NL8001445A - Loudspeaker with independent localisation for specific positions - has diaphragm of capacitive screens linked to filters for directional characteristics - Google Patents

Abstract

The effect of indirect sound in the room, such as reflection from the wall is counteracted. The loudspeaker provides independent localisation facilities for the specific position of the listener in the room. The diaphragm consists of a number of elongated capacitive screesn (2-18) linked to a low pass filter unit (19) with a number of low pass filters (20-27). The effective radiating surface is reduced with increasing frequency, making it approx. equal to a selected factor times the frequency corresp. to the wavelength of the signal being radiated. This achieves a directional characteristic related to the azimuthal orientation.

Description

X Sch / AS / 2 »i" Loudspeaker unit "

The invention relates to a loudspeaker unit with a membrane for converting electrical audio signals into sound signals.

Such a loudspeaker unit is known.

With this known loudspeaker unit the problem arises that at low frequencies the sound radiation takes place in a non-directional manner, while with increasing frequency the degree of bundling gradually increases. A consequence of this is that a listener should preferably not be too far from the axis of the speaker, as otherwise undesired timbre differences may occur. Particularly for stereo reproduction, this constitutes a serious limitation in the listener's positional freedom, since in this case the listener has to take place near the intersection between the center lines of both loudspeaker units. To overcome this problem, loudspeakers have already been proposed which function almost as monopole over a very large frequency range, that is to say, directional radiation over a wide frequency range. Known in this connection, for example, are the so-called dome-type loudspeakers, which are usual in high-quality loudspeaker units, in particular for reproducing treble.

It has now been found that the completely uniform sound radiation, such as that takes place when such dome loudspeakers are used, does entail a greater freedom in the position of the listener, but on the other hand gives rise to phenomena which affect the reproduction very adversely. For example, when using a round-beam loudspeaker unit, it cannot be prevented, for example, that side walls and the ceiling 800 1 4 45 ff -2- function as sound mirrors, which leads to the formation of mirrored, virtual sound sources, which may interfere with the primary source, namely the loudspeaker unit, that the freguance response of the transmission between the loudspeaker unit and the listener is highly dependent on the listening space and exhibits large deviations from the frequency response of the loudspeaker unit in the free field.

It has further been found that no known loudspeaker, including that of the round beam type, is capable of providing a localization possibility independent of the position of the listener in the listening room. When using radiant speaker units, it is found that the "sound image" varies with the specific position of the listener in the listening room. This is extremely undesirable, for example for monitor purposes, for example in the case in which a two-channel reduced version is to be produced on the basis of a multichannel recording, for example in a gramophone record studio, since in this case different listeners in the monitor room each have a different sound impression.

Without going into details regarding the physical phenomena underlying the possibility of locating individual instruments over a wide front using two loudspeakers, one is reminded of one. effect known from psychoacoustics, which has been investigated by, among others, De Boer, Haas, Meyer / Schodder. According to this principle, as far as the. stereo localization a relationship between sound pressure level variations and transit time differences. These two quantities can largely compensate each other for 80 0 1 4 45 s i -3-. For example, the sound from the left speaker reaches the listener 2 ms earlier than the sound from the right speaker (corresponding to a distance -5 difference of about 70 cm), this does not affect the listener's localization capability, if the right speaker gives an approximately 7 dB higher level than the left one. Other compensating level differences are obtained for other maturity differences.

The object of the invention is to provide a loudspeaker unit of a type which, to the greatest extent possible, counteracts the influence of indirect sound in the listening room, in particular reflections of walls and the like, and which is of one of the specific position of the listener in the listening room offers virtually independent localization possibilities, for which the invention proposes to make use of the aforementioned effect.

In order to achieve these objectives, the invention provides a loudspeaker unit of the type mentioned in the preamble, which according to the invention is characterized by means for reducing the effective radiating surface with increasing frequency such that the characteristic linear dimension of the effective the radiant surface is always at least approximately equal to a preselected factor times the wavelength corresponding to the frequency of the sound signal to be emitted, all this such that a direction characteristic is obtained 800 1 4 45 -4- * *, according to which sound pressure level depends on the azimuthal orientation according to at least approximately the following relationship:

Azimuthal orientation Sound pressure level 13 0 ° 0 dB (reference)

+ 10 ° -1 dB

+ 20 ° -4 dB

+ 30 ° -9 dB

± 40 ° -12 dB

For example, the loudspeaker unit may comprise a substantially rectangular diaphragm, the characteristic linear dimension varying with frequency only in horizontal direction; in this case said factor is at least about 1.1.

The invention also relates to a loudspeaker unit with a substantially rectangular membrane, wherein the characteristic linear dimension varies in horizontal and vertical direction; in this case, said factor is in the range of about 1.2-1.3.

In a further exemplary embodiment, the loudspeaker unit according to the invention comprises a substantially circular membrane, the characteristic linear dimension varying in both horizontal and vertical direction; in this case said factor is at least about 1.3 - 1.4.

According to the invention, the said means can be designed as a filter unit with a low-pass characteristic, which filter unit cooperates with the membrane in such a way that a middle part of the membrane 30 can radiate all frequencies and further away from the middle membrane parts only frequencies below a tilting frequency can radiate, which tilting frequency is lower, as the relevant membrane part is further away from the center.

This low-pass filter unit can be of the electric or the acoustic type.

In the case where the low-pass filter unit is of the electrical type, the loudspeaker unit according to the invention may comprise at least a horizontal number of adjacent membrane elements 800, the middle element of which is at least one in horizontal direction. horizontal direction number of adjacent membrane elements. the middle element of which the direct membrane and the other 5 membrane elements are each connected via a low-pass filter to audio signal supply terminals, the low-pass filters of which the tilting regulation is lower the further away the respective membrane element is from the center. The membrane elements can herein be designed as capacitive screens adjoining at least one side, and the low-pass filters can each be designed as self-inductance connected in series with a respective element and a resistance incorporated in parallel with or in series with that element, which self-inductances and which resistors all have such a value that a low-pass characteristic is obtained with a tilting frequency required for the element in question and a quality factor in the order of magnitude of 1.

In the case where the low-pass filter-20 unit is of the acoustic type, this unit may be designed in such a way that a filter member of sound-absorbing material is arranged on the front of the membrane, which filter member leaves a middle part of the membrane and has a thickness. , which increases with the distance from the middle section.

The invention will now be elucidated on the basis of the accompanying drawing. Herein: fig. 1 shows the relevant part of the direction characteristic of a loudspeaker unit according to the invention? Fig. 2 shows a schematic representation of a first exemplary embodiment of a loudspeaker unit according to the invention with a filter unit of the electrical type? Fig. 3 shows a possible further elaboration of the first exemplary embodiment shown in Fig. 2? Fig. 4 is a partly schematic front view of the membrane of a second exemplary embodiment of the 800 1 4 45-6 loudspeaker according to the invention; Fig. 5 shows a schematic front view of a third exemplary embodiment of the loudspeaker according to the invention; Fig. 6 shows a schematic front view of a fourth exemplary embodiment of the loudspeaker according to the invention; Fig. 7 shows a schematic front view of a fifth exemplary embodiment of the loudspeaker according to the invention; Fig. 8 shows a schematic front view of a sixth exemplary embodiment of the loudspeaker according to the invention; Fig. 9 shows a cross-section of a seventh exemplary embodiment of the loudspeaker according to the invention, wherein the membrane elements consist of high polymer foil (HPF); Figures 10a, b, c, by way of example, three possible configurations of electric, passive filter units for a loudspeaker unit according to one of Figures 2 to 9; Fig. 11 is a perspective view of an eighth embodiment of the loudspeaker according to the invention with an acoustic low-pass filter unit; 25 and FIG. 12 is a cross section through plane XII-XII. in fig. 11.

Fig. 1 shows a directional characteristic of a loudspeaker, with which according to the invention very favorable results are obtained, as has already been explained before; this diagram is to be interpreted as the dependence of the direction of the sound pressure level in a substantially horizontal plane. With regard to the term "horizontal", it is noted that loudspeaker units are often arranged slightly inclined; it will be clear, however, that the principle of the invention is not limited to an exactly horizontal plane. In the diagram of Fig. 1, the axial direction of the speaker unit is used as a reference; the sound pressure level at a point on the axis is set to 800 1 445 -7-, therefore O dB. With respect to this reference value, for other azimuthal angles according to the invention:

+ 10 °: - 1 dB

5 + 20 °: - 4 dB

+ 30 °: - 9 dB

+ 40 °: -12 dB

Fig. 2 schematically shows an exemplary embodiment of a loudspeaker unit 1 according to the invention.

It comprises a transducer section in the form of a membrane. This consists of a number of, in this case 17, elongated capacitive screens 2 ... 18 of, for example, the electrostatic type, and an associated electric low-pass filter unit 19, which contains a number of low-pass filters 20 ... 27. All screens 2 to 18 are chosen identically in this exemplary embodiment for the sake of simplicity of production. An electrical audio signal can be supplied via input terminals 28. The screen 10 is directly connected to the input terminals 28 and 20 therefore receives all input information, regardless of the frequency.

In this exemplary embodiment, the width of the screens 2 to 18 is about 6.3 cm, so that at about 6 kHz the ideal directional characteristic according to the invention is obtained using only one screen, in this case the screen 10. Above this frequency of 6 kHz, an increasing bundling occurs, which is subjectively hardly annoying. When the frequency decreases, the screen 10 will radiate less focused. The filter unit 20 is therefore designed such that screens 9 and 11 receive audio information below about 6 kHz. The three units 9, 10 and 11 therefore operate under this frequency, so that at a frequency 6: 3 = 2 kHz the ideal directional characteristic is again obtained. Entirely analogous to this, the filter units 21 ... 27 are designed such that their tilting regimes are inversely proportional to the number of screens to be operated in a given frequency domain. The 800 1 4 45 ί * -8 table below, which relates to this specific exemplary embodiment, is illustrative.

TABLE I

......... 1 ......... ...... f "- I

5 Frequency range Number of operating Tilting frequency (Hz) with screens Filters (Hz)> 6000 1 (10) 20: 6000 Hz 2000 - 6000 3 (9 - 11) 21: ^ 2 = 2000 10 1200 - 2000 5 (8 - 12) 22: = 1200 860 - 1200 7 (7 - 13) 23: = 860 670 - 860 9 (6 - 14) 24: = 670 15 550 - 670 11. (5 - 15), 25: ^^ = 550 '460 - 550 13 (4 - 16). 26: = 460 400 - .460 15 (3 - 17) 27: = 400 <400 17 (2-18) 20 -: --—-; -— J ’* ---

If desired, the low-pass filters 20 to 27 may each comprise a light power amplifier for driving the screens 2 to 9, 11 to 18. In that case, in the supply line to the screen 10 there may also be such an amplifier included.

Fig. 3 shows a further elaboration of the loudspeaker unit according to FIG. 2. Here, the low-pass filters each comprise an inductance (LI-L8) and a resistor (R1-R8). The value of the resistors R1 to R8 partly determines the quality of the circuit formed by the capacitance of a screen and the associated self-inductance. This quality Q is preferably of the order of 1.

In the exemplary embodiment according to Figs. 2 and 3, the bundling is gradually lost for falling frequencies below approximately 400 Hz. This is not a problem, since no direction can be observed at those lower frequencies. Attention is drawn to the fact that the bundling desired according to the invention takes place mainly in a plane, perpendicular to the longitudinal direction of the screens, i.e. in normal use in a substantially horizontal plane . In general, this is sufficient for normal house-5 room use. After the foregoing, it will be understood, however, that by using a similar arrangement and frequency selection for the other direction, i.e. the "vertical direction", a vertically controlled bundling can also be obtained. For this purpose, for example, an arrangement with a number of concentric annular screens can be used. This possible variant will be further elaborated below.

The dimensions of the different screens need not be the same, as in the exemplary embodiment according to Figs. 2 and 3. The screens can have an increasing width as the distance from the center increases. In that case, the tilting regulations must be adjusted accordingly. Fig. 4 shows a detailed example in which use is made of this principle.

The exemplary embodiment shown in fig. 4 has the special feature compared to the exemplary embodiment according to fig. 2 and 3, that the different membrane elements do not have the same width, but that the membrane elements grouped in pairs around the central element have a gradually increasing have width. In the exemplary embodiment according to Figs. 2 and 3, the tilting regimes of the different filters were equal to a preselected frequency, for example 6 kHz, divided by the number of elements active for a certain frequency. Particularly for musical purposes, to which the invention is specifically directed, it is preferable if the different tilting regimes are obvious on a logarithmic scale. Fig. 4 shows an exemplary embodiment, 800 1 4 45 -10- in which this principle is incorporated. The membrane shown in Fig. 4 is composed of 17 membrane elements 29 ..... 45.

The middle membrane element 37 has a width of 40 mm, which corresponds to a frequency with a round-beam characteristic according to the invention of 9400 Hz.

The width of the adjoining elements 36 and 38 is chosen such that at a frequency of 6300 Hz the ideal directional characteristic is again obtained in the event that the three elements 36, 37 and 38 act together at that frequency. In this exemplary embodiment, a ratio between successive crossover frequencies of approximately 1.5 has been chosen.

In accordance with this, the widths of the elements 36, 35, 34, .... 29 and 38, 39, 40, 41 ... 45 15 are also always chosen. Table II below shows the various relevant values.

TABLE II

Frequency range (Hz) Number of active Membrane width 2q screens elements (mm)> 9400 1 (37) 37: 40 6300 - 9400 3 (36 - 38) 36/38: 10 4200 - 6300 5 (35 - 39) 35/39 : 15 25 2800 - 4200 7 (34 - 40) 34/40: 23 1860 - 2800 9 (33 - 41) 33/41: 34 1240 - 1860 11 (32 - 42) 32/42: 51 830 - 1240 13 ( 31 - 43) 31/43: 76 550 - 830 15 (30 - 44) 30/44: 114 3G <550 17 (29 - 45) 29/45: 171

Table II does not show the crossover frequencies of the various filters necessary for this exemplary embodiment; It will be clear from the foregoing discussion of FIGS. 2 and 3 and Table I how the various filters can be sized.

Attention is drawn to the fact that if a directional characteristic according to the invention is to be maintained up to a lower frequency, the width of the screen can be correspondingly increased. If desired, the number of elements can also be increased, so that the tolerance in the directional characteristic can still be reduced. This will generally not be necessary for practical purposes.

Fig. 5 shows a third exemplary embodiment of a loudspeaker unit according to the invention, in which horizontal use is made of the principles 10 according to FIGS. 2 and 3, while measures have also been taken to limit the increasing bundling with increasing frequency. For this purpose the loudspeaker according to Fig. 5 has the special feature that the middle element, 49, is relatively short in vertical direction; the adjoining elements 48 and 50 are the same width but have a greater length; elements 47 and 51 are again longer than elements 48 and 50, while finally elements 46 and 52 are longer than elements 47 and 51. After the previous detailed explanations with regard to the first and second exemplary embodiments, in the With particular reference to Fig. 3 and Table I, it will be clear how the loudspeaker unit according to this third embodiment can be dimensioned; this will therefore not be discussed in more detail here.

FIG. 6 shows a fourth exemplary embodiment, which is a further elaboration of the principle shown in FIG. This loudspeaker is designed in such a way that the free surfaces between the various membrane elements are also occupied by membrane elements; in this way a directionally controllable directional characteristic can be obtained in certain horizontal and vertical directions within certain limits.

Also with regard to this fourth exemplary embodiment, no dimensioning details will be given. After all, these strongly depend on the criteria set by a designer with regard to a particular purpose of use.

Fig. 7 shows a fifth exemplary embodiment of the loudspeaker unit according to the invention. The different membrane elements are designed as rings with 800 1 4 45 -12 square circumference. The horizontal directional characteristic is equal to the vertical directional characteristic.

Fig. 8 shows a sixth exemplary embodiment of the loudspeaker according to the invention. This is a variant 5 of the embodiment shown in Fig. 7, in which the different membrane elements are designed as concentric, circular rings.

Fig. 9 shows a top view of a seventh exemplary embodiment of the loudspeaker unit according to the invention, using high-polymer foil as a transducer element for the various membrane parts.

In this Fig. 9, implementation details are omitted; after the previous explanations it will be clear how the loudspeaker unit according to this exemplary embodiment can be dimensioned.

In Figs. 6, 7, 8 and 9 the use of reference symbols is dispensed with, since these figures are mainly intended to illustrate possible geometric details of the membrane to be used in the loudspeaker according to the invention.

Figures 10a, b and c show possible embodiments of low-pass filter units, which may form part of the loudspeaker unit according to the invention.

The example according to Fig. 10a corresponds to the filter unit as used in the exemplary embodiment according to Fig. 3. The corresponding elements are therefore indicated in this Fig. 10a with the same reference symbols as in Fig. 3.

Fig. 10b shows a variant in which the membrane 30 elements 2/18., 3/17 are included in a series circuit with an inductance L9 and a resistor R9, respectively an inductance L1Q and a resistor R10. such a series filter has the same results as with the filter according to Fig. 10a.

FIG. 10c shows a variant in which the different filters are not connected in parallel, but in ladders. Only two sections of the filter unit are shown, namely the section with a series 800 1 4 45 - * -13- self-inductance Lil and a series resistance Ril with parallel load of the capacitive element 2/18 / and a second section with a series -inductance L12 and a series resistor R12 and a load of the capacitive element 3/17.

FIG. 11 shows an eighth embodiment of the loudspeaker according to the invention in perspective. Use is made here of a flat electrostatic screen 53 with a protective grid 54 on the front.

A middle strip 55 is completely free for radiating sound from all frequencies. Two wedges 56, 57 of porous sound-absorbing material extend from the center strip to the edge edges, the thickness of which depends on the distance from the center so that both wedges serve as a low-pass filter unit.

The invention is not limited to a particular type of sound-absorbing material. Due to the wide variety of materials that can be used for the acoustic filter according to the invention, the description of the implementation details has been omitted. After the foregoing discussion It will be clear about the electric filters how to select the profile for an absorbent material with known absorption properties in order to achieve the directional characteristic according to the invention.

Fig. -12 shows a cross-section in plane XII-XII in fig. 11.

The invention is not limited to the exemplary embodiments described above and elucidated with reference to the drawing. Various changes in the parts and in their mutual connection can be made, without thereby exceeding the scope of the invention.

For example, various combinations of the described embodiments are possible. As an example of this, reference should be made to the possibility of designing the speaker unit 35 in a circular manner with an acoustic filter. In that case use can be made of a circle-symmetrical wedge member with diametrically the same cross section.

It is further conceivable that a loudspeaker 800 1 4 45 -14- for certain purposes should have a directional characteristic corresponding to another value of the factor discussed earlier. It will be clear that the principles of the invention also extend to such an embodiment.

These exemplary embodiments are optimal, in which the different membrane parts behave in a highly phase-faithful manner. Most suitable, therefore, are speaker units based on electrostatic, ceramic (HPF) and orthodynamic principles. The use of electrodynamic elements, for example a number of column-arranged conventional dynamic loudspeakers, can in principle also be used.

Probably the most critical fregueritie-15 region in the context of stereo reproduction extends approximately from several hundred to several thousand Hz. Thus, for example, use can be made of a dipole type speaker unit, which radiates freely at the front and the rear, while the bass reproduction 20 below the lower cut-off frequency of the speaker unit is taken over by another speaker unit, which is more suitable for this purpose. , for example, a speaker unit of the fully closed type, a speaker unit of the bass reflex type, a horn system, a transmission line, or the like.

800 1 4 45

Claims (10)

A loudspeaker unit with a membrane for converting electrical audio signals into sound signals characterized by means for decreasing the effective radiating surface with increasing frequency such that the characteristic linear dimension of the effective radiating surface is always at least approximately equal to a preselected factor times the wavelength corresponding to the frequency of the sound signal to be radiated, one and the other such that a directional characteristic is obtained, according to which the sound pressure level depends on the azimuthal orientation according to at least approximately the following relationship: Azimuthal orientation Sound pressure level 0 ° 0 dB (reference) 15 + 10 ° -1 dB + 20 ° -4 dB + 30 ° -9 dB + 40 ° -12 dB 2. Loudspeaker unit with a substantially rectangular diaphragm, the characteristic linear dimension of which varies only in horizontal direction with the frequency, characterized in that said factor is at least about 1.1. 3. Loudspeaker unit according to claim 1, 25 with a substantially rectangular membrane, wherein the characteristic linear dimension varies in horizontal and vertical direction, characterized in that said factor is at least about 1.2-1.3. Loudspeaker unit according to claim 1, 30 with a substantially circular membrane, wherein the characteristic linear dimension varies in horizontal and vertical direction, characterized in that said factor is at least about 1.3-1.4. Loudspeaker unit according to one of the preceding claims, characterized in that the said means are designed as a filter unit with a low-pass characteristic, which filter unit cooperates with the membrane in such a way that a central part of the membrane can radiate all frequencies and membrane parts further away from the middle can only radiate frequencies below a crossover frequency / which crossover frequency is lower, as the relevant membrane part is further away from the center. Loudspeaker unit according to claim 5, characterized in that the low-pass filter unit is of the electric type. Loudspeaker unit according to claim 6, characterized by a number of adjacent membrane elements, at least in horizontal direction, of which the middle element is directly connected and the other membrane elements are each connected via a low-pass filter with audio signal supply terminals, of which low-pass flashes have the crossover frequency the lower the degree to which the relevant membrane element is located further from the center. Loudspeaker unit according to claim 7, characterized in that the membrane elements are designed as capacitive screens adjoining at least one side, and that the low-pass flashes are each designed as in series with. self-inductance included in a respective element and a resistor connected in parallel with or in series with that element, which self-inductances and which resistances all have such a value that a low-pass characteristic 25 is obtained with a tilting frequency required for the element in question and a quality factor in the size of 1. Loudspeaker unit according to claim 5, characterized in that the low-pass filter unit is of the acoustic type. Loudspeaker unit according to claim 9, characterized in that a filter member of sound-absorbing material is arranged on the front of the membrane, which filter member leaves a central part of the membrane and has a thickness which increases with the distance from it. middle section. 80 0 1 445