KR100276757B1 - Timing Error Compensation Device for Channel Modem for Satellite Communication System - Google Patents

Abstract

The present invention relates to a timing error compensator in a channel modem for a satellite communication system, which is capable of estimating and compensating timing errors of data generated due to satellites. A demodulation apparatus for a channel modem for a satellite communication system that demodulates and estimates and compensates an error for the I, Q demodulated data, the apparatus comprising: data conversion means for performing Z inverse conversion on the I, Q demodulated data; Data size generating means for generating magnitude data of the converted data, data comparing means for comparing the data applied from the data converting means with the I, Q demodulated data and outputting data corresponding to the difference, from the data comparing means Data multiplication processing means for multiplying the applied data with the reference size data, and the reference data of the I and Q demodulated data. Reference data determination means for determining, reference data conversion means for performing Z inverse transform processing of the determined reference data, reference size data generation means for generating size data of the converted reference data, data applied from the reference data conversion means and the reference data determination Reference data comparison means for comparing the reference data determined by the means, reference data multiplication processing means for multiplying the compared reference data with the size data generated in the data size generating means, data applied from the data multiplication means, and the reference data Timing error detection means for detecting the timing error component by comparing the magnitude of data applied from the multiplication processing means, and timing error compensation means for compensating and outputting the detected timing error based on the set timing error coefficient and the reference timing coefficient value. Specially configured Gong.

Description

Timing Error Compensation Device for Channel Modem for Satellite Communication System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a channel modem of a communication system using satellites. In particular, a timing error compensation apparatus in a channel modem for a satellite communication system capable of estimating and outputting a timing error of data generated due to satellites It is about.

With the recent rapid development of communication technology, wireless communication is being spread and activated to transmit and receive voice signals or data through airwave transmission network rather than the conventional wired network, so that subscribers located at remote sites can perform mutual communication through satellites. Satellite communication is becoming more and more common.

1 is a block diagram showing the internal configuration of a channel modem for a general satellite communication system.

In the figure, reference numeral 11 denotes a voice / data processor that performs an interface function between the UPH bus and the MPH bus and the channel unit processor 12, which will be described later, and specifically processes voice and data transmitted and received through an airwave transmission network. Data Processor (hereinafter referred to as SDP), and 12 is a channel unit processor (hereinafter referred to as CUP) that controls the overall configuration of the channel modem.

Further, reference numeral 13 denotes a transmission frequency synthesizer for synthesizing and outputting a predetermined frequency signal for generating an intermediate frequency signal, for example, 112.512 MHz ± 20 MHz, based on the control data from the channel unit processor 12, 14 is a reception frequency synthesizer for synthesizing and outputting a predetermined frequency signal for receiving an intermediate frequency signal, for example, 112.384 MHz ± 20 MHz, based on the control data from the channel unit processor 12.

Reference numeral 15 denotes a modulator for outputting a 512KHz modulated signal by BPSK or QPSK modulating the I, Q channel data output from the SDP 11, and 16 denotes a 512KHz output from the modulator 15. An intermediate frequency generator generates and outputs an intermediate frequency signal of 70 MHz ± 20 MHz based on a modulation signal and a frequency of 112.512 MHz ± 20 MHz and a reference frequency of 42 MHz applied from the transmission frequency synthesizer 13.

Reference numeral 17 denotes an intermediate frequency signal for outputting a modulated signal of 384 KHz based on the received 70 MHz ± 20 MHz intermediate frequency signal, the frequency of 112.384 MHz ± 20 MHz applied from the receiving frequency synthesizer 14 and the reference frequency of 42 MHz. A demodulator 18 is a demodulator for demodulating and outputting I and Q channel data from a 384 KHz modulated signal applied by the intermediate frequency signal receiver 17, and 19 stores frequency data for each frequency ID. Look-up Table.

In the above configuration, when a predetermined frequency ID is input through the UPH bus, the CUP 12 reads the frequency data corresponding to the corresponding frequency ID into the lookup table 19 to transmit the synthesizer 13 and the receive frequency synthesizer ( 14), the frequency signal (112.512 MHz ± 20 MHz, 112.384 MHz ± 20 MHz) having a variable range of 20 MHz is output controlled from the frequency synthesizer.

In the intermediate frequency signal generator 16, a 20 MHz variable is mixed by mixing a frequency signal (112.512 MHz ± 20 MHz) applied from the transmission frequency synthesizer 13 to a 512 KHz modulated signal output from the modulator 15. Generate an intermediate frequency signal (70MHz ± 20MHz) with a range. In addition, the intermediate frequency signal receiving unit 17 mixes a frequency signal (112.384 MHz ± 20 MHz) having a variable range of 20 MHz again with respect to the intermediate frequency signal having a variable range of 20 MHz to be received, corresponding to a predetermined communication channel of 384 KHz. To detect the frequency signal.

On the other hand, in a satellite communication system using satellites, data is delayed from the actual transmission time and applied to the receiver due to a long data delay due to the satellite. The channel modem on the receiving side demodulates the input data based on the timing instantaneous value set during system design.

However, in the satellite communication system, the delay time varies depending on the channel state in which data is transmitted. Therefore, when the delay time becomes longer due to poor transmission channel or deterioration of weather conditions, the timing instantaneous value of the input data is different. Since it will be different, there is a problem that the demodulation of the received data is not properly performed.

Therefore, in the demodulator of the channel modem, it is necessary to detect the exact timing instant of the data applied to the demodulator.

Accordingly, the present invention was created in view of the above circumstances, and when the data input to the demodulator of the channel modem is demodulated, the timing error of the input data is estimated and compensated for, thereby detecting the correct timing instant value of the information data. It is an object of the present invention to provide a timing error compensation device of a channel modem for satellite communication system that can be demodulated.

1 is a block diagram showing the internal configuration of a channel modem for a general satellite communication system.

Figure 2 is a block diagram showing the internal configuration of the timing error compensation device 50 of the channel modem for satellite communication system according to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

51: data conversion unit, 52: data size generation unit,

53: data comparison unit, 54: data multiplier,

55: reference data determination unit, 56: reference data conversion unit,

57: reference data size generation unit, 58: reference data comparison unit,

59: reference data multiplier, 60: error data detection unit,

61: multiplier, 62: data synthesizer,

63: limiter, 64: data delay unit.

The timing error compensation device of the channel modem for satellite communication system according to the present invention for demonstrating the above object, demodulates the input frequency signal of the predetermined level into I, Q data, A demodulation apparatus for a channel modem for a satellite communication system for estimating / compensating an error and outputting the data, comprising: data conversion means for performing Z inverse conversion on the I and Q demodulated data, data size generation means for generating magnitude data of the converted data; A data comparison means for comparing the data applied from the data conversion means with the I, Q demodulated data and outputting data corresponding to the difference, and a data multiplication process for multiplying the data applied from the data comparison means with reference size data. Means, reference data determining means for determining reference data of the I, Q demodulated data, a reference for performing Z inverse transform processing on the determined reference data. Conversion means, reference size data generation means for generating the size data of the converted reference data, reference data comparison means for comparing the data applied from the reference data conversion means and the reference data determined by the reference data determination means, compared A timing error component by comparing reference data multiplication processing means for multiplying reference data with size data generated by the data size generating means, data applied from the data multiplication means and data applied from the reference data multiplication processing means; And timing error compensating means for compensating and detecting the detected timing error based on the set timing error coefficient and the reference timing coefficient value.

That is, according to the present invention having the above-described configuration, even if the timing instantaneous value of the data is changed due to a time delay due to a defective transmission channel or deterioration of weather conditions, the timing error component is compensated to detect the timing instantaneous value. By doing so, it is possible to reduce the error rate of the data according to the timing error.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram showing an internal configuration of a timing error compensation apparatus according to the present invention.

In the drawing, reference numeral 51 denotes a data conversion unit for Z-inverting the input data, where Z inverse transformation is performed twice on the input data, which has an effect of delaying the data.

In addition, the first data Z-converted by the data conversion unit 51 is applied as input data of the data size generation unit 52. The data size data generation unit 52 takes a complex conjugate number to the input data and size the data. The data is generated, and the size data is applied as input data of the reference data multiplier 59. At this time, the input data is input in a complex form such as A + jB.

In addition, the data that has undergone two Z inverse transforms in the data converter 51 is applied as an input signal of the data comparator 53, and compares the data inputted to the timing error estimator 50 with the Z inverse transformed data. The data corresponding to the difference is output to the data multiplier 54. The data multiplier 54 multiplies the input data and outputs the multiplied data to the error data detection unit 60.

Meanwhile, the reference data determiner 55 determines predetermined reference data based on the data input to the timing error estimator 50, and applies the determined reference data as an input signal of the reference data converter 56. .

The reference data converter 56 performs Z inverse transform processing on the input reference data, which is composed of two Z conversion processors and serves to delay the reference data.

In addition, the Z-inverse transformed reference data initially applied by the reference data converter 56 is applied as an input signal of the reference data size generator 57. In the reference data size generator 57, a complex conjugate to the input reference data is input. The reference size data is generated by generating the reference size data, and the generated reference size data is applied to the input of the data multiplier 54.

On the other hand, the reference data transformed twice in the reference data converter 56 is applied as the input data of the reference data comparator 58, the reference data comparator 58 from the reference data determiner 55 The applied data is compared with the output data of the reference data converter 56 to output reference data corresponding to the difference to the reference data multiplier 59.

The reference data multiplier 59 multiplies the output data of the data size generator 52 and the output data of the reference data comparator 58 and outputs it as an input signal of the error data detection unit 60, and the error data detection unit 60. Timing error data is detected by taking only real data for each of the data applied to the reference data and reference data and comparing them.

The timing error data detected by the above method is input to the multiplier 61 and multiplied by a timing error variable set by the system operator according to the situation. The multiplied data is applied as input data of the data synthesizer 62. The input data of the limiter 63 is output.

The data applied to the limiter 63 is set at the time of system design in a setting range, for example, -π to + π, and only the data whose input data is within the setting range is output.

In addition, the output data of the limiter 63 is applied as the input data of the data delay unit 64. Although not shown in the data delay unit 64, the reference timing coefficient applied from the open loop of the demodulator is shown. On the basis of this, the data is delayed by Z conversion and then output as input data of the data synthesizer 62.

That is, the data is delayed based on the reference timing data until the data within the set range of the limiter 63 is not shifted, and then synthesized with the data applied from the multiplier 61 to confirm the range of the synthesized data. do.

On the other hand, when the data input to the limiter 63 is the data within the range set in the limiter 63, the output data of the limiter 63 is the data compensated for the timing error, and is transmitted to the next stage.

That is, the input data is converted, the size data is generated based on the converted data, the converted data is compared with the first input data, and the data corresponding to the difference is multiplied with the reference size data. In addition, the reference data of the input data is determined, converted, and the size data is generated based on the converted reference data, and the converted reference data is compared with the reference data before conversion and corresponds to the difference. Multiply the reference data with the size data. A timing error is detected by taking a real part from each of the multiplied data in this way and comparing it.

In addition, the timing error detected by the above method is estimated and compensated by the timing error variable and the reference timing coefficient set by the system operator.

Therefore, according to the above, even if the timing instantaneous value of the data is changed due to a time delay due to a defective transmission channel or deterioration of weather conditions, the timing error component is compensated to detect the timing instantaneous value. The error rate of the data can be reduced.

On the other hand, the present invention is not limited to the above embodiments and can be modified in various ways without departing from the technical spirit of the present invention.

For example, it may be used as a device for estimating timing error in a data modulation and demodulation device of a general wireless communication system.

As described above, according to the present invention, even if the timing instantaneous value of the data is changed due to a time delay due to a defective transmission channel or deterioration of weather conditions, the timing error component is compensated to detect the timing instantaneous value. It is possible to reduce the error rate of the data according to the error.

Claims (1)

A demodulation apparatus for a channel modem for a satellite communication system that demodulates an input frequency signal of a predetermined level into I and Q data, and estimates and compensates an error for the I and Q demodulated data. Data conversion means for performing Z inverse conversion on the I, Q demodulated data; Data size generating means for generating the size data of the converted data, Data comparison means for comparing the data applied from the data conversion means with the I, Q demodulated data and outputting data corresponding to the difference; Data multiplication processing means for multiplying the data applied from the data comparing means and the reference size data; Reference data determining means for determining reference data of the I, Q demodulated data; Reference data conversion means for performing Z inverse conversion on the determined reference data; Reference size data generating means for generating size data of the converted reference data; Reference data comparing means for comparing the data applied from the reference data converting means with the reference data determined by the reference data determining means; Reference data multiplication processing means for multiplying the compared reference data with the size data generated by the data size generating means; Timing error detection means for detecting a timing error component by comparing the magnitude of data applied from said data multiplication means and data applied from said reference data multiplication processing means; And a timing error compensating means for compensating and outputting the detected timing error on the basis of the set timing error coefficient and the reference timing coefficient value.