FR2994612A1 - Sound transduction device for diffusion of sound and video image, has motor elements arranged in network having rows and columns equal to thrice diameter or largest dimension of motor elements in plane parallel to image diffusion screen - Google Patents

Abstract

The device has motor elements (10) capable of transforming a movement into a varying electrical signal. The motor elements are arranged in a network having rows and columns equal to three times the diameter or largest dimension of the motor elements in a plane parallel to an image diffusion screen (14) to which the motor elements are coupled. Each motor element receives a delay signal on an individual basis. The motor elements are divided into groups, where each group receives the same delayed signal.

Description

The field of the present invention concerns both the sound diffusion and the video image diffusion.

There are indeed many sound diffusion devices associating several speakers. There are also many types of screens, both projection screens and so-called active screens, which emit light. The object of the present invention is a video image broadcast screen which is also a sound broadcasting device.

A first advantage of such a device is to obtain a coherence between the image and the sound that has until now only been possible using sound-permeable screens. Such screens, perforated or woven, are arranged in front of speakers. This makes it possible to perceive the sound as coming from inside the screen, which is desirable. This arrangement is also conventional in cinemas. However, these can only be projection screens, the active screens not being permeable to sound. A device according to the present invention makes it possible to make so-called active screens which also emit sounds whose origin is perceived on the surface of the screen, which combines the advantage of a brightness greater than that which can be obtained with projection screens, while preserving the origin of the sound in the image.

A second advantage of such a device is to obtain a compactness of the assembly which reduces the cost of operation in mobile applications. A third advantage of such a device is that it makes it possible to control on demand both the horizontal directivity and the vertical directivity of the sound diffusion. Two-axis directivity control solutions are known by the Wavefiels synthesis technology (Sound Reinforcement by Wavefield Synthesis: Adaptation of the Synthesis Operator to the Loudspeaker Directivity Characteristics). This technique however has many limitations: It is very expensive because of the large number of speakers used. In addition, its effectiveness is limited in algae frequencies by the physical dimension of the individual loudspeakers: Indeed, the coupling of adjacent individual loudspeakers is done in a coherent way only until a frequency whose wavelength is as large as the distance between said loudspeakers. For higher frequencies, coupling can not do, and interference between the wavefronts thus generated creates irregularities in the resulting transfer function. Finally, we do not know video screens generating direct sound waves.

More specifically, a transducing device according to the present invention comprises a plurality of identical motor elements (10) capable of transforming into motion a variable electrical signal, said motor elements being arranged in a network (20) comprising rows and columns following a pitch less than or equal to three times the diameter or the largest dimension of said motor elements in a plane parallel to a common membrane (14) to which they are coupled. Another feature of the present invention is that said membrane is a screen broadcasting of images. In a preferred embodiment of the invention, said membrane comprises an array of light-emitting diodes capable of producing a video image. Such light-emitting diodes are preferably of flexible organic type, known under the generic name "FOLED". The features and advantages of the present invention will be better understood on reading the description which follows, with reference to the accompanying drawings, in which: FIG. 1 is a schematic sectional view of a device according to the invention, FIG. 2 is a fragmentary diagrammatic front elevational view of a device according to the invention, FIG. 3 is a diagrammatic sectional view of a detail of FIG. FIG. 4 is a symbolic diagram illustrating the operation of a device according to the invention. FIG. 5 is a diagram symbolically representing a signal processing device implemented in a device. According to the invention, FIG. 6 is a virtual symbolic representation of a wavefront that can be emitted by a device according to the invention. FIG. 7 is a partial front elevational representation of a device according to FIG. 8 is a front elevational representation of a preferred embodiment of the invention. FIG. 9 is a rear perspective representation of a detail of the preferred embodiment of the invention as shown in FIG. Fig. 10 is a sectional representation of the same detail as shown in Fig. 9.

In more detail, with reference to Figs. 1 and 2, a device according to the invention comprises a plurality of motors 10 attached to a mechanical support 11 consisting of a frame and elements either vertical or horizontal 12 on which the motors 10 are fixed by any appropriate means. The motors 10 comprise a fixed part, fixed to the mechanical support 11, and a movable part 10 '. 1 and 2 represent by way of example a device according to the invention comprising a network 20 of 5 rows of motors and 7 columns, ie 35 motors. It will be understood that a different number of rows and columns can be implemented. The pitch, that is to say the distance that separates the motors, is constant in the rows, and also in the columns. However, the pitch of the rows may be equal to or different from that of the columns. The pitch separating the motors 10 is preferably less than three times the diameter of a motor 10, that is to say its largest dimension in the overall plane of the network 20. A semi-flexible membrane 14, preferably made in a light and well cushioned material, is stretched on the frame 11 and is connected to each of the moving parts 10 'of the motors 10 by an adhesive 2. Preferably, an internal rigid frame 16 is provided to delimit an active zone in which the membrane 14 is vibrated by the motors 10. The internal rigid frame 16 is integral with the support 11, and is in contact with the membrane 14, preferably via an adhesive.

The ends of the moving parts 10 'at rest and the ends of the inner frame 16 in contact with the membrane 14 are all aligned in the same plane so as not to deform the membrane when it is at rest. The dimensions of the internal rigid frame 16 are approximately such that it frames the network leaving a margin of a half step between the outer edge of the network and the contact with the membrane 14.

With reference to Fig. 3, a motor 10 is of the conventional type of a loudspeaker motor. The mobile part 10 'consists of a cylindrical support on which is wound a voice coil 17 immersed in the gap of a cylindrical magnet 18 having two concentric poles, one of which is inside the voice coil 17 and the other outside. A concentric suspension device 19 fixed on the one hand to the fixed part of the motor 10 and on the other hand to the movable part 10 'prevents the non-axial displacements of said movable part. Any other type of motor capable of moving the membrane 14 according to a variable electrical signal can also be implemented without departing from the scope of the present invention. With reference to FIG. 4, the motors 10 receive a signal S which is processed so as to be delayed according to a delay At.

In the example shown in FIG. 4, the central motor 21 of a column of 5 motors receives a signal for which At = 0, while the motors 22 and 23 which surround it receive a delayed signal of At = 1 and the motors 24 and 25 situated the most outside the column receive a delayed signal of At = 2. The numbers 1 and 2 correspond to arbitrary symbolic values. The actual values, expressed in milliseconds, will be defined by the user of the device according to the invention as a function of the needs related to the conditions of use. Thus, the motors 21 to 25 which are physically aligned are virtually offset from one another as shown in FIG. 4, approximately following a circular arc. When the motor 21 receives the signal S, it pushes the center of the membrane 14. Then, the motors 22 and 23 push it in turn, then finally the motors 24 and 25, the assembly thus determining in a controlled manner the deformations of the membrane. In this way, the membrane creates a curved wavefront 30 which propagates and whose surface extends as its distance from the membrane 14 increases, according to the natural laws of spherical propagation. The ideal curved wavefront that one seeks to produce is shown in dashed lines on the drawing under reference 31. The maximum differences between the theoretical wavefront 31 and the real wavefront are represented by the interval between the arrows 32. As long as the interval 32 is less than half a wavelength in size, the actual wavefront 30 is a correct approximation of the theoretical wavefront 31. This defines the upper limit frequency until to which the device according to the invention operates in a completely coherent manner. It should be noted that in the particular case where all the values of Δt are defined as equal, the wavefront 30 is flat instead of being curved, and the propagation of the wave is without expansion of its surface. . It is also appropriate to oppose this mode of operation of the invention to that, conventionally, of a membrane excited by one or a few motors distributed randomly at a few points of the membrane, the latter being left free to vibrate according to its clean modes. In the context of the present invention, the deformations and movements of the membrane are forced and controlled by the network 20 of the motors 10. The values At are adjustable either for a group of engines, or individually for each engine. According to a preferred embodiment of the invention, each motor is powered by an amplifier 36 (FIG. 5) which is itself powered by an analog output of a digital signal processing unit 35. The processing unit of FIG. signals 35 is fed in the conventional manner by an analog / digital converter 34 which receives a signal S from an analog signal source.

In a simplified embodiment, the signal S comes from a digital source and the unit 33 can process it directly. In the context of the invention, the unit 35 assigns the signal S a delay At, but it can also carry out additional processing that could be useful, such as equalization and filtering. Preferably, a computer 37 controls the delay At applied to the signal S by the processing unit 35 using appropriate software. It should be noted that each motor 10 is powered by an amplifier 36 and a processing unit 35, each of the units 35 being controlled by the computer 37. Referring to FIG. 6, the computer 37 is provided with an interface and appropriate software which makes it possible to visualize the shape of the theoretical wavefront 31 in three dimensions, as a function of the individual delays applied to each of the motors 10. The wavefront 31 determines by its shape the directivity of the source The user can thus adapt the directionality of the sound source according to the geometry of the place, the size of the audience and the other parameters that will be taken into account in the sound reproduction. In other embodiments, it is possible to freeze the various delays At according to stereotyped uses, in order to allow the use of the device according to the invention by users who do not master the directivity parameters of the sound sources.

Fig. 7 is a partial view of an embodiment of the invention in front elevation. The network 20 of motors 10 is only partially represented, as is the membrane 14 which is integral with the parts 10 'of the motors 10 and which is also stretched on the support frame 11. The membrane 14 is made of a semi-rigid plastic material , such as polycarbonate or any other material that one skilled in the art deems appropriate. Preferably, a material 40 having a good absorption of mechanical vibrations will be chosen.

In a first embodiment of the embodiment of the membrane 14, strips 40 of flexible light-emitting diodes 41 are glued in contiguous parallel rows. The strips are of such width that the distance between two diodes 41 in the same band is substantially equal to the distance between two diodes 41 of adjacent bands. The diodes 41 thus constitute a network and each receive the information corresponding to a pixel of a video image. The distance between the diodes 41 depends on the size of the screen, the resolution sought, and the acceptable cost of the assembly. Alternatively, the strips 40 may be aligned in columns instead of rows without inconvenience (not shown). Preferably, diodes having a mass as small as possible will be chosen. According to a second embodiment of the embodiment of the membrane 14, the diodes are of flexible organic type known under the trade designation "FOLED". They can then be included directly in the membrane during its manufacture.

The inclusion of such diodes in a plastic sheet is a known technique, and does not constitute the present invention per se. FIG. 8 is a frontal elevational representation of a preferred embodiment of a device according to the invention comprising a membrane 14 stretched on a support 11 and comprising three motor networks 20, 20 'and 20 ". network 20 is disposed substantially at the center of the membrane 14, and the other two networks are arranged symmetrically on either side of the network 20. The three networks are of identical dimensions and are aligned in height. 20 "is mechanically supported by a metal frame 16 which is connected to the frame 11 by removable connection means, such as screw and nut. The frame 11 is preferably provided with a series of perforations 37 making it possible to choose between several positions of the frame 16. An intermediate membrane 14 '(FIG. 10) is fixed to all the moving parts 10' of the engines 10 of the network. The membrane 14 'is of the type having a non-permanent adhesive contact surface, which makes it easy to take off from the surface with which it is in contact.

This non-permanent adhesive contact surface is located on the face 14 'which is in contact with the membrane 14, the face in contact with the moving parts 10' of the motors 10 being bonded to said moving parts. In this embodiment, each array 20, 20 ', 20 "receives an individual signal, typically Center, Left, Right, respectively, for multichannel stereo sound reproduction, and the three signals are then individually processed in each channel. The invention also provides methods for improving the contrast of the image by various surface treatments of the membrane 14, for example in the Fresnel prism or in a lenticular array. particularly useful when the images are intended to be broadcast in the open air or in brightly illuminated locations. [0022] Figs. 9 and 10 show a detail of a complementary embodiment of the invention. rigid frame 16 which also constitutes a support structure The frame 16 is provided with two vertical elements which allow the connection to be removed removably to the frame 11, which is provided with perforations 39 on its horizontal parts, to allow to choose between several possibilities of connecting the rigid frame 16. An intermediate membrane 14 'is permanently fixed to the movable parts 10' of the motors 10, and non-permanently by means of a detachable adhesive to the membrane 14. The position of the vertical elements 38 is determined so that the membranes 14 'and 14 have a common plane. Alternatively, there may be means for adjusting the relative positions of the frame 16 relative to the frame 11 (not shown). In this way, it is possible to separate the membrane 14 from the network (s) 20 to change the membrane 14 or intervene on one or more motors of the network 20 in case of failure or deterioration. The embodiments described above are given by way of non-limiting examples of the invention which is defined by the claims below. 6

Claims (10)

REVENDICATIONS1. Sound transduction device of the kind comprising a plurality of identical motor elements (10) capable of transforming into motion a variable electric signal, characterized in that said motor elements are arranged in a network (20) comprising rows and columns in a manner no less than or equal to three times the diameter or the largest dimension of said motor elements in a plane parallel to a common membrane (14) to which they are coupled. 2. Device according to claim 1 characterized in that each motor element (10) receives a signal S delayed individually. 3. Device according to claim 1 characterized in that said motor elements (10) are divided into groups, each motor of said group receiving the same signal S, each group receiving the signal S delayed individually. 4. Device according to any one of the preceding claims characterized in that the membrane (14) forcibly deforms and controlled under the action of said motors (10) according to the delays of the signal S they receive. 5. Device according to any one of the preceding claims characterized in that each zIt delay is applied to the signal S by a digital signal processing unit (35). 6. Device according to any one of the preceding claims characterized in that each motor element (10) consists of a voice coil (17) coupled to said common membrane (14) by adhesive means, said voice coil being in the gap of a magnet (18). 7. Device according to claim 2 characterized in that each motor element (10) is fed by an amplifier (36) which is associated with digital signal processing means (35). 8. Device according to claim 3 characterized in that each group of motor elements is fed by an amplifier (36) which are associated with digital signal processing means (35). 9. Device according to claim 1 characterized in that said common membrane (14) is larger than said network. 10. Device according to any one of the preceding claims characterized in that said membrane (14) is an image diffusion screen. 1. Device according to any one of the preceding claims characterized in that said membrane (14) comprises a network formed of parallel strips (40) of light-emitting diodes (41) capable of producing a video image. 12. Device according to any one of the preceding claims characterized in that said light-emitting diodes (41) are of flexible organic type. 13. Device according to any one of the preceding claims, characterized in that three networks of motor elements (20, 20 ', 20 ") are coupled to a single membrane (14), each network receiving an individual signal. according to any one of claims 2 to 10 characterized in that said signal processing means can be controlled by means of a device for visualizing the geometric shape of a theoretical wavefront (31) in function delays applied to the motors (10) so as to determine the directivity of the sound source.