KR960013698B1 - Method & circuit for detecting normal state or abnormal state of teletext signal - Google Patents

Abstract

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Description

Charging signal detection method and detection circuit

1 is a circuit diagram showing a conventional charging signal detecting whether the normal state.

2 is a schematic block diagram of a typical all-electronic exchanger.

Figure 3 is a block diagram according to an embodiment of the charging signal normal presence detection circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10: TTX signal generator 20: subscriber internal circuit

30: subscriber matching unit 40, 41: automatic tuning unit

42: tuner 43: frequency selector

44: buffer 45: microcomputer

46: full wave rectifier 47: filter

48: analog-to-digital converter 49: transmitter

50: frequency detector 60: amplitude detector

The present invention relates to a method and a detection circuit for detecting whether the charging signal is normal, and in particular, to detect whether the charging signal is normal in an all-electronic exchanger using a teletext (hereinafter, abbreviated as TTX) signal as the charging signal. The present invention relates to a method and a detection circuit for detecting a normal charging signal.

In the related art, a polarity inversion signal is used as a charging signal of a public telephone and a circuit as shown in FIG. 1 is used to detect whether a polarity inversion signal is normal. Here, charging means adding a fee in a paid communication service.

Referring to FIG. 1, the charging signal is established by forming a current loop A from the subscriber internal circuit 1 to a → R1 → b and then converting it to a current loop B from b → R1 → a. In the amplifier (3) having both ends of the resistor (R1) (2) as input, the voltage between both ends of the resistor (R1) (2) is detected and amplified, and when applied to the polarity checker (4), the polarity checker (4) provides a reference voltage. The polarity is checked in comparison with the reference voltage output from the generator 5, and the state of the current loop A and the state of the current loop B are compared. To apply.

However, the call quality may be degraded due to the disconnection of the voice signal generated when the current loop is converted from the polarity inversion signal, and the load applied to the polarity conversion part of the subscriber internal circuit 1 is variable. In addition, there is a problem in the design of the amplifier (3) for converting the signal to be used in the polarity checker (4) because -48V is supplied when the polarity inversion signal is normal or not in a loop configuration. Accordingly, an object of the present invention is to solve the above-mentioned problems, the charging signal to check whether the charging signal is normal by checking the frequency and amplitude of the charging signal in the all-electronic exchanger using the TTX signal as the charging signal. The present invention provides a method for detecting the presence or absence of normality.

Another object of the present invention is to provide a circuit that is most suitable for realizing the above-described method for detecting whether the charging signal is normal.

The present invention for achieving the above object is a method for detecting the presence or absence of the above-mentioned TTX signal when the TTX signal is supplied to the subscriber line as a charging signal in the all-electronic exchange, the frequency of the above-mentioned TTX signal is predetermined From the first step of tuning to the frequency, the second step of detecting the amplitude magnitude of the frequency of the above-described TTX signal, the result of performing the first step described above and the result of performing the second step described above, And a third step of determining that the TTX signal is normal when the amplitude of the TTX signal is normal.

The present invention for achieving the above-mentioned object is a circuit for determining whether the TTX signal is normal when the TTX signal is supplied to the subscriber line as the charging signal in the all-electronic exchange, and tuning the frequency of the TTX signal described above. From the frequency detection section for detecting the frequency of a normal TTX signal, the amplitude detection section for detecting the magnitude of amplitude by full-wave rectifying the TTX signal, the tuning signal output from the frequency detection section, and the output signal of the amplitude detection section. It comprises a micom (Micom) for determining whether the above-mentioned TTX signal is normal.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention. 2 is a schematic block diagram of a general all-electronic exchanger. The block diagram shown in FIG. 2 includes a TTX signal generator 10, a subscriber internal circuit 20, a subscriber junction 30, and an automatic tuning unit 40.

3 is a block diagram according to an embodiment of the charging signal normal presence detection circuit according to the present invention, the automatic tuning unit 41 for automatically tuning the frequency of the TTX signal, and the TTX signal output from the automatic tuning unit 41 The amplitude of the TTX signal frequency is detected by full-wave rectifying the frequency of the TTX signal output from the auto-tuning unit 41 and the frequency detector 50 for detecting whether or not the normal TTX signal is tuned by tuning the frequency of the signal to a predetermined frequency. The amplitude detection unit 60 and the microcomputer 45 for determining whether the above-described TTX signal is normal by receiving the tuning signal output from the frequency detection unit 50 and the output signal of the amplitude detection unit 60.

At this time, the frequency detector 50 selects and outputs a frequency of 12 KHz or 16 KHz according to the frequency of the TTX signal output from the auto tuning unit 41, and the TTX output from the auto tuning unit 41. A tuner 42 for tuning a signal to a frequency output from the frequency selector 43 and outputting a high level signal or a low level signal depending on whether or not the tuner is tuned. And a buffer 44 for buffering the output signal.

In addition, the amplitude detection unit 60 includes a full-wave rectifier 46 for full-wave rectifying the TTX signal output from the automatic tuning unit 41, a filter 47 for removing high frequency noise from the output signal of the full-wave rectifier 46, Analog-to-digital converter 48 which converts the output signal of the filter 47 into serial digital data and outputs it, and the microcomputer 45 mentioned above which converts serial digital data output from the analog-to-digital converter 48 into parallel digital. It consists of a transmitter 49 for transmitting. Of course, the TTX signal itself is a signal having a frequency component.

At this time, the standard of the TTX may be different depending on the country and region 12KHz / 16KHz, the allowance for each frequency, the magnitude of the amplitude.

Referring to the operation of the present invention configured as described above, the TTX signal output from the TTX signal generator 10 as shown in Figure 2 is supplied to the subscriber matching unit 30 through the subscriber internal circuit 20, subscriber matching unit The transmission size of the TTX signal supplied through 30 is 2.0 to 2.5 Vrms, and is applied to an automatic tuning unit 40 to easily detect the TTX signal.

At this time, the auto-tuning unit 40 detects the voltage difference of the TTX signal between the tip and the ring. Since the voltage difference is extremely weak, it is amplified at a predetermined amplification rate to obtain an appropriate voltage level.

As shown in FIG. 3, the frequency detector 50 detects the frequency of the TTX signal adjusted by the autotuning unit 41, and the tuner 42 in the frequency detector 50 outputs from the autotuning unit 41. FIG. The tuned TTX signal to 12KHz or 16KHz output from the frequency selector 43 so that the high level signal or the low level signal is transferred to the microcomputer 45 through the buffer 44 depending on whether the frequency of the above-described TTX signal is normal. Is authorized.

Next, the amplitude detection unit 60 is for detecting the amplitude of the TTX signal adjusted by the autotuning unit 41, and the full-wave rectifier 46 in the amplitude detection unit 60 outputs the TTX signal output from the autotuning unit 41. Is rectified and applied to the filter 47, and the filter 47 extracts or removes only a signal having a specific frequency spectrum from the output signal of the full-wave rectifier 46. Here, the high-frequency noise is removed to remove the analog-to-digital converter. Is applied at 48.

The analog-to-digital converter 48 converts the applied analog signal into serial digital data. As a result, the analog-to-digital converter 48 applies a signal whose amplitude value of the TTX signal is converted into digital data to the transmitter 49, and the transmitter 49 is applied. The digital serial data is converted into parallel data and applied to the microcomputer 45.

Accordingly, the microcomputer 45 determines whether the TTX signal is normal by the tuning signal output from the frequency detector 50 and the parallel data output from the amplitude detector 60.

As described above, the method and circuit for detecting whether the charging signal is normal according to the present invention uses the TTX signal as the charging signal in the all-electronic exchanger, and checks the frequency and amplitude of the TTX signal to determine the charging signal regardless of the change in the surrounding environment. Not only can it determine whether it is normal, but it can also reduce the circuit.

Claims (5)

A method for determining whether the TTX signal is normal when a TTX signal is supplied to a subscriber line as a charging signal in an all electronic switch, comprising: a first step of tuning a frequency of the TTX signal to a predetermined frequency; Detecting a magnitude of an amplitude of a frequency of the TTX signal; A third step of determining that the TTX signal is normal when the TTX signal is tuned to a predetermined frequency and the amplitude of the TTX signal is normal from the result of performing the first step and the result of performing the second step; Method of detecting signal presence. The method of claim 1, wherein the predetermined frequency is 12KHz or 16KHz. In a circuit for determining whether the TTX signal is normal when the TTX signal is supplied to the subscriber line as a charging signal in an all-electronic exchange, the TTX signal is detected by tuning the frequency of the TTX signal to a predetermined frequency. Detection unit 50 to perform; The amplitude detection unit 60 detects the magnitude of the amplitude by full-wave rectifying the TTX signal, and determines whether the TTX signal is normal from the tuning signal output from the frequency detection unit 50 and the output signal of the amplitude detection unit 60. The charging signal normal presence detection circuit comprising a microcomputer (45). The method of claim 3, wherein the frequency detector 50; A frequency selector 43 for selecting and outputting a frequency of 12 KHz or 16 KHz according to the frequency of the TTX signal; The tuner 42 and the tuner 42 which output the high level signal or the low level signal according to whether the frequency of the TTX signal is normal by tuning the TTX signal to the frequency output from the frequency selector 43. And a buffer 44 for buffering an output signal. 5. The amplitude detection unit (60) according to claim 4, wherein the amplitude detection unit (60) includes: a full-wave rectifier (46) for full-process rectifying the TTX signal, and a filter (47) for removing high frequency noise from the output signal of the full-wave rectifier (46); An analog / digital converter 48 for converting the output signal of the filter 47 into serial digital data; And a transmitter (49) for converting serial digital data output from the analog-to-digital converter (48) into parallel digital and transmitting the same to the microcomputer (45).