JPS62154825A - Frequency companding system - Google Patents

Abstract

PURPOSE:To reduce loop gain and to suppress effectively the generation of howling by shifting the position of a peak point of frequency spectrum in an output signal to low or high frequency. CONSTITUTION:Samples included in a frequency spectrum obtained by converting a signal sequence in a time area into a frequency area component by discrete Fourier transformation with the optional number of points and prepared differently from the number of samplies in the original discrete Fourier transformation are recomposed to a complex conjugate sequence consisting of the same number of samples as the original descrete Fourier transformation and the reverse discrete Fourier transformation of the recomposed sequence is executed to obtain an output signal. Accordingly, a signal spectrum can be companded by a simple constitution. The prevension of hawling in an audio conference device can be simply attained by using the system.

Description

[Detailed Description of the Invention] [Summary] A signal sequence in the time domain is converted into a frequency domain component by discrete Fourier transform of an arbitrary number of points, thereby converting 1/1 of the number of discrete Fourier transform points in the spectral envelope represented by a discrete value. After performing interpolation on the range of 2, samples with a different number of points from the original discrete Fourier transform are extracted from the interpolated spectral envelope, and based on this sample, samples with the same number of points as the original discrete Fourier transform are extracted. The frequency spectrum thus reorganized is reorganized into a complex conjugate sequence, and the frequency spectrum thus reorganized is subjected to inverse discrete Fourier transform to obtain an output signal in which the signal spectrum is compressed or expanded.

[Industrial application field]

TECHNICAL FIELD The present invention relates to an audio conference device, and particularly to an audio conference device for preventing howling due to acoustic coupling between a speaker and a microphone.
This invention relates to a frequency insertion method in an audio conference device.

As shown in Figure 8, the audio conferencing device has two remote points A and B.
Microphones LA and LB and speaker 2A are placed at both ends of the line connecting the
, 2b are installed to conduct conference-style calls. Note that in FIG. 8, devices such as amplifiers for microphone and speaker signals are omitted. In such a system, it is necessary to prevent howling from occurring via the echo path based on the acoustic coupling from the speakers to the microphone at both ends, and for this purpose the howling prevention device 3 is inserted into the line. .

The frequency insertion method of the present invention is applied in such cases to prevent howling.

[Conventional technology]

Conventionally, an echo suppressor has been used as a howling prevention device in an audio conference device.

An echo suppressor detects sound and controls a switch to prevent howling loops from occurring in acoustic coupling.

[Problem that the invention seeks to solve]

However, in the echo suppressor, either the transmitting side or the receiving side path is disconnected by a switch, so there are problems such as not being able to perform two-way communication, or causing disconnection of the beginning and the end of two conversations.

[Means for solving problems]

The present invention is intended to solve the problems of the prior art as described above, and has a fundamental configuration shown in FIG.

101 is a discrete Fourier transform means that transforms a time domain signal sequence into frequency domain components by discrete Fourier transform of an arbitrary number of points.

Reference numeral 102 denotes an interpolation means, which performs interpolation over a range of 1/2 of the number of discrete Fourier transform points in the spectrum envelope represented by discrete values by discrete Fourier transform.

Reference numeral 103 denotes a frequency spectrum reorganization means, which extracts samples from the interpolated frequency spectrum with fewer points than the number of discrete Fourier transform points when compressing the frequency spectrum, and inserts zero or minute values as missing samples during reorganization. When extending the frequency spectrum, extract samples from the interpolated frequency spectrum with a number of points greater than the number of discrete Fourier transform points, and discard surplus samples during reorganization to increase the number of discrete Fourier transform points. , and based on this sample, it is reorganized into a complex conjugate sequence consisting of the same number of samples as the original discrete Fourier transform.

104 is an inverse discrete Fourier transform means,
The reorganized frequency spectrum is subjected to inverse discrete Fourier transform to obtain an output signal in which the signal spectrum is compressed or expanded.

[For production]

From the frequency spectrum consisting of discrete values obtained by performing discrete Fourier transform from the original time domain signal sequence, samples are extracted using fewer or more points than the original number of discrete Fourier transform points. After reorganizing to the original number of sample points, the output signal is obtained by performing inverse discrete Fourier transform, so when samples are extracted with fewer points than the original number of discrete Fourier transform points, the frequency spectrum in the output signal is compressed and When samples are extracted with more points than the number of discrete Fourier transform points, the frequency spectrum of the output signal is expanded.

Therefore, when this method is applied to an audio conferencing device, the position of the peak point of the frequency spectrum in the output signal is shifted to a lower or higher frequency, so that the signal returned via the echo path has the same frequency spectrum as the original signal. Since the positions of the peak points are different, the loop gain is reduced to effectively prevent howling.

〔Example〕

FIG. 2 shows an embodiment of the present invention, with 11
12 is a discrete Fourier transform (DFT) device, 12 is an interpolation device, 13 is a sample point re-extraction device, 14 is a sample point number adjustment device, and 15 is an inverse discrete Fourier transform (IDFT) device. It is inserted in the position of the howling prevention device 3 shown in the figure.

In FIG. 2, the input signal sequence: t (n) is subjected to discrete Fourier transform of N (N is an integer) points in the DFT device 11, and the frequency spectrum X(il(0) consisting of N points as shown in FIG. ≦i≦N; all i below are integers).

Frequency spectrum X (
1) is expressed by the following equation.

The frequency spectrum obtained by the DFT device is
As shown in the figure, it is a complex conjugate centering on 1/2 of the number of subrings, that is, the N/2 point, and X(11=X (N
-i). Therefore, when processing the output of the DFT device in the following, it is sufficient to process the points from i=0 to N/2.

The interpolation device 12 performs interpolation in order to represent the spectrum envelope in FIG. 3 by a number M different from the actual number N of sampling points. The simplest interpolation method is linear interpolation, that is, arithmetic interpolation. In this case, as shown in FIG. 4, sample values X' ( (b) is determined by the following formula.

X' fm) = -X (n + 1) + -X(
nl mountain+b, 2. Alternatively, more precise interpolation may be performed using a more advanced interpolation method. IM, as a high-order interpolation method, y = 1ln-H)l"-'+ 72n->Z"-
'+ ・-+ J-.

n samples (pigeon,
y. ) may be obtained from αL (i=o to n 1), and (χ2ry,') at a new sample point may be obtained. Note that when interpolating the phase component, detect discontinuities in the phase characteristics as shown in Figure 5,
Interpolation is performed in a similar manner on continuous areas to find new sample points. Complex inverse Fourier transform is performed in the system shown in FIG. 2 using the amplitude and phase components interpolated in this way.

The sample point re-extracting device 13 obtains M/2 sample points for the spectral envelope interpolated in this way, and generates a new spectral envelope X'' (1) consisting of M/2 points.
(0≦i5M/2) is obtained. Furthermore, the sample point number adjustment device 14 reorganizes the spectral series consisting of N/2 points based on the new spectral envelope X'+1). The method of selecting M and the method of reorganizing the spectral sequence at this time differ depending on whether the audio frequency is compressed or expanded.

(1) When compressing the frequency domain When compressing the frequency domain, N>M, and the value of M is selected depending on the degree of compression. In this case (M/2<t:=N/
For the sample point X'(1) in the range of 2), a new spectral sequence X''(11) is obtained by inserting zero or a small value. Figure 6 shows the result obtained in this way. This shows an example of a new spectral envelope.

(2) When expanding the frequency domain When expanding the frequency domain, select the value of M so that N<M, and sample points X in the range of (M/2<t≦N/2)
'(1) is discarded and a new spectrum series X'' (1) consisting of N/2 points is obtained. Figure 7 shows an example of the new spectrum envelope obtained in this way. .

After this, in the sample point number adjustment device 14,
N-i)=X''(1);0:5i<N/2 is performed to make the spectrum envelope into a complex conjugate form.The new frequency spectrum X(1) obtained in this way is , is generally expressed by the following equation.

The IDFT device 15 obtains a frequency-compressed or frequency-expanded signal sequence χ°(n) by performing N-point inverse discrete Fourier transform on the spectrum sequence reorganized by the sample point adjustment device 14.

In this way, according to the present invention, by frequency-compressing or frequency-expanding the input signal, it is possible to shift the peak point of the frequency spectrum in the output signal to a lower frequency or a higher frequency, so that the voice conference device terminal can Even when an echo path occurs, the signal returned via the echo path has a different peak point in the frequency spectrum than the original signal, so the loop gain is set to 1.
Therefore, the occurrence of howling can be effectively prevented.

The frequency insertion method of the present invention can be applied not only to audio conferencing devices but also to harmonizers that change the tone of audio signals.

(Effects of the Invention) As explained above, according to the method of the present invention, the number of discrete Fourier transform points in the frequency spectrum obtained by converting a time domain signal sequence into frequency domain components by an arbitrary number of discrete Fourier transform points is different from the original discrete Fourier transform point. Based on the number of samples, it is reorganized into a complex conjugate sequence consisting of samples with the same number of points as the original discrete Fourier transform, and this is inversely discrete Fourier transformed to obtain the output signal, so it has a simple configuration. The signal spectrum can be compressed or expanded.

By using the method of the present invention, it is possible to easily prevent howling in an audio conference device. Alternatively, the present invention is also effective for uses such as a harmonizer.

[Brief explanation of drawings]

Fig. 1 is a diagram showing the basic configuration of the present invention, Fig. 2 is a diagram showing an embodiment of the present invention, Fig. 3 is a diagram showing the frequency spectrum of the output signal of the DFT device, and Fig. 4 is a diagram showing linear interpolation. FIG. 5 is a diagram showing interpolation of phase characteristics. FIGS. 6 and 7 are diagrams showing the frequency spectrum of the input signal of the rDFT device, and FIG. 6 is a diagram showing the frequency spectrum of the input signal of the rDFT device. FIG. 7 shows the configuration of the audio conferencing device when the frequency spectrum is expanded. FIG. 8 shows the configuration of the audio conference device. 11--Discrete Fourier Transform (DFT) device, 12--Interpolation device, 13--Sample point re-extraction device, 14--Sample point number adjustment device, 15--Inverse Discrete Fourier Transform (IDFT)
Device

Claims (3)

[Claims] (1) A method for compressing or expanding the spectrum of a signal, which includes: a discrete Fourier transform means (101) that transforms a time domain signal sequence into frequency domain components by using an arbitrary number of discrete Fourier transforms; interpolating means (102) for interpolating a range of 1/2 of the number of discrete Fourier transform points in the spectral envelope expressed by the value; and extracting samples with a different number of discrete Fourier transform points from the interpolated spectral envelope , a frequency spectrum reorganization means (103) for reorganizing the sample into a complex conjugate sequence consisting of the same number of samples as the original discrete Fourier transform, based on the sample; Inverse discrete Fourier transform means (1) to obtain an output signal whose signal spectrum is compressed or expanded by
04) A frequency insertion method characterized by comprising: (2) The frequency spectrum reorganization means (103)
By extracting samples from the interpolated frequency spectrum using fewer points than the number of discrete Fourier transform points and inserting zero or minute values as missing samples during reorganization to make the number the same as the number of discrete Fourier transform points, the frequency spectrum in the output signal is The frequency insertion method according to claim 1, characterized in that compression is performed. (3) The frequency spectrum reorganization means (103)
The feature is that the frequency spectrum in the output signal is expanded by extracting samples from the interpolated frequency spectrum with a number of points greater than the number of discrete Fourier transform points, and discarding the surplus samples during reorganization to make them the same as the number of discrete Fourier transform points. A frequency insertion method according to claim 1.