DE3733132A1 - Circuit arrangement for acoustic compensation of the ambient noise in the case of headphone (earphone) reception - Google Patents

Abstract

In known circuit arrangements for acoustic compensation of the ambient noise in the case of headphone reception, the ambient noise is picked up by means of a reference microphone arranged outside the headphones and connected to an interference-compensating filter. The negated filter output signal is superimposed in a loudspeaker on the useful signal, as a result of which it is possible to undertake a partial compensation of the ambient noise at the ear. Since the noise at the ear is generally not available for setting the interference-compensating filter, it has to be assumed that the acoustic transmission conditions are constant. Furthermore, the reduction in interference which can be achieved is limited, inter alia, by the relatively poor coherence between the microphone signal and ambient noise at the ear. A novel arrangement of the reference microphone inside the headphone on the one hand supplies a very good coherence, while on the other hand the microphone signal can be used as error signal for setting the interference-compensating filter. The undesired feedback of the loudspeaker signal is prevented in this case by means of a further compensation filter.

Description

The invention relates to a circuit arrangement for acoustic compensation of ambient noise Headphone reception according to the preamble of the patent saying 1.

From US-PS 29 72 018 is a circuit arrangement for acoustic compensation of ambient noise is known, where the ambient noise by means of an outside of the Headphone attached reference microphone recorded and this reference microphone signal to a compensation filter is fed. The filter output signal is from Useful signal subtracted. So there is an over in the ear storage of two noises with the aim of cancellation of ambient noise instead. With the proposed feast set compensation filter is however on not adapt to changed acoustic conditions or difficult to do. The problem is also Placement of the reference microphone outside the head listener. Because of the associated bad coherence between the ambient noise on the reference microphone and In principle there is only a slight interference suppression on the ear reachable.

The invention has for its object a scarf arrangement such that it is head  receiver reception and one with loud ambient noise significant reduction in the level of noise coming to the ear.

This object is achieved by an arrangement solved with the features of claim 1.

As a number of practical tests have shown, is interference compensation on the reference microphone (in un indirect proximity of the hearing input) almost the same significant with noise compensation on the eardrum (Bone sound) and sound transmission through the mouth remain unaffected because of their lesser influence inspects).

By returning and overlaying the microphone signals is set with a suitable setting of the interference component sationsfilter a partial extinction of the environment noise on the reference microphone. The through the Arrangement of the reference microphone occurring in the headphones Feedback of the speaker signal, and the result conditional cancellation or distortion of the useful signal, can be avoided by means of a compensation filter will. The compensation filter forms the Transmission path according to which from the loudspeaker, the Air distance from the loudspeaker to the reference microphone and the reference microphone. This means that from Loudspeaker originating signal component or Compensated for the useful signal in the feedback path.

The adaptive execution of the compensation filter allows an automatic adjustment to the existing one acoustic conditions.

The adaptive setting of the two compensation filters  according to claim 2 takes place according to claim 3 so that the variance of the filter input signal at the Störkompen sationsfilter or the variance of the microphone signal be minimized. This automatic setting of the Filter coefficient is preferably small or disappearing ambient noise or useful signal guided.

In a configuration of the circuit arrangement according to Claim 4, the compensation filter is not from entire speaker signal, but only from the useful signal fed so that at the input of the second interference compensa tion filter that recorded by the reference microphone Noise appears without a useful signal component. The setting of the compensation filter and the second interference compensation tion filter happens so that the variance at the input of the second interference compensation filter is minimal. The automatic setting of the filter coefficients preferably carried out continuously.

Is a according to the embodiment of claim 6 additional reference microphone outside the headphones arranged, so a further interference reduction on the first Reference microphone can be reached.

Further preferred embodiments of the fiction According circuit arrangement are in another patent state sayings.

The invention is based on the in the Described drawing embodiments described in more detail ben and explained. It shows

Fig. 1 shows a first embodiment with a arranged within the earphone reference microphone, and two compensation filters,

Fig. 2 shows another embodiment,

Figure 3 sationsfiltern. A first embodiment using two reference microphones and three Kompen,

Fig. 4 shows a second embodiment and

Fig. 5 shows an embodiment for the realization of the compensation filter,

Fig. 6 shows an embodiment for realizing the first compensation filter in the arrangements of Fig. 2 and Fig. 4.

Fig. 1 shows a first embodiment for an arrangement of a reference microphone RM within a headphone K after the ear input. To reduce the ambient noise n (t) at the reference microphone RM , the microphone signal r ₁ (t) is fed back via the first interference compensation filter H _x and is superimposed on the useful signal, ie the speech signal s (t) . The microphone signal r ₁ (t) contains not only the ambient noise n (t) but also the speaker signal emitted by the speaker L. Since a certain extinction or distortion of the speech signal s (t) would occur due to the feedback of the loudspeaker signal, a compensation filter H _{y is} provided which comprises the transmission path consisting of the loudspeaker L , the air gap from the loudspeaker L to the reference microphone RM and the reference microphone RM simulates and compensates the signal component originating from the loudspeaker L in the feedback path.

The two filters H _x and H _y can be implemented adaptively. The setting of the filter coefficients of the first interference compensation filter H _x takes place in such a way that the variance of the microphone signal r ₁ (t) becomes minimal.

With an automatic setting of the filter coefficients, this is preferably carried out when the useful signal s (t) is small or disappears. The setting of the filter coefficients of the compensation filter H _y is carried out in such a way that the variance of the input signal of the first interference compensation filter H _x becomes minimal. The automatic setting of the filter coefficients of the compensation filter H _y is preferably carried out with a small or disappearing ambient noise n (t) . The setting of the filter coefficients of H _x , H _y is indicated in Fig. 1 by the dashed line.

InFig. 2 is a second embodiment of the invention according circuit arrangement for acoustic compensation the ambient noise when receiving headphones darge poses. As with the inFig. 1 circuit shown order forms the compensation filterH _y  the transfer path from the speakerL, the air stretch from the speakerL to the reference microphoneRM and the reference microphoneRM consists. In contrast to in Fig. 1 circuit arrangement is the Compensation filterH _y  but not the whole sound speaker signal, but only from the useful signal(s (t)  fed. This will appear at the entrance of the second Noise compensation filter _x  that of the reference microphoneRM  recorded noise with no useful signal component. By appropriate setting of the second interference compensation filters _x  will partially wipe out the Ambient noisen (t) on the reference microphoneRM  reached.

The filters _x  respectively.H _y  can be done adaptively being the setting of the filter coefficients of the two  filter _x  respectively.H _y  be made such that the Variance of the input signalr _3rd (t) of the second interference component station filter _x  becomes minimal. The automatic on The filter coefficients are set continuously.

In Fig. 3, an embodiment for acoustic compensation of the ambient noise when receiving headphones is shown, in which a second reference microphone RM 2 is provided, which is located outside the headphones K. The microphone signal from the second reference microphone RM 2 is fed to a third interference compensation filter H _z and the filter output signal of the third interference compensation filter H _z is superimposed on the useful signal s (t) . In this way, further interference reduction on the first reference microphone RM 1 can be achieved in a simple manner.

The setting of the filter coefficients of the third interference compensation filter H _z can be carried out adaptively, _as can the setting of the filter coefficients of the filters H _x or H _y . The automatic setting of the filter coefficients of the third interference compensation filter H _z is preferably carried out with a small or vanishing useful signal s (t) . An extension to several reference microphones outside the headphone K is possible.

InFig. 4 is another embodiment using a second reference microphoneRM 2nd outside of HeadphonesK shown. With this circuit arrangement becomes the compensation filterH _y  not, unlike the inFig. 3 embodiment shown, of the whole Speaker signal, but only from the useful signals (t)  fed. The setting of the filter coefficients with the second reference microphoneRM 2nd connected third Noise compensation filterH _e.g.  can just like that  Setting the filter coefficients of the filters _x  respectively.H _y   be carried out adaptively. The automatic setting the filter coefficient is continuously checked in this way leads to the variance of the input signal of the second Noise compensation filter _x  is minimal. An extension on several reference microphones outside the headphonesK  is possible.

A transverse filter is preferably used for the three filters H _x , H _y and H _z , which is shown in FIG. 5.

The second interference compensation filter _x  is preferred in structureFig. 6 realized. It contains one Transversal filterH in the forward branch and another Transversal filter _y  in the return branch, whose Filter coefficients a copy of the set Filter coefficient of the compensation filterH _y  are.

The adaptive setting of the filter coefficients h ₀ , h ₁ ,. . . h _N can with the filter H _y z. B. according to the stochastic gradient algorithm (LMS algorithm) described in "Adaptive Filters, Structures, Algorithms and Applications" by ML Honig et al, Kluwer-Academic Publishers, 1984.

When adaptively setting the filters H _x , H and H _z , it must be taken into account that a transmission path occurs between the respective filter output and the error signal relevant for the filter setting. This requires a more complex adjustment process, as it is e.g. B. "Active adaptive sound control in a duct: A computer simulation" by JC Burgess, J. Acoust. Soc. Amer., Vol. 70, no. 3, 1981, pp. 715-726, for a similar problem.

Claims (10)

Is added 1. A circuit arrangement for acoustic compensation of the ambient noise at headset receiver, wherein by means of a reference microphone (RM) the ambient noise (n (t)) at which the reference microphone (RM) with a Störkompensationsfilter (H _x) and in which for Feedback of the reference microphone signal (r ₁ (t)) a loudspeaker (L) is provided, which superimposes the negated filter output signal on the useful signal (s (t)) , characterized in that the reference microphone (RM) is arranged inside the headphones (K) and that the reference microphone (RM) and a compensation filter (H _y ) are connected to the interference compensation filter (H _x ), whereby the signal component originating from the loudspeaker (L) is compensated in the feedback path. 2. Circuit arrangement according to claim 1, characterized in that the compensation filter (Hy) the speaker input signal is supplied and that the filtered and negated speaker input signal is superimposed on the reference microphone signal (r ₁ (t)) . 3. Circuit arrangement according to claim 2, characterized in that the filter coefficients of the filters (H _x , H _y ) are adaptively adjustable and that the setting of the filter coefficients of the interference compensation filter (H _x ) with a small or vanishing useful signal (s (t )) and the setting of the filter coefficients of the compensation filter (H _y ) at low or disappear the ambient noise (n (t)) . 4. Circuit arrangement according to claim 1, characterized in that a second interference compensation filter ( _x ) is connected to the reference microphone ( RM) , that at the input of the compensation filter (H _y ) the useful signal (s (t)) is present and that the negated Filter output signal of the compensation filter (H _y ) and the microphone signal ( r ₁ (t)) are fed to the second interference compensation filter ( _x ). 5. Circuit arrangement according to claim 4, characterized in that the filter coefficients of the filters ( _x , H _y ) are adaptively adjustable and that the setting is carried out continuously. 6. Circuit arrangement according to claim 2 or 4, characterized in that a second reference microphone (RM 2 ) is arranged outside the headphones (K) , that the second reference microphone (RM 2 ) is connected to a third interference compensation filter (H _z ) and that the negated filter output signal is superimposed on the useful signal (s (t)) . 7. Circuit arrangement according to claim 4, characterized in that the second interference compensation filter ( _x ) contains two filters (H, _y ), that the first filter (H) in the forward branch and the second filter ( _y ) in the feedback branch of the second interference compensation filter ( _x ) is arranged, and that the filter coefficients of the second filter ( _y ) are copies of the filter coefficients of the compensation filter (H _y ). 8. Circuit arrangement according to one of claims 1 to 7, characterized in that the first and third sturgeon _(x H, H _z) compensation filter, the two filters (H, _y) and the compensation filter (H _y) are designed as transversal filter and that the filter coefficients are adaptively adjustable. 9. Circuit arrangement according to claim 1, characterized in that the filter coefficients of the compensation filter (H _y ) are adjustable according to a stochastic gradient algorithm. 10. The circuit arrangement according to claim 6, characterized in that further reference microphones are arranged outside the headphones (K) , each of these reference microphones being connected to a further filter filter, whose negated filter output signal from the useful signal (s (t)) is superimposed .