KR20000047174A - Method for synchronizing frequencies of channel modems for satellite communication system - Google Patents

Abstract

PURPOSE: A method for synchronizing the frequencies of channel modems for the satellite communication system is provided to prevent the discord of frequency synchronization from being generated between channel models, due to the error of the operation frequency of each channel modem. CONSTITUTION: An SDP(Speech and Data Processor)(51) processes speech and data transmitted and received through a public wave transmission network. A modulation part(52) modulates I/Q channel data output from the SDP(51) into a modulation signal of 512 kilohertz. An up converter(53) converts the modulation signal of 512 kilohertz into an intermediate frequency of 70 megahertz +/- 20 megahertz upwards. A down converter(54) converts the intermediate frequency of 70 megahertz +/- 20 megahertz into a frequency signal of 384 kilohertz downwards. A demodulation part(55) demodulates the modulation signal of 384 kilohertz output from the down converter(54) into I/Q channel data.

Description

Frequency Synchronization Method for Channel Modem for Satellite Communication System

The present invention relates to a satellite communication system using satellites, and more particularly, to a frequency synchronization method in a channel modem for a satellite communication system which can prevent inconsistency of frequency synchronization between channel modems due to an error in an operating frequency in each channel modem. It is about.

Recently, with the rapid development of communication technology, satellite communication, which enables subscribers who are located at remote sites to make calls through satellites, is becoming increasingly common. Since such satellite communication does not require a separate signal line for a call, It is mainly used as a long distance communication between countries or as a communication method in a mountainous country such as Korea.

In addition, satellite communication provides a communication link between each base station using satellites, and a central station allocates a channel frequency to each base station, and each base station uses a channel frequency assigned from the center station to form a communication path between base stations. do.

1 is a block diagram showing the internal configuration of a base station in a general satellite communication system.

In the figure, reference numeral 21 denotes an antenna for transmitting and receiving satellite 1, an uplink signal and a downlink signal, and 22 denotes an antenna 21 through the antenna 21 using polarization quality of frequency. An orthogonal mode converter for separating and inputting / receiving a signal to be transmitted and received, a low noise amplifier for low noise amplification of a 12.25 to 12.75 GHz downlink frequency signal input through the orthogonal mode converter, and a frequency signal applied through the low noise amplifier, Frequency down converter for converting 70MHz intermediate frequency signal (IF), 70MHz IF signal applied from IF combination / distributor 23, which will be described later, is converted into microwaves of 14.0-14.5GHz, for example, And a high power amplifier for amplifying an uplink frequency signal outputted from the frequency upshifter.

In addition, reference numeral 23 denotes an intermediate frequency signal applied from the RF processor 22 and outputs a plurality of intermediate frequency signals, and also described below, a SCPC channel unit (Single Channel Per Carrier Channel Unit). IF Combiner / Distributer which combines and outputs the intermediate frequency signal applied from 24, and 24 demodulates and decodes the intermediate frequency signal applied from this IF combination divider 23. And a channel modem for encoding, modulating and outputting a message output from the network controller 25 to be described later.

In this case, the IF combination distribution unit 23 is employed for system scalability when using a plurality of channel modems 24.

In the drawing, reference numeral 25 controls the overall operation of the base station such as providing a predetermined communication channel to the subscriber by controlling the channel modem and the trunk interface 27 and the telephone data card 26 to be described later. The base station control unit.

Reference numeral 26 denotes a telephone data card for connecting a terminal such as a telephone, a data terminal, or a facsimile machine, and reference numeral 27 denotes a trunk interface port for connecting the base station and another switch. to be.

That is, the base station performs a modulation / demodulation process by allocating an unused channel modem to a channel frequency allocated from a central station, thereby performing data transmission / reception operation between subscribers.

However, at this time, the channel frequency allocated to each channel modem is set differently, and the error for the corresponding channel frequency is generated in the same channel modem having the same characteristics. In the above configuration, each channel modem has its own The frequency error is estimated based on the channel frequency of.

That is, in each channel modem, the same error range is estimated through the same process. In the case of a newly allocated channel modem, the current frequency error correction operation is performed by performing a frequency estimation process performed in another channel modem. In particular, in the channel modem set to the traffic mode, an error occurs in the information data as the frequency error estimation time becomes longer.

In addition, due to a hardware defect of a channel modem in which a channel frequency is randomly allocated, a frequency synchronization with another channel modem may be lost.

Accordingly, the present invention has been made in view of the above circumstances, by estimating a frequency error in a channel modem set in the TDM mode, and applying the estimated frequency error information to the channel modem operating in the traffic mode, thereby setting the channel modem set to the traffic mode. The purpose of the present invention is to provide a frequency synchronization method in a channel modem for a satellite communication system that can quickly perform a frequency error correction operation and prevent the frequency synchronization with other channel modems from being distorted.

1 is a block diagram showing the internal configuration of a base station of a general satellite communication system.

Figure 2 is a block diagram showing the internal configuration of a channel modem to which the present invention is applied.

Figure 3 is a block diagram showing the internal configuration of the frequency synchronization device according to the present invention.

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

51: SDP, 52: modulator,

53: upconverter, 54: downconverter,

55: demodulation unit, 56: channel unit processor (CUP),

57: base station control unit.

The frequency synchronization method in the channel modem for satellite communication system according to the present invention for realizing the above object, in the base station to allocate the channel frequency and channel modem assigned from the central station, the operation mode corresponding to the data currently input of the channel modem In the satellite communication system to be set to, the operation mode of the channel modem is set, the channel modem assignment step of allocating the reference frequency of the channel modem, and the frequency applied from any channel modem assigned in the channel modem assignment step. And a frequency estimate value receiving step of receiving an estimate value and a frequency estimate value loading step of applying the frequency estimate value received in the frequency estimate value reception step as frequency estimation information of another channel modem.

In other words, the frequency estimation time of the channel modem set to the TDM mode is set to the frequency estimate of the channel modem set to the traffic mode, thereby reducing the frequency estimation time of the other channel modems. Frequency synchronization can be achieved.

Next, an embodiment according to the present invention will be described with reference to the accompanying drawings.

2 is a block diagram showing an internal configuration of a channel modem for a satellite communication system to which the present invention is applied.

In the drawing, reference numeral 51 denotes an interface between an MPH bus for transmitting and receiving voice and data, an UPH bus for transmitting and receiving various control data, and a channel unit processor 52 to be described later, in particular, through an airwave transmission network. Speech / Data Processor (hereinafter referred to as SDP) for processing voice and data transmitted and received.

Reference numeral 52 denotes a modulator for outputting a 512 KHz modulated signal by BPSK or QPSK modulating the I, Q channel data output from the SDP 51, and 53 denotes a 512 KHz of 512 KHz output from the modulator 52. 70MHz modulated signal ± Up-converter outputs upconvert to 20MHz intermediate frequency signal.

On the other hand, reference numeral 54 is a received 70MHz ± A down converter converts a 20 MHz intermediate frequency signal into a 384 KHz frequency signal, and 55 is a demodulator for demodulating and outputting I and Q channel data from a 384 KHz modulated signal applied by the down converter 54.

In addition, reference numeral 56 denotes a channel unit processor (hereinafter referred to as a CUP) that controls the overall operation of the channel modem, which controls the operation mode and the overall operation of the SDP 51, and the SDP ( The carrier lookup table of the modulator 52 is set to correspond to the symbol rate of the output signal of 51. The lookup table of the modulator 52 is determined based on predetermined two-bit data included in the data string transmitted from the MPH. Control to address.

In the channel modem having the above configuration, first, when a voice signal or data is input to the SDP 51 through the MPH, the SDP 51 performs an echo cancellation process or a compression process using the ADPCM on the input signal, and the result data. I and Q channel data are transmitted to the modulator 52. Subsequently, the modulator 52 transmits the 512 KHz modulated signal to the up-converter 53, and the up-converter 53 up-converts the input 512 KHz modulated signal to an intermediate frequency of 70 MHz.

In addition, a signal input at an intermediate frequency in the 70 MHz band is down-converted to a frequency signal of 384 KHz through the down converter 54 and transmitted to the demodulation unit 55. The demodulator 55 receives the input 384 KHz signal of I, The demodulation is performed on the Q channel data and applied to the SDP 51. The demodulator 55 transmits an input 384 KHz analog signal to the CUP 56, and the CUP 56 applies the demodulation unit 55 from the demodulator 55. The frequency error of the signal is estimated. In the CUP 56, the estimated frequency error is synthesized with the channel frequency applied from the base station controller and applied to the demodulator 55.

On the other hand, Figure 3 is a block diagram showing the main configuration of the channel modem according to the present invention, which demodulates the input signal applied to the demodulator 55, and also applied to the CUP (56) frequency error for the input signal After estimating the values, a detailed diagram of the apparatus for applying the estimated frequency error to the demodulator 55 is shown.

In Fig. 3, reference numeral 561 denotes a reception synchronizer for outputting a synchronized 384KHz signal based on a signal applied from a synthesizer 572 to be described later, and 562 denotes a receiver applied from the reception synchronizer 561. The signal is a quantum / encoder that generates a frequency signal of 128 KHz by quantizing / encoding a signal based on a frequency applied from the voltage controlled oscillator 569 to be described later.

On the other hand, reference numeral 563 denotes a demodulation unit for synchronously detecting the 128KHz signal transmitted from the quantum / encoder 563 based on the oscillation frequency applied from the 128KHz oscillator and converting the signal band to "0" Hz. Is a low pass filter (LPF) that performs baseband filtering on the demodulated signal around a reference frequency (0 Hz). The signal passing through the low pass filter 564 is the original signal before both sides are removed and modulated. Will be output.

Reference numeral 565 denotes a synthesizer, which synthesizes and outputs a signal applied from the low pass filter 564 and a signal applied through the second multiplier 568 to be described later.

On the other hand, reference numeral 566 denotes a matched filter for filtering into a band having a predetermined filter coefficient value in order to detect the sampling instantaneous value of the signal applied from the synthesizer 565. In addition to setting the filter coefficient value, the input data is shifted to correspond to the converted error estimation value and demodulated.

Reference numeral 567 denotes an estimation loop for estimating an error of a signal applied from the matching filter 566, which estimates timing, phase, amplitude, and frequency error of the input signal. In the estimation loop 567, the timing / phase signal output from the voltage control oscillator 569 is controlled based on the estimated timing / phase signal, and the second multiplier 568 of the second multiplier 568 is controlled based on the estimated amplitude estimation signal. Output amplitude is controlled. In addition, the estimation loop 567 applies the estimated frequency estimation signal to the frequency estimator 571, and includes signals (ie, timing, phase, frequency, and amplitude components) estimated and output from the estimation loop 567. Signal) is applied to the input of the NCO, outputs a predetermined frequency signal to the second multiplier 568, and is applied to the frequency estimator 571.

On the other hand, reference numeral 568 mixes the signal output from the NCO with the amplitude control signal applied from the estimation loop 567 to limit the amplitude level of the output signal to a specific level to be applied to the first multiplier 565. That is, the amplitude level of the estimated signal is limited.

Reference numeral 569 denotes a voltage controlled oscillator for adjusting the output frequency based on the timing / phase control signal applied from the estimated loop 567, and the frequency output from the voltage controlled oscillator 569 generates a TDM synchronous signal. It becomes the ground to say. In addition, the output signal from the voltage controlled oscillator 569 is applied to the quantum / encoder 562 to adjust the sampling interval.

On the other hand, reference numeral 570 is a Viterbi decoder to generate a decoding synchronization signal by Viterbit decoding the signal applied from the matching filter 566, which generates a decoding synchronization signal and applies it to the frequency estimator (571).

Further, reference numeral 571 performs an operation of calculating a frequency estimation value on a satellite within a frequency range of + 32KHz to -32khz using a signal drift signal applied from the estimation loop 567, and the estimation loop 567 When the carrier lock signal is applied or the decoder synchronization signal is applied from the Viterbi decoder 570, the frequency estimation value outputs a frequency estimation value calculated based on this, and 572 is a frequency estimation value applied from the frequency estimation 571. ( Δ f) and a synthesizer for synthesizing the reference frequency value f ₀ assigned to the present channel modem applied from the base station controller 57, the signal generated from this synthesizer 572 ( Δ f + f ₀ ) is applied to the receiving device 561.

Thereafter, the reception synchronizer 561 outputs the frequency level of the input signal to the next stage in synchronization with the level applied from the synthesizer 572.

On the other hand, the frequency estimation value output from the frequency estimation (571) Δ f) is applied to the base station controller 57. In the base station controller 57, a frequency estimation value applied from the frequency estimator 571 of the channel modem set to the TDM mode ( Δ By setting f) to the frequency reference estimation value of the channel modem set to the traffic mode, fast frequency estimation is possible in the channel modem set to the traffic mode.

That is, the base station controller sets the estimated frequency estimate of the channel modem set to the TDM mode to the reference frequency estimate of the channel modem set to the traffic mode before estimating the reference frequency estimate of the channel modem assigned to the traffic mode. In the modem, the step of estimating the reference frequency estimate is omitted.

Therefore, according to the present invention, frequency estimation in the channel modem set to the traffic mode can be performed quickly.

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.

As described above, according to the present invention, the frequency estimation time of the channel modem set to the TDM mode is set to the frequency estimation value of the channel modem set to the traffic mode, thereby shortening the frequency estimation time of the other channel modem. Frequency synchronization between modems can be easily achieved.

Claims (3)

In the satellite communication system in which the base station assigns a channel frequency and a channel modem allocated from the central station, and sets the operation mode corresponding to the data currently input to the channel modem. A channel modem assignment step of setting an operation mode of the channel modem and allocating a reference frequency of the channel modem; A frequency estimation value reception step of receiving a frequency estimate applied from an arbitrary channel modem allocated in the channel modem assignment step; And a frequency estimation value loading step of applying the frequency estimation value received in the frequency estimation value reception step as frequency estimation information of another channel modem. The method of claim 1, Performing frequency estimation in the channel modem set to the TDM mode, and loading the frequency estimate applied from the channel modem set to the TDM mode as the frequency estimate of the traffic channel modem. . The method of claim 1, In the frequency estimation step of receiving a frequency estimation method of a specific channel modem, An error component estimating step of performing quantization, encoding, and demodulation on the input signal, and estimating an error component of the demodulated input signal; A frequency estimating step of outputting the frequency error component estimated in the error component estimating step to the next stage based on the detection of the carrier lock signal of the input signal; A frequency estimation value sending step of transmitting the frequency estimation value output in the frequency estimation step to a control means; And an input frequency synchronization step of synthesizing the frequency of the input signal based on the synthesized frequency estimation value output from the frequency estimation step and the reference frequency assigned to the channel modem. Frequency synchronization method.