KR100362587B1 - Method for measuring dial pulse - Google Patents

Abstract

PURPOSE: A method for measuring dial pulse is provided to detect a dial pulse by using a digital signal processor, thereby enhancing a response speed and reliability when detecting the dial pulse. CONSTITUTION: When an input level of a dial pulse is higher than a predetermined reference value, a digit counter counts as '0' and at the same time a count is performed for detecting a pulse high time. Thereafter, after the dial pulse is maintained and admitted as a pulse, the digit counter counts as '1' at a downward edge of the dial pulse and at the same time a count is performed for detecting a pulse 1 period time. Thereafter, when the dial pulse is applied and admitted as a pulse, after the digit counter counts by '1' and in a case that the dial pulse is not applied, it is sensed that an input level is maintained as a ground level for a predetermined time. Thereafter, when the input level is the ground level for a predetermined time, a pulse high time and pulse 1 period time are detected and outputted by digit result value of the digit counter and a sample counter.

Description

Dial pulse measuring method.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of measuring a dial pulse, and more particularly, to a method for measuring a dial pulse generated at a subscriber station using a digital signal processor (hereinafter, referred to as a DSP).

In general, a subscriber station generates a dial pulse for an incoming service. A dial pulse is a pulse generated by a dial, which is a part of an automatic telephone, also called an impulse. Therefore, there is a measurement item of an exchange that checks the state of a terminal for the best access from another subscriber to the subscriber under measurement. Therefore, it is necessary to detect a dial pulse for maintenance.

Accordingly, an object of the present invention is to provide a dial pulse measuring method for increasing the reliability and having a fast response speed in detecting a dial pulse using a digital signal processor.

In the digital signal processing for inputting a dial pulse of a subscriber station to achieve the objects of the present invention, in the method for measuring the dial pulse, the digit counter is set to 0 when the input level of the dial pulse is higher than a preset reference value. The first step of performing a sample counter for detecting pulse high time at the same time as the counter, and after the first step the dial pulse is continued to be recognized as a pulse, and the digit counter is counted to 1 at the falling edge of the dial pulse. And a second counter for performing a sample counter for detecting a pulse one cycle time, and adding the digit counter by one at a falling edge of the dial pulse when the dial pulse is applied and recognized as a pulse after the second step. Also, if the dial pulse is not applied, the input level is A third process of sensing that the ground level is maintained for a predetermined time; and returning to the third process when the dial pulse is applied within the predetermined time after the third process, and when the input level is the ground level during the predetermined time. And a fourth process of detecting and outputting the digit result value by the digit counter and the pulse high time and the pulse 1 cycle time by the sample counter.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that like elements in the figures represent like reference numerals wherever possible.

As used herein, the term " pulse one cycle time " denotes a value multiplied by a sampling period by a sampling value generated in one pulse period. The term " pulse high time " denotes a value multiplied by a simplification period by a sampling value generated during a high level of one pulse period.

A system block diagram for carrying out the invention is shown in FIG. A description with reference to FIG. 1 is as follows.

The dial pulse generated in the subscriber station 112 is applied to the pie pulse detector 114. Then, the DSP 116 of the dial pulse detector 114 recognizes the dial pulse and calculates a digit, a pulse high time, and a pulse 1 cycle time according to the dial of the subscriber station 112.

A flowchart showing a method of measuring a dial pulse using a general purpose digital signal processor in accordance with the present invention is shown in FIG.

First, FIG. 1 is configured using the programming language of DSP, and the examiner checks the state of the subscriber terminal by using the path generated while talking with the subscriber. The dial pulses received at the tip and ring ends are analog signals. The analog signal of the dial pulse is converted into 16-bit sample data of 8KHz through an analog / digital converter that converts the analog signal into a digital signal. Thus, the pulse measurement data to be obtained by calculating this in the DSP are obtained.

In this regard, first, DSP 116 linearizes data to convert the analog signal of the input dial pulse signal through the 14-bit A / D converter and convert it into data suitable for an operation function of 125 msec every frame. Since this linearized data can be negative along the direction of the tip and ring ends, the absolute pulses are taken from this data and compared to the reference value of 1.2V, so that the dial pulse is "high". Determine if you are in a state. That is, when the dial pulse is to be measured in step 211, step 211 is transitioned to step 212. The reference value is then compared with the data leveled at step 212. Accordingly, when the data input level is larger than the reference value, the dial pulse is in a "high" state, and the digit counter (hereinafter referred to as DC) becomes zero in step 213. In step 214, the pulse counter performs a sample counter to detect the pulse high time while the " high " state continues and stores it in the memory of the DSP. Thereafter, in step 215, DC is 0 rather than 1, so step 214 transitions to step 217. In step 217, the glitch of the input signal included in the dial pulse is checked to detect the input of the pulse, thereby checking the continuity of the pulse signal. In step 218, if the sum of the frames is 10 ₁₆ or more, the pulse is recognized and the digit town counter is counted by one at the falling edge of the signal in step 219, and the DC becomes 1. In addition, since there is no pulse applied in step 218, if it is not recognized as a pulse, step 218 transitions to step 220. If the signal ground level (GrouND: hereinafter referred to as GND) input in step 220 is greater than a predetermined time, that is, 300 msec or more, it is recognized that the pulse is terminated and step 220 transitions to step 221. When the GNB of the input signal does not last 300 msec or more in step 220, step 220 returns to step 215. This is because DC is one.

In step 215, since DC is 1, step 215 transitions to step 216. The state of the dial pulse input at this time is "low". In step 216, while the pulse " low " state is continued, a sample counter is performed to store a pulse count period time in memory of the DSP. If the dial pulse continues to be applied, the pulse state transitions from "low" to "high". If the continuity of the pulse is checked at step 217, the sum of the frames at step 218 is 10 ₁₆ or more, and the dial pulse is recognized as a pulse. do. Then DC is countered to 2 at the falling edge of the dial pulse by step 219. Then, when the input GND does not pass a predetermined time in step 220, the process returns to step 213, and the process is now performed in step 217.

This is repeated while the dial pulse continues to be applied. In step 220, when the dial pulse is not input and the input GND has elapsed for a predetermined time, step 220 transitions to step 221. Therefore, the number of dial pulses input by DC can be detected, and the pulse high time can be measured by multiplying the sample period by the sample counter of pulse "high" time, and the sample counter of pulse one cycle time is sampled. By multiplying the period, the pulse 1 period time can be measured. The measured value is transmitted to the dial pulse detector 114, and then initializes the values of the memory, for example, the register used in the calculation process, and waits for the next pulse.

A waveform diagram showing the Fiji counter value for the dial pulse of the present invention is shown in FIG. Hereinafter, a description will be given with reference to FIGS. 2 and 3.

When the dial pulse is applied as shown in the waveform of FIG. 3, BC becomes 0 at the first rising edge of which the input level is higher than the reference value, and a sample counter for detecting pulse high time is started. In addition, since the pulses are recognized by the steps 217 and 218, the DC is countered to 1 at the first falling edge, and from this time, the sample counter for detecting the pulse 1 period time is started. Since the dial pulse is continuously applied, it is recognized as a pulse by steps 217 and 218, and the DC is countered to 2 at the second falling edge. Thereafter, if the input signal continues to be GND to pass the predetermined time T in step 220, it is determined that the dial pulse is no longer applied. In step 221, the digit, pulse high time, and pulse 1 cycle time are output.

As described above, by implementing a dial pulse detection function on the DSP for checking the state of the telephone terminal 112, which is a subscriber station, a faster response time and accurate test are realized, which contributes to improving the reliability of the exchange.

1 shows a block diagram for carrying out the present invention.

2 is a flow chart showing a method of measuring a dial pulse using a general purpose digital signal processor in accordance with the present invention.

3 is a waveform diagram showing a digit counter value for a dial pulse of the present invention.

Claims (1)

In digital signal processing for inputting a dial pulse of a subscriber station, the method for measuring the dial pulse, A first step of counting a digit counter to zero and performing a sample counter to detect pulse high time when an input level of the dial pulse is higher than a preset reference value; A second step of performing a sample counter for detecting a pulse one cycle time at the falling edge of the dial pulse after the dial pulse is recognized as a pulse after the first step, and at the falling edge of the dial pulse; After the second process, when the dial pulse is applied and is recognized as a pulse, the digit counter is added by one at the falling edge of the dial pulse, and when the dial pulse is not applied, the input level is grounded for a predetermined time. A third process of detecting that the level persists, When the dial pulse is applied within the predetermined time after the third process, the process returns to the third process, and when the input level is the ground level during the predetermined time, the digit counter and the sample counter pulse the digit result value. A dial pulse measuring method comprising a fourth process of detecting and outputting a high time and a pulse 1 cycle time.