KR19980050193A - Number of intermediate frequency signals in satellite communication system with automatic gain adjustment - Google Patents

Abstract

The present invention generates, for example, a frequency signal of 384 kHz for data demodulation by frequency converting a received intermediate frequency signal of 70 MHz, and also receives an intermediate frequency signal of a satellite communication system that can automatically set a gain of the frequency signal. An apparatus comprising: first mixer means for mixing a frequency signal having a predetermined second frequency to an intermediate frequency signal having a first frequency to generate a third frequency signal, and at least 20 Hz or more of the third frequency signal; First amplifying means for amplifying, second mixer means for mixing a frequency signal having a fourth frequency with respect to the third frequency signal and outputting a modulated signal having a predetermined frequency, and a second amplifying means according to a predetermined control signal. Performing a demodulation process on the modulated signal outputted through the second amplifying means and the second amplifying means; Reads amplification control data from the ROM table based on a digital signal processor for outputting level data, a ROM table storing amplification control data corresponding to the level data, and level data output from the digital signal processor, In this case, it characterized in that it comprises a processor for controlling the amplification degree of the second amplifier based on the read control data.

Description

Intermediate frequency signal receiver of satellite communication system with automatic gain adjustment

In the satellite communication system, an automatic gain adjustment is made, for example, by frequency converting a received 70 MHz intermediate frequency signal to generate a 384 kHz frequency signal for data demodulation and automatically adjusting its signal output level. The present invention relates to an intermediate frequency signal receiver of a satellite communication system having a function.

Recently, with the rapid development of communication technology, wireless communication for transmitting and receiving voice signals or data through the airwave transmission network rather than the conventional wired network is being spread and activated, and in recent years, satellite communication through satellites is gradually being spread.

On the other hand, in satellite communication, since communication is performed through satellites located thousands to tens of thousands of kilometers from the ground, signal transmission and reception are usually performed through digital communication, and as a transmission / reception frequency, for example, in case of uplink, In the case of 14.0 to 14.5 G㎐ and downlink, a high frequency of 12.25 to 12.75 G㎐ is used.

Currently, in some commercially available satellite communication systems, for example, binary code modulation (PCM) data input through a public switched telephone network (PSTN) or binary phase shift keying (BPSK) or quadrature phase shift keying (QPSK) is used. Modulation is performed to generate a 512 kHz modulated signal, which is then frequency-converted to generate a 70 MHz intermediate frequency signal. The 70 MHz intermediate frequency signal is further frequency-converted to generate a transmission frequency of 14.0 to 14.5 GkHz.

On the other hand, the receiving side receiving the frequency signal transmitted as described above down-converts the 12.25 to 12.75 GkHz downlink signal to an intermediate frequency of 70 MHz, and then downconverts it to a 384 kHz frequency signal again. The demodulation operation is executed.

However, in the satellite communication, since data is transmitted and received through an airwave transmission network, a signal level decreases significantly while data is transmitted through a medium-wave transmission network, which causes a problem in that the receiver cannot restore the original data.

Therefore, it is necessary to improve the resilience of the signal by amplifying the intermediate frequency signal which is normally received. In this case, if the gain of the received signal is simply amplified largely, the linearity of the signal is lost and data demodulation becomes impossible. When the gain of the received signal is amplified low, the signal level is lowered and the data recoverability is lowered.

In particular, in a satellite communication system, since data transmission and reception are performed through an airwave transmission network, the received signal level fluctuates from time to time according to a climatic condition. This situation becomes a great obstacle in properly amplifying an input signal.

Accordingly, the present invention has been made in view of the above circumstances, and, for example, the automatic gain adjustment is made so that the intermediate frequency signal of 70 MHz is converted into a frequency signal of 384 kHz and the output level of the received frequency signal can be automatically adjusted. The purpose of the present invention is to provide an intermediate frequency signal generator of a satellite communication system with a function.

1 is a block diagram showing an intermediate frequency signal receiving apparatus of a satellite communication system with an automatic gain adjustment function according to an embodiment of the present invention.

* Brief description of the main parts of the drawing

1, 5, 8: attenuator, 2, 6, 15, 18: band pass filter,

3, 7, 9, 12, 16, 17: amplifier, 4, 14: mixer,

11: surface acoustic wave filter, 13: low pass filter,

19: analog-to-digital converter, 20: digital signal processor,

21: ROM table, 22: channel unit processor,

23 buffer, 24 digital to analog converter.

The intermediate frequency signal receiving apparatus of the satellite communication system with an automatic gain adjustment function according to the present invention according to the present invention for realizing the above object is a frequency signal having a predetermined second frequency with respect to the intermediate frequency signal having a first frequency A first mixer means for mixing to generate a third frequency signal, a first amplifying means for amplifying the third frequency signal by at least 20 Hz or more, and a frequency signal having a fourth frequency for the third frequency signal to be mixed A second mixer means for outputting a modulated signal of frequency, a second amplification means for amplifying the modulated signal according to a predetermined control signal, and a demodulation process for the modulated signal outputted through the second amplification means; A digital signal processor for outputting level data corresponding to the level value of the modulated signal, and amplification control data corresponding to the level data are stored. And a processor for reading amplification control data from the ROM table based on a ROM table and level data output from the digital signal processor, and controlling the amplification degree of the second amplifier based on the read control data. It features.

According to the present invention having the above-described configuration, the intermediate frequency signal having the first frequency is output through a two-step frequency mixing operation to output a desired modulated data signal. Then, a stable data demodulation operation is performed by variably amplifying the output level of the modulated data based on the level of the modulated data signal.

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

1 is a block diagram showing an intermediate frequency signal receiving apparatus of a satellite communication system according to an embodiment of the present invention.

In the drawing, reference numeral 1 denotes, for example, a first attenuator ATT1 for impedance matching which inputs an intermediate frequency signal having a signal level of −7 kHz and a frequency of 70 MHz ± 18 MHz and attenuates its gain by about −9 kHz. 2 is a band pass filter (BPF) having a center frequency of 70 MHz, a bandwidth of 40 MHz, and a signal gain of -17 GHz, and 3 is a compensation for gain loss of the first attenuator 1 and the band pass filter 2. Is the first amplifier A1 of 18 kHz gain.

In the drawing, reference numeral 4 denotes a first mixer M1 for mixing 112.384 MHz ± 18 MHz frequency signal applied from a frequency synthesizer (not shown) with respect to the intermediate frequency signal applied from the first amplifier 3. 5 is an impedance matching second attenuator ATT2 for attenuating the frequency signal output from the first mixer 4 by about -3 kHz, and 6 has a center frequency of 42 MHz and a bandwidth of 7 MHz. A band pass filter (BPF) which outputs a 42.384 MHz frequency signal from the frequency signal output from the mixer 4.

In the drawing, reference numeral 7 denotes a second amplifier A2 that amplifies the frequency signal output from the bandpass filter 6 by +12 kHz, and 8 denotes a frequency signal output from the second amplifier 7. The third attenuator ATT3 and 9 for attenuating about 3 Hz are the third amplifier A3 for amplifying the frequency signal output from the third attenuator 8 by about +12 Hz.

Here, the second and third amplifiers 7 and 9 are used to increase the power level because the output level of the second attenuator 5 is low, and the third attenuator 8 is the second and third. This is to prevent the third amplifier 9 from saturation due to continuous signal amplification by the amplifiers 7 and 9.

That is, when the output level of the second attenuator 5 is amplified by an amplifier having a gain of +20 dB, for example, the amplifier is saturated and distortion is generated in the output signal. While amplifying the signal level with the third amplifiers 7 and 9, an attenuator 8 is inserted between the amplifiers 7 and 9 to prevent saturation of the amplifier.

In the drawing, reference numeral 10 denotes the fourth attenuator ATT4 for impedance matching having an attenuation characteristic of -3 kHz, and 11 is 42.384 from the frequency signal applied from the fourth attenuator 10 having a center frequency of 42.384 MHz. A surface acoustic wave filter (SAW) for filtering and outputting a frequency signal of MHz, 12 is a fourth amplifier A4 for amplifying a frequency signal output from the surface acoustic wave filter 11 by about +18 Hz.

In this case, the surface acoustic wave filter 11 has a gain loss of -30 dB when the input and output are matched, and the fourth amplifier 12 compensates the gain loss of the surface acoustic wave filter 11.

In the drawing, reference numeral 13 denotes a low pass filter (LPF) for removing high frequency noise from the frequency signal output from the fourth amplifier 12.

In the drawing, reference numeral 14 denotes a second mixer M2 for mixing a frequency signal of 42 MHz applied from a reference clock generator (not shown) with respect to the frequency signal of 42.384 MHz output from the low pass filter 13. 15 is a frequency signal output from the second mixer 14, having a center frequency of 384 Hz and a bandwidth of 0.2 to 0.4 MHz, that is, a frequency signal of 384 Hz from 42 MHz and 384 Hz and 84.384 MHz. Band pass filter (BPF) that outputs.

In the drawing, reference numeral 16 denotes an amplifier for amplifying a frequency signal of 384 kHz output from the band pass filter 15 according to a predetermined control signal, which is used to respectively input an input frequency signal of 10 to 30 kHz according to the control signal. The amplifiers 161 and 162 to amplify are provided.

In the drawing, reference numeral 17 denotes a fifth amplifier A5 that amplifies a frequency signal of 384 Hz output from the amplifier 16 by +12 Hz, and 18 denotes a center frequency of 384 Hz and a bandwidth of 0.2 to 0.4 MHz. And a band pass filter (BPF) for filtering the frequency signal of 384 kHz output from the fifth amplifier 17.

In the figure, reference numeral 19 denotes an analog / digital converter for converting a 384 kHz modulation signal output from the bandpass filter 18 into digital data, and 20 denotes modulation data applied from the analog / digital converter 19. The digital signal processor (DSP) outputs I and Q channel data corresponding to the received data by demodulating and outputs data corresponding to the signal level value of the input modulation signal.

In the drawing, reference numeral 21 is a ROM table in which predetermined amplification data corresponding to level data applied from the digital signal processor 20 is stored, and 22 is a level of a signal received from the digital signal processor 20. When level data indicating a value is input, the channel unit processor CUP reads the ROM table 21 based on the input level data and outputs amplified data corresponding thereto.

In the drawing, reference numeral 23 denotes a buffer for buffering amplified data output from the channel unit processor 22, and 24 denotes amplified data applied through the buffer 23 as a voltage signal corresponding to the data value. Is a digital / analog converter applied to the amplifier 16.

That is, in the above configuration, 112.384 MHz ± 18 MHz is mixed with the 70 MHz ± 18 MHz intermediate frequency input from the first mixer 4, and the mixed frequency signal is 42 MHz with a center frequency of 7 MHz. Filtering with a band pass filter 6 having a bandwidth of 4 to generate a frequency signal of 42.384MHz.

The second mixer M2 again mixes the 42 MHz frequency signal with the 42.384 MHz frequency signal, and mixes the mixed frequency signal with a center frequency of 384 kHz and a bandwidth of 0.2 to 0.4 MHz. By filtering by (15), a data signal of 384 ㎑ is obtained.

In addition, the frequency signal output from the bandpass filter 6 is amplified by +12 kHz through the amplifier 7, attenuated by -3 kHz through the attenuator 8, and then amplified by +12 kHz by the amplifier 9 again. Sufficient amplification of the power level of the frequency signal while preventing saturation of the amplifier by the method, and sufficient power level for data demodulation by amplifying the 384 kHz frequency signal output from the bandpass filter 15 through the amplifier 16. Outputs a data signal.

Subsequently, when the modulated signal of 384 kHz amplified as described above is output through the band pass filter 18, the modulated signal is converted into digital data through the analog-to-digital converter 19 and then to the digital signal processor 20. To be authorized.

The digital signal processor 20 performs demodulation processing on the input modulation data and outputs the level data corresponding to the level value of the input modulation data. The level data is applied to the channel unit processor 22. Will be.

Meanwhile, when level data is applied from the digital signal processor 20, the channel unit processor 22 reads the ROM table 21 based on the level data to obtain amplified data corresponding to the current received signal level. This is applied to the amplifier 16 through the buffer 23 and the digital-to-analog converter 24 to vary the level of the modulation signal applied to the digital signal processor 20.

That is, in the above embodiment, the amplifier 7 and 9 are used to amplify the output level of the modulated signal primarily and greatly reduce the level of the modulated signal based on the received signal level data output from the digital signal processor 20. By adjusting, the signal level applied to the digital signal processor 20 is always maintained at a stable value.

Therefore, it is possible to efficiently cope with a communication failure state caused by fluctuations in weather conditions and the like.

In addition, this invention is not limited to the said Example, It can be variously deformed and implemented in the range which does not deviate from the technical summary of this invention.

As described above, according to the present invention, it is possible to realize the intermediate frequency signal receiving apparatus of the satellite communication system with the automatic gain adjustment function which enables the stable frequency demodulation operation by always controlling the signal level of the intermediate frequency signal efficiently. do.

Claims (1)

First mixer means for generating a third frequency signal by mixing a frequency signal having a predetermined second frequency with respect to an intermediate frequency signal having a first frequency, and a first amplification for amplifying the third frequency signal by at least 20 Hz or more. Means, second mixer means for mixing a frequency signal having a fourth frequency with respect to the third frequency signal to output a modulated signal of a predetermined frequency, second amplifying means for amplifying the modulated signal according to a predetermined control signal, and A digital signal processor for performing demodulation processing on the modulated signal output through the second amplifying means and outputting level data corresponding to the level value of the modulated signal, and amplifying control data corresponding to the level data is stored Reading amplification control data from the ROM table based on the ROM table and the level data output from the digital signal processor, At this time, the intermediate frequency signal receiving apparatus of the satellite communication system having an automatic gain adjustment function, characterized in that it comprises a processor for controlling the amplification degree of the second amplifier based on the read control data.