Classifications

• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
  • G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
  • G10K11/18—Methods or devices for transmitting, conducting or directing sound
  • G10K11/26—Sound-focusing or directing, e.g. scanning
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R1/00—Details of transducers, loudspeakers or microphones
  • H04R1/20—Arrangements for obtaining desired frequency or directional characteristics
  • H04R1/32—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired directional characteristic only
  • H04R1/40—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired directional characteristic only by combining a number of identical transducers
  • H04R1/403—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired directional characteristic only by combining a number of identical transducers loud-speakers
• • G—PHYSICS
  • G10—MUSICAL INSTRUMENTS; ACOUSTICS
  • G10K—SOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
  • G10K11/00—Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
  • G10K11/18—Methods or devices for transmitting, conducting or directing sound
  • G10K11/26—Sound-focusing or directing, e.g. scanning
  • G10K11/34—Sound-focusing or directing, e.g. scanning using electrical steering of transducer arrays, e.g. beam steering
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R1/00—Details of transducers, loudspeakers or microphones
  • H04R1/02—Casings; Cabinets ; Supports therefor; Mountings therein
  • H04R1/025—Arrangements for fixing loudspeaker transducers, e.g. in a box, furniture
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R1/00—Details of transducers, loudspeakers or microphones
  • H04R1/20—Arrangements for obtaining desired frequency or directional characteristics
  • H04R1/22—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired frequency characteristic only 
  • H04R1/24—Structural combinations of separate transducers or of two parts of the same transducer and responsive respectively to two or more frequency ranges
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R3/00—Circuits for transducers, loudspeakers or microphones
  • H04R3/12—Circuits for transducers, loudspeakers or microphones for distributing signals to two or more loudspeakers

Definitions

• the present invention relates generally to the field of sound, professional or domestic.
• it aims at a sound distribution system of the "column" type capable of producing a high level of sound pressure, in English: Sound Pressure Level or SPL, with a high range in order to be able to cover an extended audience, while maintaining coherence / high intelligibility.
• a stack of acoustic sources provides a level of sound pressure SPL increased relative to the SPL level produced by a single acoustic source.
• the vertical directivity of a vertical stack of acoustic sources has a narrowed and clearly elongated lobe. Also the vertical directivity is increased relative to the vertical directivity of a single acoustic source, thus increasing the range and the volume of hearing covered.
• acoustic sources are not added as simply and unavoidable distances between sources acoustics produce interference that impairs coherence / intelligibility.
• the vertical directivity of a sound diffusion device has a slightly negative angle of inclination relative to the horizontal. This allows, for a sound diffusion device, conventionally installed in a slight height, on the one hand to cover a larger audience and on the other hand to avoid spreading to the ceiling, which constitutes a loss of energy in the room. absence of audience at this location and may be the cause of unwanted reflections that can degrade intelligibility.
• a negative inclination of the vertical directivity is generally obtained by tilting the acoustic source or sources or the sound diffusion device.
• Another constraint for a sound diffusion device is its visual integration. To facilitate this visual integration, it is advantageous that a device has a visual footprint the lowest possible. This constraint, added to the previous one, makes a "column" arrangement of the acoustic sources advantageous.
• the object of the invention is to provide a sound diffusion device achieving a compromise between seemingly contradictory characteristics, increasing the sound pressure level, SPL, and scope, while maintaining a level of consistency / high intelligibility.
• a sound diffusion device comprising a high frequency section comprising at least one high frequency acoustic source, and a medium frequency section comprising at least two medium frequency acoustic sources, the acoustic sources being superposed vertically, where the medium frequency section comprises a lower subsection disposed below the high frequency section and comprising at least one medium frequency acoustic source and an upper subsection disposed above the high frequency section and comprising at least one acoustic source medium frequency, and where the vertical directivity of the high frequency section has a slope, relatively to the horizontal, substantially equal to the inclination of the vertical directivity of the middle frequency section relative to the horizontal, so that the vertical directivity overall device presents an inc non-zero lineage relative to the horizontal.
• the inclinations are negative with respect to the horizontal.
• the high frequency section has an asymmetrical vertical wavefront.
• the wavefront has a variable curvature, preferentially increasing downwards, still preferably continuously variable to form a "J".
• the wavefront is shaped by means of a vertical waveguide integrating at least one high frequency acoustic source, preferably all high frequency acoustic sources.
• the acoustic center of the lower subsection is retracted relative to the acoustic center of the subsection.
• a recoil such as an axis, connecting the acoustic center of the lower subsection to the acoustic center of the upper subsection, has an angle of misalignment relative to the vertical substantially equal to the inclination.
• the medium frequency acoustic sources of the lower subsection are aligned with each other along a first vertical axis and / or the medium frequency acoustic sources of the upper sub-section are aligned with each other along a second axis. vertical.
• the high frequency section comprises a first number of high frequency acoustic sources, preferably identical, the first number being preferably equal to 3.
• At least one high frequency acoustic source is a compression motor.
• the lower subsection comprises a second number of medium frequency acoustic sources and the upper subsection comprises a third number of medium frequency acoustic sources, the medium frequency acoustic sources being preferably identical and the difference between the second number and the third number is less than or equal, in absolute value, to 2 and the second number is preferentially greater than the third number, preferably the second number is equal to 4 and / or the third number is equal to 2, or still said difference is zero.
• the vertical wavefront is shaped, at least partially, electronically by processing the sound signals respectively sent to each of the high frequency acoustic sources.
• At least one part (Rb) of the recoil is electronically simulated by delaying the sound signals respectively sent to each of the medium frequency acoustic sources of the lower subsection and / or the upper subsection, a delay equal to the time taken by the sound to cover the recoil portion.
• the device is integrated in a single enclosure, type "column”.
• the invention also relates to a sound diffusion system comprising a first sound diffusion device according to one of the preceding embodiments, a second sound diffusion device comprising a low frequency section and / or a very low frequency section.
• the system further comprises a means of mechanical interface between the first device and the second device adapted to allow one of the devices, preferably the second device, to support the other device, with or without assembly , and / or an electrical interface means between the first device and the second device adapted to allow one of the devices, preferably the second device, to transmit sound signals and / or a power supply to the other device.
• FIG. 1a shows the directivity of an acoustic source, here of type source point
• FIG. 2 presents in profile view a device according to the prior art
• FIG. 3 is a profile view of a device according to the invention
• FIG. 4 shows the vertical directivity of a medium-frequency acoustic source, here of the source point source,
• FIG. 5 presents the vertical directivity of a superposition of medium frequency acoustic sources similar to the source of FIG. 4,
• FIG. 6 shows the vertical directivity of a superposition of high frequency acoustic sources
• FIG. 7a shows the vertical directivity of the same superposition of high frequency acoustic sources, provided with a plane waveguide
• FIG. 8 shows the vertical directivity of the same superimposition high frequency acoustic sources provided with an asymmetrical waveguide with constant curvature
• FIG. 9 shows the vertical directivity of the same superposition of high frequency acoustic sources, provided with an asymmetrical waveguide with variable curvature
• FIGS. 10a-b illustrate the function of a waveguide
• FIGS. 11a-b show different types of waveguides
• FIG. 12 illustrates, in profile view, a preferred embodiment of a variable-curvature asymmetric type waveguide, increasing downward and continuously variable, in the form of a "J",
• FIG. 13 shows, in profile view, an embodiment of the device according to the invention
• FIG. 14 shows, in profile view, another embodiment of the device according to the invention
• FIG. 15 shows, in perspective view, an embodiment of the device according to the invention
• FIG. 16 illustrates, in perspective view, a system according to the invention
• FIG. 17 illustrates, in a perspective view, the system of FIG. 16 assembled
• Figures 18a-b illustrate in view, respectively front and side, an embodiment of the device.
• An acoustic source S or a sound diffusion system 1, comprising several acoustic sources S, can be characterized by a directivity diagram showing a sound pressure level (in English: Sound Pressure Level, or SPL) according to the position in space.
• SPL Sound Pressure Level
• This diagram typically shows nested volume lobes, the SPL is substantially constant in a lobe and decreasing as one moves away from the source S or device 1.
• FIG. 1a illustrates the vertical directivity of a single acoustic source S, for example of the type source point pavilion.
• An acoustic source of source point type radiates isotropically and has a spherical directivity.
• a horn of substantially conical shape, makes it possible to restrict this directivity to an angular sector advantageously more restricted.
• An example of an acoustic source S source flagged is the product X12 of the applicant.
• the directivity of such an acoustic source S has an acoustic axis A, connecting the source S to the maximum of SPL, substantially aligned with the horizontal H.
• the source is arranged on the left of the figure and diffuses to the right.
• the audience is across the entire width of the chart, mostly concentrated at the bottom horizontal level of the chart.
• the surface of the diagram measures 5 m in height and 40 m in width / depth.
• Each change of gray color corresponds to a decrease of 3 dB as one moves away from the acoustic source S.
• an acoustic source S or a sound diffusion system 1 is generally arranged facing an audience, the acoustic axis A being substantially horizontal so that the lobe covers the audience. It can be seen by comparing FIG. 1b with FIG. 1a that a slightly negative GDIT inclination of the acoustic axis A relative to the horizontal H is advantageous in terms of the volume of hearing covered and in terms of uniformity of the SPL. This is all the more true as the range is increased. In addition, such a negative inclination ⁇ ⁇ avoids unnecessary and / or harmful diffusion towards the ceiling.
• a sound diffusion device 1 It is conventional in a sound diffusion device 1 to cut the sound spectrum into frequency bands, and to dedicate a section, comprising one or more acoustic sources, to each frequency band. This allows each section to be made with one or more acoustic sources adapted to this frequency band.
• a high frequency band, HF covers the highest frequencies, typically a 1kHz-20kHz range.
• a medium frequency band, MF covers intermediate frequencies, typically 200Hz-1kHz.
• a low frequency band, BF covers low frequencies, typically a 50Hz-200Hz range.
• TBF optional covers the lowest frequencies, typically frequencies below 50Hz.
• the device 1 proposes to cover the two upper bands: the high frequency band and the medium frequency band.
• this sound diffusion device 1 comprises a high frequency section 2 and a medium frequency section 3, 4.
• the high frequency section 2 comprises one or more high frequency acoustic sources SHF.
• the medium frequency section 3, 4 comprises several medium frequency acoustic sources SMF.
• all acoustic sources, high frequency and low frequency SHF, SMF are superimposed vertically, without necessarily being aligned.
• the existing devices group on the one hand all the high frequency acoustic sources within a single high frequency set HF and secondly all the medium frequency acoustic sources within a single medium frequency MF set, and then joins the two sets HF, MF.
• This is detrimental in that, because of the considerable size of the acoustic sources, the CHF high frequency acoustic center is located far from the center medium frequency CMF acoustics. Such an offset is the cause of a deterioration of the coherence / intelligibility of the sound.
• this problem is remedied by producing a device 1 which shares the medium frequency section in two subsections 3, 4 and arranging these two subsections 3, 4. on either side of the high frequency section 2.
• any one of the two subsections is disposed below the high frequency section 2 and is called lower subsection 3, while the other under - section is arranged above the high frequency section 2 and is named upper subsection 4.
• the medium frequency acoustic center CMF resulting from the two subsections 3, 4 is situated between the two subsections 3, 4 and can thus be to be close, or even advantageously confused, with the CHF high frequency acoustic center.
• This proximity of high frequency CHF and medium frequency CMF acoustic centers improves the coherence / intelligibility of the sound.
• the respective directivities in medium frequency and high frequency are substantially overlapping.
• the GHF inclination of the high frequency SPL of the vertical directivity of the high frequency section 2, relative to the horizontal H, and the GMF inclination of the SPL maximum frequency of the vertical directivity of the medium frequency section 3, 4, relative to the horizontal H are substantially equal.
• the term "substantially equal” means that the absolute value of the difference between the inclination GHF and the inclination GMF is between 0 ° and 5 °, preferably between 0 ° and 2 °.
• a device 1 comprising a high frequency section 2, framed by two sub-sections 3, 4 medium frequency, the two subsections 3, 4 and the high frequency section 2 being substantially aligned, along a vertical axis, has a high frequency vertical directivity coming from the center CHF high frequency and having a high frequency inclination GHF substantially zero relative to the horizontal H, and a medium frequency directivity from the medium frequency center CMF and having a medium frequency inclination GMF substantially zero relative to the horizontal H.
• the two inclinations GHF, GMF are thus substantially equal. It follows that the respective vertical directivities in high frequency and in medium frequency are substantially superimposed.
• the vertical directivity has a negative slope GDIT, to better cover an audience, conventionally located below.
• this inclination GDIT which must remain the same for the medium frequency inclination GMF and for the high frequency inclination GHF, can be obtained by tilting the device 1, relative to the vertical V, by a GMéca angle.
• the vertical directivities of the medium frequency or high frequency sources have an inclination, in absolute value, between 1 ° and 30 °.
• acoustic sources S are, in principle producing interference, due to the unavoidable removal of the acoustic sources S.
• a rule of the art indicates that the distance between two acoustic sources S can be neglected in view interference if this distance remains smaller than a magnitude increasing function of the wavelength.
• this rule is all the more difficult to respect as the wavelength decreases.
• this rule can be respected for the medium frequency section 3, 4, including when a high frequency section 2 is interposed, increasing the distance between the average acoustic sources SMF frequency.
• the height of the high frequency section is of the order of a few tens of centimeters in a preferred embodiment.
• Figure 4 shows the vertical directivity of a single medium frequency source SMF.
• Figure 5 shows the resulting vertical directivity for a stack of SMF medium frequency acoustic sources.
• the stacking of several medium frequency acoustic sources SMF advantageously makes it possible to increase the resulting range. However, there is no disturbance, indicating a virtual absence of interference.
• Figure 6 shows the resulting vertical directivity for a stack of high frequency acoustic sources SHF, here three sources.
• the stacking of several high frequency acoustic sources SHF advantageously makes it possible to increase the resulting range relative to a single acoustic source.
• the disturbance of the diagram is indicative of the interference problem.
• a waveguide 5 is a device incorporating one or more acoustic sources S and designed to perform two functions.
• a first function is to suppress interference by phasing said acoustic sources integrated, which then function as a single, more powerful source.
• a second function is to conform the outgoing sound wavefront according to a given profile.
• FIGS. 10a-b The action of a waveguide 5 is illustrated in FIGS. 10a-b.
• three acoustic sources S are juxtaposed.
• the sources S supposedly point, each produce a spherical wavefront F.
• Each front F is centered on its source S. Also the fronts F are inconsistent with each other and potentially interfere with each other.
• FIG. 10b the same three sources S are joined by means of a waveguide 5.
• the produced wavefront F is unique.
• a waveguide 5 is advantageously used to eliminate the harmful consequences of interference at the level of the high frequency section 2.
• Abuse of language is characterized by a waveguide 5 by the shape of the wavefront it produces.
• the waveguide 5 of FIG. 10b which conforms the wavefront F produced in a plane is called a plane waveguide.
• FIG. 7a illustrates the vertical directivity resulting from the vertical superposition of several high frequency sources SHF integrated within a plane waveguide.
• the advantageous presence of such a waveguide 5 is still exploited by using said waveguide 5 to shape the wavefront from the high frequency section 2, and thus the high frequency directivity, so that it maximizes audience coverage.
• the wavefront is asymmetrical. This asymmetry, exhibiting a downward accentuation, presents another embodiment for producing a negative frequency high frequency inclination GHF.
• FIG. 11a illustrates an example of a symmetrical waveguide relative to the horizontal H.
• FIG. 11b comparatively illustrates an example of an asymmetrical waveguide: the upper angle ⁇ 2 is different from the lower angle ⁇ , in absolute value, and here it is smaller than the lower angle ⁇ . This results in an equivalent dissymmetry of the wavefront.
• the dissymmetry of the wavefront can be used to achieve a high frequency inclination GHF of the vertical directivity, advantageously negative, and thus replace an inclination of the high frequency section 2 or the device 1. This advantageously allows to be able to conserve a vertical arrangement for the high frequency section 2 or the device 1, thus improving the visual impression and facilitating the architectural integration.
• the device 1 especially if the device 1 must be arranged higher and it is desired to increase the inclination GDIT of the overall directivity of the device 1, it is possible to combine an inclination obtained by the dissymmetry of the wavefront with an inclination of the device 1, these two inclinations are added together.
• the shape of the wavefront may be arbitrary and is advantageously described by a curvature.
• Said curvature can be any.
• a constant curvature produces a circular outer surface.
• Figures lla-b further illustrate the curvature of the waveguide 5.
• the radius of curvature RI, R2 is constant and equal in every respect.
• the radius of curvature varies and RI can be different from R2.
• variable curvature is advantageous in that it makes it possible to conform the directivity so as to enable it to cover an extended audience.
• the variation of the curvature is such that it increases downwards or what is equivalent as the radius of curvature decreases downwards.
• the curvature is continuously varied.
• the wavefront then has a shape of "J" with a radius of curvature decreasing as one goes down.
• Figure 8 shows the vertical directivity obtained for a high frequency section 2 having an asymmetrical wavefront constant curvature.
• the improvement made is measured, mainly in terms of homogeneity of the SPL in the area covered.
• FIG. 9 shows the directivity obtained for an asymmetrical wavefront with variable curvature, the curvature increasing downwards. There is a clear increase in the scope and homogeneity of the SPL.
• Figure 12 illustrates a possible embodiment of such a waveguide 5 asymmetrical variable curvature, curvature increasing downwardly, continuously varied, to present a shape of "J".
• the conformation of the wavefront mainly by means of its asymmetry, makes it possible to achieve a high frequency inclination GHF negative.
• GHF high frequency inclination
• GMF medium frequency inclination GMF substantially identical.
• substantially identical means that the absolute value of the difference between the inclination GHF and the inclination GMF is between 0 ° and 5 °, preferably between 0 ° and 2 °.
• the acoustic center C ⁇ n f of the lower subsection 3 is moved back relative to the acoustic center C sup of the upper subsection 4, This recoil R produces a GMF inclination of the medium frequency directivity.
• the recoil R should be such that an axis, connecting the two subsections 3, 4, or more precisely the acoustic center Cmf of the lower subsection 3 to the acoustic center C sup of the upper subsection 4, forms with the vertical V an angle of misalignment GD substantially equal to the angle of inclination of the GHF high frequency directivity.
• the arrangement of the medium frequency acoustic source or sources SMF within a subsection 3, 4 is a priori any.
• an alignment of the SMF medium frequency acoustic sources within a sub-section 3, 4 has a better efficiency in terms of power addition in order to obtain a high resulting SPL.
• an ideal configuration for the sound produced, is that where the SMF medium frequency acoustic sources within a sub-section 3, 4 are aligned on the axis. described above, connecting the acoustic centers ⁇ C n f C sup and sub-sections 3, 4.
• such a configuration increases the size, especially the long and degrades the visual impression.
• SMF medium frequency acoustic sources of the lower subsection 3 are aligned with each other along a first vertical axis.
• the medium frequency acoustic sources SMF of the upper subsection 4 are aligned with each other along a second vertical axis, which may be identical to the first.
• the positioning of the subsections 3, 4 relative to the high frequency section 2, along a horizontal axis, in depth, is slightly constrained. It is preferable not to move them too far away, so as not to distance the CHF and CMF acoustic centers too much, also the sub-sections 3, 4 are preferably substantially aligned with the high frequency section 2. According to one possible embodiment, illustrated in Figure 13, the upper subsection 4 is aligned with the top of the high frequency section 2, to limit the size of the device 1, in depth. This is further illustrated by the embodiment of FIG. 14.
• the high frequency section 2 comprises a first number n of high frequency acoustic sources SHF.
• This number is mainly related to the desired level of SPL in high frequency, which level increases with the number of high frequency acoustic sources SHF.
• a single high frequency acoustic source SHF is possible. It can be noted that a waveguide works with a single acoustic source. The increase in the number of high frequency acoustic sources SHF could be detrimental in that it distances both subsections 3, 4. However, this damage remains low due to the small size typical of high frequency acoustic sources SHF.
• Figures 3, 13-14 or 18a-b show, in an illustrative manner, a high frequency section 2 comprising two, three or four high frequency acoustic sources SHF and then having a indicative height of 20 to 40 cm.
• these high frequency acoustic sources SHF are identical.
• the first number n of high frequency acoustic sources SHF of the high frequency section 2 is equal to 3.
• this first integer n is in the range [2; 5].
• the lower subsection 3 comprises a second number m of medium frequency acoustic sources SMF and the upper subsection 4 comprises a third number p of medium frequency acoustic sources SMF.
• the total number m + p is mainly related to the desired level of SPL in medium frequency, increasing level with the total number of medium frequency acoustic sources SMF. This SPL level is preferably consistent with the high frequency SPL level.
• a single medium frequency acoustic source SMF in one or the other or both sub-sections 3, 4 is possible.
• the increase in the number of SMF medium frequency acoustic sources is detrimental only in that it increases the height and therefore the size of the device 1.
• the medium frequency section comprises 6 medium frequency acoustic sources.
• the second number m of medium frequency acoustic sources SMF of the upper subsection 4 is equal to 2 and the third number p of the medium frequency acoustic sources SMF of the lower subsection 3 is equal to 4.
• the second number integer m is in the range [1; 5]
• the third integer p is in the range [2; 6].
• an average acoustic source SMF frequency has a height of the order of 13 cm and a high frequency acoustic source SHF has a height of about 8 cm. This results in a height of the device 1 advantageously less than 1.30m, thus allowing easy handling.
• the distribution of medium frequency acoustic sources SMF between the two subsections 3, 4 can be arbitrary. Ideally, in order for the CMF medium frequency acoustic center to be as close as possible to the high frequency acoustic center CHF, an equilibrium or a second number m equal to the third number p is preferred.
• FIG. 13 shows, in an illustrative manner, a lower subsection 3 and an upper subsection 4 balanced each comprising three acoustic sources medium frequency SMF. However, a slight imbalance is acceptable. A difference less than or equal, in absolute value, to 2, between the second number m of medium frequency acoustic sources SMF in the upper subsection 4 and the third number p of the medium frequency acoustic sources SMF in the lower subsection 3 is acceptable.
• the most "voluminous" subsection may be either the lower subsection 3 or the upper subsection 4.
• the lower subsection 3 is favored, with for example one or as illustrated two additional acoustic sources.
• This causes a slight remoteness of the medium frequency acoustic center CMF, relatively to the high frequency acoustic center CHF, whose consequences can however be neglected.
• this advantageously makes it possible to raise the average axis of diffusion, passing substantially through the middle of the acoustic centers CMF, CHF, of the device 1, so as to adapt it to the listening height of the audience. This is particularly advantageous for a device 1 laid.
• the medium frequency acoustic sources SMF are identical.
• the identity can be within a subsection 3, 4, or global.
• the conformation of the wavefront can be achieved mechanically by means of a waveguide 5.
• the waveguide 5 is then a frame shaped specifically to form the front of the waveguide. wave and welcoming acoustic sources by imposing a position and a relative orientation.
• the conformation of the wavefront is performed electronically by processing the sound signals respectively sent to each high frequency acoustic sources SHF.
• This electronic conformation can be partial or total.
• the electronic conformation completely replaces the mechanical waveguide and electronically realizes the relative positioning and orientation of the acoustic sources SHF.
• the curvature imposed by the waveguide 5 to the acoustic sources SHF is no longer necessary. This then makes it possible to have several, preferably all the high frequency acoustic sources SHF of the high frequency section 2 in a chosen arrangement, for example aligned between it, and still preferably aligned along a vertical axis. This characteristic makes it possible to optimize the reduction of the visual impression.
• a mechanical waveguide 5 is used.
• the electronic processing then makes it possible to complete the shaping of the wavefront produced mechanically by the waveguide 5, in order to accentuate or reduce its curvature.
• this setback R can partially or completely be realized electronically. This requires a processing of the sound signals respectively sent to each of the medium frequency acoustic sources SMF lower subsection 3 and / or upper subsection 4.
• a recoil R is performed by delaying the sound signals sent to the medium frequency acoustic sources SMF that we want to move back, that is those of the lower subsection 3.
• the applied delay T then corresponds to the time required for the sound to go through. the distance R.
• the application of such a relative delay T, between the lower subsection 3 and the upper subsection 4, then makes it possible to align geometrically the two subsections 3, 4, or more precisely, their Cinf acoustic center, respective Csup along a vertical axis. This characteristic is advantageous in terms of the visual impression of the device 1 and architectural integration.
• a first part Ra of the recoil R is made geometrically by actually retracting the SMF acoustic sources by a distance Ra, whereas a second part Rb of the recoil R is made electronically by delaying the signals. sound of a delay corresponding to the time necessary for sound to travel the distance R.
• Each medium frequency acoustic source SMF can be electronically controlled in an individualized manner.
• the electronic processing means are expensive.
• a single electronic processing comprising a fixed delay is applied to the sound signals of the medium frequency acoustic sources SMF of the lower subsection 3. If the delay corresponds to the recoil R, this makes it possible to vertically align the acoustic sources of the lower subsection 3 with the upper subsection 4.
• the device 1 as previously described can be realized in different ways. Thus it can be the object of a modular assembly from kit elements. According to one preferential embodiment, it is advantageously integrated within a single enclosure.
• the device 1, as described so far, provides the broadcast for high frequencies and medium frequencies.
• the device 1 is advantageously completed by a second sound diffusion device 7 comprising a low frequency section and / or a very low frequency section 9, in order to constitute a system capable of covering the entire audible sound spectrum.
• Such an embodiment separating the low and / or very low frequency is advantageous in that the volume, and therefore the lateral and depth space of an acoustic source increases as the frequency drops. Also a low frequency or very low frequency acoustic source, if it dimensions the width / depth of a system over its entire height, leads to a very wide system having a strong visual impression.
• the second device 7 is typically placed on the ground or on a stage.
• the first device 1 may advantageously be independently suspended, as illustrated in FIG.
• the devices 1.7 comprise an interface means 8, arranged on one or on the other or distributed on both, such as interfaces male / female, among the first device 1 and the second device 7.9.
• This interface means 8 advantageously comprises a mechanical interface means capable of allowing one of the devices 1.7 to support the other device.
• the second device 7 is preferably the one that supports the first device 1 and therefore integrates the mechanical interface. This assembly can be done with or without assembly at the interface. The result of the combination of a first device 1 and a second device 7 is illustrated in FIG. 17.
• this mechanical interface means is capable of allowing the devices 1.7 to fit together. one in the other.
• the interface means 8 also advantageously comprises an electrical interface means adapted to allow one of the devices 1.7, to transmit sound signals and / or power supply to the other device, to connect the system. only once at the control room.
• FIGS 18a-b An embodiment of the device 1 is given in Figures 18a-b which respectively represent a front view and a side view of the device 1.
• the upper subsection 4 here comprises two medium frequency acoustic sources SMF and the lower subsection 3 includes four medium frequency acoustic sources SMF.
• the high frequency section 2 it comprises three high frequency acoustic sources SHF and a waveguide 5 with curvature continuously variable, shaped "J".

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• 2017
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  • 2018-01-10 EP EP18702758.6A patent/EP3574498A1/fr active Pending
  • 2018-01-10 WO PCT/FR2018/050060 patent/WO2018138425A1/fr unknown
  • 2018-01-10 RU RU2019123538A patent/RU2760383C2/ru active

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