FI62921C - ELIMINERINGSKRETS FOER AOTERKOPPLING - Google Patents

Description

RKrrl ΓβΙ ^ ADVERTISING PUBLICATION a 9 Q 9 1 jff * M (") UTLAOONINGtSKRIPT Il C .... Patent granted 10 03 1983 ^ Patent ceddclnt ^ (51) Kv.Nt? /Lnc.CL^ H 04 E 3/02 ENGLISH —FINLAND (21) ΡκμΜΜμμν — PKaMmMcnins 3072/7 ^ (22) - Amdtolng ^ n 21.10.7 ^ (Fl) (23) AlkupUvft — GlMfhwtei 21.10.?1 (41) TuHut —Writ 22.0 ^ .76 Γ · tantti · And the National Board of Registers / 44) νιμμΜρμο *) · kmiL | ulkai * un pvm.

Patent and registration form AMOkan uth ^ d och utl ^ krifun subUc «r» d 30.11.62 (32) (33) (31) muoMmh — taglrd prior ** (71) A.R.D. Anstalt, P, 0. Box 3 ^ 613, 9 ^ 90 Vaduz, Liechtenstein (LI) (72) Saad Zaghloul Mohamed Gabr, Canterbury, Kent, England-England (GB) 7M Oy Kolster Ab (5U) Feedback elimination circuit - Elimineringskrets för äterkoppling

The invention relates to electrical arrangements that can be combined with acoustic arrangements to provide interference cancellation and acoustic feedback. The arrangements of the invention can be applied to speaker communication systems, telephone systems, sound reproduction systems, and public address systems.

Acoustic feedback in such systems is due to three specific main reasons.

The first reason, which can be called direct acoustic feedback, is because sound reaches the microphone means from the speaker means of the system by moving directly through the air.

Another reason, which may be called conductive acoustic feedback, is that sound reaches the diaphragm or diaphragms of the microphone means as a result of vibrations of connected mechanical means such as microphone and speaker or housing vibration and vibration of a physical structure connected to speaker and microphone converters vibration of the supports or scaffolding of these parts.

SBPi r. n 2 62921

Third, there is indirect acoustic feedback, where sound reaches the microphone diaphragm after being reflected from objects such as walls and furniture surrounding the system.

The invention relates to an apparatus and method for eliminating noise and acoustic feedback by using an electrical circuit which, in combination with acoustic measures, handles acoustic feedback resulting from three reasons.

The invention has thus provided an apparatus for removing acoustic feedback, the apparatus comprising first circuit means for processing the first and second signals, each of which consists of unwanted and unwanted portions, so as to obtain a third signal obtained substantially only of unwanted portions and a second circuit means that uses a third signal to remove an unwanted portion of the fourth signal including the desired and unwanted portions.

The invention also provides an apparatus comprising means for separating interference sound signals from electrical signals obtained as output signals of microphone means and for generating from the interference sound signals two signals having substantially the same phase angle ratio at all frequencies but not necessarily the same amplitude, two so as to obtain two further signals having interfering audio signals having a phase difference of substantially 180 ° and having substantially the same amplitude, and combining these additional signals to eliminate interfering audio signals to obtain a stable audio signal substantially free of acoustic feedback audio signals.

The invention also provides a method for removing acoustic feedback, comprising the steps of processing the first and second signals, each containing an unwanted and an unwanted portion, to obtain a third signal obtained substantially only from the unwanted portions, and not using the third signal. to remove the desired portion of the fourth signal containing the unwanted and desired portion.

The third signal is then obtained by combining the first and second signals so as to provide the removal of the desired part, whereby the third signal is a substantially pure interfering sound and / or echo signal. If the first and second signals have a similar desired part and the phase of their undesired parts is different and also differs from the phase of the desired part, they can simply be reduced, i. the second phase can be changed by 180 °, after which the signals are combined.

• »· Λ 3 62921 Such signals can be obtained, for example, from a microphone unit comprising two microphones or microphone means whose sound-responsive elements are equally exposed to the desired sound because they are placed side by side and very close together due to the deviation of unwanted parts from different sources and possibly variations on these. The first and second signals, on the other hand, can be obtained in any suitable manner, and the invention does not preclude adjusting the second or both in terms of phase and / or amplitude before combining, so that the signal is given a suitable shape.

The desired signal, consisting essentially only of the desired part, can then be obtained from the fourth signal in the second combining step, after possibly processing the third and / or fourth signal, which may be necessary to make the unwanted part of the fourth signal similar in amplitude. and opposite to the phase than the third signal. When the first and second signals are as described, it is easy to simply combine them so that the amplitude of the desired part is effectively doubled in the fourth signal and the resulting unwanted part is forced to vary by 90 ° in phase compared to the third signal. Then only a 90 ° phase shift is required, together with a suitable gain or attenuation, before combining the third and fourth signals to obtain the desired output signal. Apparently, the fourth signal could be just one of the first and second signals or a completely independent signal obtained from a separate microphone. To achieve the required output ratio between the third and fourth signals, phase and / or amplitude adjustment of one or both is performed before the signals are combined to obtain the desired output signal. Conventional circuit arrangements can be used to perform the required phase and amplitude adjustment and to provide the required combinations of different signals.

The method and device according to the invention have developed effective measures for removing interference sounds and acoustic feedback from the microphone output signals, and in order to obtain the best results, these electrical arrangements are combined with mechanical or physical measures as disclosed in Finnish patent application 3071/74. The two microphone means then preferably have similar sound-responsive elements or membranes which are independently mounted very close to each other in the housing so that they can generate substantially similar output signals as a result of housing vibration and random input sound and echo. Preferably, the direct acoustic feedback is also reduced by arranging the sound waves from the speaker means to run parallel to the two sides of each microphone diaphragm so that the output signal due to the movement of each diaphragm is substantially free of components provided by these direct sound waves. In addition, the conductive feedback can be reduced by means of a laminated or multi-material housing structure, which is described in Finnish patent application 3071/74. Combining these measures po. with the circuit according to the invention can lead to an almost complete elimination of all forms of said acoustic feedback.

The invention will be better understood from the following illustrative description taken in conjunction with the accompanying drawing, in which:

Fig. 1 shows in the form of a block diagram a circuit diagram of a device according to the invention and a converter unit connected thereto; and Figures 2-5 show schematic views of the phase and amplitude of the signals present in the circuit of Figure 1.

The circuit device according to the invention is shown in combination with a converter unit comprising one or more speakers represented by one speaker 12 and two microphone means, each containing one or more microphones and each represented by one microphone 14 and 16. The microphone and speaker means can be used close together, whereby they can be mounted in a common housing 10, as shown. Figure 1 shows only schematically the relative placement of the speaker 12 and the microphones 14 and 16, and in practice they should be encapsulated and positioned so as to reduce acoustic feedback as described above.

In the device of the invention, the output signals of the two microphones 14 and 16 are connected to both an increasing circuit element 20 and a reducing circuit element 22, each of which is a transformer or a differential amplifier. The added and subtracted output signals are then passed through the phase and amplitude control or control means 24 and 26, respectively, and then combined, either simply or repeatedly, in a second circuit element 26, which may be an amplifier as shown, to further transmit the electrical output signal. Each of the various circuit elements 20-26 is in itself conventional and preferably adjustable and is designed to be either pre-adjusted or controlled from outside the unit.

The output signal of the displayed device and the input signal of the speaker 12 and its combined amplifier 28 can be connected, if necessary, via the displayed hybrid 30 to a line and thus to a similar device in the remote 62921 position. The automatic power control circuit 32 shown may be included to control amplifiers 28 and / or 26.

The operation of the device shown in Figure 1 is shown in Figures 2-5. Each of the microphones 14 and 16 produces an output signal, shown in Figures 2 and 3, respectively, which contains the desired part or signal S caused by a sound generated far away from the device, usually the speech of a person using the unit. The parts S of the output signals of the microphones can be considered to have the same effect in all respects. In addition, each output signal contains an unwanted part or interference sound caused by sound coming from the speaker. The interfering sound portions N1, N2 differ in phase and amplitudes from each other and from the signals S, as shown. The circuits 20, 22 combine and subtract the output signals of the two microphones, respectively. According to Fig. 4, the output signal of the circuit 20 includes a signal S doubled in amplitude and an interference audio signal N 1 + 2 »which is the sum of the parts N 1 and N 2. The signal S is substantially absent from the output signal of the circuit 22 shown in Fig. 5, but has an interference signal result N 1 - 2. Thus, an analysis of the output signals of the microphones and a difference of the part N 1 - 2 representing a substantially pure interference sound has taken place. The signal from either can thus be released from its interference section by processing the pure interference signal from the circuit 22 appropriately in terms of phase and amplitude so that it is similar to this interference section. The pure interference signal has a practically unchanged ratio to the interference sub-signals N1, N2 and the interference signal sum N1 + 2, which is of course 90 ° out of step with respect to this. Thus, it can be easily treated to be similar to one of the signals N 1, N 2 and N 2 + 2. In the device shown, the interference signal sum N N 1 + 2 »and then added or combined with the output signal of circuit 20 in amplifier 26, as shown in Figure 1. Gain and phase shift can, of course, be further or alternatively coupled to the output signal of circuit 20 to provide output signals to amplifier 26 at this desirable ratio, and a second circuit 24 may be placed between the amplifier of circuit 20 for this purpose, as shown in Figure 1. The output signal of the amplifier 26, which forms the output signal of a conventional microphone, is thus substantially free of components produced by interfering sounds from the speaker.

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Claims (11)

A method for canceling acoustic feedback between a microphone arrangement (14, 16) and a speaker arrangement (12) electrically connected to each other, wherein the two microphones (14, 16) are arranged to form a first and a second electrical signal, respectively, which each comprising a desired component and a detrimental feedback component, characterized by the steps of: separating the first and second signals to form a third signal dependent only on the feedback component, deriving a fourth signal containing the desired component and the detrimental feedback component used in the speaker system 12 , adjusting the phase and / or amplitude of the third and / or fourth signal to match the harmful component of the third signal and the fourth signal, and generating a difference between the adjusted third and fourth signals so as to remove the feedback component. i from the fourth signal. Method according to Claim 1, characterized in that the first and second signals have the desired components in substantially the same amplitude and phase and, accordingly, harmful components which differ in phase from the desired components and in amplitude and / or phase. Method according to Claim 1 or 2, characterized in that the fourth signal is derived from either the first or the second signal. Method according to claim 1 or 2, characterized in that the fourth signal is derived from the first and second signals. A method according to claim 4, characterized in that the fourth signal is obtained by adding the first and second signals to each other. Method according to one of Claims 1 to 5, characterized in that it comprises at least one repetition of the steps in order to further improve the cancellation of the acoustic feedback. 6,62921 An electrical circuit for carrying out a method according to any one of claims 1 to 6, characterized in that it comprises first circuit means (22) for subtracting the first and second signals to form a third signal, second circuit means (24) for the third and / or fourth signal phase and / or or adjusting the amplitude to match the third signal and the detrimental component of the fourth signal, and third circuit means (26) for subtracting the adjusted third and fourth signals so as to form a fourth signal containing only the desired component for use in the speaker arrangement (12). Electrical circuit according to claim 7, characterized in that the first circuit means (22) comprise a transformer. Electrical circuit according to claim 7, characterized in that the first circuit means (22) comprise a differential amplifier. An electrical circuit according to any one of claims 7 to 9, characterized in that it comprises fourth circuit means (20) for summing the first and second signals to form a fourth signal, the second circuit means (24) being arranged to shift the phase of one of the third or fourth signals by 90 °, that the phase difference between the third signal and the harmful component of the fourth signal is 180 °. An electrical circuit according to claim 10, characterized in that it has an automatic gain control circuit (32), the inputs of which are connected to the outputs of the first (22) and fourth (20) electrical circuit means, a summing amplifier (26) receiving the output of the second circuit means (24). after processing the second and third signals, and further, an amplifier (28) acting as a power amplifier connecting the microphone and speaker arrangements, the output of the gain control circuit (32) being connected to the summing amplifier (26) and / or the power amplifier (28) . 62921 8