FR2646048A1 - Polyphonic room with homogeneous sound and installation of the same type - Google Patents

Abstract

Homogeneity and a polyphonic effect are obtained simultaneously by creating a plurality of sound-propagation directions which converge towards the same spot 3 at which listeners are located. Acoustic enclosures 10, 111-141 are distributed in each of the directions of propagation in such a way that, relative to each direction, all the areas in which the listeners are located receive the sound in the same way. In order to ensure that these listeners have a sensation of provenance, the emissions from the acoustic enclosures located near these listeners are delayed with respect to the emission produced by a so-called directing acoustic enclosure 40 located at the start-end of the emission. It is shown that by acting in this way a large number of listeners may be provided with homogeneous and polyphonic perception.

Description

POLYPHONIC ROOM WITH ITS HOMOGENEOUS
AND INSTALLATION OF THE SAME TYPE
The present invention relates to a polyphonic room has its homogeneous. This room is intended to receive a large audience. The invention applies to the field of public performances. It more particularly provides a large audience with listening known as high fidelity, in particular for listening to music alone. But it can allow this audience to listen to sounds at the same time as they watch a show, in particular a cinematographic film.

 There are two types of listening rooms. A first type concerns opera or theater halls in which the public faces a stage on which an orchestra is placed or on which actors play. In ancient theaters the audience is even distributed around the perimeter of the stage. The distribution of sound in such buildings is based on more or less judiciously realized acoustic phenomena. The main problem encountered in these rooms is the homogeneity of the listening. In fact, listeners placed near one side of the stage, for example on the piano side, hear more the sounds emitted by the instruments located on this side than the sounds emitted by the instruments located on the other side, for example the sounds of violins. And the opposite happens for those who are placed closer to the violins than to the piano, and the farthest listeners obviously hear less well than the closest listeners. So not everyone hears the same thing.

 In these rooms the stereophonic or multiphonic effect, which allows a listener to associate with a sound which he listens to a precise origin, is however relatively well assured. In other words the listener recognizes the source of the sounds emitted by the instruments even if he does not hear them too well because of his particular position. It is said in this case that the sound distribution is not homogeneous. In these buildings of the first type, the propagation of sounds is essentially linked to resonance phenomena, some of which are favored and others which are attenuated.

 In buildings of a second type, in particular cinemas, o even for outdoor performances, we seek to favor homogeneity. We want everyone to hear, to the detriment of the stereophonic or even multiphonic effect. In these buildings the distribution of sounds is ensured by loudspeakers supplied with an electrical signal. These speakers flood volumes with sound or listeners are placed. We only know how to approach a multiphonic effect by sharing, in such rooms, the sound emitted, in particular in four ways: front, back, right and left. But no significant homogeneity is obtained because a homogeneous listening area - can therefore only concern a small part of the center of the room1 and both in amplitude and frequency.

 Indeed, there remain in all cases the differences which are highlighted all the more as the room is larger. If, for example, it is large, we can seek to compensate for the resulting effect of inhomogeneity. For listeners placed on the left, sounds coming from the right can be better perceived if one approaches the intermediate speakers powered by the right phonic path. We then restore the homogeneity of distribution but we immediately lose the stereophonic effect for the listeners on the right who now hear the right channel from their right and their left.

 The problem to be solved is therefore to manage both the homogeneity of the sound distribution and the preservation of the polyphonic effect. The latter represents the effect of provenance which in principle opposes the effect of homogeneity. It is recalled schematically that stereophony allows homogeneity only for listeners placed on a perpendicular bisector of a segment which connects emitting speakers. With regard to quadraphony, the combined feeling of homogeneity and double stereophony is only accessible to a single listener who is at the point of competition of the mediators concerned. This low result also explains; basically, the relative failure of the sale to individuals of quad fidelity hi-fi channels.

 In the invention, a particular feature of human hearing is used to solve this technical problem. We direct to listeners a sound coming from a so-called directing speaker. This sound fades as it spreads, depending on the distance of the listeners. This attenuation is compensated for by a similar sound produced by acoustic speakers focused on some of the listeners. But the sound of these focused speakers only reaches these listeners after the arrival of the sound that propagates from the directing speaker. In this way each listener is flooded, because of this acoustic speaker focused with a really audible sound. This really audible sound arrives by propagation at the place of each listener very slightly behind the barely audible sound emitted by the directing speaker. If the delay is around 18 ms this listener hears "good" the sound which comes from the directing enclosure whereas in practice it comes from an acoustic enclosure placed nearby. In the invention, the polyphonic channels are then divided into as many propagation axes. These propagation axes comprising one or more guide chambers and one or more focused chambers. We organize the axes according to the feeling that we want to give to everyone.

The invention therefore relates to a polyphonic room with its homogeneous, intended to receive a large audience, comprising
- a plurality of monophonic axes for distributing sounds,
- these distribution axes each substantially covering the center of the room, where the public is placed,
- for each axis, a direction of sound propagation oriented from one edge of the room to the center of this room,
- and for each axis, an aerial structure aligned along this axis which overhangs the room and which carries a plurality of acoustic speakers,
- And a system to delay the transmission of sound emitted by the speakers located on a downstream axis, in the direction of the propagation of the sound towards the. center of the room, of a directing enclosure placed, on this same axis, near the edge of this room,
The invention will be better understood on reading the description which follows and on examining the figures which accompany it. These are given for information only and in no way limit the invention.

The figures show
- Figure 1: the sectional representation of a room according to the invention
- Figure 2: in plan, details of embodiment of a preferred embodiment of the invention
Figure I shows a room 1 with its homogeneous polyphonic sound intended to receive a large audience. In one example, this audience which takes place on seats 2 can be distributed in the center of the room and be of the order of 250 people.

 Figure 2 shows schematically a top view of location 3 in the middle of room 1 ot are distributed seats 2. The area of location 3 is about a quarter of the area of room 1. It is nevertheless possible to implement the invention in such a way that the useful surface represents a larger proportion of the total surface of room 1.

 The room has a plurality of monophonic axes to distribute the sounds. These axes are, Figure 2, for example axes 4 to 9. In the example the room is slightly rectangular, two axes1 6 and 9, are oriented as the perpendicular bisectors of two small ribs of this rectangle, while the other four1 facing each other in pairs, 4-7 and 5-8, are distributed so as to form with those directly adjacent to them angles of the order of 600. The spirit of the invention will easily be transposed to a number N of monophonic axes making with those which are adjacent to them angles preferably of 3600 / N. The axes -4 to 9 compete substantially towards the center of the room, that is to say towards the center of region 3 where the listeners are placed.

 The definition of an axis is twofold, it concerns firstly a direction of sound propagation and secondly the orientation of an aerial structure which carries the acoustic devices necessary to spread the sound with the quality allowed by the invention. These directions of propagation are generally oriented from the edge of the room towards the center. FIG. 2 shows, for axis 4, a plurality of loudspeakers denoted 10, 111 and 112, 121, 122 and 123, 131 and 132 and finally 141. These nine loudspeakers are intended to focus their sound each on a ninth of the area of region 3. We manage with this relatively tight mesh so that the sound amplitude, relative to an axis, in each of these parts of region 3 is equal. We focus the sound on elementary surfaces in region 3. We assign to each speaker one of these elementary surfaces. This results in hoinoaenity. It will be noted that the speakers are generally aligned along axis 4 and that according to their position downstream, in the direction of sound propagation, they are grouped in pairs, or even in threes, given the importance of the surface concerned. For example, enclosure 141 produces sound for the lower left corner of region 3 in FIG. 2. The two speakers 131 and 132 of a set of speakers 13 produce sound for the regions located in a half -diagonal of the square of region 3. The three speakers 121 to 123 of a set of speakers 12 produce the sound necessary for listeners placed in diagonal 4, and so on.

 There is shown in Figure 1 in vertical section a plurality of loudspeakers or sets of loudspeakers iO to 14 which correspond, for this axis 4 to a monophonic channel. These speakers or sets of speakers 10 to 14 are thus placed in the ceiling 15 of the room 1 so that they overhang the room. To maintain the enclosures 10 to 14, it is possible, depending on the room available, either to physically produce the axis 4 or to hang the enclosures from the ceiling 15 in the desired alignment. There is also a so-called directing acoustic enclosure 40 whose angle of distribution of the sound takes in succession all the listeners of the region 3. This enclosure may have a lower focusing power than the speakers or sets of speakers 10 to 14 FIG. 1 shows a focusing enclosure 10 and the so-called directing enclosure 40. Taking into account the grazing incidence of the propagation of the useful sound emitted by the enclosure 10 it is even possible in a preferred variant not to use the directing enclosure 40 but making the focusing enclosure 10 directing itself. For this purpose, the focusing power of this enclosure 10 is reduced so that it sends its sound over the entire surface of the location 3. In this case, there are only 5 sets of speakers in the room. 'axis 4.

 For each monophonic channel there is also a system which produces emission delays so that, wherever a listener is, he receives a weakened sound from a directing speaker (40 or 10 for axis 4) before the sound adjusted to the desired amplitude and which is emitted by the speaker or the set of speakers (10 to 14) which focuses on it for this monophonic channel. The delays are thus calculated in such a way that at the level of this listener, the two sounds are delayed with respect to each other by approximately 18 ms.

 In practice, for each channel, there is downstream of an amplifier 41 a delay generator 42 which transmits an amplified electrical signal to the speakers or sets of electro-acoustic speakers 10 to 14 with the corresponding delays. These delays also take into account the difference in propagation speed between sound and electricity. This difference thus corresponds to the distance difference between the directing speaker 40 and a speaker or a set of acoustic speakers 10 to 14. For example, the speaker 14 must emit a sound, with a delay relative to the instant when the directing speaker 40 emits its own. This delay which is equal to 18 ms plus the propagation time of the sound (360 meters per second) over the distance which separates the directing speaker 40 from the verticality of the speaker 14. In each channel there is the same system delay: there is thus an amplifier 51 to 91 in cascade, each time, with a delay circuit 52 to 92.

 To restore the effect of polyphony, it is now sufficient to supply each of the different channels materialized by axes 4 to 9 with a different sound channel. We are then able to provide the same overall feeling for all listeners. For example, we may want to make each listener hear the sounds he would hear if he were himself a particular musician of the musicians of the orchestra. In this case, for the recording of sound, microphones are placed at this location with as many directions for picking up the sound as we later want to create polyphonic voices (and also channels). Then each of channels 4 to 9 is supplied with a signal corresponding to the recorded voices. In another example, we try to recreate the feeling of volume. We can cause such results by taking an adequate sound or also by pre-processing musical signals in their electrical form.

 Taking into account that the sound distribution is entirely positive in the room of the invention, that is to say without resonance effect, the ceiling, the walls and the floor of the room are preferably decorated with absorbent devices. such as foams.

In one example, the foams are distributed in tetrahedral volumes such as 17, preferably placed on the ceiling. Indeed, the sounds being generally emitted from the ceiling towards the floor their reflection on this one is not too audible because at the level of the listeners it is almost simultaneous with the direct sound which they receive and especially that the carpet and the armchairs in the room allow it to be cushioned. On the other hand, the reflection coming from the ceiling, taking into account the height of the ceiling, would be sufficiently offset in time to be perceptible. Of course, if the room is open to the sky we can do without damping devices.

 The distribution of the axes, angularly with respect to the center of the room, of the speakers or sets of speakers along these axes, and the number of speakers in a set of speakers (for example 3 in set 12) is essentially determined by the rigor with which we want to respect homogeneity on the one hand and the polyphonic effect on the other. We can for example reduce the number of speakers or the number of direction at the expense of the finesse of the result of course. It seems however that a good compromise is constituted by the example of the invention: 6 directions, in each direction, a directing speaker and 4 speakers or sets of focusing speakers, with for the speakers intended to transmit their sound towards the bigger part of the room more speakers. In an exemplary embodiment, the room of the invention is embellished with speakers placed at the zenith of the room or distributed in the slab supporting the public. These speakers allow you to recreate in addition to the effects known elsewhere.

 The invention is intended for a large audience. But it can also be used to make the polyphonic effect provided by current quadraphonic systems accessible to a larger number of listeners. It suffices to decorate these current systems firstly with several loudspeakers per acoustic voice and secondly, for each voice, with a system causing emission delays. The installation can then be carried out in an apartment.

Claims (7)

 1- Polyphonic and homogeneous room (1), intended to receive a number (3) audience, comprising  -a plurality of monophonic axes (4-9) for distributing sounds,  these distribution axes each substantially covering the center (3) of the room where the public is placed,  -for each axis, a direction of sound propagation oriented from one edge of the room to the center of this room,  and for each axis an aerial structure (15) aligned along this axis, which overhangs the room and which carries a plurality (10-14) of acoustic speakers,  -and a system (41-42) for delaying the transmission of sounds emitted by speakers situated on a downstream axis, in the direction of sound propagation towards the center of the room, of a directing speaker (40) placed , on this same axis, near the edge of this room.  2- Room according to claim 1 characterized in that the speakers are provided to focus the sounds they emit towards a region of the room which receives little or no sounds emitted by other speakers located on the same axis as it, outside the guiding enclosure.  3- Room according to any one of claims 1 to 2, characterized in that it comprises a central region for receiving the public and whose area is of the order of a quarter of the total area of the room.  4- Room according to any one of claims 1 fi 2, characterized in that it comprises on each axis 5 sets (40, 10-14) of speakers including the set of guide speakers.  5- Room according to any one of claims 1 to, 4, characterized in that it comprises 6 monophonic axes oriented substantially like the diagonals of the room.  6- Room according to any one of claims 1 to 5, characterized in that it comprises means (17) for reducing the resonance of the room.  -and a system (41-42) for delaying the transmission of sounds emitted by loudspeakers located on a downstream axis, in the direction of sound propagation towards the center of the room, - of a directing loudspeaker (40) placed, on this same axis, near the edge of this room.  and for each axis an aerial structure (15) aligned along this axis, which overhangs the room and which carries a plurality (10-14) of acoustic speakers,  -for each axis, a direction of sound propagation oriented from one edge of the room to the center of this room,  - these distribution axes being intended to cover each the center of a room where the public is placed  -a plurality of monophonic axes (4-9) for distributing sounds,  7.- Installation at its homogeneous polyphonic comprising