JP2006050205A - Satellite loading repeater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a satellite loading repeater for automatically changing-over an uplink wave in response to the rain attenuation of the uplink wave to a satellite or the situation of the interruption without causing the discontinuity of a downlink wave with the changeover. <P>SOLUTION: The satellite loading repeater 1(1B) comprises a demodulator 20B for demodulating digital broadcasting signals transmitted from a plurality of transmitting stations as the uplink wave into base band signals; a program editing device 21B for determining a reception level or an error rate, selecting one base band signal (demodulation signal), and performing the changeover; and a modulator 22 for modulating the changed-over base band signal by a second modulation system. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a satellite-mounted repeater mounted on a satellite that is operated in a satellite digital broadcasting system.

In general, a satellite-mounted repeater used in a satellite digital broadcasting system converts a digital broadcast signal transmitted from a transmission station on the earth into a signal in a frequency band that can be received by a receiving device on the earth. The signal is relayed.
In addition, the conventional satellite-mounted repeater has a modulation method for the uplink (uplink) from the transmitting station to the satellite-mounted repeater, and a modulation method for the downlink (downlink) from the satellite-mounted repeater to the receiving device. By using the same method, the simple structure and reliability are improved. Also, the conventional satellite-borne repeater operates in a saturation region where the signal level of the downlink wave is not linear in order to increase the output of the downlink wave. Therefore, in general, in a satellite digital broadcasting system, a phase shift keying (PSK) signal, quadrature amplitude modulation (QAM: Quadrature Amplitude) that can be received at a receiver device with a CN ratio (Carrier to Noise ratio) as low as possible. Modulation signal is used.

  In the satellite digital broadcasting system, high reliability is required for signal degradation (rain attenuation) due to rainfall in the uplink wave. As countermeasures for this rain attenuation, the probability of large rain attenuation occurring at multiple different points at the same time is low. Therefore, grasp the situation of rain attenuation at multiple transmitting stations (uplink transmitting stations) and reduce rain attenuation. Operations such as switching the uplink wave transmission source to the transmitting station (site diversity) are performed (for example, see Non-Patent Document 1 and Non-Patent Document 2).

Here, a conventional satellite-mounted repeater will be described with reference to FIG. FIG. 13 is a block diagram showing an example of the configuration of a conventional satellite-mounted repeater.
As shown in FIG. 13, the satellite-mounted repeater 1F filters only the frequency of the uplink signal (uplink frequency) by the transmitter / receiver demultiplexer (diplexer) 3 to thereby transmit a transmitter station (uplink station) not shown. ) To receive a digital broadcast signal (uplink wave). The digital broadcast signal is a wideband signal in which signals of a plurality of channels are multiplexed for each frequency.
Then, the satellite-mounted repeater 1F amplifies the received digital broadcast signal by amplifying means (not shown), and the frequency conversion / amplifier 10 (10 ₁ , 10) corresponding to the transmitting station is kept at a high frequency (RF signal) ₂ ) to convert the frequency of the downlink wave from the satellite-mounted repeater 1F to the receiving device on the earth (downlink frequency) (for example, convert 17 GHz to 12 GHz) and amplify the power. In the on-board repeater 1F, the frequency conversion / amplifier 10 (10 ₁ , 10 ₂ ) is switched between active and standby based on an instruction from an operation site (not shown) and a switch (SW) 4 or a hybrid Alternatively, it is performed by switching the switch (H / SW) 5.

Further, the satellite-mounted repeater 1F demultiplexes the frequency-converted signal into a frequency band signal (channel signal) for each channel by the input demultiplexer 11 configured by a multiplexer (MUX: MULTipleXer) filter. The satellite-mounted repeater 1F controls gain so that the output signal level of each channel signal becomes constant by an AGC (Automatic Gain Control) 30 (30 ₁ to 30 _n ). A signal is amplified to a power level for transmission by a power amplifier (TWTA: Traveling Wave Tube Amplifier) 31 (31 _{1 to} 31 _n ). This amplified signal is synthesized by the output multiplexer 32 composed of a MUX filter, and only the frequency of the downlink signal (downlink frequency) is filtered by the transmitter / receiver demultiplexer 3, and the downlink digital signal is transmitted through the antenna AT. Radiated (distributed) as a broadcast signal (downlink wave).
Tadashi Shiomi and Mitsutoshi Hatori, “Wave Summit Course Digital Broadcasting”, Ohmsha, February 25, 2001, 1st Edition, p. 176-177 The Institute of Image Information and Television Engineers, “Digital Broadcasting Handbook”, Ohmsha, June 20, 2003, 1st Edition, p. 186-187

  In the satellite digital broadcasting system described above, measures against rain are taken by switching the transmitting station (uplink transmitting station) that transmits digital broadcasting signals by site diversity operation. However, the digital broadcast signal (uplink wave) received by a conventional satellite-mounted repeater is lost when the digital broadcast signal is switched off (reception level is cut), superimposed, or the phase is changed. An uplink wave discontinuity occurs such as discontinuity. As a result, the downlink wave transmitted through the satellite-borne repeater also becomes discontinuous, and the bit stream obtained by demodulating the digital broadcast signal received by the receiving device on the earth is not reproduced correctly (for example, screen disturbance). There is a problem.

  Further, in the conventional satellite digital broadcasting system, an operator who performs site diversity operation needs to constantly monitor the rain attenuation status of a plurality of uplink transmission stations. In addition, high-frequency uplink waves used for satellite broadcasting are subject to rapid radio attenuation due to rain, so site diversity operators must quickly switch between transmitting stations when radio attenuation occurs. However, there is a problem that the burden is very large.

  Further, the uplink wave in the conventional satellite digital broadcasting system is a signal modulated with a signal for each predetermined channel band as one bit stream. Usually, this bit stream is obtained by multiplexing a plurality of independent broadcast program signals (for example, MPEG-TS [Transport Stream]), and these broadcast program signals need to be multiplexed at an uplink transmission station. There is. As described above, although it is an individual broadcast program signal, since it must be multiplexed and transmitted in one uplink transmission station, there is a problem that rain attenuation affects the entire broadcast. Furthermore, it takes time and effort to constantly multiplex a program produced by one broadcast program production company with a program produced by another broadcast program production company at an uplink transmission station. Apart from the program, there is a desire to uplink individually.

  The present invention has been made in order to solve the above-described problems, and by changing the modulation method of each of the uplink wave and the downlink wave and processing the internally demodulated bitstream, It eliminates the discontinuity of the downlink wave, automatically switches the uplink wave due to rain attenuation, and further, independently broadcasts the broadcast program signal (for example, MPEG-TS [Transport Stream]) to other broadcast programs. An object of the present invention is to provide a satellite-mounted repeater that can be combined with a signal to make a broadcast format suitable for the downlink.

  The present invention was devised to achieve the above object. First, the satellite-mounted repeater according to claim 1 relays a digital broadcast signal transmitted from a transmitting station via a broadcast satellite. The satellite-mounted repeater mounted on the broadcasting satellite has an input demultiplexing unit, a demodulating unit, a modulating unit, an amplifying unit, and an output multiplexing unit.

  According to such a configuration, the satellite-mounted repeater demultiplexes the digital broadcast signal, which is received from the transmitting station and modulated by the first modulation method, by the input demultiplexing unit for each predetermined channel frequency band. As a result, the digital broadcast signal is separated into signals for each channel unit.

  Subsequently, the satellite-mounted repeater demodulates the demultiplexed digital broadcast signal for each channel unit into a baseband signal by the demodulation means. In this way, once the digital broadcast signal is demodulated into a baseband signal, even if the signal is subjected to processing such as interleaving, processing correction in units of bits or bytes becomes possible. Further, error correction can be performed. In addition, by using a modulation scheme that can be demodulated for multipaths such as an OFDM modulation scheme and a CDM modulation scheme as the first modulation scheme, the same digital broadcast signal is transmitted from a plurality of transmission stations. However, it is possible to demodulate individual signals into baseband signals.

  Then, the satellite-mounted repeater modulates the baseband signal demodulated by the demodulating means by the modulating means by the second modulation method. Note that the first modulation scheme and the second modulation scheme may be the same modulation scheme or different modulation schemes. In this way, the satellite-mounted repeater converts the digital broadcast signal into a baseband signal, so that even if the uplink wave is switched to a different transmission station by site diversity operation, the satellite-based repeater can be improved due to a phase shift or the like. It becomes possible to process the discontinuity of the link wave as a continuous signal of the baseband signal.

  The satellite-mounted repeater amplifies the modulation signal for each channel frequency band modulated by the modulation means to a predetermined signal level that can be transmitted as a downlink wave by the amplification means, and amplifies the amplified signal by the output multiplexing means. The modulated signal is combined as a second digital broadcast signal for transmission. This second digital broadcast signal is distributed as a downlink wave to a receiving device on the earth.

  The satellite-mounted repeater according to claim 2 is a satellite-mounted repeater mounted on the broadcast satellite that selectively relays digital broadcast signals transmitted from a plurality of transmitting stations at different points via the broadcast satellite. The repeater is configured to include input demultiplexing means, demodulation means, demodulation signal selection means, modulation means, amplification means, and output multiplexing means.

  According to such a configuration, the satellite-mounted repeater demultiplexes the digital broadcast signal modulated by the first modulation method and received from the plurality of transmission stations by the input demultiplexing unit for each predetermined channel frequency band. To do. As a result, the digital broadcast signal is separated into signals for each channel unit. As a first modulation method, a modulation method capable of demodulating multipath (delayed wave) such as OFDM modulation can be used to demodulate a signal for each channel as a signal for each transmission station. . Therefore, the satellite-mounted repeater demodulates the demultiplexed digital broadcast signal into a baseband signal for each transmission station by the demodulation means.

  Note that the baseband signal for each transmitting station may deteriorate due to rain attenuation. Therefore, the satellite-mounted repeater determines the reception level or error rate in the demodulated signal (baseband signal) that is demodulated by the demodulating means by the demodulating signal selecting means and is different for each transmitting station, and determines one demodulated signal. select. As a result, the uplink wave can be switched in the satellite-borne repeater.

  Then, the satellite-mounted repeater modulates the demodulated signal selected by the demodulated signal selecting means by the modulating means by the second modulation method. The satellite-mounted repeater amplifies the modulation signal for each channel frequency band modulated by the modulation means to a predetermined signal level that can be transmitted as a downlink wave by the amplification means, and amplifies the amplified signal by the output multiplexing means. The modulated signal is combined as a second digital broadcast signal for transmission.

  Further, the satellite-mounted repeater according to claim 3 is the satellite-mounted repeater according to claim 2, wherein the digital broadcast signal transmitted from the transmitter station is divided into the channel frequency bands for each transmitter station. The demodulated signal selection means determines a reception level or an error rate for each divided band and selects one demodulated signal.

  According to such a configuration, the satellite-mounted repeater transmits the digital broadcast signal transmitted from the transmission station by performing demodulation by the demodulation unit because the digital broadcast signal is a divided band signal obtained by dividing the channel frequency band for each transmission station. A baseband signal divided for each station and for each channel is generated. The satellite-mounted repeater determines the reception level or error rate in the modulation signal (baseband signal) that is demodulated by the demodulation means by the demodulation signal selection means and differs for each transmission station, and determines one demodulation signal. select.

  In addition, the satellite-mounted repeater according to claim 4 is mounted on the broadcast satellite that selectively relays digital broadcast signals having different polarizations transmitted from two different stations via the broadcast satellite. A satellite-mounted repeater comprising a polarization separation unit, an input demultiplexing unit, a demodulation unit, a demodulated signal selection unit, a modulation unit, an amplification unit, and an output multiplexing unit .

  According to such a configuration, the satellite-mounted repeater detects the polarization of the digital broadcast signal received from the two transmission stations by the polarization separation means and separates it into two reception signals. For example, the digital broadcast signal is separated into two received signals by detecting right-handed circular polarization and left-handed circular polarization, or horizontal polarization and vertical polarization of the digital broadcast signal.

Further, the satellite-mounted repeater demultiplexes the received signal separated by the polarization demultiplexing means for each predetermined channel frequency band by the input demultiplexing means. As a result, the digital broadcast signal is separated into signals for each channel and for each transmission station.
The satellite-mounted repeater demodulates the demultiplexed digital broadcast signal into a baseband signal by the demodulating means. The satellite-mounted repeater determines the reception level or error rate in the demodulated signal (baseband signal) for each channel and demodulated by the demodulating means by the demodulated signal selecting means, and determines one demodulated signal. Select.

In addition, the satellite-mounted repeater modulates the demodulated signal selected by the demodulated signal selecting means by the modulating means by the second modulation method.
The satellite-mounted repeater amplifies the modulation signal for each channel frequency band modulated by the modulation means to a predetermined signal level that can be transmitted as a downlink wave by the amplification means, and amplifies the amplified signal by the output multiplexing means. The modulated signal is combined as a second digital broadcast signal for transmission.

  The satellite-mounted repeater according to claim 5 is a satellite-mounted repeater mounted on the broadcast satellite that multiplexes and relays individual broadcast program signals transmitted from a plurality of transmitting stations via the broadcast satellite. And an input demultiplexing unit, a demodulating unit, a synthesizing unit, a modulating unit, an amplifying unit, and an output multiplexing unit.

  According to this configuration, the satellite on-board repeater receives a digital broadcast signal for each broadcast program signal modulated by the first modulation method, received from a plurality of transmission stations by the input demultiplexing means, with a predetermined channel frequency. Demultiplexes each band. The satellite-mounted repeater demodulates the demultiplexed digital broadcast signal into a baseband signal for each broadcast program signal by the demodulation means. The baseband signal demodulated by the demodulating means is bit stream data for each broadcast program such as MPEG-TS. The broadcast program signal transmitted as a digital broadcast signal from the transmission station may be a single broadcast program signal (transport stream), or a plurality of different frequency bands divided in the same channel. It may include a broadcast program signal.

Then, the satellite-mounted repeater generates a baseband signal corresponding to one channel frequency band by combining the plurality of baseband signals demodulated by the demodulation unit by the combining unit. The baseband signal generated by this combining means is a signal obtained by multiplexing a plurality of broadcast programs in the same channel.
The satellite-mounted repeater modulates the baseband signal of the same channel generated by the synthesizing unit using the second modulation method.

  The satellite-mounted repeater amplifies the modulation signal for each channel frequency band modulated by the modulation means to a predetermined signal level that can be transmitted as a downlink wave by the amplification means, and amplifies the amplified signal by the output multiplexing means. The modulated signal is combined as a second digital broadcast signal for transmission.

  Furthermore, the satellite-borne repeater according to claim 6 is the satellite-borne repeater according to any one of claims 1 to 5, wherein a known unique signal is inserted in advance into the digital broadcast signal. The signal is configured to include transmission characteristic estimation means and waveform equivalent means.

According to such a configuration, the satellite-mounted repeater estimates the transmission characteristic of the demodulated signal based on the unique signal in the digital broadcast signal in which the known unique signal is inserted in advance by the transmission characteristic estimation unit. For example, transmission characteristics such as frequency characteristics and time axis characteristics are estimated by detecting the position of the specific signal of an OFDM signal in which a known specific signal is multiplexed in advance.
The satellite-mounted repeater then shapes the demodulated signal by correcting the amplitude, phase, etc., based on the transmission characteristics estimated by the transmission characteristic estimation means by the waveform equivalent means.

  Further, the satellite-mounted repeater according to claim 7 is the satellite-mounted repeater according to claim 6, wherein the transmission characteristic estimation means uses the transmission characteristic estimated by the transmission characteristic estimation means as a corresponding transmission station. It is characterized by notifying.

  According to such a configuration, the satellite onboard repeater notifies the transmission station that has transmitted the estimated digital broadcast signal of the transmission characteristic estimated by the transmission characteristic estimation means. As a result, the transmitting station can grasp the transmission characteristics of the uplink wave transmitted by itself.

  Furthermore, the satellite on-board repeater according to claim 8 is the satellite on-board repeater according to claim 7, wherein the demodulating means and the demodulating means are based on at least a parameter for controlling demodulation and modulation transmitted from the transmitting station. The modulation means changes the operation of demodulation and modulation.

  According to such a configuration, the satellite-mounted repeater performs demodulation and modulation operations based on parameters for controlling demodulation and modulation transmitted from the transmitting station, for example, guard interval length in the OFDM modulation scheme, carrier modulation scheme, and the like. By changing it, it becomes possible to change the transmission characteristics.

  The satellite-mounted repeater according to claim 9 is the satellite-mounted repeater according to any one of claims 1 to 8, wherein the digital broadcast signal is scrambled into broadcast bitstream data. Is a signal that is modulated after being added by calculation, and includes a descrambling means and a judging means.

  According to such a configuration, the satellite-borne repeater reverses the scramble information added to the demodulated signal demodulated by the demodulator by the descrambler and the inverse operation when the scramble information is added on the transmitting station side. By doing so, the scramble information is released. Then, the determination means determines the validity of the demodulated signal by comparing information in a predetermined area of the scrambled signal with known information. That is, the determination means determines that the demodulated signal is transmitted from a regular transmission station if the collation results are the same.

  According to the first aspect of the present invention, an uplink wave (digital broadcast signal) transmitted from a transmission station is demodulated into a baseband signal in a satellite-mounted repeater. The signal can be processed in units. As a result, when site diversity operation against rain attenuation is performed, discontinuities that occur when the uplink wave transmitted from the transmitting station is switched to transmission from another transmitting station are processed as a continuous signal of the baseband signal. It becomes possible to do. Further, the discontinuity of the downlink wave is eliminated at the time of site diversity operation, and the digital broadcast signal can be correctly reproduced in the receiving apparatus even when the transmitting station is switched.

  According to the invention described in claim 2, claim 3 or claim 4, as a measure against rain attenuation, it is possible to independently carry out site diversity operation within the satellite-mounted repeater. As a result, the burden on the operator of the satellite digital broadcasting system can be reduced.

  According to the fifth aspect of the present invention, it is possible to transmit a plurality of broadcast programs constituting a channel from individual transmitting stations (uplink transmitting stations). Thus, for example, by individually transmitting each broadcast program such as audio, video, and data from a plurality of transmitting stations, it is possible to solve the problem that the entire channel cannot be viewed due to rain attenuation. That is, according to the present invention, it is possible to increase the diversity effect for each program constituting the channel.

  According to the sixth aspect of the present invention, the amplitude, phase, etc. of the demodulated signal can be corrected based on the transmission characteristics of the demodulated signal. As a result, it is possible to reduce the influence of rain attenuation and the like of the digital broadcast signal that should be originally transmitted, and the receiving apparatus can stably receive the digital broadcast signal.

  According to the seventh aspect of the present invention, since it becomes possible for the transmitting station to grasp the transmission characteristics of the uplink wave transmitted by the own station, when the transmission characteristics deteriorate due to the influence of rain attenuation, etc. Thus, it is possible to perform processing such as changing the parameters of the modulation scheme, and to suppress degradation of the uplink wave.

  According to the eighth aspect of the invention, it is possible to control the demodulation and modulation operations in the satellite-mounted repeater from the transmitting station, and change the parameters for controlling the demodulation and modulation according to the transmission characteristics of the uplink wave. As a result, it is possible to reduce the influence of rain attenuation and the like of the digital broadcast signal that should be transmitted.

  According to the ninth aspect of the present invention, even if an unauthorized uplink wave is transmitted, it is possible to detect the unauthorizedness, thereby preventing the distribution of an unauthorized digital broadcast signal such as a radio jack. be able to.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Outline of satellite digital broadcasting system]
First, with reference to FIG. 1, an outline of a satellite digital broadcasting system realized by a satellite-mounted repeater according to the present invention will be described. FIG. 1 is a configuration diagram showing the overall configuration of a satellite digital broadcasting system.
The satellite digital broadcast system 100 demodulates an uplink wave, which is a digital broadcast signal transmitted from the transmission station Sd (Sd1, Sd2), by the satellite-mounted repeater 1 in the broadcast satellite Bs and modulates it to another modulation method. Then, it is delivered to the receiving device Rv as a downlink wave. In FIG. 1, two transmission stations Sd are provided, but there may be a plurality of other transmission stations.

The transmitting station Sd transmits program data for broadcasting as digital broadcasting (satellite digital broadcasting) distributed from the broadcasting station Ts to the satellite-mounted repeater 1 as an uplink wave. The transmitting station Sd multiplexes program data (broadcast program signal) for each of a plurality of channels, performs error correction coding, modulates the coded data (OFDM modulation, CDM modulation, etc.), and the modulated signal. Is converted to an RF frequency, and power is amplified to obtain an uplink wave. Here, the transmitting station Sd is arranged at a plurality of different points on the earth as a countermeasure against rain attenuation of the uplink wave.
The program data distributed from the broadcasting station Ts is a plurality of bit stream data such as MPEG-TS for each channel, and is distributed to the transmitting station Sd via a communication cable such as an optical fiber.

  The receiving device Rv receives a digital broadcast signal (downlink wave) distributed from the satellite-mounted repeater 1 and demodulates it into viewable data (video, audio, data, etc.). Thereby, the viewer can view the program data transmitted from the transmitting station Sd.

The satellite-mounted repeater 1 demodulates the uplink wave transmitted from the transmission station Sd, remodulates it to another modulation scheme, and distributes it to the receiving device Rv as a downlink wave.
In the first embodiment described below, when the operator switches the transmission from the plurality of transmission stations Sd and performs the site diversity operation based on the rain attenuation state as in the prior art, An example in which the satellite-borne repeater 1 according to the invention is applied will be described.

In the second embodiment, the digital broadcast signal (for example, OFDM signal, CDM signal) of the same channel is transmitted from the plurality of transmission stations Sd, and one channel is transmitted in the satellite-mounted repeater 1 according to the present invention. An example of selecting and distributing a digital broadcast signal will be described.
In the third embodiment, the digital broadcast signal of the same channel is transmitted by changing the frequency band for each of the plurality of transmitting stations Sd, and the satellite-mounted repeater 1 according to the present invention digitally transmits one channel. An example in which broadcast signals are selected and distributed will be described.

In the fourth embodiment, a digital broadcast signal (program data is the same) that differs only in polarization characteristics is transmitted from two different transmitting stations Sd, and the satellite-mounted repeater according to the present invention is used. 1, an example in which one of two digital broadcast signals is selected and distributed will be described.
Furthermore, in the fifth embodiment, the individual broadcast program signal in the channel is transmitted as a digital broadcast signal for each of the plurality of transmitting stations Sd, and the broadcast program signal is transmitted by the satellite-mounted repeater 1 according to the present invention. A description will be given of an example of multiplexing and distributing.

[First embodiment]
(Configuration of satellite mounted repeater 1A)
First, the configuration of the satellite-mounted repeater 1 (1A) will be described with reference to FIG. 2 (refer to FIG. 1 as appropriate). FIG. 2 is a block diagram showing the configuration of the satellite-borne repeater according to the first embodiment of the present invention. As shown in FIG. 2, the satellite-mounted repeater 1A demodulates the digital broadcast signal (uplink wave) modulated by the first modulation scheme transmitted from the transmission station Sd and modulates it to the second modulation scheme. It is corrected and distributed to the receiving device Rv. Here, the satellite-mounted repeater 1A includes a transmission / reception duplexer 3, a frequency converter / amplifier 10 and an input duplexer 11 as a receiver, a demodulator 20 as a modulation scheme converter, a program editing device 21A, and a demodulator. Unit 22, a gain controller 30 as a transmission unit, a power amplifier 31, and an output multiplexer 32.

  The transmitter / receiver demultiplexer (diplexer) 3 is a frequency filter for identifying the frequency of the uplink signal (uplink frequency) and the frequency of the downlink signal (downlink frequency). This transmitter / receiver demultiplexer 3 filters a specific frequency for reception (for example, 17 GHz), thereby converting the uplink wave transmitted from the transmitting station Sd and received by the antenna AT as a digital broadcast signal. Output to the amplifier 10. Further, the transmitter / receiver demultiplexer 3 filters a specific frequency for transmission (for example, 12 GHz) to distribute the digital broadcast signal to the receiving device RV as a downlink wave via the antenna AT.

  The frequency converter / amplifier 10 amplifies the power of the digital broadcast signal output from the transceiver 3 and down-converts the frequency (uplink frequency) of the digital broadcast signal. That is, the frequency converter / amplifier 10 converts the uplink frequency into a frequency suitable for demodulating the digital broadcast signal (for example, 1 to 2 GHz) and the digital broadcast signal received by the antenna AT. It has a function as a low noise amplifier (LNA) that amplifies a weak signal attenuated by propagation loss. Either amplification or frequency conversion of the digital broadcast signal may be performed first.

The input demultiplexer (input demultiplexing means) 11 is a filter that separates (demultiplexes) the digital broadcast signal amplified and frequency converted by the frequency conversion / amplifier 10 into signals for each channel frequency band. The signal for each channel demultiplexed by the input demultiplexer 11 is output to a demodulator 20 (20 _{1 to} 20 _n ) provided for each channel frequency band.

Those demodulator (demodulation means) 20 (20 ₁ ~20 _n) is that present in each channel frequency band, demodulates the signal of the input demultiplexer 11 at demultiplexed each channel frequency band to a baseband signal It is. Here, the demodulation unit 20 includes a demodulation processing unit 201, a descrambling unit 202, and a determination unit 203.

  The demodulation processing unit 201 demodulates a signal (channel signal) in a channel frequency band by the modulation method (first modulation method) used in the transmission station Sd. The signal demodulated by the demodulation processing unit 201 is a video / audio broadcast signal (MPEG-2 or the like), a transmission control signal (TMCC: Transmission and Multiplexing Configuration Control), an error correction signal (convolutional code, Reed-Solomon code), or the like. Is a baseband signal that is combined. The demodulated signal (baseband signal) demodulated by the demodulation processing unit 201 is output to the descrambling unit 202.

  The scramble release unit (scramble release means) 202 adds scramble information (bits, bytes, or random information of these integer multiples) set by the operator to broadcast bitstream data (eg, MPEG-TS). The digital broadcast signal that has been added and calculated by subtraction or the like is descrambled. The descrambling unit 202 performs descrambling by performing an inverse operation of the operation performed at the time of scrambling. The baseband signal that has been descrambled by the descrambling unit 202 is output to the determination unit 203.

The determination unit (determination means) 203 determines whether or not the baseband signal that has been descrambled by the scramble cancellation unit 202 is transmitted from a valid transmission station Sd. For example, the determination unit 203 collates information on a predetermined position (for example, identification information of the transmitting station Sd) of the scrambled baseband signal with known information held in advance by the determination unit 203. Thus, the validity of the baseband signal is determined.
Then, the determination unit 203 outputs the baseband signal to the program editing apparatus 21A only when the baseband signal is a valid signal.

  The program editing apparatus 21A corrects a signal (channel signal) for each channel frequency band with respect to the baseband signal demodulated by the demodulator 20. In the program editing apparatus 21A, the signal is corrected by equalizing the deteriorated baseband signal. In this configuration, correction of the channel signal is not essential, but it is preferable to perform this correction in order to improve the quality of the relayed digital broadcast signal.

  Here, the configuration of the program editing apparatus 21A will be described with reference to FIG. 3 (refer to FIGS. 1 and 2 as appropriate). FIG. 3 is a block diagram illustrating an example of a program editing apparatus. Here, the program editing apparatus 21A includes an equalization unit 40 for each demodulation unit 20 corresponding to a channel frequency band, and each equalization unit 40 includes an error correction decoding unit 41, a transmission characteristic estimation unit 42, a waveform, and the like. And an error correction adding unit 44.

  The error correction decoding unit 41 corrects an error during transmission of a signal (channel signal) for each channel frequency band demodulated by the demodulation unit 20. The error correction decoding unit 41 corrects an error of the channel signal based on the error correction code added to the channel signal in advance at the transmitting station Sd. As this error correction code, for example, a Reed-Solomon code, a convolutional code, or the like can be used. The channel signal whose error has been corrected by the error correction decoding unit 41 is output to the waveform equalization unit 43. In addition, the error correction decoding part 41 is good also as performing the decoding (deinterleaving), when signal processing, such as a bit or byte unit, such as an interleaving process, is performed with respect to the demodulated signal.

The transmission characteristic estimation unit (transmission characteristic estimation means) 42 estimates the transmission characteristic of the channel signal demodulated by the demodulation unit 20. In addition to the digital broadcast signal to be originally transmitted, a known unique signal, identification information of the transmitting station, and the like can be added to the uplink wave transmitted from the transmitting station Sd.
Therefore, for example, when an OFDM signal is used as an uplink wave, a demodulation unit 20 performs fast Fourier transform (FFT) on the OFDM carrier by multiplexing a known specific signal in advance on an OFDM carrier for each time axis and frequency axis. ), The transmission characteristic estimation unit 42 can estimate the transmission characteristics (frequency characteristics, time axis characteristics, etc.).
Further, when using a CDM signal as an uplink wave, the transmission characteristic estimation unit 42 can estimate the transmission characteristic by inserting a known unique signal for each multiplexed code or changing its insertion position.

  Then, the transmission characteristic estimation unit 42 notifies the transmission station Sd of the estimated transmission characteristic as telemetry information in association with the identification information of the transmission station. Thereby, the operator of the satellite digital broadcast system can grasp the reception characteristics of the uplink wave in the satellite-mounted repeater for each transmission station, or can improve the reception characteristics. The transmission of telemetry information will be described later with reference to FIG.

  A waveform equalization unit (waveform equalization means) 43 performs amplitude, phase, etc. on the channel signal whose error has been corrected by the error correction decoding unit 41 based on the transmission characteristics estimated by the transmission characteristic estimation unit. By performing the correction, the received signal that is distorted on the transmission path is equalized so as to have a target waveform. Here, the target waveform is, for example, a waveform synchronized with the synchronous detection frequency when the OFDM signal is synchronously detected. The waveform signal equalized by the waveform equalizing unit 43 is output to the error correction adding unit 44.

The error correction adding unit 44 adds an error correction code to the waveform signal equalized by the waveform equalizing unit 43. For example, the error correction adding unit 44 adds an error correction code (for example, Reed-Solomon code, convolutional code, etc.) corresponding to the error correction of the receiving device Rv. A signal for each channel (channel signal after equalization) to which the error correction code is added by the error correction adding unit 44 is output to the modulation unit 22 corresponding to the channel. The error correction adding unit 44 may perform interleaving processing in units of bits or bytes.
By configuring the equalization unit 40 in this way, the channel signal for each channel frequency band is shaped and becomes a signal from which phase noise and the like are removed.
Returning to FIG. 2, the description of the configuration of the satellite-mounted repeater 1A will be continued.

Modulation unit (modulation means) 22 (22 ₁ through 22 _n) are present for each channel frequency band, channel signal equalized by the equalizer 40 (see FIG. 3) of the program editing apparatus 21A (baseband signal) Every time, modulation is performed by the second modulation method. As the second modulation method, a phase shift keying (PSK) method and a quadrature amplitude modulation (QAM) method, which are currently generally used as a modulation method for satellite broadcasting, are used. be able to. The modulation signal modulated by the modulation unit 22 is output to the gain control unit 30 for each channel frequency band.

The gain control unit 30 (30 ₁ to 30 _n ) controls the gain (gain) in order to keep the signal for each channel frequency band output from the modulation unit 22 at a predetermined voltage. That is, the gain control unit 30 multiplies the input signal input to the gain control unit 30 by a coefficient based on the voltage of the output signal output by itself (the gain control unit 30), so that the output voltage is predetermined. It functions as automatic gain control (AGC) that controls the level. The signal whose gain is controlled by the gain control unit 30 is output to the power amplifier 31.

The power amplifier (amplifying means) 31 (31 _{1 to} 31 _n ) amplifies the signal for each channel frequency output from the gain control unit 30 to power that can be received by the receiving device Rv. The power amplifier 31 can be realized by using a general traveling wave tube amplifier (TWTA). A signal (channel signal) for each channel frequency whose power is amplified by the power amplifier 31 is output to the output multiplexer 32.

  The output multiplexer (output multiplexer) 32 is a filter that multiplexes (combines) signals for each channel frequency, the power of which is amplified by the power amplifier 31. The digital broadcast signal generated by being multiplexed by the output multiplexer 32 is output to the transmission / reception duplexer 3 and distributed to the receiving device Rv via the antenna AT.

As described above, the satellite-mounted repeater 1A can change the modulation system of the digital broadcast signal between the uplink wave and the downlink wave.
In this case, the modulation method for the uplink wave uses the first modulation method such as an OFDM modulation method or a CDM modulation method that can be demodulated with respect to the multipath (delayed wave). It becomes possible to use a second modulation method such as PSK modulation or QAM modulation that can be received at a low CN ratio in the device Rv.

  As a result, in the satellite-mounted repeater 1A, even when digital broadcast signals are transmitted from a plurality of transmission stations Sd, the digital broadcast signals are once demodulated and converted into baseband signals. Only the digital broadcast signal of the transmitting station Sd instructed by the operator (operation site) can be selected. At this time, since the satellite-mounted repeater 1A switches the signal that has undergone the above-described processing based on the baseband signal, the conventional downlink wave discontinuity does not occur, and the receiving apparatus Rv Does not affect viewing.

(Operation of satellite mounted repeater 1A)
Next, referring to FIG. 4 (see FIGS. 1 and 2 as appropriate), the operation of the satellite-mounted repeater 1A will be described. FIG. 4 is a flowchart showing the operation of the satellite-borne repeater according to the first embodiment of the present invention.
First, the satellite-mounted repeater 1A receives a digital broadcast signal (uplink wave) transmitted from the transmitting station Sd by the transmission / reception demultiplexer 3 (step S1). The satellite-mounted repeater 1A then amplifies the power of the received digital broadcast signal by the frequency converter / amplifier 10 and down-converts the frequency (step S2). Each time the digital broadcast signal is demultiplexed (step S3).

  Then, the satellite-mounted repeater 1A demodulates the channel signal, which is a signal for each channel frequency band demultiplexed by the input demultiplexer 11, by the demodulator 20 into a baseband signal (step S4). In this step S4, the demodulation corresponding to the first modulation method which modulates the digital broadcast signal performed in the transmission station Sd is performed.

  Furthermore, the satellite-mounted repeater 1A equalizes the channel signal based on the transmission characteristics by the program editing device 21A and corrects the channel signal (step S5). Then, the satellite-mounted repeater 1A modulates the channel signal corrected in step S5 by the modulation unit 22 using the second modulation method (PSK modulation method or QAM modulation method) (step S6).

The satellite-mounted repeater 1A controls the voltage of the modulated channel signal to a predetermined level by the gain controller 30 (step S7), and the power amplifier 31 converts the power of the channel signal to the receiving device. It amplifies to the power receivable by Rv (step S8).
In the operations from step S4 to step S8, channel signals for each channel frequency band are processed in parallel.

  Then, the satellite-mounted repeater 1A multiplexes (combines) the channel signals for each channel frequency whose power is amplified in step S8 by the output multiplexer 32 (step S9). Then, the satellite-mounted repeater 1A distributes the digital broadcast signal generated by being multiplexed in the step S9 by the transmitter / receiver demultiplexer 3 to the receiving device Rv via the antenna AT (step S10).

  Through the above operation, the satellite-mounted repeater 1A can change the modulation method of the digital broadcast signal between the uplink wave and the downlink wave, and even if the transmitting station Sd is switched by the operation of the site diversity operator, It becomes possible to make the link wave a continuous signal.

[Second Embodiment]
(Configuration of satellite-borne repeater 1B)
Next, the configuration of the satellite-mounted repeater 1B will be described with reference to FIG. 5 (refer to FIG. 1 as appropriate). FIG. 5 is a block diagram showing the configuration of the satellite-borne repeater according to the second embodiment of the present invention. As shown in FIG. 5, the satellite-mounted repeater 1B switches and relays the same digital broadcast signal (uplink wave) transmitted from a plurality of transmission stations Sd at different points. A plurality of transmitting stations Sd at different points can demodulate a digital broadcast signal, which is the same broadcast program on the same channel, by a signal that can be demodulated even if it is a multipath (multiple wave) such as an OFDM modulated signal or a CDM modulated signal. Shall be sent.

Here, the satellite-mounted repeater 1B includes a transmitter / receiver demultiplexer 3, a frequency converter / amplifier 10 and an input demultiplexer 11 as a receiver, a demodulator 20B as a modulation scheme converter, a program editing device 21B, and a modulator. Unit 22, a gain controller 30 as a transmission unit, a power amplifier 31, and an output multiplexer 32.
Since the configuration other than the demodulator 20B and the program editing device 21B is the same as that of the satellite-mounted repeater 1A (see FIG. 2), the same reference numerals are given and description thereof is omitted.

  The demodulating unit (demodulating means) 20B exists for each channel frequency band, and demodulates the signal (channel signal) for each channel frequency band demultiplexed by the input demultiplexer 11 to obtain a baseband signal. Note that the channel signal input from the input demultiplexer 11 includes a plurality of signals transmitted by a plurality of transmitting stations Sd at different points. Therefore, the demodulation unit 20B separates the channel signal into channel signals for each transmission station Sd by performing demodulation for modulation such as the OFDM modulation method. Then, the demodulation unit 20B outputs the channel signal for each transmission station Sd to the program editing device 21B. Here, as an example, two transmitting stations Sd are used, and two channel signals are output from one demodulating unit 20B. However, the demodulating unit 20B uses channel signals in accordance with the number of transmitting stations Sd. Is output.

  The program editing device 21B selects one demodulated signal based on the reception level or error rate of the demodulated signal (baseband signal) for each transmission station Sd demodulated by the demodulator 20B.

  Here, the configuration of the program editing apparatus 21B will be described with reference to FIG. 6 (refer to FIGS. 1 and 5 as appropriate). FIG. 6 is a block diagram illustrating an example of a program organization apparatus. Here, the program editing apparatus 21B includes a signal switching unit 50 for each channel frequency band, and each signal switching unit 50 includes an error correction decoding unit 51, a storage unit 52, a reception level determination unit 53, and a switching unit 54. And a storage unit 55 and an error correction addition unit 56.

The error correction decoding unit 51 corrects an error during transmission of a signal (channel signal) for each transmission station Sd demodulated by the demodulation unit 20B. Here, error correction decoding units 51 ₁ and 51 ₂ that perform error correction for each channel signal of the same channel are provided.
The demodulated signal of the channel signal whose error is corrected by each error correction decoding unit 51 is stored in the storage unit 52. Further, each error correction decoding unit 51 notifies the reception level determination unit 53 of the reception level or error rate of the demodulated signal detected when performing error correction.

The storage unit 52 stores the demodulated signal whose error has been corrected by each error correction decoding unit 51, and functions as a temporary buffer. Here, storage units 52 ₁ and 52 ₂ are provided for each of the error correction decoding units 51 ₁ and 51 ₂ .

Whether the reception level determination unit (demodulation signal selection means) 53 should switch channel signals based on the reception level or error rate notified from each error correction decoding unit 51 (which channel signal should be selected) Is determined. For example, the reception level determination unit 53 detects signal deterioration such as rain attenuation by comparing the reception level or error rate of one channel signal with a predetermined threshold value, and the other is not deteriorated. The switching unit 54 is instructed to switch to the channel signal.
Note that the reception level determination unit 53 may determine whether to switch channel signals by directly receiving information such as rain attenuation from the transmission station Sd as the reception level.

The switching unit 54 switches the output of the channel signal transmitted from the transmission station Sd based on an instruction from the reception level determination unit 53. Based on an instruction from the reception level determination unit 53, the switching unit 54 reads from _one storage unit 52 (for example, the storage unit 52 ₁ ) to the other storage unit 52 (for example, the storage unit 52 ₂ ). The read signals are sequentially stored in the storage unit 55.

The storage unit 55 stores the signal switched by the switching unit 54, and functions as a temporary buffer.
By providing the storage unit 52 and the storage unit 55, for example, an operation such as switching the switching timing of the channel signal in units of packets can be performed, and discontinuity due to channel switching does not occur.

  The error correction adding unit 56 is switched by the switching unit 54 and adds an error correction code to the signal (channel signal) stored in the storage unit 55. For example, the error correction adding unit 56 adds an error correction code (for example, Reed-Solomon code, convolutional code, etc.) corresponding to the error correction of the receiving device Rv.

As described above, when the same digital broadcast signal is transmitted from a plurality of transmitting stations using OFDM signals or the like from the plurality of transmitting stations, the satellite-mounted repeater 1B causes signal degradation such as rain attenuation to occur in the satellite-mounted repeater 1B. , And site diversity operation can be performed without the operator's work from the earth.
Here, the digital broadcast signal (uplink wave) is transmitted from the two transmission stations Sd, but the digital broadcast signal may be transmitted from three or more transmission stations Sd. In this case, the error correction decoding unit 51 and the storage unit 52 increase in accordance with the number of transmitting stations Sd.

(Operation of satellite-borne repeater 1B)
Next, referring to FIG. 7 (refer to FIGS. 5 and 6 as appropriate), the operation of the satellite-mounted repeater 1B will be described. FIG. 7 is a flowchart showing the operation of the satellite-borne repeater according to the second embodiment of the present invention.

  First, the satellite-mounted repeater 1B receives digital broadcast signals (uplink waves) transmitted from the plurality of transmission stations Sd by the transceiver 3 (step S11). Then, the satellite-mounted repeater 1B amplifies the power of the received digital broadcast signal by the frequency conversion / amplifier 10 and performs frequency conversion (down-conversion) (step S12). The digital broadcast signal is demultiplexed for each frequency obtained by dividing the frequency band for each transmission station Sd (step S13).

Then, the satellite-mounted repeater 1B corresponds to the first modulation scheme in which the channel signal, which is a signal for each frequency band demultiplexed by the input demultiplexer 11 by the demodulator 20B, is modulated by the transmitting station Sd. Demodulation is performed to obtain a baseband signal (step S14).
Furthermore, the satellite-mounted repeater 1B corrects the error of the baseband signal by the error correction decoding unit 51 of the program editing device 21B and stores it in the storage unit 52 (step S15).

Then, the satellite-mounted repeater 1B uses the reception level determination unit 53 to determine whether the channel signal should be switched (which channel signal should be selected) from the reception level or error rate at the time of error correction (step S1). S16).
Here, when the satellite-mounted repeater 1B determines that the reception level determination unit 53 needs to switch (Yes in step S16), the satellite-mounted repeater 1B switches the channel signal (step S17). That is, the satellite-mounted repeater 1B reads the signal from the storage unit 52 (for example, 52 ₂ ) different from the currently read storage unit 52 (for example, 52 ₁ ) by the switching unit 54 and stores the signal in the storage unit 55.

Then, the satellite-mounted repeater 1B adds an error correction code to the channel signal read from the storage unit 55 by the error correction adding unit 56 (step S18), and performs modulation by the second modulation method (step S18). S19).
Further, the satellite-mounted repeater 1B controls the voltage of the modulated channel signal to be a predetermined level by the gain controller 30 (step S20), and the power amplifier 31 converts the power of the channel signal to the receiving device. It amplifies to the power receivable by Rv (step S21).

The satellite-mounted repeater 1B then multiplexes (combines) the channel signals whose power has been amplified in step S21 by the output multiplexer 32 (step S22). Then, the satellite-mounted repeater 1B distributes the digital broadcast signal generated by being multiplexed in step S22 by the transmitter / receiver demultiplexer 3 to the receiving device Rv via the antenna AT (step S23).
With the above operation, the satellite-mounted repeater 1B can select and relay a signal with little deterioration of rain attenuation from the digital broadcast signal transmitted from each of the plurality of transmission stations Sd.

[Third embodiment]
(Configuration of satellite mounted repeater 1C)
Next, the configuration of the satellite-mounted repeater 1C will be described with reference to FIG. 8 (refer to FIG. 1 as appropriate). FIG. 8 is a block diagram showing a configuration of a satellite-borne repeater according to the third embodiment of the present invention. As shown in FIG. 8, the satellite-mounted repeater 1C switches and relays the same digital broadcast signal (uplink wave) transmitted from a plurality of transmission stations Sd at different points. A plurality of transmitting stations Sd at different points divide the frequency band of the channel and transmit digital broadcast signals that are the same broadcast program on the same channel in different frequency bands for each transmitting station Sd.

Here, the satellite-mounted repeater 1C includes a transmitter / receiver demultiplexer 3, a frequency converter / amplifier 10 and an input demultiplexer 11B as a receiver, a demodulator 20 as a modulation system converter, a program editing device 21B, and a modulator. Unit 22, a gain controller 30 as a transmission unit, a power amplifier 31, and an output multiplexer 32.
The configuration other than the input demultiplexer 11B and the program editing device 21B is the same as that of the satellite-mounted repeater 1A (see FIG. 2), and the program editing device 21B is the same as the satellite-mounted repeater 1B (FIG. 5). The same reference numerals are used and description thereof is omitted.

The input demultiplexer (input demultiplexing means) 11B separates the digital broadcast signal amplified and frequency-converted by the frequency conversion / amplifier 10 into signals for each frequency band different for each channel frequency band and for each transmission station Sd ( This is a filter for demultiplexing. For example, assuming that the transmission station Sd1 uses the upper sideband and the transmission station Sd2 uses the lower sideband in the frequency band of a certain channel, the input duplexer 11B further divides the channel frequency band into the digital broadcast signal. Separate the upper sideband and the lower sideband. The input demultiplexer 11B includes a demodulation section 20 ₁ a signal of the upper sideband, the signal of the lower sideband as demodulator 20 ₂ in the frequency band of a channel, the demodulation unit differs for each transmission station Sd 20 Output to.

  As described above, the satellite-mounted repeater 1C detects signal degradation such as rain attenuation in the satellite-mounted repeater 1C when digital broadcast signals having different frequency bands are transmitted from a plurality of transmitting stations. This makes it possible to perform site diversity operation without the operations of the operator from the earth.

Although an example in which the frequency band of one channel is divided into two in the upper side band and the lower side band is shown here, the channel frequency band is further subdivided so that three or more transmitting stations Sd It is good also as transmitting a digital broadcast signal (uplink wave) from. In this case, the demodulation unit 20, the error correction decoding unit 51 and the storage unit 52 in FIG. 6 increase in accordance with the number of transmission stations Sd.
As for the operation of the satellite-mounted repeater 1C, the satellite-mounted repeater 1B demodulates the signal for each transmission station Sd by the demodulator 20B, whereas the satellite-mounted repeater 1C uses the input demultiplexer. The only difference is that the output from 11B is already a signal for each transmission station Sd, and the description thereof will be omitted.

[Fourth embodiment]
(Configuration of satellite mounted repeater 1D)
Next, the configuration of the satellite-mounted repeater 1D will be described with reference to FIG. 9 (refer to FIG. 1 as appropriate). FIG. 9 is a block diagram showing a configuration of a satellite-borne repeater according to the fourth embodiment of the present invention. As shown in FIG. 9, the satellite-mounted repeater 1D switches and relays digital broadcast signals (uplink waves) transmitted from two transmission stations Sd (Sd1, Sd2) having different polarization characteristics. It is. Here, different polarizations are polarizations orthogonal to each other. For example, in the case of circular polarization, right-handed circular polarization and left-handed circular polarization, and in the case of linear polarization, horizontal polarization, vertical polarization. It refers to polarization.

Here, the satellite-mounted repeater 1D includes a polarization separator 7 as a receiver, a frequency converter / amplifier 10 and an input demultiplexer 11, a demodulator 20 as a modulation system converter, a program editing device 21B, and a modulator. 22, a gain controller 30 as a transmission unit, a power amplifier 31, and an output multiplexer 32.
Since the configuration other than the polarization separator 7, the frequency converter / amplifier 10 and the input demultiplexer 11 is the same as that of the satellite-mounted repeater 1C (see FIG. 8), the same reference numerals are given, Description is omitted.

The polarization separator (polarization separation means) 7 separates digital broadcast signals having different polarization characteristics received by the antenna AT1, and is a general polarization separation filter. The signals separated by the polarization separator 7 (for example, a right-handed circularly polarized signal and a left-handed circularly polarized signal, or a horizontal polarization signal and a vertical polarization signal) are respectively different frequency conversion / amplifiers 10 ( 10 ₁ , 10 ₂ ).
Here, since the polarization separator 7 is provided instead of the transmitter / receiver demultiplexer 3 shown in FIG. 8, the digital broadcast signal output from the output multiplexer 32 is transmitted via the transmission antenna AT2. To the receiving device Rv.

The frequency converter / amplifier 10 and the input demultiplexer 11 are the same as those described in the satellite-mounted repeater 1A (see FIG. 2), but here each has a double configuration for each polarization characteristic. . For example, right-handed circularly polarized wave signal is processed by the frequency conversion and amplifier 10 ₁ and the input demultiplexer 11 _1, left-hand circularly polarized signal is processed by the frequency conversion and amplifier 10 ₂ and the input demultiplexer 11 ₂ The

In this way, by configuring the satellite-mounted repeater 1D, when digital broadcasting signals having different polarization characteristics are transmitted from the two transmission stations Sd1 and Sd2, signal degradation such as rain attenuation is reduced. It can be detected in the repeater 1D, and site diversity operation can be performed without the operator's work from the earth.
Note that the operation of the satellite-mounted repeater 1D will be described with reference to FIG. 7 after the polarization separator 7 separates the received digital broadcast signal as a signal transmitted from each transmitting station Sd based on the polarization characteristics. Since this is the same as the operation of the satellite-mounted repeater 1B, the description is omitted.

[Fifth embodiment]
(Configuration of satellite mounted repeater 1E)
Next, the configuration of the satellite-mounted repeater 1E will be described with reference to FIG. 10 (refer to FIG. 1 as appropriate). FIG. 10 is a block diagram showing a configuration of a satellite-borne repeater according to the fifth embodiment of the present invention. As shown in FIG. 10, the satellite-mounted repeater 1E synthesizes and relays digital broadcast signals of different broadcast programs transmitted from a plurality of transmission stations Sd. Note that a plurality of transmission stations Sd1 and Sd2 (which may include other transmission stations) at different points are digital broadcasts that are different broadcast program signals (for example, MPEG-TS) in the same channel frequency band. The signals (TS1, TS2) are transmitted in different channel bands for each transmission station Sd. The broadcast program signal may be a signal including a plurality of TSs (transport streams) as well as one digital broadcast signal (TS1 or the like). In this case, it is assumed that the transmitting station Sd transmits a TS for each frequency band divided within the channel.

  Here, the satellite-mounted repeater 1E includes a transmitter / receiver demultiplexer 3, a frequency converter / amplifier 10 and an input demultiplexer 11 as a receiver, a demodulator 20B as a modulation scheme converter, a program editing device 21C, and a modulator. Unit 22, a gain controller 30 as a transmission unit, a power amplifier 31, and an output multiplexer 32. Since the configuration other than the program editing device 21C is the same as that of the satellite-mounted repeater 1B (see FIG. 5), the same reference numerals are given and description thereof is omitted.

The program editing device 21C synthesizes a broadcast program signal, which is a demodulated signal for each transmission station Sd demodulated by the demodulator 20B, for each channel.
Here, the configuration of the program editing device 21C will be described with reference to FIG. FIG. 11 is a block diagram illustrating an example of a program organization device. Here, the program editing apparatus 21C includes a signal synthesis unit 60 for each channel frequency band, and each signal synthesis unit 60 includes an error correction decoding unit 61, a storage unit 62, a synthesis unit 63, a storage unit 64, And an error correction adding unit 65.

  The error correction decoding unit 61, the storage unit 62, the storage unit 64, and the error correction addition unit 65 are the same as the error correction decoding unit 51, the storage unit 52, the storage unit 55, and the error correction addition unit 56 described in FIG. Therefore, the description is omitted here. However, the difference is that the demodulated signal demodulated by the demodulator 20B is not a signal for each channel (channel signal) but a broadcast program signal (MPEG-TS) constituting the channel signal.

  The synthesizing unit (synthesizing means) 63 generates one channel signal by synthesizing broadcast program signals. For example, when the broadcast program signal is MPEG-TS, control information for multiplexing a plurality of MPEG-TS called TMCC (Transmission and Multiplexing Configuration Control) is added to the signal. Therefore, the synthesis unit 63 synthesizes (multiplexes) each MPEG-TS with reference to the MPEG-TS TMCC stored in the storage unit 62.

As described above, the satellite-mounted repeater 1E demodulates the digital broadcast signals transmitted in units of broadcast program signals (MPEG-TS) from a plurality of transmission stations, so that the broadcast program signal is transmitted in the satellite-mounted repeater 1E. Can be multiplexed.
Regarding the operation of the satellite-mounted repeater 1E, the switching operation from step S15 to step S17 in the operation of the satellite-mounted repeater 1B described with reference to FIG. Therefore, the description is omitted.

  As described above, as the first to fifth embodiments, the various modifications of the satellite-mounted repeater have been described, but the present invention is not limited to this. For example, the transmission characteristic adjustment function described below can be realized by demodulating and modulating the uplink wave once as in the present invention.

<Transmission characteristics adjustment function>
In general, a satellite-mounted repeater is provided with a command / telemetry control unit shown in FIG. The command / telemetry control unit 70 processes a command (instruction command) transmitted from a not-shown control station (or transmitting station) and controls information (telemetry information) indicating the operation state of the satellite-mounted repeater. It is to be distributed to the station. As shown in FIG. 12, the command / telemetry control unit 70 generally includes a command demodulation unit 71, a command control unit 72, a telemetry creation unit 73, and a telemetry modulation unit 74.

The command demodulator 71 demodulates a command modulated at a frequency different from that of the digital broadcast signal. The command transmitted from the control station is input to the command demodulator 71 via the receiver of the satellite-mounted repeater.
Then, the command demodulated by the command demodulator 71 is output to the command controller 72.

The command control unit 72 analyzes the command demodulated by the command demodulation unit 71 and gives an instruction as a control signal to each unit in the satellite-mounted repeater.
The telemetry creation unit 73 collects the status of each part in the satellite-mounted repeater as a status signal and creates telemetry information. The telemetry information created by the telemetry creation unit 73 is output to the telemetry modulation unit 74.

The telemetry modulation unit 74 performs modulation by a modulation method capable of transmitting telemetry information as a downlink wave. The telemetry information modulated by the telemetry modulation unit 74 is distributed to the control station via the transmission unit of the satellite-mounted repeater.
Therefore, in the present invention, the satellite-mounted repeater 1A (FIG. 2), the satellite-mounted repeater 1B (FIG. 5), the satellite-mounted repeater 1C (FIG. 8), the satellite-mounted repeater 1D (FIG. 9), the satellite-mounted repeater In each of the devices 1E (FIG. 10), for example, parameters of the modulation scheme performed by the demodulator 20 (20B) and the modulator 22 are transmitted as commands from the control station, and the demodulator 20 (20B) and the modulator 22 It is also possible to adjust the transmission characteristics by performing control to change the parameters of the modulation scheme (for example, the guard interval length in the OFDM modulation scheme, the carrier modulation scheme, etc.).

  For example, the type of transmission characteristic performed by the transmission characteristic estimation unit 42 of the program editing apparatus 21A (FIG. 3) is instructed by a command, or the criterion for determination performed by the reception level determination unit 53 of the program editing apparatus 21B (FIG. 6) is used. It is also possible to perform control such as instructing or instructing parameters (for example, time interleave length, convolutional coding rate, etc.) at the time of combining performed by the combining unit 63 of the program editing apparatus 21C (FIG. 11).

Furthermore, by using the telemetry information, the transmission characteristic result performed by the transmission characteristic estimation unit 42 of the satellite-mounted repeater 21A (FIG. 3) is distributed to the control station, or the error correction decoding of the satellite-mounted repeater 21B (FIG. 6). The error rate or the like in the section may be distributed to the control station or controlled.
As a result, the control station can grasp the transmission characteristics of the satellite-mounted repeater, and can adjust various parameters based on the transmission characteristics.

It is a block diagram which shows the whole structure of the satellite digital broadcasting system which concerns on this invention. The block diagram which shows the structure of the satellite mounted repeater which concerns on 1st embodiment of this invention. It is a block diagram which shows an example of the program edit apparatus of the satellite-mounted repeater which concerns on 1st embodiment of this invention. It is a flowchart which shows operation | movement of the satellite mounted repeater which concerns on 1st embodiment of this invention. It is a block diagram which shows the structure of the satellite mounted repeater which concerns on 2nd embodiment of this invention. It is a block diagram which shows an example of the program organization apparatus of the satellite-mounted repeater which concerns on 2nd embodiment of this invention. It is a flowchart which shows operation | movement of the satellite mounted repeater which concerns on 2nd embodiment of this invention. It is a block diagram which shows the structure of the satellite mounted repeater which concerns on 3rd embodiment of this invention. It is a block diagram which shows the structure of the satellite mounted repeater which concerns on 4th embodiment of this invention. It is a block diagram which shows the structure of the satellite mounted repeater based on 5th Embodiment of this invention. It is a block diagram which shows an example of the program organization apparatus of the satellite onboard repeater which concerns on the 5th Embodiment of this invention. It is a block diagram which shows the structure of a command / telemetry control part. It is a block diagram which shows an example of a structure of the conventional satellite mounting repeater.

Explanation of symbols

1 Satellite-mounted repeater 3 Transmitter / receiver demultiplexer 7 Polarization separator (polarization separation means)
10 Frequency converter / Amplifier 11 Input demultiplexer (input demultiplexing means)
20 Demodulator (Demodulator)
201 demodulation processing unit 202 scramble release unit (scramble release means)
203 determination unit (determination means)
21 Program Editing Device 22 Modulation Unit (Modulation Means)
30 Gain controller 31 Power amplifier (amplifying means)
32 output multiplexer (output multiplexing means)
41 Error correction decoding unit 42 Transmission characteristic estimation unit (Transmission characteristic estimation means)
43 Waveform equalization unit (waveform equalization means)
44 Error correction adding unit 51 Error correction decoding unit 52 Storage unit 53 Reception level determination unit (demodulated signal selection means)
54 switching section 55 storage section 56 error correction adding section 61 error correction decoding section 62 storage section 63 combining section (combining means)
64 storage unit 65 error correction adding unit

Claims (9)

A satellite-mounted repeater mounted on the broadcasting satellite that relays the digital broadcasting signal transmitted from the transmitting station via the broadcasting satellite,
Input demultiplexing means for demultiplexing the digital broadcast signal received from the transmitting station and modulated by the first modulation method for each predetermined channel frequency band;
Demodulation means for demodulating the digital broadcast signal demultiplexed by the input demultiplexing means into a baseband signal;
A modulation means for modulating the baseband signal demodulated by the demodulation means by a second modulation method;
Amplifying means for amplifying the modulated signal for each channel frequency band modulated by the modulating means to a predetermined signal level;
Output multiplexing means for multiplexing the modulated signal amplified by the amplification means as a second digital broadcast signal for transmission;
It is equipped with a satellite-mounted repeater. A satellite-mounted repeater mounted on the broadcast satellite, which relays a digital broadcast signal transmitted from a plurality of transmission stations at different points via a broadcast satellite,
Input demultiplexing means for demultiplexing the digital broadcast signal received from the plurality of transmitting stations, modulated according to the first modulation method, for each predetermined channel frequency band;
Demodulation means for demodulating the digital broadcast signal demultiplexed by the input demultiplexing means into a baseband signal;
Demodulated signal selection means for determining a reception level or an error rate and selecting one demodulated signal in a modulated signal demodulated by the demodulating means for each transmission station,
Modulation means for modulating the selected demodulated signal by the second modulation method;
Amplifying means for amplifying the modulated signal for each channel frequency band modulated by the modulating means to a predetermined signal level;
Output multiplexing means for multiplexing the modulated signal amplified by the amplification means as a second digital broadcast signal for transmission;
It is equipped with a satellite-mounted repeater. The digital broadcast signal transmitted from the transmitting station is a divided band signal that is different for each transmitting station, which is obtained by dividing the channel frequency band.
The satellite-mounted repeater according to claim 2, wherein the demodulated signal selecting means determines a reception level or an error rate for each divided band and selects one demodulated signal. A satellite-mounted repeater mounted on the broadcast satellite, which relays a digital broadcast signal having a different polarization transmitted from a transmission station at two different points via a broadcast satellite,
Polarization separation means for detecting the polarization of the digital broadcast signal received from the two transmitting stations and separating it into two received signals;
Input demultiplexing means for demultiplexing the received signal separated by the polarization separating means for each predetermined channel frequency band;
Demodulation means for demodulating the received signal demultiplexed by the input demultiplexing means into a baseband signal;
In the demodulated signal demodulated by the demodulating means, a demodulated signal selecting means for determining a reception level or an error rate and selecting one demodulated signal;
Modulation means for modulating the selected demodulated signal by the second modulation method;
Amplifying means for amplifying the modulated signal for each channel frequency band modulated by the modulating means to a predetermined signal level;
Output multiplexing means for multiplexing the modulated signal amplified by the amplification means as a second digital broadcast signal for transmission;
It is equipped with a satellite-mounted repeater. A satellite-mounted repeater mounted on the broadcast satellite that multiplexes and relays individual broadcast program signals transmitted from a plurality of transmitting stations via the broadcast satellite,
Input demultiplexing means for demultiplexing a digital broadcast signal for each broadcast program signal, which is received from the transmitting station and modulated by the first modulation method, for each predetermined channel frequency band;
Demodulating means for demodulating the digital broadcast signal demultiplexed by the input demultiplexing means into a baseband signal for each broadcast program signal;
A synthesizing unit that generates a baseband signal corresponding to one channel frequency band by synthesizing a plurality of baseband signals demodulated by the demodulating unit;
Modulation means for modulating the baseband signal synthesized by the synthesis means by the second modulation method;
Amplifying means for amplifying the modulated signal for each channel frequency band modulated by the modulating means to a predetermined signal level;
Output multiplexing means for multiplexing the modulated signal amplified by the amplification means as a second digital broadcast signal for transmission;
It is equipped with a satellite-mounted repeater. The digital broadcast signal is a signal in which a known unique signal is inserted in advance,
Transmission characteristic estimation means for estimating the transmission characteristic of the demodulated signal based on the eigensignal;
Based on the transmission characteristics estimated by the transmission characteristic estimation means, waveform equalizing means for shaping the demodulated signal, and
The satellite-mounted repeater according to any one of claims 1 to 5, further comprising:   The satellite-mounted repeater according to claim 6, wherein the transmission characteristic estimation unit notifies a transmission station corresponding to the transmission characteristic estimated by the transmission characteristic estimation unit.   8. The satellite-borne relay according to claim 7, wherein the demodulation unit and the modulation unit change the operation of demodulation and modulation based on at least a parameter for controlling demodulation and modulation transmitted from the transmission station. vessel. The digital broadcast signal is a signal modulated after adding scramble information to the bitstream data for broadcasting by calculation,
A descrambling means for releasing the scramble by performing an inverse operation of the operation on the demodulated signal,
Determining means for determining the correctness of the demodulated signal by comparing predetermined information of the signal descrambled by the descrambling means with known information;
The satellite-mounted repeater according to any one of claims 1 to 8, further comprising:

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