NO874509L - DEVICE FOR IMPROVEMENT OF SIDE TONE IMPROVEMENT UNLESS LOOP ENHANCEMENT BY TWO-WAY COMMUNICATION DEVICES. - Google Patents

Description

The present invention relates to a device for improving side tone damping or loop amplification of the type stated in the introduction to claim 1.

In a known circuit arrangement of this kind which is preferably intended for two-wire or four-wire amplifiers in telecommunications lines, preferably telephone lines for the transmission of telecommunications, both contain current paths for providing a feedback-free transmission of one or more electrical filters, e.g. bandpass filter, whose permeability lies within a frequency band necessary for telecommunication transmission, and which is distributed so that the permeability area of the filter of one transmission path coincides with the carrier area of the filter of the other path, so that the frequencies associated with the telecommunications of one the direction is mostly suppressed by the one that is let through in the other direction. The filter can thereby be designed so that each individual filter for one of each current path can be permeable to several frequency bands.

In the case of a similar circuit for electroacoustic transmission systems, preferably two-way communication devices, it is further known to keep the transmission paths free of filter devices or equalization devices at up to a certain amplification designated as critical level, from which self-generation will usually occur by acoustic feedback. If the above-mentioned level is exceeded, however, the transmission channels must be connected so that only specific frequency bands are transmitted, which in turn are distributed among the channels that form the transmission paths in the above-mentioned manner, so that one channel is blocked for respective bands to be transmitted from others and vice versa.

In the working principle of known two-way communication devices, it must in principle be taken into account that there is a danger of self-generation in the case of electrical and acoustic coupling between both transmission devices, but quite simply, the electrical couplings can be largely brought under control by corresponding appropriate coupling devices, e.g. . when using a four-wire line, while with the two-wire connection the line impedance in the speech circuit is approximated by means of a variable complex resistance as line balance.

Otherwise, it is not possible to eliminate the acoustic coupling to a large extent, and special measures are needed to control this coupling. It occurs when a circuit is partially closed by noise picked up by the microphone of one speaker, e.g. in that in the case of a two-way communication device system with separate voice channels, the noise signal from one speaking location reaches back to the speaker at the output location via amplifier, speaker to the opposite location, the microphone to the opposite location, and its amplifier, each time converting the noise effect into electrical effect and vice versa, and finally can it affects the microphone of the output point.

Thus, in principle, by using two separate transmission paths, it is possible to avoid for both transmitters and receivers (four-wire connection) the electrical coupling of the transmitter and receiver signal at the speech circuit in the telephone set (cf. 1984).

An acoustic feedback due to a misaligned bridge or interference due to electrical side tones therefore no longer takes place. Quite simply, echo conditions and feedback resistance when using free-talk devices are not improved with this device.

It is also known (DE-OS 2 813 432 and DE-OS 2 811 065) to disconnect the approximate transmitter and receiver signal with a two-wire connection theoretically similar to the use of a four-wire line by means of a so-called adaptive fork. This takes place with the help of the already mentioned variable, complex resistance, which approximates the line impedance as a line balance. However, only an improvement in the electrical side tone damping is provided here, and an acoustic feedback is avoided in the case of a misaligned bridge.

In this context, it is also known to suppress the spatial transfer function by means of an echo compensation, Cf. the article by Zelinsky "Eine Analyze des transienten Ver-haltens des LMS-Algorithmus bel Filteranwendungen in der Raumakustlk", 5th Aachener Kolloquium, Tagungsband, pages 239 to 240, an article by Becker, Schultheiss and Hensler, "Probleme bel der Kompensation austischer Echos ", journal frequency 36, 1984, pages 142 to 148. With the help of such echo compensation, the speaker signals and the room echo that occurs due to reflection of the noise by walls are suppressed. In addition, the loudspeaker signal is filtered with the inverse spatial transfer function and finally subtracted from the microphone signal. The filtering takes place using a transversal filter, the coefficient of which must be set using a suitable error measure. The setting must be adaptive, as the room transfer function changes with any change in the room (movement of the speaker). Moreover, the balance of the fine structure of the spatial transfer function must be very accurate so that the greatest possible echo attenuation can be provided for all frequency ranges. This requires transversal filters with a length of 2000 to 4000 coefficients, which must be constantly readjusted. It is possible to provide a gain of 10 to 30 dB. Problems with equalizing the transversal filter arise especially when the additional noise source is in the room. The same method (filtering with an inverse spatial transfer function) can be used for echo cancellation of the conversation microphone. A realization of such a method has not yet been possible.

All known measures and proposals have in common the essentially insufficient compatibility with existing telephone networks associated with clearly reduced tone coloring in speech understanding.

Problems arise here in particular when at least one so-called free speech device participates in an existing speakerphone connection, i.e. where the signal received by a subscriber from the other subscriber is radiated freely over a loudspeaker in the room, and this subscriber produces his own communication at a corresponding distance from the microphone acoustically, e.g. as he moves around the room. In this case, an unpleasant echo-like impression occurs at the loud speaking location alone due to the room reflection, which is recorded by the microphone of the free speech device.

If such a two-way communication device connection consists of two long-distance conversation devices, the loop gain for the individual frequencies 1 depending on the set speaker power can become VS>1, which is known to lead to so-called feedback piping.

In the following, some of the terms often used in the description of the invention are defined in more detail. The expression "side tone attenuation" is understood to mean the attenuation that can be registered when, during transmission from microphone to telephone, the same measurement object is heard, e.g. a telephone set with a certain termination impedance relates the expression at the earphone that occurs and the (transmitting) sound pressure on the microphone.

A two-way communication facility enables the acoustic connection of at least two participants using electroacoustic converters, as it is possible to have a conversation in both directions at the same time. As a rule, microphones are used as sound recorders, earphones or loudspeakers are possible as sound transmitters, as the most common form of a two-way communication device is a telephone.

The mentioned sidetone attenuation can be divided into an electric sledtone attenuation, which e.g. at a telephone set is limited by the only rough approximations of the complex line impedance in the bridge circuit (forked circuit) of the telephone device, which usually results in an unbalanced bridge, whereby the audio signals picked up by the microphone are passed on to the telephone receiver of the same telephone and in acoustic sledtone attenuation.

This previously precisely defined acoustic sidetone attenuation is limited by the recording of the sound radiated from the reproduction converter through the microphone. If the telephone device consists of a stand-alone speech device instead of normal hand-held devices, the reproduction takes place over a loud speaker, then the side tone attenuation is reduced when the sound is fed to the microphone of one participant with the sound signal reproduced from the other participant via the loudspeaker, the side tone attenuation is therefore less, which corresponds to a reinforced side tone possibly accompanied by a feedback beep or the like.

The object of the present invention is to design a two-way communication device of the type mentioned at the outset by means of a structure and special arrangement and design of the filter so that speech intelligibility is improved to a considerable extent, especially by the fact that tone coloring becomes negligible when using special filter structures, and especially by in noisy environments, speech understanding is significantly improved, regardless of whether you are working with a normal hand-held telephone or a loud-speaking device.

The task solved by the present invention has the advantage that with the improvement of the side tone attenuation ensured according to the present invention and the simultaneous increase of the possible loop gain also in noisy environments and especially in the case of loud speakers, even when this is present at both ends of the transmission path, a speech understanding that differs significantly from the systems known to date. With an existing telephone connection, it is also possible to arrange a filter according to the present invention without compatibility problems arising here.

The invention makes it possible to increase the loop amplification in a sensible way without the microphone signals to the same participant device being amplified at the same time.

Also in the case of complete misalignment of the bridge circuit, which can occur in the case of a non-central when separating the handset from the public line, when using the invention the side tone attenuation is so great that no acoustic side tone coupling can occur.

With the help of the invention, it is possible to avoid the negative, echo-like impression that occurs at a called station when, on the other side, a conversation is made with a telephone subscriber who uses a loud-speaking device.

With the help of the present invention, it is possible to suppress the unpleasant feedback plpetone when the loop gain for the individual frequencies, depending on the set loudspeaker power, is greater than V$>1.

The invention then uses as a starting point for enlarging the acoustic or electrical side tone attenuation in a two-way communication device the knowledge, and builds on this, that the human hearing is subjected to incident sound signals in a special way by means of a power density analysis. The signal transformed acoustically from the outer ear over the middle ear into the inner ear forms specific filter patterns on the basilar membrane comparable to a third analysis, so that individual loudness impressions are recorded approximately at third distances from the respective third intermediate frequencies, which are known in and of themselves and described in the book " Psychoacoustics" by E. Zwicker, Springer-Verlag 1982.

If the basilar membrane is affected by a sound signal in a particular way, the hearing is no longer able to observe this, depending on the level of a single tone whose frequency is close to an intermediate frequency. The effect is termed in psychoacoustics as so-called covering and is in and of itself known and described in the book "Das Ohr als Nachrichten-empfanger" by E. Zwicker and R. Feldtkeller, Hirzel-Verlag Stuttgart 1967.

Both of these special psychoacoustic properties of hearing enable the division of both speech paths of a two-way communication device into different frequency bands formed specifically by means of the present invention. The signals are filtered using band-stops to widths corresponding to less than 1/2 teras. The band barriers are further arranged in non-harmonic distances, and as the attenuation target of the barrier area is increased with increasing frequency. In this way, it is possible on the one hand to prevent a feedback beep at higher frequencies and on the other hand to ensure that the timbre is not perceptibly affected in the voice fundamental frequency range of the human.

With the help of the measures listed in the sub-requirements, it is possible to make advantageous further designs or improvements to the devices specified in the main requirement. Speech understanding thus increases further when the respective spectral parts, which are in the speech range, are shifted by means of a frequency shift in the upper or next adjacent pass-through range, and the pass-through spectral parts are added in addition. The leading and blocking area of the band pass, which has been used as a filter in the invention, has constant distances (not harmonic distances) either in a linear or logarithmic frequency scale.

In what follows, the invention will be described in more detail with reference to the drawings, where:

Fig. 1 shows in the form of a block diagram a sending and receiving device for Duplex operation. Fig. 2 shows a block diagram of the structure of a common telephone device. Fig. 3 shows, in the form of a diagram, the attenuation over the frequency of a preferred embodiment of the transmission filter used by respective participants of the two-way communication device in relation to the offset position of the blocking and conducting area. Fig. 4 shows the possible circuit structure of a filter for an existing analogue network. Fig. 5 shows the overall structure of a filter embodiment with means for shifting the signal portion in the spectral range to a blocking range in the frequency range in front of it and in the following frequency range. Fig. 1 shows the call point 10 of the participant A and the call point 11 of the participant B. Between the call points is the transmission path formed by the respective end-side channel encoders/decoders 8a, 8b and the actual transmission or transmission path (wireless or by a corresponding wired connection) .

On each side of the two-way conversation connection, which in the embodiment shown can be a telephone device or a loudspeaker device, the same connection components are located so that only the structure of the device 10 will be described in more detail. A microphone Ml is arranged which transforms the sound signals from a participant to the electrical output signal SM1(t), which signals reach a first switching device, namely a switch 3a. The loudspeaker or telephone receiver is denoted by LI and receives the signal SLi(t) over different line connections, as described further below. Loudspeaker microphones are connected with a first filter 1a and a second filter 2a, which respectively have different conduction and blocking ranges, which will be described in more detail below. A central transmitter and receiver circuit 10a is also arranged, which is in immediate connection with the respective direct output or input-side arranged channel encoders/decoders 8a and controls a further decoder 11a, which connects all four simultaneously to the respective telephone stations (calling stations) hearing switches 3a, 4a, 5a and 6a to respective other positions.

The call points (telephone stations) for the subscriber B are identically structured, and the reference numbers for the respective circuit components of the call point 11 are denoted by index "b".

The circuit components 1a, 2a, 8a, 10a, 1a are connected to each other via various line connections which are necessary to ensure a connection with the vertices 3a, 4a, 5a and 6a, so that the call path can be weighted by means of previously given transfer functions , while the acoustic and electrical sidetone attenuations can be described using different transfer functions.

Fig. 2 shows a circuit diagram of a normal telephone conversation device, the sender/receiver block 10a being designed only as a known fork circuit 10a', 11b' and therefore the following functional descriptions are valid for both embodiments.

The position of the switch in the one in fig. The position shown in Fig. 1 and Fig. 2 ensures that different transmission functions are always present on the one side for the conversational path, and on the other side for the acoustic and electrical side tone attenuation.

Then, as previously mentioned, the switch position is determined by the decoders 11a, 11b, these are designed so that, depending on whether the respective participant calls or is called, which is possible to distinguish using a decoder without problem, if a specific switch position, which for both of these cases is different so that it appears for one participant A, who is here assumed to be the calling participant, a different switch position than that for participant B.

In the assumed case and at the now predetermined switch position, the microphone signal to the participant A therefore proceeds over the line Lia and the branch line Lia' to the filter la with a filter characteristic given in advance (transfer function), and from this over the switch position shown in the figure to the switch 4a to transmitter/receiver 10a via the channel encoders/decoders 8a, 8b to transmitter/receiver 10b to participant B, and from the receiver side via the connection line L2b with the branch line L2b' to the filter lb, which has the same filter properties and therefore the transfer function as the filter la (both denoted as the filter X). From the filter lb, the signal then goes via the line L3b to the speaker or handset L2 of the other participant B.

On the other hand, a sound signal from the microphone M2 to the other participant B in this context picked up, i.e. from the loudspeaker or telephone handset L2, is reproduced at this position to the inverter 3b via the filter 2b (the filter with the transfer function or filter characteristic Y). The audio signal continues from this via the line L4b to the transmitting area of the transmitter/receiver block 10b via the transmission path to the receiver transmitter/receiver block 10a, from this at the switch position to the inverter 5a via the filter 2a (transfer function Y) and from this to the earphone or loudspeaker LI . It appears that the transfer function is different on the one hand for the conversation path and on the other hand for the acoustic and electrical sidetone attenuation.

The size of the transfer function H^(f) to the filter X as well as H2(f) to the filter Y is shown by X and Y in fig. 3, as the frequency is recorded on a logarithmic scale.

As already mentioned and as can be seen from what is shown in fig. 1 and fig. 2, there are two filters 1a, 2a and 1b, 2b respectively in each two-way conversation device, as well as respective filters X and Y with presumably different transfer functions Hi(f) and H2(f), the course of the filter curve being exactly the opposite, i.e. the conducting range of one filter X corresponds to the blocking range of the other filter Y and vice versa. Both filters are connected as needed in the signal path for the telephone receiver or speaker or for the microphone.

In the design example in fig. 2, the filter device can be controlled via the switch, e.g. by means of distribution of the ringing tone of a telephone, which reaches via the fork circuit 10a', 10b' to the respectively assigned decoders 1a', 11b', i.e. the calling participant (in the drawing participant A) then has in the signal path to the microphone the filter X with the transfer function Hi(f) and in the signal path of the telephone receiver or speaker the filter Y with the transfer function ^(f). At the called participant, the assignment takes place exactly the other way around, so that the call path is weighted using the transfer function Hs (f)

while the acoustic and electrical sidetone attenuation is weighted accordingly using the transfer functions Har(f) and Her(<f>)<:>

with A(f) and B(f) describing the respective relevant acoustic and electrical sidetone attenuations without filtering.

For realizing the filter transfer function Hi(f) and H2(f) in a digital telephone call connection, as shown in fig. 1 e.g., one can proceed so that the short-time spectra are formed from the sensed signals with the help of the Fast-Fourier transformation. The corresponding frequency coefficient is set to zero before the back transformation, so that in addition to the desired filter effect, a further desirable data reduction also occurs.

From the course of the filter curve, i.e. the transfer functions Hx(f) and H2(f) to both filters X and Y (fig. 3), it appears that, based on special psychoacoustic properties of hearing, both speech paths of the two-way conversation device are divided into two different frequency bands, since the signals is filtered using the bandstops with a width of 12, which is less than 1/2 terass, as the bandstop is located at non-harmonic distances and the further the attenuation magnitude in the blocking area is increased with increasing frequency, which is shown by the somewhat significant increase in attenuation at frequencies above 1000 Hz .

It must be expressly pointed out that the respective leading and blocking areas of the bandpasses, of which the filters X and Y consist, are neither linearly nor in a logarithmic frequency scale constant distance, and the composite filter curve progressions in fig. 3 must therefore not be understood quantitatively, but only quantitatively indicates a possible embodiment example of a transfer function respectively.

The principle of such a filter can have the appearance shown in fig. 5. Several bandpass filters BP1, BP2, ... BPn-1, BPn are arranged, as in fig. 5 is provided with the reference numbers 17 and 18, respectively, whose outputs are summarized in a summation unit 20, without going into the intervening blocks 19 here.

With a corresponding layout of the bandpass filter with an increase in the attenuation size of the cut-off range with increasing frequency, the feedback whistling that may occur at higher frequencies is reduced, but otherwise the tone color in the human voice fundamental frequency range remains practically unaffected.

In order to further prevent the spectral components of the tonal portion from being filtered out, such a filter, as shown in fig. 5, be designed so that the filtering takes place by means of a filter with a static and thus random order of the guide areas (filter 17 in Fig. 15) and the blocking areas (filter 18 with subsequently connected blocks 19). Thereby, the signal parts, which lie in the spectral range of a blocking range (bandpass filter 18), can be shifted into the frequency ranges lying in front of the frequency axis and behind, and then with the help of per se known frequency shifter units 19, which are connected after the bandpass filter 18. With other In other words, it is not necessary in this area of analog technology with bandstops, but the spectral parts that are passed through by the bandpass filter 18 are only shifted in the pass-through area lying in front or behind.

In this method of filtering by means of band-pass filters 17 and 18 and the frequency shift unit 19, the band-pass filter 17, 18 can have a width corresponding to 1/8 ters and take place at 1/8 ters intervals. The frequency ranges for further transmission, which are to be blocked by means of the filter, reach through the effect of the frequency shift unit into the pass-through range of the filter and are added to the pass-through signal portions at 20.

For a specific analogue network, an e.g. approximate realization of the filter with an equalization circuit, as shown in fig. 4, by which in a here valid frequency range of e.g. 300 Hz to approximately 4KHz twelve reducers in the form of a on a coil L, a resistor R and a capacitor C formed series circuit are connected in parallel. The series circuit can e.g. have a goodness of 20 and an attenuation of 20 dB.

In fig. 4, two successive operational amplifiers 12 and 13 are arranged, the reducer 16 being located in the feedback branch of the second operational amplifier. Such an equalization circuit is of ordinary construction and is therefore not described in more detail here.

Investigations by hearing tests have shown that, with the help of the invention, tone coloration practically does not occur, and the gain in speech intelligibility is also significantly positive in noisy environments. By the problem-free integration of the filter into existing voice connections, it is therefore possible to provide a significant improvement without compatibility problems arising.

All the features shown in the description and the subsequent claims and in the drawing can thus be individual which, also in arbitrary combinations with each other, can be essential to the invention.

Claims (16)

1. Device for improving side tone attenuation or loop amplification in two-way communication devices, with at least one, respectively, inverse transfer function-forming filter at each voice station of a general comb-filter-like structure and relative to each other offset conducting and blocking areas, characterized in that the conducting and blocking area of those in relative to each other, inverse filters are in a non-harmonic relationship to each other and have an increasing blocking attenuation with increasing frequency, so that only the energy parts relevant to tone formation and speech understanding are transmitted in respective frequency groups corresponding to human hearing, since the energy parts that do not contribute to speech understanding due to pre-, post- and simultaneous coverage is omitted. 2. Device according to claim 1, characterized by that the respective conducting and blocking areas of the filter (la, lb; 2a, 2b) are less than 1/2 thirds and have non-constant distances (12) referred to both linear and logarithmic frequency scales. 3. Device according to claim 1 or 2, characterized in that, simultaneously with the features according to claim 1 or 2, the amplification of the transmitter-side signals and/or the important signals of the telephone hearing capsule is raised to improve the signal-to-noise ratio and to suppress the feedback effects and the echo feeling in loud-speaking telephones . 4. Device according to one of the claims 1 to 3, characterized in that the respective spectral parts, which lie in the blocking area of the filter (la, lb; 2a, 2b) are displaced into the next adjacent conducting area by means of a frequency shift and are additionally let through. 5. Device according to one of claims 1 to 4, characterized in that by arrangement of respective two filters (la, 2a; lb, 2b) with respective inverse transfer functions (Hi(f); H2 (f)), which are arranged in such a way that when calling participant in the signal path of the microphone is arranged a filter (X) with a first transfer function (Hj _(f)), and in the signal path of the telephone receiver or loudspeaker (LI) is arranged a filter (Y) with the second transfer function (H2 (f) ) with the assignment changed when called party, as the respective voice paths are defined using the transfer functions: with an emphasis on the acoustic and electronic sidetone attenuations using the transfer functions: 6. Device according to one of the claims 1 to 5, characterized in that each speaking location has a decoder (lia, 11b), which registers whether it is a caller or a called party, and which by corresponding connection of the filter (la, lb; 2a , 2b) connects in the respective transmission paths from the microphone (Ml; M2) to the telephone receiver or speaker (LI, L2) to the respective other participant. 7. Device according to claim 6, characterized in that the decoder (11a, 11b) affects the switch (3a, 4a, 5a, 6a; 3b, 4b, 5b, 6b), which is designed so that they switch in the respective signal transmission paths from the microphone (Ml) to one participant to the other participant's loudspeaker (L2) respectively, from the other participant's microphone (M2) to one participant's loudspeaker (LI) filters of the same type (X respectively Y) in series, so that both the low-tone attenuation between the microphone and the handset respectively speaker to the respective participants, which also increases the total loop attenuation due to the coincidence of filters of different types (X with Y). 8. Device according to claim 6 or 7, characterized in that in the telephone network the control of the decoder (Ila', 11b') takes place by ring tone and supply via the fork circuit (10a'f 10b'). 9. Device according to one of the claims 1 to 8, characterized in that the available transmission channel capacity as a result of the suppression of the Irrelevant energy share for speech understanding is utilized by the respective output side of each speech location arranged channel encoder/decoder (8a, 8b; 8a', 8b ') for an increase in bandwidth, dynamics and transmission security. 10. Device according to one of claims 1 to 8, characterized in that each filter consists of a predetermined number of bandpasses (BP1, BP2 ... BPn-1, BPn) and that certain of the bandpasses (18) connected after the frequency shifter units (19 ), which is thereby shifted for the further transmission through the blocked frequency range of the filter into the pass-through range of the adjacent bandpass and added to the pass-through signal portion. 11. Device according to claim 10, characterized in that the outputs of all band passes (17) and all specific band passes (18) connected after the frequency shift unit (19) are fed to a common summing unit (20). 12. Device according to one of claims 10 or 11, characterized in that the filter (la, lb; 2a, 2b) has a static (random) sequence of guide areas (17) and blocking areas (18/19). 13. Device according to one of claims 10 to 12, characterized in that the bandpass filter (17, 18) has a width corresponding to 1/8 ters and is arranged with 1/8 ters distances. 14. Device according to one or more of claims 1 to 13, characterized in that for the realization of respective filters, reducers of a series circuit consisting of a coil (L), a resistor (R) and a capacitor (C) are parallel-connected in relation to each other and arranged in the feedback branch of an amplifier (13). 15. Device according to one of claims 1 to 14, characterized in that the filtering with the filter (X, Y) takes place with static and thus random sequences of guide areas and blocking areas. 16. Device according to one of claims 1 to 15, characterized in that for filtering with digital telephone connections, the short-term spectrum of sampled signals is formed by means of the Fast-Fourier transformation and the respective corresponding (corresponding frequency bands that are blocked) frequency coefficients are set to zero.