KR100444523B1 - Method for determining optimum transmission symbol rate of modulator/demodulator, especially minimizing transmission delay of data - Google Patents

Abstract

PURPOSE: A method for determining an optimum transmission symbol rate of a modulator/demodulator is provided to minimize the transmission delay of the data by determining the symbol rate and the carrier frequency through analyzing the power distribution of the received signal frequency. CONSTITUTION: A method for determining an optimum transmission symbol rate of a modulator/demodulator is characterized in that it is initialized as the most upper symbol rate and the carrier frequency by using the frequency characteristics table for each symbol rate, and it calculates each of the high frequency signal power of the central frequency of the top side wavelength range and the bottom side wavelength range of the carrier frequency from the signal received from the modulator/demodulator. And, it also adjusts the symbol rate and the carrier frequency by using each of the high frequency signal power.

Description

Method for Determining Optimum Transmission Symbol Rate of Modulator

The present invention relates to a handshaking process for determining a transmission channel between modulators used in a data transmission apparatus, and in particular, an optimum transmission of a modem for determining a symbol rate and a transmission frequency band of a modulator. It relates to a symbol rate determination method.

In general, a demodulator is a kind of data relay that is used in a digital transmission device to modulate the digital data to be transmitted in the form of an analog signal and to recover the digital data from the received analog signal. Such a demodulator must maintain an optimal channel state with the other side's demodulator in order to accurately relay digital data.

In addition, the modulator demodulates in accordance with the demand for high speed data transmission, and has a trend of having a plurality of symbol rates and carrier frequencies to enable data communication with a low demodulation demodulator. For example, the demodulator may have six symbol rates of 2400, 2743, 2800, 3000, 3200, and 3429 symbol rates, and corresponding carrier frequencies, as shown in the table of FIG.

In the full-duplex demodulator, the demodulator on the transmitting or receiving side had to shake hands with the demodulator on the other side to match the symbol demodulation and the carrier frequency with the other side demodulator. To this end, in the data transmission apparatus including the demodulator, the symbol demodulation and carrier frequency of the demodulator are gradually lowered from the highest value to the lowest value, and the optimal transmission symbol rate of the modulator for detecting an error-free symbol rate and carrier frequency is detected. Determination methods are used. This method of determining the optimal transmit symbol rate causes the demodulators on both sides (i.e., the transmit / receive side) to involve multiple handshaking until the symbol rate is matched from the symbol value of the highest value. For this reason, the conventional method for determining the optimal transmission symbol rate of the modulator requires much time until the symbol rate and carrier frequency between the modulators are matched. Problems of the conventional transmission symbol rate determination method of the conventional demodulator will be described with reference to FIGS. 2 and 3.

2 shows a typical data transmission apparatus including a modulator. In FIG. 2, the data transmission device is referred to as an input / output device 10 for inputting and outputting data, and a micro controller unit (hereinafter referred to as "MCU") connected in series with the input / output device 10. 14, a modulator 16, and a memory 12 connected to the MCU 14. The input / output device 10 transmits data and control commands to be transmitted from the operator to the MCU 14. The MCU 14 transmits data from the input / output device 10 to the communication network 11 via the modulator 16, and inputs data received from the communication network 11 via the modulator 16. Output via the output device 10. The MCU 14 performs handshaking to match the symbol rate and carrier frequency of the demodulator (not shown) and the demodulator 16 of the counterpart connected to the communication network 11. The memory 12 temporarily stores the data to be transmitted and the information processed by the MCU 14, and also stores the symbol rate and carrier frequency table shown in FIG. The demodulator 16 modulates data to be transmitted toward the communication network 11 in the form of an analog signal using a carrier wave of the frequency specified by the MCU 14 and demodulates the data from the analog signal from the communication network 11.

3 is a flowchart illustrating a method of determining an optimal transmission symbol rate of a conventional modem, which is performed by the MCU 14 shown in FIG. The flowchart of FIG. 3 will be described in conjunction with the circuit of FIG.

The MSU 14 sets the demodulator 16 to the mode of the highest symbol rate and carrier frequency (step 20), and then searches whether the received data symbol from the modulator 16 contains an error ( Step 22). If an error occurs in the data symbol received in step 22, the MCU 14 resets the modulator 16 to the mode of the next symbol rate and carrier frequency and then returns to step 22 (step 24). ). On the other hand, when there is no error in the data symbol received in step 22, the MCU 16 sets the symbol rate and the carrier frequency set in the modulator 16 as the symbol rate and the carrier frequency of the transmission channel (26th). step). The MCU 14 transmits and receives data through the modulator 16 (step 28).

As described above, in the conventional method of determining the optimal transmission symbol rate of the modulator, handshaking is performed until the error does not occur in the received data symbol while sequentially setting the symbol rate and the carrier frequency of the modulator from the highest value to the lower value. Must be repeated. For this reason, the conventional method for determining the optimal transmission symbol rate of a modulator has not only a long time to match the symbol rate and the carrier frequency between the modulators, but also has a disadvantage of delaying data transmission.

Accordingly, an object of the present invention is to provide a method for determining an optimal transmission symbol rate of a demodulator capable of minimizing a handshaking process and shortening a data transmission delay time.

In order to achieve the above object, the method for determining the optimum transmission symbol rate of the modulator according to the present invention comprises the steps of determining the average power at the carrier frequency of the received signal, initial setting the highest symbol rate and carrier frequency for the modulator; Retrieving a lower band upper / lower reference frequency power from the received signal; retrieving a lower band center frequency power from the lower band upper / lower reference frequency power; A first comparing step of comparing with a lower limit threshold of an included frequency band, retrieving an upper band upper / lower reference frequency power from the received signal, and a center frequency of an upper band from the upper band upper / lower reference frequency power; Retrieving power; and the signal source includes the upper band center frequency power. And a second comparison step of comparing the upper limit threshold value with each other, and determining an optimal symbol rate and a carrier frequency according to the comparison result of the first and second comparison processes.

The method of determining an optimal transmission symbol rate of the modulator further includes adjusting the symbol rate and the carrier frequency according to a comparison result of the first and second comparison processes.

The method for determining an optimal transmission symbol rate of a demodulator according to the present invention comprises initial setting the highest symbol rate and a carrier frequency using a frequency characteristic table for each symbol rate, and an upper band of the carrier frequency from a signal received from the modulator. Obtaining each high frequency signal power of the center frequency of the lower band and adjusting the symbol rate and the carrier frequency using the high frequency signal power.

Other objects and advantages of the present invention in addition to the above object will become apparent from the detailed description of the embodiments of the present invention with reference to the accompanying drawings.

Hereinafter, with reference to FIGS. 4 and 5 attached to an embodiment of the present invention will be described in detail.

4 is a flowchart illustrating a method for determining an optimal transmission symbol rate of a demodulator according to an embodiment of the present invention, which is performed by the MCU 14 illustrated in FIG. 2. The flowchart of FIG. 4 performed by this MCU 14 will be described as follows.

First, the MCU 14 obtains power distribution in the frequency domain with respect to the input signal received by the modulator 16. This power distribution data is stored in the memory 12 by the MCU 14. The MCU 14 sets the highest symbol rate R (0) of 3429 and the low carrier frequency mode of 1959 KHz in the symbol characteristic frequency characteristic table as shown in FIG. 5 (step 32). The MCU 14 then determines the power P _A of the received high frequency signal at the primary lower band lower limit reference frequency f _A , e.g. 150 KHz, for the mode of the 3429 symbol rate and the low carrier frequency of 1959 KHz, the primary lower side. The power P _B of the received high frequency signal at the band upper limit reference frequency f _B , for example, 300 KHz, is searched from the input power distribution data (step 34). First lower-sideband lower limit reference frequency power P _A of the high-frequency signal at f _A, and the first lower-sideband upper reference frequency f by using the power P _B of the high-frequency signal in the _B primary lower sideband power of the RF signal at the center frequency P _L is calculated by the following equation (36).

K _L in Equation 1 is an experimentally obtained constant and is calculated by Equation 2 below.

In this equation, f _L is the center frequency of the first lower band. Next, the MCU 14 compares whether the power P _L of the high frequency signal at the first lower band center frequency f _L is greater than the product of the first critical slope α and the reference power P _ref (step 38). The first critical slope α and the reference power P _ref are experimentally obtained values, and the reference power P _ref is assumed to be a power value at a frequency of 1050 KHz in the frequency power distribution. This is because the linear distortion is the least in the 1050 KHz band. Steps 34 to 38 calculate the power of the high frequency signal at the first lower band frequency with respect to the set carrier frequency and determine whether the power is above a predetermined value.

In a step 38, when the power P _L of the high frequency signal at the center frequency of the first lower side band is smaller than the product of the first critical slope α and the reference power P _ref , the MCU 14 performs the carrier frequency of the current received high frequency signal. And the lower carrier frequency f _C (0) (0) of the modulator 16 set as described above do not coincide, and the carrier frequency f _C that can be used for the highest symbol rate R (0) is set to the low frequency carrier frequency f _C (0). Readjust to the high carrier frequency f _C (0) (1) instead of (0) (step 40). At this time, if the current symbol rate is R (1) = 3200 in the table of FIG. 5, according to the comparison result of step 38, in step 40, the carrier frequency is 1920 instead of 1829 KHz as the carrier frequency f _C (0) (0). Set the high frequency carrier frequency f _C (0) (1) in KHz. Subsequently, the MCU 14 receives the power P _A of the received high frequency signal at the first lower band lower limit reference frequency f _A for the set high carrier frequency f _C (0) (1), and the first lower band upper limit reference frequency f _B. In step 42, the power P _B of the received high frequency signal is retrieved from the input power distribution data. The power P of the high frequency signal at the primary lower band center frequency using power P _A of the high frequency signal at the first lower band lower limit reference frequency f _A and the power PB of the high frequency signal at the first lower band upper limit reference frequency f _{B. L} is calculated by Equation 1 (44). Next, the MCU 14 compares whether the power P _L of the high frequency signal at the first lower band center frequency f _L is greater than the product of the first critical slope α and the reference power P _ref (step 46). At this time, when the power P _L of the high frequency signal at the center frequency of the first lower side band is smaller than the product of the first critical slope α and the reference power P _ref , the MCU 14 may be connected to the carrier frequency of the current received high frequency signal. It is determined that the set high frequency carrier frequency f _C (0) (1) of the modulator 16 does not match.

When the power P _L of the high frequency signal at the lower band center frequency in step 38 or 46 is greater than the product of the first critical slope and the reference power P _ref , that is, the currently received high frequency signal of the modulator 16 is set. In the case of including the first lower band component for the carrier frequency, the MCU 14 performs the power P _D and the upper band upper limit reference frequency f _E of the high frequency signal at the set symbol rate and the upper band lower limit reference frequency f _D for the carrier frequency. In step 48, the power P _E of the high frequency signal in is searched for from the input frequency power distribution. For example, if the symbol rate is R (0) = 3429, which is the highest symbol rate shown in FIG. 4, and the carrier frequency is 1959 Hz, the upper band lower limit reference frequency f _D is 3600 Hz, and the upper band upper limit reference frequency f _E is 3750 Hz. Received high frequency signal power at the high sideband center frequency f _U with respect to the carrier frequency set in the modulator 16 using the power P _D and P _E of the high frequency band upper and lower reference frequencies retrieved in step 48. P _U is calculated by the following equation (3).

In Equation 3, K _U is an experimentally obtained constant and is determined by Equation 4 below.

As in Equation 4, K _U is determined by the upper band lower limit reference frequency f _D and the upper band center frequency f _U obtained in the 48th step. It is checked whether the power P _U of the high frequency signal at the upper band center frequency obtained in step 50 is greater than the product of the second critical slope β and the reference power P _ref (step 52). At this time, if the power P _U of the high frequency signal at the upper band center frequency obtained in the 50th step is smaller than the product of the second critical slope β and the reference power P _ref , the MCU 14 determines that the carrier frequency of the received high frequency signal is It is assumed that it does not coincide with the set carrier frequency.

The power P _L of the high frequency signal at the center frequency of the first lower band in step 46 is less than the product of the first critical slope α and the reference power P _ref , or the power of the high frequency signal at the center frequency of the upper band in step 52. When P _U is less than the product of the second critical slope β and the reference power P _ref , the MCU 14 performs the carrier frequency of the current received high frequency signal and the high frequency carrier frequency f _C (0) of the set modulator 16. Determines that mismatches result in readjusting the symbol rate R (i) and the corresponding carrier frequency f _C (j) to the next symbol rate and the low carrier frequency f _C (0) that can be used for the symbol rate, Return to step (step 54). If the current symbol rate in FIG. 4 is R (0) = 3429 and the carrier frequency is f _C (1) = 1959 Hz, the readjusted symbol rate R (i) and the carrier frequency fc (j) are respectively the next lower The symbol rate R (1) = 3200 and the low carrier frequency fc (1) (0) = 1829 Hz.

Finally, when the upper band average frequency power P _U is greater than the product of the upper limit threshold slope β and the reference frequency power P _ref in step 52, the MCU 14 may have a symbol rate and a carrier frequency to be applied to the current demodulator 16. In operation 56, the symbol rate and the carrier frequency are determined as the symbol rate and the carrier frequency of the modulator 16, as determined to be appropriate.

As described above, the method for determining the optimal transmission symbol rate of the demodulator according to the present invention can analyze the power distribution of the received signal frequency and determine the symbol rate and the carrier frequency of the modulator so that the handshaking can be shortened by one time and the determination time. Can shorten. Accordingly, the method for determining the optimal transmission symbol rate of the modulator according to the present invention can minimize the transmission delay of data and further improve the reliability of the product.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 is a table showing the symbol rate of a modulator and its carrier frequency.

2 is a block diagram of a typical data transmission apparatus.

3 is a flowchart illustrating a process of determining an optimal transmission symbol rate of a conventional modulator.

4 is a flowchart illustrating an optimal transmission symbol rate method of a demodulator according to an embodiment of the present invention.

5 is a table showing the symbol rate and frequency characteristics of the demodulator used in the present invention.

Explanation of symbols on the main parts of the drawings

10: input / output device 11: communication network

16 microcontroller unit 14 memory

16: change demodulator

Claims (5)

Determining an average power at a carrier frequency of the received signal; Initially setting the highest symbol rate and carrier frequency for the demodulator; Searching for a lower band upper / lower reference frequency power in the received signal; Retrieving a lower band center frequency power from the lower band upper / lower reference frequency power; A first comparing step of comparing the lower band center frequency power with a lower limit threshold of a frequency band including a signal source; Retrieving an upper sideband upper / lower limit reference frequency power from the received signal; Retrieving a center frequency power of an upper band from the upper / lower limit reference frequency power of the upper band; A second comparing step of comparing the upper band center frequency power with an upper limit threshold including a signal source; Determining an optimal symbol rate and a carrier frequency according to a comparison result of the first and second comparison processes. The method of claim 1, And adjusting the symbol rate and the carrier frequency according to the comparison result of the first and second comparison processes. Initial setting to a highest symbol rate and a carrier frequency using a frequency characteristic table for each symbol rate; Obtaining each of the high frequency signal powers of the center frequency of the lower band of the upper frequency band of the carrier frequency from the signal received from the modulator and adjusting the symbol rate and the carrier frequency using the respective high frequency signal powers. A method for determining optimal transmission symbol rate of a demodulator. The method of claim 3, wherein The high frequency signal power P _L at the lower band center frequency is calculated by equations (1) and (2).

Where f _L is the lower band center frequency, f _A is the lower band lower limit reference frequency, P _A is the high frequency signal power at the lower band lower limit reference frequency, and P _B is the high frequency signal power at the lower band upper limit reference frequency. to be. The method of claim 3, wherein The power P _U of the high frequency signal at the upper band center frequency is calculated by equations (3) and (4).

Where f _U is the upper band center frequency, f _D is the upper band lower limit reference frequency, P _D is the high frequency signal power at the upper band lower limit reference frequency, and P _E is the high frequency signal power at the upper band upper limit reference frequency. to be.

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