JPS634986B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a howling prevention device used in conference telephones and the like.

Conventionally, a border is generally used in this type of device. Bordas uses a voice switch, which compares the levels of the transmitted signal and the received signal, and selectively passes the signal with the higher level, while the signal with the lower level does not cause howling. This provides attenuation of . When such a voice switch is used, there is a drawback that when a simultaneous two-way call is made, the signal is necessarily cut off (or attenuated), resulting in the call being interrupted. Even in the case of a one-way call using only the received signal, there is a drawback that the signal that has passed through the acoustic path to the transmitting path cuts off the end of the received signal, impairing the quality of the call.

Adaptive echo cancellers are applied to solve the above-mentioned drawbacks. An adaptive echo canceller is a pseudo signal that is output from the receiver circuit to the transmitter circuit via a transversal filter with a variable tap coefficient, and a loop signal that appears from the receiver circuit to the transmitter circuit via the acoustic path. The tap coefficient of the transversal filter is modified so as to minimize the residual signal appearing at the output of the subtractor. When the modification of the tap coefficient is completed,
The tap coefficient represents the impulse response of the acoustic path, the residual signal is minimized, and howling can be prevented. However, at the start of operation, it is naturally difficult to prevent howling.
Separate controls are required to counter this. Also,
Since the tap coefficients are corrected by considering the acoustic path as linear, if the listener speaks while the tap coefficients are being corrected, the tap coefficients will be incorrectly corrected. Even after the correction of the tap coefficient is completed, it is necessary to correct the tap coefficient according to changes in the acoustic path. Control is required to make a judgment based on monitoring or the like and to correct the tap coefficient only when a received signal arrives. Furthermore, it is difficult to perform these corrections accurately in an environment where normal room noise exists, especially in the high frequency range. Further, a circuit for calculating the amount of correction for correcting the tap coefficients using the residual signal is required. Therefore, the disadvantages are that the control is complicated and the scale of the hardware is large.

Furthermore, the power in the high frequency range of the voice is generally small, and the level difference between the indoor noise and the loop signal becomes small in the high frequency range, making it extremely difficult to modify the tap coefficient. This is because the spectrum of an audio signal drops by 10 dB per octave in the high range as shown by curves S or R in Figure 1, whereas the drop in the high range of indoor noise occurs by 10 dB per octave as shown in curve N in the same figure. This is because it is only about 5 dB per hit. Note that the indoor noise level is approximately 60 phon, and intersects the listening level curve R in the high frequency range. Therefore, suppression of the loop signal in the high frequency range is limited by this S/N ratio. In order to increase this S/N ratio, the caller must place his or her lips close to the microphone, and each conference participant must prepare the microphone close to their lips.

Further, FIG. 1 is a diagram showing an acoustic spectrum at a normal microphone position where a conference phone is used, where a curve S is a transmission level and a curve N is a room noise level. Further, curve R is the listening level, which is approximately 5 dB higher than the transmitting level. That is, the speaking level is 65 dB at a point 1 meter in front of the lips, while the listening level is about 70 dB. Therefore, if the received sound waves enter the microphone as they are, it will naturally cause howling, so the characteristics of the microphone should be made directional.
Moreover, it is difficult to sufficiently prevent howling even if the relative positional relationship between the speaker and the microphone is considered.

The purpose of the present invention is to solve the above-mentioned conventional drawbacks and
An object of the present invention is to provide a howling prevention device which has a simple configuration and is highly effective.

The howling prevention device of the present invention includes a variable delay line that delays a received signal, a pseudo acoustic path that outputs a pseudo feedback signal by multiplying the output signal of the variable delay line by a fixed tap coefficient, and a transmission line for a sending system. the impulse response characteristic of the pseudo acoustic path, the subtractor being inserted therein to subtract and output the output signal of the pseudo acoustic path from the detour signal, and a temperature-electrical conversion circuit outputting a voltage corresponding to the ambient temperature. is set in advance by a measured value, etc., and the temperature-electric conversion circuit and the variable delay line correct for a temporal change between the delay time of the acoustic path at the time of setting and the delay time of the acoustic path during use. It is characterized by

The present invention focuses on the fact that the propagation time of sound waves changes depending on the temperature of the medium, and achieves the above object by electrically correcting the delay time of the pseudo transmission path.

Next, the present invention will be explained in detail with reference to the drawings.

FIG. 2 is a block diagram showing one embodiment of the present invention. That is, the received signal 22 inputted to the receiving system input terminal 21 is inputted from the receiving system output terminal 23 to the speaker 24, where it is converted into acoustic energy and listened to by the listener 26. Further, the received signal 22 is branched and delayed by a variable delay line 212,
The signal is applied to the subtractor 210 through a pseudo acoustic path 213. The delay time of the variable delay line 212 is controlled by the output of the temperature-electric conversion circuit 215. The pseudo acoustic path 213 is constituted by, for example, a transversal filter, and is connected from the speaker 24 via the microphone 27 to the transmission system input terminal 28.
It is suitable for the impulse response of a detour signal transmission path (hereinafter simply referred to as an acoustic path), including electroacoustic conversion characteristics and air propagation characteristics. However, most of the delay time is due to delay line 2.
Match with 12. The impulse response of the acoustic path is not simple; the speaker 24, the sound field 2
5. Includes frequency characteristics, amplitude characteristics, delay characteristics, etc. of the microphone 27. A subtractor 210 calculates the difference between the wraparound signal input to the transmission system input terminal 28 and the output signal of the pseudo acoustic path 213.
It is output from the transmitting system output terminal 211. Therefore,
If the impulse responses of the delay line 212 and the pseudo transmission path 213 match those of the acoustic path, the residual signal will be small and howling will be prevented.

FIG. 3 shows an example of an impulse response of an acoustic path. That is, when an impulse as shown in _FIG .
The impulse response waveform of T _r appears. Most of the delay time T _d is based on the propagation time of the sound wave in the sound field 25 .

FIG. 4 shows an example of the configuration of the pseudo acoustic path 213. Register 42 includes variable delay line 2 (of FIG. 2).
The register 43 is a register that stores the twelve output signals 41, and the register 43 is a register that stores the impulse response of the acoustic path described above. registers 42 and 43
The contents of are multiplied by the multiplication circuit 44, and the multiplication results are accumulated by the accumulator 45. The output signal 46 of the accumulation circuit 45 is the output signal of the pseudo acoustic path 213 and is sent to the subtractor 210. Since the above configuration constitutes a general transversal filter with a fixed tap coefficient, the output signal 46 becomes a pseudo wrap-around signal that is the same as the wrap-around signal in the acoustic path. The impulse response can be stored in the register 43 by applying an impulse to the receiving output terminal 23 and accumulating the impulse response waveform appearing at the transmitting input terminal 28, as shown in FIG. 2, for example. but,
Measure the impulse response separately and register 4
By presetting to 3, it can be realized with simple hardware. In this case, even if the contents of the register 43 are erased due to a failure such as a power outage (as long as the data remains), there is no need to remeasure. Also,
Since it is also possible to perform measurements with the influence of room noise removed, more precise settings are possible.

Now, when the envelope of the audio waveform at the receiving system output terminal 23 is a waveform as shown in _FIG . An envelope that is slightly deformed depending on the characteristics of the road appears. delay line 2
The envelope of the 12 output waveforms appears after a delay time T' _d . This difference between the delay times T _d and T' _d can be solved by increasing the number of taps of the transversal filter in the pseudo acoustic path 213.
That is, the setting of the register 43 is determined for the period of the impulse response length T _r shown in FIG. 3 plus the difference in the delay time.
Making the difference between the delay time T′ _d and T _d small helps in constructing a more economical pseudo-acoustic path.

Now, we have set the upper limit of the frequency band of the howling prevention device.
Assuming 3400 Hz, the impulse response waveform of the transmitting system input terminal 28 is 8 kHz (the period is
125 microseconds).
Then, the sampled value every 125 microseconds is preset in the register 43 so as to correct the difference between the delay times _Td and _T'd . That is, the tap coefficient is fixed. If a telephone conversation is made in this state, the residual signal appearing at the transmitting system output terminal 211 is very small because the loop signal of the received signal is canceled by the output signal of the pseudo acoustic path. In other words, howling is prevented.

However, if the temperature at the time of impulse response measurement differs from the temperature during the actual meeting, the delay time T _d of the acoustic path changes, which equivalently shifts the tap of the transversal filter. That is, the residual signal output to the transmitting system output terminal 211 becomes large, and the howling prevention effect decreases. In this embodiment, a temperature-electrical conversion circuit 215 is used to control the delay time of the variable delay line 212 using its output signal 214, thereby preventing the howling prevention effect from decreasing due to temperature changes. The temperature electrical conversion circuit 215 can use a normal temperature sensor. Since the relationship between temperature and sound speed in the air is known, the change in delay time T _d relative to the temperature change is known,
It is easy to set the delay time of the variable delay line to be controlled by the above change. For example, the above control can be achieved by configuring the variable delay line 212 as a voltage-controllable variable delay line and selecting the output gain of the temperature-electric conversion circuit 215. Since the temperature changes extremely slowly, the above control can be performed with sufficient stability using a control system with a large time constant.

According to this embodiment, there is no need for a circuit that performs switch control by detecting the levels of the received signal and the transmitted signal, as in the past, and there is no risk that the end of the call will be cut off, ensuring good call quality. There are effects that can be ensured. Further, the variable delay line is controlled simply by measuring the air temperature, so the control is simple.

In addition, a circuit for detecting a residual signal due to only the received signal, a tap coefficient correction value calculation circuit for minimizing the residual signal, a tap coefficient correction circuit, and howling in the initial state until tap coefficient correction is provided. No control circuit or the like for prevention is required, and the amount of hardware can be significantly reduced. In addition, since it is possible to increase the impulse amplitude for impulse response measurement within the range where non-linear distortion from speakers, microphones, etc. occurs, it is possible to eliminate the influence of room noise and to measure impulse responses with high precision. This is possible, and therefore the howling prevention effect is also great. If the impulse response is measured during a time when indoor noise is low, accuracy can be further improved, and sufficient margin for howling prevention can be ensured even in the high-frequency range of the voice. Furthermore, since the characteristics of the pseudo acoustic path are not disturbed by simultaneous two-way communication, there is no unnatural noise in the pseudo loop signal, which has the effect of improving speech quality.

As described above, the present invention achieves great effects with a simple configuration.

In the above embodiment, the speaker, microphone, and temperature-to-electrical conversion circuit were explained as one each for convenience, but in an actual conference, multiple speakers,
If microphones are used, it is possible to provide corresponding pseudo lines and variable delay lines for each microphone. In this case, the temperature-electric conversion circuit may be used in common, or a plurality of them may be used to more precisely correct the delay time. Of course, these modifications are included in the present invention.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing an example of the acoustic power spectrum at the microphone position, Fig. 2 is a block diagram showing an embodiment of the present invention, Fig. 3 is a diagram showing an example of the impulse response of the acoustic path, and Fig. 4 is a diagram showing an example of the acoustic power spectrum at the microphone position. 2 is a block diagram showing an example of the configuration of the pseudo acoustic path of the embodiment shown in FIG. 2, and FIG. 5 is a diagram showing an example of the envelope of the audio waveform of each main part of the embodiment shown in FIG. 2. In the figure, 21...reception system input terminal, 22...
... Received signal, 23 ... Receiving system output terminal, 24 ...
Speaker, 25... Sound field, 26... Listener, 27
...Microphone, 28...Talking system input terminal, 41...
Output signal of variable delay line 212, 42, 43... register, 44... multiplication circuit, 45... accumulation circuit,
46... Output signal of pseudo acoustic path, 210... Subtractor, 211... Transmission system output terminal, 212...
...Variable delay line, 215...Temperature electrical conversion circuit.

Claims (1)

[Claims] 1 a variable delay line 212 that delays a received signal;
a pseudo acoustic path 21 that multiplies the output signal of the variable delay line by a fixed tap coefficient and outputs a pseudo wraparound signal;
3, a subtractor 210 that is inserted into the transmission line of the transmission system and outputs the result by subtracting the output signal of the pseudo acoustic path from the wraparound signal, and a temperature-electric conversion circuit 215 that outputs a voltage corresponding to the ambient temperature. The impulse response characteristics of the pseudo-acoustic path are set in advance, and the temperature-electric conversion circuit and the variable delay line are configured to compensate for changes in delay time between when the acoustic path is set and when it is used. Features a howling prevention device.