and the second speaker 2 (referred to as the rear surfaces, hereinafter). The reverse local sound emission structure is provided with a first rear surface transmission portion for transmitting the acoustic signal radiated from the rear surface of the first speaker 1, a second rear surface transmission portion for transmitting the acoustic signal radiated from the rear surface of the second speaker 2, and a rear surface non-transmission portion for interrupting the transmission of the acoustic signals radiated from the rear surfaces of the first speaker 1 and the second speaker 2. The acoustic signals radiated from the rear surfaces of the first speaker 1 and the second speaker 2 are radiated in the phase opposite to that of the acoustic signals radiated from the front surfaces of said speakers. The first rear surface transmission portion and the second rear surface transmission portion are provided so that, when the acoustic signals that have been radiated from the rear surfaces of the first speaker 1 and the second speaker 2 and passed through the first rear surface transmission portion or the second rear surface transmission portion diffract in the direction of directional control, the acoustic signals radiated in the direction of directional control are not canceled at a desired distance from the speakers.
In addition, for example, at least one of the rear surface tone holes of the speakers may be covered with a sound insulation board.
As illustrated in
The distance between the center position of the transmission portion of the rear surface of the speaker 1 and the center position of the transmission portion of the rear surface of the speaker 2 is preferably equal to the distance between the center position of the first transmission portion and the center position of the second transmission portion in front of the speakers.
When filtering a signal to be input to the speakers using a FIR filter or the like, the positional information of the sound sources used in designing the filter does not employ the center position of each of the plurality of speakers but employs the center position of each of the plurality of transmission portions.
Specifically, a FIR filter design unit 4 may design the FIR filter using the transmission characteristics between the center position of each of the plurality of transmission portions and a listening position and the transmission characteristics between the center position of each of the plurality of transmission portions and a suppression position.
In this case, as illustrated in
As described above, the plurality of speakers (e.g., the first speaker 1 and the second speaker 2) may radiate acoustic signals that are filtered by a filter designed based on the acoustic signals transmitted through the transmission portions (e.g., the first transmission portion 311 and the second transmission portion 312).
In addition, when the transmission characteristics used in designing the filter are obtained by actual measurement or simulation, the actual measurement or simulation is performed with the local sound emission structure 3 attached.
Although the embodiments of the present invention have been described above, specific configurations of the present invention are not limited thereto, and needless to say, design modifications and the like not departing from the gist of the present invention are also included in the present invention.
For example, in the examples described above, the speaker array is provided with two speakers, but three or more speakers may be provided in the speaker array. That is, the speaker array may be provided with a plurality of speakers.
In this case, the local sound emission structure 3 is arranged in the direction of directional control with respect to the plurality of speakers.
Furthermore, the local sound emission structure is provided with a plurality of transmission portions for transmitting acoustic signals radiated from the plurality of speakers, respectively, and a non-transmission portion for interrupting the transmission of the acoustic signals radiated from the plurality of speakers.
In order to generate sound sources that are arranged at an interval narrower than the interval between the plurality of speakers, the plurality of transmission portions are arranged in such a manner that the interval between the plurality of transmission portions is narrower than the interval between the plurality of speakers.
Note that three or more speakers do not have to be arranged linearly. For example, as illustrated in
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/015925 | 4/9/2020 | WO |