KR19980075427A - Processing method of polarity inversion signal in private exchange - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

The present invention relates to a method of processing a polarity inversion signal in a private exchange.

I. The technical problem to be solved by the invention

Provided are a polarity inversion signal processing method capable of selectively detecting two types of polarity inversion signals in a private exchange.

All. Summary of Solution of the Invention

According to the operation time of the polarity inversion signal designated by the user in the private exchange, the private exchange can be in the variable or continuous polarity inversion signal detection mode to selectively detect the variable or continuous polarity inversion signal.

la. Important uses of the invention

It is used in the private exchange which processes the polarity inversion signal for charging.

Description

Processing method of polarity inversion signal in private exchange

The present invention relates to a private exchange, and more particularly, to a method of processing a polarity inversion signal in a private exchange.

In general, a polarity reverse signal (hereinafter referred to as PRS) is a signal sent from a local exchange to a private exchange for charging. There are two types of types, permanent type PRS and temporary type PRS. have.

1 and 2 show polarity state diagrams according to talk time of the continuous PRS and the variable PRS, respectively. First, as shown in FIG. 1, the continuous PRS is a signal in which the polarity remains unchanged until t2, when the call ends, after the polarity is inverted from high to low at the time t1 when the call starts.

In contrast, the variable PRS is inverted from high to low at time t1 when the call starts, as shown in FIG. 2, and maintained for 300 msec, and then restored to polarity again at time t2. It is a repeating 300 msec polarity inversion pulse signal.

The two types of PRS described above have been used not only in the national exchange for billing but also in the private exchange. However, the conventional private exchange has been fixed to detect only one type of PRS of the two types of PRS. Therefore, the private exchange has a problem that can not be used in the local exchange that transmits other types of PRS in addition to the PRS it can detect.

As described above, since the private exchange is fixed to detect only one type of PRS, either a continuous PRS or a variable PRS, the private exchange transmits a PRS of another type in addition to the PRS that it can detect. It could not be used in a local exchange.

Accordingly, an object of the present invention is to provide a PRS processing method in a private exchange capable of selectively detecting two types of PRS according to a PRS operation time specified by a user.

1 is a polarity state diagram of a continuous polarity inversion signal according to an embodiment of the present invention;

2 is a polarity state diagram of a variable polarity inversion signal according to an embodiment of the present invention;

3 is a block diagram of a conventional private exchange;

4 is an internal block diagram of a PRS trunk;

5 is a process flow diagram for detecting two types of polarity inversion signals in a private exchange in accordance with an embodiment of the invention.

In order to achieve the above object, the present invention allows a user to designate an operating time of PRS to 0 or 300 msec in MMC (Man Machine Communication) to selectively detect two types of PRSs in a private exchange. The exchange enters a continuous PRS detection mode that can detect continuous PRS when the operation time of the PRS is set to 0. On the other hand, the exchange can detect a variable PRS when the operation time of the PRS is set to 300 msec. Characterized in that the variable PRS detection mode. The PRS operation time refers to the time from the time when the PRS is inverted from high to low when the call starts and the time when the polarity is reversed from low to high again.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Many specific details are set forth in the following description and in the accompanying drawings to provide a more general understanding of the invention. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

First, a block diagram of a conventional private exchange to which the present invention is applied is shown as FIG. Referring to FIG. 3, a polarity reverse signal (hereinafter referred to as a PRS) line 100 is a trunk line for transmitting a PRS in a central office exchange. The PRS trunk 102 detects the PRS transmitted from the PRS line 100, and the switching circuit 104 switches the pulse code modulation (PCM) data of the private exchange. 106 to 114 are highways inside the private exchange, and multiplex the PCM data of each module (Trunk, DLI, SLI, etc.) of the private exchange into 32 channels. It is connected to the switching circuit 104 and is switched in the switching circuit 104 and transmitted to different parts. The DLI module 116 interfaces a plurality of digital phones, and 118 to 120 are digital phones that are connected to the main device of the private exchange via the DLI module 116 and are operated by data communication. The SLI module 132 is a part for interfacing a plurality of general telephones. Reference numerals 122 to 124 operate by connecting to the main unit of the private exchange through the SLI module 132 as a general telephone. The signal transmitter module 134 is a module for transmitting signals of the private exchange, and is a part for generating DTMF, R2MFC, TONE, and the like. The signal receiver module 136 is a module that receives a signal of a private exchange and detects DTMF, R2MFC, TONE, and the like, and transmits the signal to the central processing unit (CPU) 130. The CPU 130 controls the operation of each part of the private exchange according to the program stored in the ROM 126. The ROM 126 stores an operation program and a control program of the CPU 130, and the RAM 128 temporarily stores data according to program execution of the CPU 130.

In addition, referring to FIG. 4, which shows an internal block diagram of the PRS trunk 102 of FIG. 3 having a PRS detector for detecting a PRS transmitted from a local exchange, the ring detector 200 is a ring signal transmitted from a trunk line. Detect. The trunk line matching unit 202 matches the ring detection unit 200 with the trunk line impedance. The codec unit 204 converts an analog signal into a digital signal or a digital signal into an analog signal and is connected to the switching circuit 104. The PRS detecting unit 206 detects the PRS and sends it to the I / O interface unit 208 when the PRS received from the trunk line is inverted from high to low or low to high, and the I / O interface unit 208 transmits the PRS. The PRS detected by the PRS detector 206 is applied to the CPU 130.

FIG. 5 is a flowchart illustrating a process of selectively detecting two types of PRSs shown in FIGS. 1 and 2 according to an embodiment of the present invention. The operation according to the flowchart of FIG. 5 is programmed in the ROM 126 to be performed by the CPU 130 of FIG. 1.

Hereinafter, a process of selectively detecting two types of PRSs by the CPU 130 will be described in detail with reference to FIGS. 3 and 5. First, the user sets the operation time of the PRS to 0 or 300msec on the MMC during system initialization.

The CPU 130 checks whether there is a trunk line transmission from the extension subscriber in step 502 of FIG. If there is no trunk line transmission in step 502, the CPU 130 continues to be in a standby state. On the other hand, when there is a trunk line transmission from an extension subscriber, the CPU 130 proceeds to step 504 to clear the PRS counter, and proceeds to step 506 to PRS through the PRS detector 206. Check if is detected. In step 506, when the CPU 130 detects the PRS through the PRS detector 206, the CPU 130 checks the PRS once again by delaying for a predetermined time in step 508, and proceeds to step 510. Check if the operation time is specified as 0. If the user designates the operation time of the PRS as 300 msec, the private exchange enters the variable PRS detection mode and detects the variable PRS. Therefore, the CPU 130 proceeds to step 512 to check whether the PRS detected at the start of the call is detected again after 300 msec has elapsed. If the PRS is detected again after 300 msec has elapsed in step 512, the CPU 130 proceeds to step 514 to increase the value of the PRS counter and proceeds to step 516 to check whether the call is terminated. If the call is not terminated in step 516, the CPU 130 returns to step 512 to perform steps 512 to 516 again. On the contrary, if the call is terminated in step 516, the CPU 130 proceeds to step 518 to output the value of the PRS counter and returns to step 502 to enter the standby state.

Unlike the above, if the user designates the operation time of the PRS to 0, the private exchange enters the continuous PRS detection mode and detects the continuous PRS. Therefore, the CPU 130 proceeds from step 510 to step 520 to check whether the PRS detected at the start of the call is detected again through the PRS detector 206. If the PRS is not detected in step 520, the extension subscriber is still in a call, and thus, the CPU 130 proceeds to step 522 and increases the value of the PRS counter whenever a predetermined time elapses. The predetermined predetermined time refers to a time preset by the user at a predetermined size during system initialization for charging in a private exchange fixed to detect a continuous PRS. On the other hand, if the PRS is detected in step 520, the extension is terminated by the subscriber, and the CPU 130 outputs the value of the PRS counter in step 524, and returns to step 502 to become a standby state. .

Therefore, when the system is initialized in the private exchange, the private exchange enters the variable or continuous PRS detection mode according to the operation time of the PRS designated by the MMC, thereby selectively detecting the variable or continuous PRS transmitted from the local exchange.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. Particularly, in the embodiment of the present invention, the case where the operation time of the variable PRS is designated as 300 msec in the private exchange is illustrated. However, the operation time of the variable PRS may be set to a different value to match the operation time of the variable PRS of each local exchange.

Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the equivalents of the claims.

As described above, according to the present invention, the private exchange enters the variable or continuous PRS detection mode according to the operation time of the PRS designated by the user, thereby selectively detecting the variable or continuous PRS. Therefore, the user can change the PRS detection mode of the private exchange according to the type of PRS transmitted by each local exchange.

Claims (3)

In the method for processing the continuous and variable polarity inversion signal in a private exchange, A process in which the private exchange enters a continuous, variable polarity inversion signal detection mode according to the operation time of the polarity inversion signal specified by the user at system initialization; When the private exchange enters the variable polarity inversion signal detection mode, checking whether the variable polarity inversion signal is detected when there is a trunk line transmission from an extension subscriber; If the variable polarity inversion signal is detected at the start of a call, checking whether the variable polarity inversion signal is detected again after an operation time of the specified polarity inversion signal has elapsed; Incrementing the polarity inversion signal counter when the variable polarity inversion signal is detected again after the operation time of the specified polarity inversion signal elapses; Outputting a value of the polarity inversion signal counter when a call ends; When the private exchange enters the continuous polarity reverse signal detection mode, checking whether the continuous polarity reverse signal is detected when there is a trunk line transmission from an extension subscriber; Incrementing the polarity inversion signal counter if the continuous polarity inversion signal is not detected again for a predetermined time after being detected at the beginning of a call; And if the continuous polarity inversion signal is detected again, outputting a value of the polarity inversion signal counter. The method of claim 1, In the continuous polarity inversion signal detection mode, the private exchange operates to detect the continuous polarity inversion signal when the operation time of the polarity inversion signal is set to 0 by the user. . The method of claim 1, The variable polarity inversion signal detection mode operates the private exchange to detect the variable polarity inversion signal when the operation time of the polarity inversion signal is designated by the user as a time corresponding to the interval between the polarity inversion points of the variable polarity inversion signal. Polarity reverse signal processing method in a private exchange characterized in that.