KR20000052149A - Data demodulating apparatus - Google Patents

Abstract

PURPOSE: A data demodulating apparatus is provided to achieve a noiseless data demodulation by a correct level detection from a multi level frequency shift keying(FSK) demodulation signal. CONSTITUTION: A data demodulating apparatus comprises a limiter(400) for amplitude-limiting a multi level FSK signal into a predetermined level and outputting the result, a band-pass filter(410) for performing band-pass filtering for the FSK signal output from the limiter(400), a sampling unit(420) for sampling the FSK signal passed the band-pass filter(410) during an inputted clock period, an analog to digital converting unit(430) for converting the sampled FSK signal output from the sampling unit(420) into a digital signal, and a control unit(440). The control unit(440) generates a clock corresponding to a demodulation level, restores the digital data output from the analog to digital converting unit(430) during a clock period inputted to the sampling unit(420), compares the restored data with a configuration of data frame, and outputs a binary data if the restored data matches with the configuration of data frame.

Description

Data demodulating apparatus

The present invention relates to a demodulation device, and more particularly, to a data demodulation device for demodulating data through level detection for multiple frequency shift keying (FSK) signals.

In demodulating a signal modulated by FSK in an FSK modulation / demodulation device, which is widely used in a wireless telephone, a terminal, or a wireless device, a method of detecting a level with respect to a two-level FSK has conventionally been used.

1 is a block diagram showing the configuration of a conventional data demodulation device.

FIG. 2 is a spectral diagram of a signal input to the apparatus of FIG. 1 according to a two level frequency shifting scheme. FIG.

3 is a waveform diagram of signals input / output to the apparatus of FIG.

The wireless signal input through the antenna (not shown) is demodulated and output as a base band signal while passing through a demodulator (not shown). At this time, the output two-level FSK signal is well shown in the spectrum diagram of FIG. 2 and the input signal of FIG. The signal is input to the limiter 100 to remove signals of a predetermined level or more, and to pass through a base band filter 110 to remove harmonics and noise. The diode detector 120 performs level detection and inputs the signal to a bistable multivibrator 140 via a low pass filter 130. The signal output from the diode detector 120 is input to the bistable multivibrator 140 via a carrier clamp 150. Thus, the bistable multivibrator 140 receiving the two signals executes a binary output through internal signal processing. At this time, the output signal is fed back to the band pass filter 110 to remove noise, and the above process is repeated, and the final output signal is the same as the output signal of FIG. 3.

As described above, when the FSK demodulation signal level is detected through an analog circuit and the binary data is output from the bistable multivibrator 140, an error occurs or the noise is not detected because the signal level is not accurately detected near a threshold. The data is often broken by

In addition, the signal demodulated only by the two-level FSK can detect the level, but it is difficult to detect the level of the multiple FSK demodulated signal demodulated together with the two or four levels.

The technical problem to be achieved by the present invention is to provide a data demodulation device for recovering data by error-free accurate level detection from a multi-level FSK demodulation signal.

1 is a block diagram showing the configuration of a conventional data demodulation device.

FIG. 2 is a spectral diagram of a signal input to the apparatus of FIG. 1 according to a two level frequency shifting scheme. FIG.

3 is a waveform diagram of signals input / output to the apparatus of FIG.

4 is a block diagram showing the configuration of a data demodulation device according to the present invention.

5 is a spectral diagram of a signal input to the apparatus of FIG. 4 in accordance with a four-level frequency shifting scheme.

6 is a waveform diagram of signals input / output to the apparatus of FIG.

The data demodulation device for solving the technical problem to be achieved by the present invention is a device for demodulating the original data from the multi-level FSK signal output by demodulating the signal input through the antenna,

A limiter for amplitude-limiting the multi-level FSK signal to a predetermined level and outputting the amplitude limiter;

A band pass filter for passing the FSK signal output from the limiter to a predetermined band;

A sampling unit for sampling an FSK signal passing through the bandpass filter during an input clock period;

An analog / digital converter converting the sampled FSK signal output from the sampling unit into digital; And

A control unit for generating a clock corresponding to a demodulation level, restoring a clock period inputted from the analog / digital converter to the sampling unit, and outputting binary data when the data is matched with a structure of a data frame; It is preferable to include.

In the present invention, the control unit has a structure of a different data frame according to the demodulation level of the FSK signal, and recovers the clock period inputted to the sampling unit from the digital data outputted from the analog / digital converter and compares the structure of the data frame. If it does not match, it is characterized by restoring data by generating a clock corresponding to the demodulation level up to the maximum level of the FSK signal input to the limiter.

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

4 is a block diagram showing the configuration of a data demodulation device according to the present invention.

The apparatus illustrated in FIG. 4 includes a limiter 400 for limiting an input FSK signal to a predetermined level, a bandpass filter 410 for passing only a predetermined band of the signal output from the limiter 400, and a bandpass filter 410. A sampling unit 420 for sampling the output signal according to a clock control signal input from an external source, an analog / digital conversion unit 430 for converting a sampling signal output from the sampling unit 420 into a digital signal, and analog / digital conversion The controller 440 restores the data based on the symbol period of the clock output from the digital signal output from the unit 430 to the sampling unit 420 and compares it with the basic structure of the data frame. It is composed.

5 is a spectral diagram of a signal input to the apparatus of FIG. 4 in accordance with a four-level frequency shifting scheme.

6 is a waveform diagram of signals input / output to the apparatus of FIG.

Hereinafter, the present invention will be described in detail with reference to FIGS. 4 to 6.

The signal input through the antenna (not shown) is demodulated by a high frequency demodulator (not shown), and the output signal is well represented in the spectral diagram of the 4 level FSK of FIG. 5 and the multi level input signal of FIG. have.

The limiter 400 limits the FSK signal to a predetermined level, and the bandpass filter 410 passes only a signal of a predetermined band among the signals limited to the predetermined level.

When the signal output from the bandpass filter 410 is input to the sampling unit 420, the control unit 440 outputs a clock set as a default value of a symbol period corresponding to a basic demodulation level for sampling to the sampling unit 420. do.

The sampling unit 420 samples the signal output from the bandpass filter 410 by the symbol period with the initial clock output from the control unit 440.

The analog / digital converter 430 converts the signal sampled by the sampling unit 420 into digital and outputs the digital signal to the controller 440.

The control unit 440 is a digital signal output from the analog / digital converter 430 to restore the data according to the symbol period of the clock initially sent to the sampling unit 420 to compare the basic structure of the data frame with the same case. Print binary data. The basic structure of the data frame in the controller 440 is different depending on the FSK demodulation level.

If the initially sent symbol period clock is not correct, the controller 440 outputs the symbol period clock corresponding to the second demodulation level to the sampling unit 420 to sample again. The resultant value is sent to the analog / digital converter 430 to be converted into a digital signal and output to the controller 440. The control unit 440 restores the data by the symbol period of the second clock and compares it with the basic structure of the data frame to output binary data in the same case.

However, if the sent symbol period clock does not match again, the controller 440 outputs the symbol period clock corresponding to the third demodulation level to the sampling unit 420 to sample again. The resultant value is sent to the analog / digital converter 430 to be converted into a digital signal and output to the controller 440. The control unit 440 restores the data according to the symbol period of the third sent clock and outputs binary data in the same case compared with the basic structure of the data frame, as shown in the output signal of FIG. 6.

As described above, when an error occurs because the data is not restored to the maximum level of the FSK demodulation signal level input to the limiter 400 and the error does not match the basic structure of the data frame, the sampling unit 420 only clocks up to the symbol period of the maximum level of the demodulation signal. Will output If this process is performed during one cycle, most of the demodulated data is completely generated without error. However, if the phase-locked loop (PLL) is not locked properly or the system is unstable at the beginning or the middle, an error occurs and the above process is repeated one cycle. Thus, it is possible to recover the complete demodulation symbol without errors.

The present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the spirit of the invention.

As described above, according to the present invention, since the clock is generated and sampled for the FSK signal by the symbol period, even if a demodulation signal of any level is mixed, noise-free data recovery by accurate level detection is possible.

Claims (3)

In the apparatus for demodulating the original data from the multi-level FSK signal output by demodulating the signal input through the antenna, A limiter for amplitude-limiting the multi-level FSK signal to a predetermined level and outputting the amplitude limiter; A band pass filter for passing the FSK signal output from the limiter to a predetermined band; A sampling unit for sampling an FSK signal passing through the bandpass filter during an input clock period; An analog / digital converter converting the sampled FSK signal output from the sampling unit into digital; And A control unit for generating a clock corresponding to a demodulation level, restoring a clock period inputted from the analog / digital converter to the sampling unit, and outputting binary data when the data is matched with a structure of a data frame; Data demodulation device comprising. The method of claim 1, wherein the control unit A data demodulation device comprising a structure of a data frame different in accordance with a demodulation level of an FSK signal. The method of claim 2, wherein the control unit When the digital data output from the analog / digital converter is restored during the clock period input to the sampling unit and does not match with the structure of the data frame, the demodulation level corresponds to the maximum level of the FSK signal input to the limiter. A data demodulation device, comprising: generating a clock to restore data.