KR900005168B1 - Multifrequency code detecting and transmitting method - Google Patents

Abstract

The circuit transmitting or detecing the multifrequency code by the software instructions of the microprocessor comprises: a filter (111) removing noises of the input and output signal; a time switch (TSW) switching the transmitting and receiving channels (TxA, RxA, TxB, RxB) to form a calling path; CODECS (112,121) coding or decoding input and output signals; a multifrequency detector (114) receiving and processing the multifrequency code from the filter to send the data changed into digits to the read port (RDP); a multifrequency transmitter (113) changing the dialing digit data inputted to RWP into the multifrequency code to output it to the filter; and a microprocessor (CPU).

Description

Multi-frequency Code Detection and Transmission Circuit of Electronic Switch and Method

1 is a conventional multi-frequency code detection and transmission circuit diagram.

2 is a flow chart of FIG.

3 is a multi-frequency code detection and transmission circuit in accordance with the present invention.

4 is a flow chart according to the present invention.

* Explanation of symbols for main parts of the drawings

110: trunk line interface unit 111: filter

112, 121: Cortec 113: Multi-frequency transmitter

114: multi-frequency detector 120: subscriber interface unit

TSW: Time switch HYB2, HYB3: Hybrid coil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-frequency code detection and transmission circuit of an electronic exchange and a method thereof, and more particularly, to a microprocessor program for a multi-frequency code input and output to an exchange without being assigned a channel of a time switch. The present invention relates to a circuit and a method for directly detecting and transmitting a dialing signal.

In order to process dialing digits that are input and output, i.e., multi-frequency codes, in a typical electronic exchange, an interface board capable of detecting and transmitting a dialing digit must be configured.Analog for dialing signals processed in the interface board is provided. Only when the signal was converted into a digital signal, the actual switching was possible in the time switch.

As shown in FIG. 1, a conventional circuit having the above-mentioned purpose includes a trunk line interface unit 10 composed of a hybrid coil HYBO, a filter 11, and a codec 12, and an input / output signal as a microcomputer. Multi-frequency detection comprising a time switch (TSW) for time-division switching operation under the control of a processor, a codec 21, a multi-frequency transmitter 22, and a multi-frequency receiver 23 And a subscriber interface unit 30 composed of a transmitter 20, a codec 31 and a hybrid coil HYB1, and a microprocessor (CPU) for controlling various performances of the exchange.

FIG. 2 is a flowchart illustrating the operation of the multi-frequency code input and output through the trunk line interface unit 10 by receiving the channel assignment of the time switch TSW.

Referring to the conventional circuit configured as shown in FIG. 1 with reference to the flowchart of FIG. 2, the microprocessor (CPU) for controlling various performances of the exchange is periodically connected to the subscriber interface unit 30 as shown in FIG. The microprocessor (CPU) outputs a switching control signal to the time switch (TSW) when there is an outgoing port (TP) of the hooked-off subscriber (TA) by checking the outgoing port (TP) of the subscriber. By assigning the transmission and reception channel (Tx2) (Rx2) of the subscriber side (TA), the dialing tone channel (not shown) is connected to the receiving channel (Tx2) in the process of FIG.

As described above, when the dialing tone is connected to the receiving channel Rx2 on the subscriber side, its signal is converted into an analog signal by the codec 31 and output to the receiving port RP through the hybrid coil HYB1 on the subscriber side. The subscriber will hear the dialing tone. In addition, the microprocessor (CPU) accessing the dialing tone channel determines whether the subscriber TA is a dual tone multi frequency (DTMF) subscriber in the process of FIG. 2 (c). The input terminal of the multi-frequency detector 23 is connected to Tx2) in the process of FIG.

At this time, when the subscriber TA dials the digit to select the CO line in the process of FIG. 2 (e), the analog digit inputted to the outgoing port TP is outputted to the codec 31 through the hybrid coil HTB1. The codec 31 converts the analog digit signal into a digital signal and outputs it to the transmission channel Tx2 on the subscriber side.

Accordingly, the signal dialed to select the CO line at the subscriber TA is converted into an analog signal at the codec 21 and input to the input terminal of the multi-frequency detector 23 by the above-described second process (d).

As described above, when the trunk line selection dialing digit of the subscriber TA is input to the input terminal of the multi-frequency detector 23 through the codec 21, the microprocessor CPU read port of the multi-frequency detector 23. Read the digit processing data output from the CPU to determine whether the CO line selection data is selected. At this time, when the CO line selection data is output, the switching control signal is output to the time switch TSW to connect the receiving channel Rx2 of the subscriber TA side to the transmitting channel Tx1 of the CO line in FIG. 2 (f). The trunk line dialing tone outputted from the terminals L1 and L2 is input to the reception channel Rx2 on the subscriber TA side.

Therefore, the subscriber TA hears the dialing tone of the trunk line side which is output from the transmission channel Tx1 of the trunk line side through the reception port RP of the hybrid coil HYB1.

When the subscriber (TA) who has heard the CO line dialing dials a digit outgoing to the CO line interface 10 (co-line side) in the process of FIG. 2 (e) through the outgoing port TP, the dialing digit As described above, the transmission digit signal is converted into an analog signal by the codec 21 by being input to the transmission channel Tx2 of the subscriber TA through the hybrid coil HYB1 and the codec 31. It is input to the input terminal of (23).

At this time, the microprocessor CPU reads the data converted by the multi-frequency detector 23 through the lead port RDP of the multi-frequency detector 23 and displays the loaded dialing data in FIG. As shown in the procedure of FIG. 2, it is determined whether the output dialing is finished and the output dialing is completed in the process shown in FIG. By outputting a signal, the transmission channel Tx2 on the subscriber TA side and the reception channel Rx1 on the trunk line side are switched in the process of FIG.

After the switching is made as described above and the call path is formed, data written to the light port WRP of the multi-frequency transmitter 22 in the microprocessor CPU is converted into a multi-frequency code in the multi-frequency transmitter 22 and Input to the codec 21 through the output terminal of the multi-frequency transmitter 22 is converted into digital data and input to the transmission channel (Tx2) of the subscriber (TA) side.

Therefore, the multi-frequency code inputted to the transmission channel Tx2 on the subscriber TA side is output to the codec 12 through the reception channel Rx1 on the trunk line side, so that the digital multi-frequency transmission data is converted into an analog signal and a filter ( After filtering by 11), it is output to the trunk line terminals L1 and L2 of the hybrid coil HYB0, and thus the trunk line terminals L1 and the trunk line interface unit 10 of the trunk line interface unit 10 to the subscriber port TA. A ringback tone is inputted from L2), and a call is made when the other subscriber hooks off.

On the other hand, the analog digit, which is a multi-frequency code (MFC) input to the trunk lines L1 and L2, is input to the filter 11 through the hybrid coil HYB0, and noise is removed to be input to the codec 12. The multi-frequency code is converted into a digital signal and input to the transmission channel Tx1 of the time switch TSW.

At this time, the time switch TSW carries only the digitized signals in the assigned time slots and transmits them through the assigned channels, and the digitized signals are transmitted to the reception channel Rx2 of the multi-frequency detection and transmission unit 20. (Digital switching method)

Therefore, when the digital digit in which the analog signal is converted is converted into the analog signal by the codec 21 and input to the input terminal of the multi-frequency detector 23, the microprocessor CPU may read the lead port of the multi-frequency detector 23. By reading the output data of R), the data input from the trunk line interface unit 10 is judged, and the switching is performed by outputting it to the time switch TSW as a switching control signal.

However, the circuit for detecting and transmitting the multi-frequency code in the above manner has to modify the multi-frequency code many times. The multi-frequency transmitter 22 uses the transmission channel Tx2 of the time switch TSW and the multi-frequency detector 23. ) Has a problem in that the time switch TSW cannot be usefully used by assigning a reception channel Rx2 to transmit a signal. In addition, due to the complexity of the circuit, the number of man-hours has been increased, which has been a factor of the cost increase and the efficiency of the system has been deteriorated.

Accordingly, an object of the present invention is to provide a multi-frequency detection and transmission unit in a trunk line interface in an electronic exchanger, so that the system control microprocessor does not assign a channel of a time switch for detecting or transmitting a multi-frequency code to a software instruction. The present invention provides a circuit and method for transmitting or detecting a multi-frequency code.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram of a multi-frequency detection and transmission circuit according to the present invention, wherein a primary side is connected to trunk line terminals L1 and L2, and a hybrid coil HYB2 for matching impedance of the trunk line and two of the hybrid coil HYB2. A filter 111 for removing noise of a signal inputted to and outputted from the hybrid coil HYB2 by connecting both ends to the vehicle side HT2, and transmitting / receiving channels TxA and RxA on the trunk line side and subscriber side transmission / reception by a switching control signal. A time switch TSW which switches channels TxB and RxB to form a communication path, and is connected between the positive and second cutoffs of the filter 111 and the trunk line-side transmit / receive channels TxA and RxA of the time switch TSW. And a codec 112 for coding or decoding an input / output signal and outputting the same, a hybrid coil HYB3 having a primary side connected to a subscriber rule transmission port TP1 and a reception port RP1, and two of the hybrid coil HYB3. Transmitting and receiving subscriber side of vehicle side and time switch (TSW) A codec 121 connected between nulls TxB and RxB to code or decode an input / output signal, and an output terminal, and an input terminal is connected to one end of a second end of the filter 111 and a terminal 300 to the filter 111. The output terminal is connected to the multi-frequency detector 114 for outputting the data reduced to digit to the lead port (RDP) by inputting and processing the multi-frequency code on the side of the main line output from the output line, and the other end of the second stage of the filter 111. And a multi-frequency transmitter 113 for converting the dialing digit data inputted to the light port WRP into a multi-frequency code and outputting the multi-frequency code to the filter 111 through the output terminal, the codec 121 and the time switch TSW. And a microprocessor (CPU) which is connected to the light port (WRP) of the multi-frequency transmitter 113, outputs a switching control signal and performs control for performing various functions of the exchange.

In the configuration shown in FIG. 3, the portion consisting of the hybrid coil HYB2, the filter 111, the codec 112, the multi-frequency transmitter 113, and the multi-frequency detector 114 is the trunk line interface unit 110, and the hybrid coil ( The part consisting of HYB3) and codec 121 is subscriber interface unit 120.

4 is a flowchart illustrating a process of inputting and outputting a multi-frequency code input and output to the trunk line interface unit 10 without receiving a channel assignment of the time switch TSW.

Hereinafter, the operation process of the present invention will be described with reference to the configuration of FIG. 3 and the flowchart of FIG. 4, and the microprocessor (CPU) performing various functions of the switch periodically hooks off as shown in FIG. If there is a subscriber (TB) that is hoop-off by searching for a subscriber having a subscriber, the channel of the subscriber (TB) that is hooked off is allocated in the process of FIG. 4 (b), and the reception channel (TB) of the subscriber (TB) is allocated. Dialing Tone is connected to RxB) so that the subscriber TB hears the dialing tone.

That is, when the subscriber TB is hooked off, the microprocessor CPU allocates the transmission / reception channels TxB and RxB of the subscriber TB to the time switch TSW and dials the dialing tone to the reception channel RxB. By supplying the subscriber (TB) will hear the dialing tone.

When the subscriber TB who listens to the dialing tone presses the dialing digit to seize the trunk line, the dial digit is input to the terminal 300 so that the multi-frequency detector 114 converts it to digit.

At this time, the microprocessor (CPU) outputs the data output from the multi-frequency detector 114 through the read port (RDP) to detect the trunk line in the idle state when the trunk line is data in the process of FIG. Seizure in the process (d).

As described above, the microprocessor CPU having the trunk line inputs a switching control signal to the time switch TSW, and transmits the transmission channel TxA of the trunk line that has been scissors to the receiving channel RxB of the subscriber TB. e) By connecting in the process, the trunk line dialing tone supplied through the trunk line terminals L1 and L2 is received through the receiving port RP1 of the subscriber TB.

When the subscriber (TB) receiving the dialing tone of the CO line is dialed in the process of FIG. 4 (f) to transmit to the trunk unit, the analog dialing digit signal is input to the terminal 300. .

Therefore, the multi-frequency detector 114 detects and outputs an analog digit signal as a signal of digit data, and at this time, the microprocessor (CPU) reads the lead port (RDP) of the multi-frequency detector 114.

The microprocessor (CPU) reading the digits of the multi-frequency code converted by the multi-frequency detector 114 analyzes them and outputs them to the light port (WRP) of the multi-frequency transmitter 113 in FIG. 4 (g). For this reason, the multi-frequency transmitter 113 outputs a multi-frequency code (MFC) corresponding thereto to the filter 111.

Therefore, after the noise is removed by the action of the filter 111, the multi-frequency code MFC is matched by the action of the hybrid coil HYB2, and is transmitted to the trunk line switch through the trunk lines L1 and L2.

When the digit is written to the multi-frequency transmitter 113 as described above, the microprocessor (CPU) starts to search whether the dialing transmission is finished in the process of FIG. By outputting the switching control signal, the transmission channel TxB on the subscriber TB side and the reception channel RxA on the trunk line side are connected in the process of FIG.

On the other hand, when the multi-frequency code (MFC) transmitted from the counter-pole exchanger is input to the trunk line terminals (L1, L2) of the trunk line interface unit 110, the multi-frequency code (MFC) is impedance matched by the hybrid coil (HYB2) The filter 111 is then input to the filter 111.

The filter 111 which inputs the multi-frequency code (MFC) inputs the multi-frequency code (MFC) from which the noise is removed to the multi-frequency detector (114) while filtering the codec (112). Will print

At this time, the multi-frequency detector 114 converts the input multi-frequency code into a digital signal, and the microprocessor (CPU) in a predetermined detector (Seizure Detector) when the multi-frequency code is input to the trunk line terminals (L1, L2) The data output from the read port (RDP) of the multi-frequency detector 114 is read and analyzed by the generated signal, and a switching control signal is output to the time switch TSW.

Therefore, the COS 112 transmits / receives the data transmitted from the codec 112 by the COS transmission / reception channels TxA and RxA and the subscriber / TB transmission / reception channels TxB and RxB in a unique operation of the time switch TSW. Through the channel TxA and the receiving channel TxB on the subscriber side, the codec 112 converts the analog signal to the receiving port RP1 of the subscriber TB, and the outgoing port TP1 of the subscriber TB. The signal output from is converted into a digital signal by the codec 121 after impedance matching is performed by the hybrid coil HYB3.

In addition, the digitally converted data of the codec 121 is an analog signal from the codec 112 through the transmission channel TxB on the subscriber (TB) side and the reception channel (RxA) on the trunk line side, so that the filter 111 and Since the output through the hybrid coil HYB2, it can be seen that the input multi-frequency code can be detected without separately assigning a channel of the time switch TSW for detecting the multi-frequency code.

Therefore, as described above, the present invention incorporates a multi-frequency detector and a transmitter to process input / output dialing digits in the trunk line interface unit, so that the microprocessor directly reads and outputs the digits so that the time-switch channel can be used effectively and system efficiency can be improved. There is an advantage to increase.

Claims (2)

In the multi-frequency code detection and transmission circuit of an electronic exchange, a hybrid coil (HYB2) having a primary side and a secondary side (HT2) and connected to the trunk line terminals L1 and L2 at the primary side for matching impedance of the trunk line, Both ends of the hybrid coil HYB2 are connected to the secondary side HT2, and a filter 111 for removing noise of a signal inputted and outputted to the hybrid coil HYB2, and a transmission / reception channel of a trunk line side by a switching control signal. (TxA, RxA) and the time switch (TSW) for switching the subscriber-side transmission and reception channels (TxB, RxB) to form a communication path, both secondary ends of the filter 111 and the trunk line-side transmission and reception channel of the time switch (TSW) A codec 112 connected between the TxA and the RxA to code or decode and output an input / output signal, a hybrid coil HYB3 having a primary side connected to the subscriber's source port TP1 and the receiver port RP1, Secondary side of the hybrid coil HYB3 and the time switch Codec 121 connected between subscriber-side transmit / receive channels TxB and RxB of the TSW to code or decode and output an input / output signal, and one end of a second end of the filter 111 to be connected to the filter 111. The multi-frequency detector 114 for outputting the data reduced to digit to the lead port (RDP) by inputting and processing the multi-frequency code on the side of the trunk line output from the main line, and the second stage of the filter 111 are at the other end. A multi-frequency transmitter 113 connected to the dialing digit data input to the light port WRP and output to the filter 111 through an output terminal, the codec 121 and the time switch TSW. ) Is connected to the light port (WRP) of the multi-frequency transmitter 113 and the light port (RDP) of the multi-frequency detector 114 to output a switching control signal and to control to perform various functions of the exchange. Multi-frequency code detection and transmission circuit comprising a processor (CPU). In the multi-frequency code detection and transmission method of an electronic exchange, periodically searching for a hooked-off subscriber and assigning a transmit / receive channel if there is a hooked-off subscriber and connecting a dialing tone to the subscriber's receiving channel The first process (a, b) which causes the user to hear the dialing tone, and read and analyze the data output from the multi-frequency detector by the dial digits input from the subscriber. The second process (c, d, e) of connecting the transmission channel of the trunk line to the receiving channel of the subscriber side, and when the subscriber dials the digit to be sent to the trunk line, the digit data read through the multi-frequency detector is read out. The third process (f, g) of transmitting the dialing digit through the frequency transmitter and the dialing transmission are completed. A fourth process (h, i) which makes a call by connecting the receiving channel of the trunk line to the transmission channel of the subscriber by a switching control signal when the dialing is completed by searching for a value; How to send.

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