KR100262155B1 - Method for transmitting data in a channel modem for satellite communication system - Google Patents

Abstract

PURPOSE: A transmission method in demodulation device of channel modem for satellite communication system is provided to prevent discontinuation of data transmission due to increment of error elements of data so as to improve transmission efficiency. CONSTITUTION: A demodulator(50) in a channel modem for satellite communication system is composed of a demodulator(54), an LPF(Low Pass Filter,55), matching filter(57), a decimator(58), a carrier lock signal generator(58), an error estimation unit(59),and a timer(60). Errors occurred from the satellite are detected. An error presumption unit(59) decides whether the error presumption values are under certain level. A carrier lock signal generator(61) generates carrier lock signals if the error estimation values are under certain level. I and Q demodulated data are transmitted to voice and data processor in base of carrier lock signals. Carrier lock signals are produced periodically to the input data in basis of carrier lock signals, and errors are presumed repeatedly. The carrier lock signals generated when errors are presumed repeatedly, a timer(60) generates coefficient. Even error elements of input data increases, the increased error elements of I and Q data are estimated and sent out by detecting the carrier lock signals periodically.

Description

Data transmission method in a demodulation device for a channel modem for a 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, when a channel modem is set to a data mode, demodulating the input data and estimating an error of the input data, the carrier lock signal is generated. The present invention relates to a data transmission method in a demodulation device for a channel modem for a satellite communication system.

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 corresponding 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. An intermediate frequency signal (70 MHz ± 20 MHz) having a range is generated, and in the intermediate frequency signal receiving unit 17, a frequency signal having a variable range of 20 MHz is again applied to the intermediate frequency signal having a variable range of 20 MHz (112.384 MHz). By mixing ± 20 MHz), a frequency signal of 384 KHz corresponding to a predetermined communication channel is detected.

On the other hand, the demodulator performs an error estimation operation of the data based on the carrier lock signal, compensates for the estimated error, and transmits the data to the Viterbi decoder of the next stage voice / data processor (SDP).

In addition, when the carrier lock signal indicating that the error estimation has been performed to the allowable range for the input data is enabled in the data mode, the input data continues to be input. The error is compensated based on the estimated error value and transmitted to the next stage.

However, if the satellite is suddenly changed severely after the carrier lock signal is enabled in the data mode, or if the error component of the input data increases due to bad weather conditions, the error is based on the previous error estimate. Since the data to be compensated and transmitted to the next stage becomes meaningless data, a problem arises in that the data transmission is actually stopped.

Accordingly, the present invention was created in view of the above circumstances, and in the state of setting the data mode, the carrier lock signal of the input data is periodically detected so that the I, Q data even if the error component of the input data increases. It is an object of the present invention to provide a data transmission method in a demodulator of a channel modem for a satellite communication system, which is capable of estimating an increased error component of a next step.

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

2 is a block diagram showing an internal configuration of a demodulation device 50 in a channel modem for a satellite communication system according to an embodiment of the present invention.

Fig. 3 is an operation flowchart for explaining the operation of the apparatus in the configuration of Fig. 2;

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

50: demodulation device, 51: down converter,

52: encoder, 53: quantizer,

54: demodulation section, 55: low pass filter (LPF),

56: synthesizer, 57: matching filter,

58: data message, 59: error estimator,

60: timer, 61: carrier lock signal generator.

In the demodulation apparatus for the channel modem for satellite communication system according to the present invention for achieving the above object, the data transmission method, in addition to demodulating the input frequency signal of the predetermined level into the I, Q data, this I, Q demodulated data An error detection step of detecting an error component generated through satellites in the I and Q demodulated data when the demodulation device of the channel communication system for satellite communication system for estimating / compensating and outputting an error is set to the data mode; An error estimation level determination step of determining whether the error estimation value detected in the error detection step is less than or equal to a predetermined level, a carrier lock signal generation step of generating a carrier lock signal when the error estimation value is less than or equal to a predetermined level in the error estimation level determination step; Transfer the error estimated I, Q demodulated data to the voice / data processor based on the carrier lock signal generated in the carrier lock signal generation step. And a repetitive error estimation step of periodically generating a carrier lock signal for data input based on the carrier lock signal generated in the carrier lock signal generation step.

According to the present invention having the above-described configuration, by periodically detecting a carrier lock signal with respect to the input data in the state set to the data mode, an error component is added to the input data due to a change in attitude of the satellite or deterioration of weather conditions. Even if the number is significantly higher than the previous estimate, the data can be transmitted stably to the next stage.

That is, the transmission efficiency of the system can be improved by preventing the interruption of data transmission due to the rapid increase in the error component of the data input to the demodulator in the data mode.

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 demodulation device 50 according to an embodiment of the present invention.

In the figure, reference numeral 51 denotes a down-converted intermediate frequency signal transmitted from an intermediate frequency terminal (IF stage) to a band of 384 KHz based on a synchronization signal applied from an RX synchronizer (not shown). A converter 52 is an encoder for sampling the 384 KHz signal applied from the down converter 51 based on a sampling frequency of 512 KHz, and 53 is a quantizer for quantizing the 128 KHz sampled signal applied from the encoder 52.

Reference numeral 54 is a demodulation unit for synchronously detecting the 128 KHz signal transmitted from the quantizer 53 on the basis of the oscillation frequency applied from the 128 KHz oscillator and converting the signal band to 0 Hz. A low pass filter (LPF) that performs baseband filtering around a reference frequency (0 Hz). The signal passing through the low pass filter 55 is an original signal before both sides of the band are removed and modulated. Q data is output.

Reference numeral 56 denotes a synthesizer which synthesizes and outputs a signal applied from the low pass filter 55 and a signal applied through the error estimator 59 to be described later.

On the other hand, reference numeral 57 is a matched filter for filtering to a band having a predetermined filter coefficient value in order to detect the sampling instant value of the signal applied from the synthesizer 56, which is a route selected by a modulator (not shown). By convoluting the same root-laid cosine function with the signal applied by the lased cosine function, the sampling instant value of the applied signal is detected, and a predetermined carrier lock is generated from the carrier lock signal generator 60 to be described later. When the signal is applied, the input data is output to the voice / data processor (SDP).

Also, reference numeral 58 denotes a decimator which detects the data applied from the matching filter 57 at predetermined intervals, which has a predetermined size between the information data in a modulator (not shown) on the transmitting side. As a corresponding process of the receiving side in inserting the dummy data and performing the modulation process, if the size of the dummy data is one bit, the decimator 58 of the demodulator is defined to have a detection interval of '2'.

Further, reference numeral 59 detects an error component of data applied from the decimator 58, applies the detected signal to the synthesizer 56, and matches the timing error component data along the satellite. An error estimator applied to the filter 57, 60 is a timer for generating a time coefficient based on a predetermined control signal, 61 is a predetermined value based on an error rate of I, Q data applied from the data 58. A carrier lock signal generator for generating a carrier lock signal, which is driven by the timer 60 in a state set to a data mode, and error compensated based on an error value estimated by the error estimator 59 at regular intervals. The carrier lock signal is generated when the error rate of the Q data is equal to or less than a predetermined value.

3 is an operation flowchart for explaining a data transmission method in a demodulation device for a channel modem for a satellite communication system according to an embodiment of the present invention.

First, when data mode setting data is received from the channel unit processor CUP (ST1), the operation mode of the demodulation device 50 is changed to the data mode based on this data (ST2).

Subsequently, the demodulation device 50 demodulates the 384 KHz frequency signal input from the down converter 51 which receives the intermediate frequency and converts the frequency down to a frequency of 384 KHz into I and Q data (ST3). In the Q demodulation data, an error component generated while passing through the satellite is detected and estimated (ST4).

Thereafter, the demodulation device 50 determines whether the error estimation value is less than or equal to a predetermined level during the execution of the error estimation operation (ST5). When the error estimation value of the input I and Q demodulation data is less than or equal to the predetermined level, the carrier lock signal generator By driving 61, the carrier lock signal is transmitted to the Viterbi decoder of the voice / data processor SDP, thereby transmitting the error estimated I and Q data (ST6 and ST7).

In addition, the demodulation device 50 drives the timer 60 together with the generation of the carrier lock signal, and determines whether a predetermined time has elapsed after transmitting the I and Q data to the Viterbi decoder (ST8). .

In step ST8, if it is determined that a predetermined time has elapsed after transmitting the Viterbi decoder to the I and Q data, it is checked whether data transmission is completed based on the presence or absence of data input thereafter (ST9).

When it is determined in step ST9 that data transmission is completed, the demodulation device 50 is initialized. When it is determined in step ST9 that data transmission is not completed, an error is detected in the input I and Q data. The estimation of ST4 is repeated.

That is, according to the demodulation device according to the present invention as described above, by periodically detecting a carrier lock signal for the input data in the state set to the data mode, it is input due to the change in attitude of the satellite or the deterioration of weather conditions. Even if the error component in the data increases rapidly than the previous estimate, the data can be stably transmitted to the next stage.

Therefore, the transmission efficiency of the system can be improved by preventing the interruption of data transmission due to the rapid increase in the error component of the data input to the demodulator in the data mode.

In addition, this invention is not limited to the said Example, It can variously deform and implement within the range which does not deviate from the technical summary of this invention.

For example, in generating a carrier lock signal, data transmission of a channel modem for a satellite communication system that stores a predetermined number (128,600) of sampling values of input data and generates a carrier lock signal in units of sampling numbers of set data. The method can be realized.

As described above, according to the present invention, transmission efficiency of the system can be improved by preventing interruption of data transmission due to a sudden increase in error components of data input to the demodulation device in the data mode.

Claims (3)

The demodulator of the channel modem for satellite communication system, which demodulates the input frequency signal of the predetermined level into I and Q data, estimates and compensates for the error and outputs the I and Q demodulated data. In An error detection step of detecting an error component generated through satellites in the I and Q demodulated data; An error estimation level determination step of determining whether the error estimation value detected in the error detection step is less than or equal to a predetermined level; A carrier lock signal generation step of generating a carrier lock signal when the error estimation value is less than or equal to a predetermined level in the error estimation level determining step; A data transmission step of transmitting the error estimated I, Q demodulated data to a voice / data processor based on the carrier lock signal generated in the carrier lock signal generation step; In the demodulation device for a channel modem for a satellite communication system comprising a repeating error estimation step of periodically generating a carrier lock signal for the data input based on the carrier lock signal generated in the carrier lock signal generation step Data transfer method. The method of claim 1, In the iterative error estimation step, the timer is driven based on the carrier lock signal generation generated in the iterative error estimation step, and when the timer generates a predetermined time coefficient, the error component of the input I, Q demodulated data is detected. And performing an error detection step of estimating an error, and generating a carrier lock signal when the error estimation value is less than or equal to a predetermined level. The method of claim 1, In the iterative error estimating step, in periodically generating a carrier lock signal, the sampling value of the input data is stored for a predetermined number, and the carrier lock signal is generated in units of sampling numbers of the set data. Channel modem data transmission method.

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