DE3732985A1 - Multipath dipole acoustic transducer of highest quality according to the principle of mutually interleaved frequency ranges (regions) - Google Patents

Abstract

A description is given of a multipath dipole acoustic transducer of highest quality, in which the principle of mutually interleaved frequency ranges is applied, which is taken to mean that the chassis of the highest frequency range is "surrounded" by the chassis of the second highest frequency range, and this overall arrangement is, for its part, "surrounded" by the chassis of the third highest frequency range, and so on.

Description

For the highest quality reproduction of a sound event among other things, all linear and non-linear Distortion of a transducer as much as possible turned off. Ideally, there should be a sound pressure signal are produced, the first completely unrelated is distorted and, secondly, its timing is exact corresponds to the target signal.

There is currently no broadband baffle principle known that these requirements are satisfactory Fulfills. Therefore, one tries to achieve the ideal through Speakers come close. That brings two fundamental Problems with themselves.

On the one hand, the assembly is carried out for the various Frequency ranges optimized speaker chassis in all mean above or next to each other. Difference che frequency components of a complex control signal are thus located in completely different places shine. This breaks the spatial coherence of the  Sound signal together. Pinpoint location of a sound source is no longer possible. Instead, it results a "spatially smeared location field" from which the Information "somehow not very tangible" seems.

On the other hand, multi-way speakers are mandatory frequency-selective networks required, which the com plex frequency mixes in their different fre split frequency ranges and the appropriate speaker assign chassis. The interpretation of such "Frequency Wei chen "is of crucial importance for the overall system tung. No concept currently used can be strict Withstand standards. Drastic differences between mathematically based and actually acoustically edge steepness achieved, non-in-phase in Takeover area, significant group jumps with ten in the listening area, etc. are generally accepted. This is partly due to the principle, partly as an artifact unbalanced frequency response, oblique to the baffle radiation characteristics, destruction of the time Chen coherence (i.e. the impulse reproduction) and so on.

For these and other reasons, always again tried to realize sound emitters where all frequencies come from the same point source seem and on the other hand still arguing about which crossover concept is the optimal one.

Real coaxial is a step towards the point source speakers. These are constructions in which one large bass-midrange membrane in the area of the pole core with a mid-high range radiator is provided. Such Spotlights, however, could therefore not prevail because the coaxial design is a compromise loose optimization of the individual chassis prevented and because desirable versions with three or better more ways to become practically completely unrealizable.

Another way to the spotlight is through a bend wave converter driven (DE 22 36 374, DE 25 00 397 and DE 31 23 098). This converter principle points to the axis actually have good impulse behavior. It owns however compared to conventional sound transducers considerable disadvantages with regard to the degree of bundling in the high frequency range range and in terms of distortion behavior in the lower to medium range lower frequency range.

A newer idea tried two chassis over a half translucent "acoustic mirror" virtually on the same Bring place. There are two main advantages to this procedure Trouble with yourself. On the one hand, there are numerous diffracted secondary waves, the sound-obscuring "early  reflections ". The second is shielding measures necessary, as the tweeter is not direct, son which may only take effect in a mirrored manner. Such shielding In principle, measurements are not satisfactorily real sizable.

The task of using a spotlight of the highest quality provide, whose basic advantages are not in other Inadequacies must perish from the above and other reasons than previously unsolved.

This problem is solved by the present invention solved.

Part of the inventive idea is the application of the principle of the nested frequency ranges. This is to be understood as usual for her Frequency range consistently optimized speakers chassis are arranged so that the chassis of the highest frequency range from the chassis of the second highest frequency range are "surrounded" and these Overall arrangement in turn from the chassis of the third highest frequency range is "surrounded" and so on.

This is illustrated in Figure 1 using the example of a 3-way system. The highs are radiated centrally, the basses on the outside and the mids in between. Such an arrangement ensures that all frequencies appear to come exactly from the center, since they are located there in the center, similar to the center location via a stereo system.

However, an arrangement based on the principle of interleaved frequency ranges does not have to be flat-ring-shaped. Less elaborate, more linear realizations are ideally suited, because here, too, virtually all frequencies are emitted from the location of the high-frequency chassis. Figures 2a and 2b show examples of such arrangements with 3 and 5 channels.

The principle of the nested frequency areas does not only offer the advantage of one Spotlights approach, but brings decisive other advantages:

With regard to the compromise between slope steepness and phase rotation in the sum signal set crossovers with odd multiples of 6 dB / oct the optimum The crossover with 6 dB / oct takes a whole outstanding special position. As the only switch type it does not cause any phase shift in the sum signal. The disadvantage is that their radiation characteristics in the over principle, the range is inclined to the baffle  (Tilt away from the higher frequency chassis towards the lower frequency quents). The crossover with 18 dB / oct generated (at alternating polarity of the channels) a relatively mild one Phase rotation in the sum signal, that of a switch of 12 dB / oct corresponds to a larger flange despite 6 dB / oct steepness. However, it is also disadvantageous here that the Directional characteristic in the takeover area due to the principle is crooked to the baffle.

This weakness of both switch types is due to the principle of the nested frequency ranges does. The directional characteristic is therefore also for Fre In principle, sequences in the takeover area are exactly on the Baffle axis and is, in principle, completely sym metric to this axis. This remains valid even if otherwise due to artifacts on chassis or switch additional inclinations of the directional characteristic would call. Balanced polar patterns are one important prerequisite for discoloration-free loudspeakers reproduction.

Since the essential frequency ranges are processed by at least two chassis, each individual chassis can be designed smaller. This results in considerably less Partialschwingungsprobleme and significantly wider horizonzale emission characteristics (for vertical chassis assembly as shown in figure 2a and 2b). This also enables denser chassis assembly. With clever arrangements, it is also possible to ensure that the distance between two chassis is less than half of the shortest wavelength they process, even in the vertical direction up to the mid-high range. This means that the directional characteristic has no side lobes.

Radiating low frequencies leads to in the listening room Standing waves. If several bass Used chassis that are spaced apart in the Order of magnitude of the listening room dimensions on average a cheaper standing wave ratio, i.e. a similarly good one for all listening locations Bass reproduction.

Through reflections on the floor, ceiling and walls of the Each chassis produces mirror sound sources. At the listening location, therefore, arise after the primary sound numerous "early reflections" and echoes. Meet the former within the first milliseconds after the primary sound and lead to an irritation of the auditory Systems, whereby the location suffers and the "Naturalness" of the reproduction affected becomes. If you populate a channel with several, spatially cleverly distributed chassis, so you get instead of one  large "early reflection" several, significantly smaller ones are staggered in time. Such are for Locability and "naturalness" considerably less detrimental.

However, all the advantages mentioned only represent one Partial step on the way to "unmistakable" success. If you link the principle of each other nested frequency ranges using the principle of Dipole radiator, so are loudspeaker constructions possible, their tonal qualities, in principle, every outperform previously known model.

The principle "dipole emitter" is through literature, patents and numerous commercially available loudspeaker models well known. Especially full range electrostats and full-range magnetostats work out practically finally on this principle. Both types of converters will always excellent spatiality and special certified transparent and "natural" reproduction.

In general, this is due to their extremely light weight Film membranes back through which an excellent Impulse behavior should be made possible. For one thing it is but physically wrong, from a slight one Membrane to expect good impulse behavior ten, because the shape accuracy of a sound pressure signal is Put simply, proportional to the shape accuracy of the Membrane acceleration. The latter can be used for heavy membra be as good as for light ones. On the other hand it turns out during re-measurements that the impulse ver by no means keep film converters remarkably good, son who is rather bad. The reason is to find that their dimensions compared to that to be blasted Wavelength are large, usually even in one dimension extremely large. This leads to pronounced interference and correspondingly disturbed impulse behavior.

The decisive reason for the excellent sound quality hold of dipole radiators is rather that since There is almost no radiation from the baffle. Firstly, this means that there are hardly any reflections on the side walls and the ceiling of the listening room, secondly hardly any standing waves between the side walls and between Third and third floor stimulated floor and ceiling results for cleverly designed dipole emitters Bundling measure that is strikingly frequency-independent. The Dipole radiators therefore do not have to, as with closed ones Boxes usual, are designed so that too much on the axis is radiated at heights so that the deficit of heights in the Diffuse sound is absorbed to some extent. So he can Dipole emitters sound transparent and "natural" without to be shrill on the axis.  

A combination of dipole emitters and ver nested frequency ranges combine the advantages both principles. This is how a sound transducer becomes the highest Quality feasible, but still with very commercial Chen, inexpensive optimized for their frequency range dynamic speaker chassis. Here work suitable bass, mid-range and rear open possibly also tweeter chassis directly as dipole radiators. Who the closed chassis, e.g. in the high frequency range, used, there are two for realizing the dipole effect to use, one of which is forward and one (ver pin connected) radiates to the rear.

Electrostats and magnetostats are limited Membrane deflections and correspondingly limited deep bass level too. This problem arises when using large Bass chassis with a light membrane and low-lying resonance frequency not. It even makes sense if there is enough large deep bass membrane area e.g. through equalization network work the lower limit frequency of the dipole radiator up to the area of 5. . . 15 Hz shift. The apparent resonance be strongly dampened and the fre quenzgang already 1. . . 3 octaves above 5. . . 15 Hz a drop of about 3. . . 6 dB / oct. Such Votes allow because of the unusually good Phase response in the low-frequency range a strikingly contoured bass reproduction. Even the most powerful deep bass passa conditions are affected "despite the acoustic short circuit" reproduced in a realistic manner.

Claims (9)

1. Multi-way dipole transducer of the highest quality, which consists essentially of a baffle, in which che commercially available, dynamic chassis are installed, which are either open to the rear and thus act as a dipole radiator, or can be closed at the rear, in which case two Chassis "back to back" are to be used, one of which shines forward as usual, the other with reverse polarity, characterized in that the principle of the interleaved frequency ranges is used, which means that the chassis of the highest frequency range are surrounded by the chassis of the second highest frequency range and this overall arrangement is in turn surrounded by the chassis of the third highest frequency range and so on. 2. Arrangement according to claim 1, characterized in that the chassis of each Channels are arranged in such a way that approximately results in a system of concentric rings, the Outer rings emit increasingly lower frequencies. 3. Arrangement according to one of the preceding claims, characterized in that only two narrow Sectors of the concentric ring system actually are studded with chassis, these sectors (in relation to the center) essentially diametrically opposite. 4. Arrangement according to one of the preceding claims, characterized in that in addition to the channel which is in the Center emits the highest frequencies, all channels are occupied twice, the two channel halves ten (based on the center) essentially diame tral opposite. 5. Arrangement according to one of the preceding claims, characterized in that an essentially line arrangement of the chassis modified in this way will be the same acoustic regarding direct sound Runtimes from each individual chassis to the head of the Handset arise what is due to progressive offset higher-frequency chassis to the rear or through progressive lateral offset of higher frequency chas sis to the left at the left box, or to the right can happen at the right box.   6. Arrangement according to one of the preceding claims, characterized in that the lower cut-off frequency of the lowest frequency channel through very low tuned bass chassis or through active equalization networks in the range of around 5. . . 15 Hz is lowered. 7. Arrangement according to one of the preceding claims, characterized in that to protect the chassis already 1. . . 3 octaves above the lower cutoff frequency of the lowest frequency channel a drop in frequency response of about 3. . . 6 dB / oct is provided, which corresponds to appropriately designed equalization networks or accordingly low quality of the natural resonance is achieved. 8. Arrangement according to one of the preceding claims, characterized in that the principle of interlocking nested frequency ranges at lower frequencies zen is given up and these frequencies e.g. from a separate, laterally arranged bass column be emitted. 9. Arrangement according to one of the preceding claims, characterized in that crossovers with 6 dB / oct or with 18 dB / oct.