KR100260439B1 - Analog tone detection method of private exchange - Google Patents

Abstract

PURPOSE: An analog tone detecting method in a private exchanger is provided to widen a detection band of a tone signal and stably detect a tone signal without a variation of a detection band even for a signal input beyond a predetermined input level. CONSTITUTION: A center frequency of a band-pass filter is set by f0 and a detection band width is set ΔHz. In this state, when a signal is inputted, the band-pass filter performs first filtering with a center frequency of f0-Δ/2 (or f0+Δ/2). In a second filtering, the signal outputted from the first filter is again filtered with a center frequency of f0+Δ/2 (or f0-Δ/2). After undergoing the first and the second filtering, a signal outputted from the band-pass filters has a level value between f0-Δ/2-f0+Δ/2 Hz. This signal is level-compared with a non-filtered input by comparators. If it has the same level as the input, frequencies within the detected band width have the same level as the input signal and are recognized as a signal. If the signal has a different level as that of the input signal, frequencies existing at other than the detected band width have a lower level than that of the input signal and is not recognized as a signal.

Description

Analog tone detection method in private exchange

The present invention relates to an analog tone detection circuit of a private exchange, and more particularly, to an analog tone detection method in a private exchange for stably detecting a tone signal of a predetermined frequency range when detecting a tone signal composed of a plurality of frequencies. will be.

In general, when providing a call service to a subscriber accommodated in a private exchange, the private exchange needs to detect various tone signals applied through a line.

In a conventional private exchange, an analog tone detection circuit as shown in Fig. 1 is used. Such an analog tone detection circuit includes a plurality of band pass filters (1, 2), notch filters (3), a plurality of full-wave rectifiers (4-6), a plurality of comparators (7-10), a plurality of tone decoders (11, 12), a plurality of end gates (14, 15) and voltage divider (13). When the tone signal is input, the band pass filter (1, 2) filters the signal once, passes the signal of the frequency band set to it, and applies it to the full-wave rectifier (4, 5) connected to it. At the same time, the notch filter 3 removes the set main depth from the input signal and applies it to the full-wave rectifier 6, where the full-wave rectifiers 4, 5, and 6 receive full-wave rectified signals applied to their input terminals. The signal is converted and output. Accordingly, the comparator 7 compares the voltage level applied from the full-wave rectifier 4 with the voltage level applied from the full-wave rectifier 6 to output the noise f1_SNR of the first frequency, and the tone decoder 11 propagates. The signal applied from the rectifier 4 is decoded and output to the AND gate 14, and the comparator 8 compares the voltage level applied from the full-wave rectifier 4 with a reference voltage applied from the voltage divider 13. The resultant signal is output to the AND gate 14 side. In addition, the comparator 9 compares the voltage level applied from the full-wave rectifier 5 and the full-wave rectifier 6 to output the noise f2_SNR of the second frequency, and the tone decoder 12 outputs the full-wave rectifier 5 from the full-wave rectifier 5. The decoded signal is decoded and output to the AND gate 15 side, and the comparator 10 compares the voltage level applied from the full-wave rectifier 5 with the reference voltage applied from the voltage divider 13, and compares the result signal with the AND gate. Output to the (15) side, and the AND gate 14 outputs the tone signal f1_TONE of the first frequency by ANDing the signals received from the tone decoder 11 and the comparator 8, and the AND gate 15 The signal received from the tone decoder 12 and the comparator 10 is ANDed to output a tone signal f2_TONE of a second frequency.

In the analog tone detection circuit of the conventional private exchange as described above, the tone signal is detected by using a tone detection element such as the tone decoder 11, and due to the characteristics of the tone detection element, the detection range is not wide and is outside the constant input level. The signal input has a problem that a large change in the detection band is generated.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and it is possible to stably detect a tone signal without changing the detection band even with a wider detection band of the tone signal and at the same time a signal input outside the predetermined input level. An object of the present invention is to provide an analog tone detection method of a private exchange.

In order to achieve the above object, there is provided a method of detecting an analog tone in a private exchange, comprising: a first step of setting a predetermined center frequency f _o and a predetermined detection bandwidth Δ; A second step of filtering the first frequency band when the signal is input and filtering by the center frequency f _o -Δ / 2 (or f _o + Δ / 2); Performing a second band filtering on the first band filtered signal at a center frequency f _o + Δ / 2 (or f _o −Δ / 2); A fourth step of comparing the signal subjected to the second band filtering with a level unfiltered input to determine whether the signal is at the same level; A fifth step of comparing the levels to determine frequencies within a detection bandwidth as the tone signal when the level is the same; And a sixth step of not determining frequencies other than the detection bandwidth as the tone signal when the level is different from the level.

According to another aspect of the present invention, in the analog tone detection method in a private exchange,

A first step of converting the input signal into a predetermined DC voltage after full-wave rectifying the first and second band filters; A second process of directly rectifying the input signal and converting the input signal into a predetermined DC voltage; Comparing the direct current voltage in the first process and the direct current voltage in the second process, it is determined whether the level is the same level, and if the same level is determined, it is determined as a tone signal. It is included.

1 is a block diagram of an analog tone detection circuit in a conventional private exchange.

2 is a block diagram of an analog tone detection circuit in a private exchange according to the present invention;

FIG. 3 is a filtering waveform diagram of the bandpass filter shown in FIG. 2; FIG.

4 is a schematic diagram showing voltage readjustment by a comparator;

Fig. 5 is a flowchart showing a tone detection process in the present invention.

Explanation of symbols on the main parts of the drawings

21, 22: band pass filter 23: notch filter

24-27: full-wave rectifier 28-33: comparator

34: voltage divider 35, 36: end gate

The analog tone detection circuit in the private exchange according to the present invention includes a plurality of band pass filters 21 and 22, a notch filter 23, a plurality of full-wave rectifiers 24 to 27, and a plurality of comparators as shown in FIG. 28 to 33, a voltage divider 34 and a plurality of end gates 35 and 36. The band pass filter 21 is provided with a primary and a band pass filter therein, and bands an input signal from a predetermined center frequency to a frequency range and outputs the signal to the full-wave rectifier 24 side. 22 is provided with a primary and a band pass filter therein, and outputs the input signal to the full-wave rectifier 25 by band-passing the frequency from a predetermined center frequency to a predetermined range, and the notch filter 23 is inputted. The set main depth is removed from the signal and applied to the full-wave rectifier 26 side. In addition, the full-wave rectifier 24 full-wave rectifies the signal applied from the band-pass filter 21 and outputs it to the comparators 28, 29, and 30, and the full-wave rectifier 25 is a band-pass filter 22. The signal applied from the full wave rectifier is output to the comparators 31, 32, and 33, and the full wave rectifier 26 carries out the full wave rectification of the signal applied from the notch filter 23 to the comparator 28, The output signal is output to the (31) side, the full-wave rectifier 27 is full-wave rectified and directly outputs the signal to the comparator 29, 32, the voltage divider 34 is the reference voltage comparator 30, (33) Output to the The comparator 28 compares the level of the signal applied from the full-wave rectifier 24 and the full-wave rectifier 26 to output the noise f1_SNR of the first frequency, and the comparator 29 is connected to the full-wave rectifier 24. The level of the signal applied from the full-wave rectifier 27 is compared to output the comparison result signal to the AND gate 35 side, and the comparator 30 receives the level of the signal applied from the full-wave rectifier 24 and the voltage divider 34. The voltage level applied from the circuit is compared to output the comparison result signal to the AND gate 35 side. The comparator 31 compares the level of the signal applied from the full-wave rectifier 25 and the full-wave rectifier 26 to output the noise f2_SNR of the second frequency, and the comparator 32 is applied from the full-wave rectifier 25. The level of the signal is compared with the voltage level applied from the full-wave rectifier 27, and the comparison result signal is output to the AND gate 36 side, and the comparator 33 receives the level of the signal applied from the full-wave rectifier 25 and the voltage divider. The voltage level applied from (34) is compared and the comparison result signal is output to the AND gate 36 side. Meanwhile, the AND gate 35 performs an AND operation on the signals applied from the comparator 29 and the comparator 30 to output the tone signal f1_TONE of the first frequency, and the AND gate 36 is configured to the comparator 32 and the comparator ( The signal applied from 33 is ANDed to output the tone signal f2_TONE of the second frequency.

The band pass filters 21 and 22 have a first and second band pass filters therein, and the first filter is -Δ / 2 (or + Δ) from the center frequency f _o as shown in FIG. / 2) is filtered by the center frequency f _o -Δ / 2 (or f _o + Δ / 2), and the second filter again filters the signal output from the primary filter, as shown in (B) of FIG. filters with a center frequency (f _o) from the + Δ / 2 (or -Δ / 2) the center frequency f _o + Δ / 2 (or f _o -Δ / 2) the frequency. Therefore, the band pass filters 21, 22 finally output the filtering signal as shown in Fig. 3C.

In addition, the notch filter 23 outputs frequency band signals other than two frequencies input as tone signals, thereby passing a main frequency considered as a kind of noise. Accordingly, the original signal and the other noise signals are compared by the comparators 28 and 31, and if the noise level is larger than the signal, it is recognized as not detecting the tone, and only when the level of the signal is above a certain level compared to the noise. It is recognized as a signal.

On the other hand, full-wave rectifiers 24 to 27 serve to convert the input of the sine wave to the same DC voltage level as the maximum voltage level of the sine wave.

The comparators 28 and 31 compare the signal level applied through the full-wave rectifier 24 with the voltage level of the noise applied through the full-wave rectifier 26, and as a signal when the voltage level of the noise is higher than a predetermined level compared to the signal voltage level. It does not recognize, but it serves to prevent errors that can be detected by the signal if the level of noise is too high in the level range of detecting the signal. This is because the harmonics that can occur in the signal frequency band, especially due to the high noise level, can be falsely detected as a signal.

The comparators 29 and 32 compare the voltages of the input signals with the useful signals from the band pass filters 21 and 22 in any input signal, and if the level difference is large, noises of frequency components other than the two center frequencies are input. It is considered to have been made and not recognized as a signal. The comparators 30 and 33 are configured to be ignored even if the input signal is a low level signal even if the input frequency is the center frequency.

In addition, the AND gates 35 and 36 recognize the signal as an actual signal only when the outputs of the comparators 28 and 31 and the comparators 29 and 32 are satisfied at the same time, and the voltage divider 34 provides the level of the input signal. If it is below this detection level, for example, below -20dB, a reference voltage level is provided to prevent detection.

Meanwhile, the detection band may be adjusted by redistributing the voltage levels by the comparators 29 and 32. As shown in FIG. 4, after rectifying the input signal, the signal is passed through a voltage distribution circuit to convert the DC voltage to the comparator. By simultaneously inputting the second-filtered signal by the bandpass filter to the comparator, the comparator may recognize the tone in a predetermined level range of the input signal.

The overall process in the analog tone detection circuit according to the present invention is performed as shown in FIG. 5, that is, the center frequency is set to f _o and the detection bandwidth is set to ΔHz in the band pass filters 21 and 22. In the state in which the signal is input, the band pass filters 21 and 22 filter the first order and filter by the center frequency f _o -Δ / 2 (or f _o + Δ / 2), and the secondary filter is the primary filter. The signal output from the filter is filtered again by the center frequency f _o + Δ / 2 (or f _o -Δ / 2). In this way, when the first and second filtering are performed, the signal output from the bandpass filters 21 and 22 has a level value between f _o -Δ / 2 to f _o + Δ / 2 Hz. Level comparison is made by the input and the comparators 28 to 33, and if the level is equal to the input, frequencies within the detection bandwidth have the same level as the input signal and are recognized as signals. If the level is different from the input, frequencies other than the detection bandwidth are input signals. It has a lower level and is not recognized as a signal.

In the present invention, the above-described tone detection process has been described with reference to a hardware configuration. However, the present invention is not limited thereto, and a person having ordinary skill in the art may easily implement a software process.

As described above, the present invention makes it possible to stably detect the tone signal without changing the detection band even for a signal input that is wider than the conventional technology and to a signal input that is out of a constant input level.

Claims (2)

In the analog tone detection method in the private exchange, A first step of setting a predetermined center frequency f _o and a predetermined detection bandwidth Δ; A second step of filtering the first frequency band when the signal is input and filtering by the center frequency f _o -Δ / 2 (or f _o + Δ / 2); Performing a second band filtering on the first band filtered signal at a center frequency f _o + Δ / 2 (or f _o −Δ / 2); A fourth step of comparing the signal subjected to the second band filtering with a level unfiltered input to determine whether the signal is at the same level; A fifth step of comparing the levels to determine frequencies within a detection bandwidth as the tone signal when the level is the same; And a sixth step of not determining a frequency other than a detection bandwidth as a tone signal if the level is different from the level comparison. In the analog tone detection method in the private exchange, A first step of converting the input signal into a predetermined DC voltage after full-wave rectifying the first and second band filters; A second process of directly rectifying the input signal and converting the input signal into a predetermined DC voltage; Comparing the direct current voltage in the first process and the direct current voltage in the second process, it is determined whether the level is the same level, and if the same level is determined, it is determined as a tone signal. Analog tone detection method in a private exchange comprising a.

Images