JP3592454B2 - Satellite communication joint reception facility - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a satellite communication joint listening facility for transmitting digital satellite communication signals to a plurality of terminals.
[0002]
[Prior art]
Digital satellite communications from communications satellites will soon commence. Like a conventional analog satellite communication signal, a digital satellite communication signal uses vertically polarized waves and horizontally polarized waves in almost the same frequency band. When transmitting this digital satellite communication signal to each terminal of the joint hearing facility, each terminal uses vertical and horizontal polarization digital satellite communication in order to be able to receive the desired digital satellite communication signal at any time. It is necessary to convert the frequency to a non-overlapping frequency band and transmit it. An apparatus disclosed in Japanese Patent Application Laid-Open No. Hei 2-309782 is an apparatus for converting the frequency of an analog vertically and horizontally polarized satellite communication signal so that the frequency bands do not overlap. In this device, a frequency conversion device must be provided for each of a plurality of channels of vertical and horizontal polarizations, which complicates the configuration of the device and increases the cost. In addition, at the building joint receiving facility, transmission of an FM broadcast signal, a VHF band broadcast signal, a UHF band broadcast signal, a satellite broadcast intermediate frequency signal or a CATV signal has already been performed. When frequency conversion of the vertically and horizontally polarized digital satellite broadcast signals into non-overlapping frequency bands is performed at a building joint receiving facility, it is necessary not to change the frequency relationship between the above-mentioned signals. Is desirable because it does not change
[0003]
The present invention provides a satellite communication joint listening facility capable of transmitting digital satellite communication signals with a simple configuration, at low cost, and without changing the frequency relationship of existing signals transmitted through the joint receiving facility. The purpose is to:
[0004]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, in the invention according to claim 1, a mixing unit to which at least one of a UHF band broadcast signal, a VHF band broadcast signal, a signal for a joint reception facility, and a satellite broadcast intermediate frequency signal is input is provided. Maintain the frequency relationship between vertically and horizontally polarized digital satellite communication signals, each consisting of multiple channels, transmitted from the same communication satellite and having the same frequency bandwidth and partially shifted frequency bands. The first intermediate frequency signal of the vertical and horizontal polarizations, each of which has been frequency-converted as it is, is converted into a second intermediate frequency of the vertical and horizontal polarizations having a higher frequency than the satellite broadcast intermediate frequency signal and mutually non-overlapping frequencies. A conversion means for performing block frequency conversion for performing frequency conversion on the signal at a time, and supplying these second intermediate frequency signals of vertical and horizontal polarization to the mixing means; A force signal, and transmission means for transmitting to a plurality of terminals are provided.
[0005]
further,The first intermediate frequency signal of the vertical polarization is frequency-converted by a satellite communication frequency converter from a plurality of continuous vertical polarization digital satellite communication signals transmitted from a plurality of transponders for vertical polarization of the communication satellite. This is a wideband signal. The first intermediate frequency signal of horizontal polarization is obtained by converting a plurality of continuous horizontal polarization digital satellite communication signals transmitted from a plurality of transponders for horizontal polarization of the communication satellite by the satellite communication frequency converter. This is a converted wideband signal.
[0006]
The conversion means comprises: first frequency conversion means for vertical and horizontal polarization for frequency-converting a first intermediate frequency signal of vertical and horizontal polarization to a third intermediate frequency signal of vertical and horizontal polarization; A first local oscillation unit for vertical and horizontal polarization, which supplies first local oscillation signals for vertical and horizontal polarization to the conversion unit, respectively. The first local oscillation signal for vertical and horizontal polarization has a higher frequency than the first intermediate frequency signal for vertical and horizontal polarization, and,Having a frequency such that the frequency band of the third intermediate frequency signal of vertically and horizontally polarized waves is equal to or less than half the lower limit frequency of the first intermediate frequency signal of vertically and horizontally polarized waves,Further, the frequency difference between the two is determined by the frequency band of the channel in the vertically and horizontally polarized digital satellite communication signal so that the frequency band and the frequency bandwidth of the vertically and horizontally polarized third intermediate frequency signal are the same. Is selected so as to correspond to the deviation of
[0007]
The conversion means further includes second frequency conversion means for vertical and horizontal polarization for frequency-converting the third intermediate frequency signal of vertical and horizontal polarization to the second intermediate frequency signal of vertical and horizontal polarization, and And a second local oscillation means for vertical and horizontal polarization, respectively, for supplying second local oscillation signals for vertical and horizontal polarization to the second frequency conversion means. The second local oscillation signal for vertical and horizontal polarization has a higher frequency than the second intermediate frequency signal for vertical and horizontal polarization, and the frequency difference between both is the third intermediate frequency signal for vertical and horizontal polarization. And the transmission center frequency difference between the transponders are selected.
[0008]
According to the first aspect of the present invention, the vertically and horizontally polarized digital satellite communication signal is converted into a second intermediate frequency signal of vertical and horizontal polarization in a frequency band higher than that of the satellite broadcasting intermediate frequency signal by block frequency conversion. Is done. That is, the second intermediate frequency signal of the vertical and horizontal polarizations does not overlap the frequency band of the satellite broadcast intermediate frequency signal. Accordingly, the frequency band does not overlap with any of the UHF band broadcast signal, the VHF band broadcast signal, the signal for the joint viewing facility, and the satellite broadcast intermediate frequency signal. Moreover, the frequency bands of the second intermediate frequency signals of vertical and horizontal polarization do not overlap with each other. Therefore, any of the terminals in the joint receiving facility can receive the above signals. In addition, the frequency conversion of digital satellite communication signals of vertical and horizontal polarization is performed not by frequency conversion for each of the channels constituting them, but by block frequency conversion in which the entire frequency is converted at once. Therefore, the circuit configuration of the satellite communication joint receiving facility is simplified and inexpensive.
[0009]
Also,The first intermediate frequency signal of the vertical and horizontal polarization is used to convert a vertical polarization digital satellite communication signal composed of a plurality of continuous channels transmitted from a plurality of transponders for vertical polarization of a communication satellite into a frequency converter for satellite communication. This is a wideband signal that has been frequency-converted. The first horizontally-polarized intermediate frequency signal is obtained by converting a horizontally-polarized digital satellite communication signal composed of a plurality of continuous channels transmitted from a plurality of transponders for horizontal polarization of the communication satellite into the satellite communication frequency conversion signal. This is a wideband signal whose frequency has been converted by a filter. These first intermediate frequency signals of vertically and horizontally polarized waves are block-frequency-converted into third intermediate frequency signals of vertically and horizontally polarized waves by first frequency conversion means for vertically and horizontally polarized waves. The same applies to the first intermediate frequency signal of horizontal polarization.
[0010]
The frequency band and the bandwidth are completely the same between the vertically polarized third intermediate frequency signal and the horizontally polarized third intermediate frequency signal. In addition, since the frequency band is equal to or less than 1/2 of the lower limit frequency of the first intermediate frequency signal, even if the second harmonic of the third intermediate frequency signal is generated, the first intermediate frequency signal is adversely affected. Do not give.
[0011]
The third intermediate frequency signals of these vertical and horizontal polarizations are frequency-converted by the second frequency conversion means into second intermediate frequency signals of vertical and horizontal polarization. In this frequency conversion, the second local oscillation signal for vertical and horizontal polarization has a frequency difference between the vertical and horizontal polarization so that the frequencies of the second intermediate frequency signals of vertical and horizontal polarization do not overlap. The frequency band of the third intermediate frequency signal of the polarization is selected so as to be a combination of the transmission center frequency difference between the transponders. The reason why the second local oscillation signal for vertical and horizontal polarization has a higher frequency than the second intermediate frequency signal for vertical and horizontal polarization is that even if an image signal is generated, This is because there is no adverse effect.
[0012]
Claim 2According to the invention of the first aspect, in the satellite communication joint receiving facility according to the first aspect, there is provided a digital satellite communication receiving tuner for receiving and demodulating the second intermediate frequency signals of vertical and horizontal polarizations, respectively.
[0013]
Claim 2According to the invention, the tuner for digital satellite communication reception provided in each terminal has a higher frequency than the intermediate frequency signal for satellite broadcasting, and the second vertical and horizontal intermediate frequency converted to frequency bands which do not overlap each other. Each of the frequency signals can be received and demodulated. Note that this reception demodulation makes it possible to view a plurality of programs included in each channel constituting the vertical and horizontal second intermediate frequency signals on a television receiver.
[0014]
Claim 3According to the invention of the first aspect, in the satellite communication joint receiving facility according to the first aspect, the digital satellite communication receiving tuner provided in the terminal includes a specific frequency band of the first intermediate frequency signal and a specific frequency band of the second intermediate frequency signal. Is received, and it is determined whether or not a specific signal is identified from the received signal, and a reception mode corresponding to the first intermediate frequency signal or the second intermediate frequency signal is set.
[0015]
The digital satellite communication receiving tuner used in such a satellite communication common receiving facility should be constructed so that it can also be used as a digital satellite communication receiving tuner used in ordinary households, rather than manufactured exclusively for the satellite communication common receiving facility. Is desirable. That is, a mode for receiving and demodulating the first intermediate frequency signal of the vertically polarized wave and the horizontally polarized wave, and a case of using the vertically and horizontally polarized wave for use in a common receiving facility, in case of use in a general home. It is configured so that it can be used in a mode for receiving and demodulating the second intermediate frequency signal. Then, it is necessary to determine which mode to use. By the way, the digital satellite communication signal of a specific frequency band transmitted from a specific transponder includes a signal that can be freely received, for example, a non-scrambled specific signal. This specific signal is included in both the first intermediate frequency signal and the second intermediate frequency signal. Therefore, if the specific signal included in the first intermediate frequency signal can be received, it is known that the tuner is used in a general home. If the specific signal contained in the tuner can be received, it is known that the tuner is being used at the joint receiving facility, and the joint receiving facility reception mode is set.
[0016]
Claim 4According to the invention of the first aspect, in the satellite communication joint receiving facility according to the first aspect, the conversion means has a built-in power supply for the satellite communication frequency converter. This power supply is configured to be able to switch and supply voltages corresponding to the satellite communication frequency converters having different configurations.
[0017]
There are various configurations of a frequency converter for satellite communication used in a satellite communication joint receiving facility. For example, in order to receive vertically and horizontally polarized digital satellite communication signals, respectively, it is necessary to supply voltages of different magnitudes, and a voltage of the same magnitude is required to receive both. There is something that needs to be supplied. Since it is not determined which configuration is used, the invention according to claim 5 can cope with the use of any configuration of the satellite communication frequency converter. The voltage can be switched and supplied.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
As shown in FIG. 1, the digital satellite communication joint listening facility according to one embodiment of the present invention has a satellite communication receiving antenna 2. This satellite communication receiving antenna 2 is provided with a satellite communication frequency converter 4. Satellite communication signals received by the satellite communication receiving antenna 2 are transmitted from the same communication satellite. This communication satellite has a large number of transponders for transmitting vertically polarized signals and a large number of transponders for transmitting horizontally polarized signals.
[0019]
Among these many transponders, eight transponders transmitting the vertically-polarized satellite communication signal received by the satellite communication receiving antenna 2 transmit eight channels. Each channel has, for example, a center frequency of 12.508 GHz, 12.538 GHz, 12.568 GHz, 12.598 GHz, 12.628 GHz, 12.658 GHz, 12.688 GHz, and 12.718 GHz. It has a frequency bandwidth of ± 15 MHz, that is, 30 MHz.
[0020]
Similarly, the eight transponders transmitting the horizontally polarized satellite communication signal received by the satellite communication receiving antenna 2 also transmit eight channels. Each of the eight channels has a center frequency of, for example, a center frequency of 12.523 GHz, 12.553 GHz, 12.583 GHz, 12.613 GHz, 12.643 GHz, 12.673 GHz, 12.703 GHz, and 12.733 GHz. Both sides of the frequency have a frequency bandwidth of ± 15 MHz, that is, 30 MHz.
[0021]
That is, the frequency band of each vertically polarized satellite communication signal received by the satellite communication receiving antenna 2 is from 12.493 GHz to 12.733 GHZ, and the frequency band of each horizontally polarized satellite communication signal is 12. From 508 GHz to 12.748 GHz, both frequency bands are almost the same, and the horizontally polarized satellite communication signal is slightly shifted upward by 15 MHz. These satellite communication signals are digital satellite communication signals, and one satellite communication signal transmitted from one transponder includes a plurality of programs.
[0022]
A satellite communication frequency converter 4 attached to the satellite communication receiving antenna 2 converts the frequency of the vertically and horizontally polarized satellite communication signals using a local oscillation signal of 11.2 GHz. That is, as shown in FIG. 3, the vertically-polarized satellite communication signal is frequency-converted to a first intermediate frequency signal of a vertical polarization of 1293 MHz to 1533 MHz, and the horizontally-polarized satellite communication signal is converted to a horizontal signal of a 1308 MHz to 1548 MHz. The frequency is converted to a first intermediate frequency signal of polarization.
[0023]
The digital satellite communication joint receiving facility further has a satellite broadcast receiving antenna 6. The satellite broadcast receiving antenna 6 receives a satellite broadcast signal transmitted from a broadcast satellite. This satellite broadcast signal is frequency-converted by a satellite broadcast receiving frequency converter 8 attached to the satellite broadcast receiving antenna 6 to a satellite broadcast intermediate frequency signal of, for example, 1035 MHz to 1335 MHz as shown in FIG. In this embodiment, the satellite broadcast receiving antenna 6 and the satellite communication receiving antenna 2 are provided separately, but a satellite broadcasting / satellite communication shared receiving antenna may be used.
[0024]
This digital satellite communication joint receiving facility also has an antenna 10 for receiving UHF band, VHF band television broadcast signals and FM broadcast signals. Although the antenna 10 is of a common type, it is also possible to provide each antenna for individually receiving a UHF band, a VHF band television broadcast signal and an FM broadcast signal. In addition, in addition to these UHF band, VHF band television broadcast signals and FM broadcast signals, or in place of any or all of them, a joint reception signal separately created for transmission to a joint reception facility ( CATV signal) can also be used. The satellite broadcast intermediate frequency signal and each signal from the antenna 10 are mixed by the mixer 14 and supplied to the block converter 16.
[0025]
On the other hand, the vertically polarized first intermediate frequency signal and the horizontally polarized first intermediate frequency signal from the satellite communication frequency converter 4 are also supplied to the block converter 16. The block converter 16 converts the frequency of the vertically polarized first intermediate frequency signal into a vertically polarized second intermediate frequency signal from 1385 MHz to 1625 MHz as shown in FIG. 3, and converts the horizontally polarized first intermediate frequency signal. As shown in FIG. 3, the frequency is converted from a 1655 MHz to a 1895 MHz horizontally polarized second intermediate frequency signal. The second intermediate frequency signal of vertical and horizontal polarization, the satellite intermediate frequency signal, the UHF band, the VHF band television broadcast signal and the FM broadcast signal are mixed by the block converter 16.
[0026]
As is clear from FIG. 3, the second intermediate frequency signal of vertically and horizontally polarized waves is frequency-converted to a frequency higher than the upper limit frequency of the satellite broadcast intermediate frequency signal. Further, the frequency bands of the second intermediate frequency signals of vertical and horizontal polarization do not overlap, and the upper limit frequency of the second intermediate frequency signal of vertical polarization and the lower limit frequency of the second intermediate frequency signal of horizontal polarization are different from each other. There is a frequency difference between exactly equal to the frequency bandwidth of one channel transmitted by one transponder. In this embodiment, the frequency of the vertically polarized second intermediate frequency signal is lower than the frequency of the horizontally polarized second intermediate frequency signal. The frequency of the second intermediate frequency signal may be higher than the frequency of the horizontally polarized second intermediate frequency signal.
[0027]
The output signal of the block converter 16 is supplied to the transmission means 18. The transmission means 18 uses a large number of terminals 26 and a large number of branching devices and distribution amplifiers (not shown), such as a wideband amplifier 20, a four-way branching device 22, 24, and the like. 26, the output signal of the block converter 16 is transmitted. There are various configurations of the transmission means 18, and the configuration shown in FIG. 1 is merely an example.
[0028]
Each terminal 26 is provided with, for example, a duplexer 28. As a result, the signal is demultiplexed into a low-frequency signal lower than the UHF band and a higher-frequency signal higher than the satellite broadcast intermediate frequency signal. The demultiplexed signal of a low frequency lower than the UHF band is supplied to, for example, an input terminal for receiving a UHF band and a VHF band of a television receiver 30 with a built-in tuner for satellite broadcast reception and demodulated. The split signal having a higher frequency than the first intermediate frequency signal of the satellite broadcast is divided into two by a two-way divider 32, and one of the divided outputs is output from a satellite broadcast of a television receiver 30 with a built-in tuner for satellite broadcast reception. It is supplied to a receiving input terminal and demodulated. The other distributed output is supplied to a tuner 34 for digital satellite communication reception and demodulated, and the demodulated video signal and audio signal are supplied to a television receiver 30 with a tuner for satellite broadcast reception.
[0029]
Here, the tuner 34 is configured to be usable even in such a joint reception facility or in a case where reception is individually performed in each home. That is, it is configured to be switchable between an individual reception mode that can demodulate the first intermediate frequency signal of vertical and horizontal polarization and a joint reception mode that demodulates the second intermediate frequency signal of vertical and horizontal polarization. . This switching can be automatically performed.
[0030]
That is, among the vertically polarized satellite communications, for example, those having a center frequency of 12.658 GHz include a specific program that is not scrambled. The center frequency of the first intermediate frequency signal of the satellite communication signal is 1458 MHz, and the center frequency of the second intermediate frequency signal is 1550 MHz. Accordingly, the tuner 34 receives and demodulates the 1458 MHz satellite communication signal, and if the tuner 34 can detect the signal of the unscrambled program from the received signal, it sets the individual reception mode. The tuner 34 receives and demodulates a satellite communication signal of 1550 MHz, and if it can detect a signal of an unscrambled program from the signal, it sets the mode to the joint reception mode.
[0031]
In the case where the arrangement of the vertically polarized satellite communication first intermediate frequency signal and the horizontally polarized satellite communication first intermediate frequency signal can be reversed in the block converter 16, as shown in FIG. Receives and demodulates the satellite communication signal corresponding to the above in the reverse case, and if a signal of an unscrambled program can be detected from the received signal, the reception mode is set to the joint reception mode in which the signal is received in this reception arrangement.
[0032]
The block converter 16 is configured, for example, as shown in FIG. The first intermediate frequency signal of vertical polarization is supplied to the input terminal 40V. The vertically polarized first intermediate frequency signal from the input terminal 40V is supplied to the high-pass filter 42V. The high-pass filter 42V is configured to allow passage of a frequency signal having a lower limit frequency of 1293 MHz or more of the vertically polarized first intermediate frequency signal. The output of the high-pass filter 42V is supplied to the attenuator 44V. The attenuator 44V attenuates the output of the high-pass filter 42V when the switch 46V is turned on, and passes the output of the high-pass filter 42V as it is when the switch 46V is off.
[0033]
The output of the attenuator 44V is amplified by the amplifier 48V. The output of this amplifier 48V is supplied to a variable attenuator 50V. The attenuation of the variable attenuator 50V is adjusted by operating the adjuster 52V.
[0034]
The output of the variable attenuator 50V is supplied to first frequency conversion means for vertical polarization, for example, a frequency converter 54V. The frequency converter 54V includes a first local oscillator of, for example, 1870 MHz from a first local oscillator for vertical polarization, for example, a first local oscillator for vertical polarization 60V composed of a voltage variable oscillator 56V and an IC 58V for PLL. A signal is being supplied. The frequency converter 54V uses the first local oscillation signal of 1870 MHz to frequency-convert the first intermediate frequency signal of vertical polarization from 1293 MHz to 1533 MHz into a third intermediate frequency signal of vertical polarization from 337 MHz to 577 MHz. That is, the first local oscillation signal of 1870 MHz is used as the upper local oscillation signal. In this case, even if an image signal is generated, its frequency is far apart from the first and second intermediate frequency signals of vertically and horizontally polarized waves, so that these intermediate frequency signals are not affected at all.
[0035]
The third intermediate frequency signal for vertical polarization is supplied to a bandpass filter 62V having a pass band of 337 MHz to 577 MHz. The band-pass filter 62V has a characteristic in which the attenuation is steep as 30 dB or more at a frequency lower than 307 MHz and a frequency higher than 607 MHz, that is, at a pass block, but the group delay within the pass band is It is suppressed to 20 ns or less. This is because the digital communication signal uses QPSK as a modulation method, and the group delay characteristic in the transmission system greatly affects the quality of the digital communication signal. This is because the group delay characteristic is emphasized and an extreme group delay is not generated particularly at the end of the pass band.
[0036]
The third intermediate frequency signal of the vertical polarization from the band-pass filter 62V is supplied to a second frequency converter for vertical polarization, for example, a frequency converter 64V. The frequency converter 64V includes a second local oscillator of, for example, 1962 MHz from a second local oscillator for vertical polarization, for example, a second local oscillator for vertical polarization 70V including a variable voltage oscillator 66V and an IC 68V for PLL. An oscillation signal is supplied. The frequency converter 64V converts the frequency of the vertically polarized third intermediate frequency signal from 337 MHz to 577 MHz into a vertically polarized second intermediate frequency signal from 1385 MHz to 1625 MHz using the second local oscillation signal of 1962 MHz. That is, the second local oscillation signal of 1962 MHz is used as the upper local oscillation signal. In this case, even if an image signal is generated, its frequency is far apart from the first to third intermediate frequency signals of vertical and horizontal polarization, so that these intermediate frequency signals are not affected at all.
[0037]
The vertically polarized second intermediate frequency signal from the frequency converter 64V is amplified by the amplifier 72V and supplied to the mixer 74.
[0038]
The horizontally polarized first intermediate frequency signal is similarly frequency-converted to a third intermediate frequency signal, further frequency-converted to a second intermediate frequency signal, and supplied to the mixer 74. Portions having the same configuration as that for converting the frequency of the vertically polarized first intermediate frequency signal are denoted by the same reference numerals as those, and the description thereof is omitted with the letter H appended to the end.
[0039]
The high-pass filter 42H is configured to pass a signal having a lower limit frequency of 1308 MHz or more of the first intermediate frequency signal of horizontal polarization. Further, the first local oscillator 60H of horizontal polarization generates a first local oscillation signal of 1885 MHz. Further, the oscillation frequency of the third local oscillator 70H is selected to be 2232 MHz.
[0040]
Since the oscillation frequency of the first local oscillator 60V for vertical polarization is selected as 1870 MHz and the oscillation frequency of the second local oscillation 60H for horizontal polarization is selected as 1885 MHz, the third intermediate between vertical and horizontal polarization is selected. The frequency band of the frequency signal is the same frequency band from 337 MHZ to 577 MHz as shown in FIG. The third intermediate frequency signals of the vertical and horizontal polarizations are in the same frequency band, and the frequency bands of the eight channels constituting the third intermediate frequency signals of the vertical and horizontal polarizations are the same in the corresponding ones. It is. Therefore, for example, even if a strong interfering wave is present at the boundary between a certain channel and a channel adjacent thereto, the third intermediate frequency signals of the vertical and horizontal polarizations are not affected.
[0041]
Further, the frequency band of the third intermediate frequency signal of the vertical and horizontal polarizations is a relatively low frequency band of the UHF band which is half or less of the lower limit frequency of the first intermediate frequency signal of the vertical and horizontal polarizations. It is. Since the first local oscillators 60V and 60H are sufficiently shielded, the leakage of the local oscillation signal and its harmonics is very small. In the Kinki region, there are broadcasting stations having relatively high transmission power in the low frequency band of the UHF band. Therefore, even if the third intermediate frequency signal of vertical and horizontal polarization leaks, the transmission power of these transmission power is low. Large broadcasts do not cause significant interference.
[0042]
Also, since the third intermediate frequency signals of the vertical and horizontal polarizations have a frequency equal to or less than half the lower limit frequency of the first intermediate frequency signal of the vertical and horizontal polarizations, the third intermediate frequency signals of the vertical and horizontal polarizations Part of the second harmonic of the frequency signal falls in the frequency band of the satellite broadcast intermediate frequency signal. However, since the satellite broadcast intermediate frequency signal is modulated by the FM system, it is less affected by these second harmonics. Moreover, since the satellite communication signal received by the satellite communication receiving antenna 2 is a QPSK digital satellite communication signal, the second harmonic of the third intermediate frequency signal of vertical and horizontal polarization is also a QPSK signal. Yes, it is unlikely that it will adversely affect the satellite broadcast intermediate frequency signal itself.
[0043]
The upper limit frequency of the vertically polarized second intermediate frequency signal is 1625 MHz, and the lower limit frequency of the horizontally polarized second intermediate frequency signal is 1655 MHz. A corresponding guard band is formed. This is because if the upper limit frequency of the vertically polarized second intermediate frequency signal and the lower limit frequency of the horizontally polarized second intermediate frequency signal are the same frequency, if the two signals are mixed by the mixer 74, This is because they may interfere with each other.
[0044]
That is, in order to make the upper limit frequency of the second intermediate frequency signal of the vertical polarization and the lower limit frequency of the second intermediate frequency signal of the horizontal polarization the same, and to prevent interference, the band-pass filter 62V , 62H must have a very large amount of attenuation at their upper and lower cutoff frequencies. However, a bandpass filter having such characteristics cannot be realized. Therefore, a guard band is provided to prevent interference.
[0045]
Note that the width of the guard band can be smaller than 30 MHz. However, in this case, for example, spurious of the upper limit frequency of the vertically polarized second intermediate frequency signal may occur in the band of the horizontally polarized second intermediate frequency signal. To prevent this, the width of the guard band is set to 30 MHz.
[0046]
The PLL ICs 58V, 58H, 68V, 68H are controlled by the CPU 76.
[0047]
In the block converter 16, the television broadcast signal and the FM broadcast signal in the UHF band and the VHF band from the mixer 14 are supplied to an input terminal 78, and supplied to the mixer 78 via the input terminal 78. You. The mixer 78 is supplied with second vertically-polarized and horizontally-polarized intermediate frequency signals from the mixer 74. The output of the mixer 78 is supplied to an output terminal 80 and then to the transmission means 18. A one-branch unit 82 is provided between the mixer 78 and the output terminal 80, and the output of the mixer 78 is branched and supplied from the branch terminal of the one-branch unit 82 to the monitor terminal 84.
[0048]
In addition, the block converter 16 is also provided with a power supply circuit 86 that receives a commercial AC power supply and generates, for example, DC voltages of +15 V and +11 V. These DC voltages are supplied to the switch 90 via the superimposing circuit 88. This switch 90 is connected to input terminals 40V and 40H via high frequency blocking coils 92 and 94. The switch 90 is in a state where no DC voltage is supplied to the input terminals 40V and 40H, when a DC voltage of + 11V is supplied to the input terminal 40V for vertical polarization and a DC voltage of + 15V is supplied to the input terminal 40H for horizontal polarization. It is configured to be able to manually switch between a state in which a voltage is supplied and a state in which a DC voltage of +15 V is supplied to both input terminals 40V and 40H.
[0049]
This is for supplying an operating voltage to the satellite communication frequency converter 4 of the satellite communication receiving antenna 2 via a coaxial cable (not shown). The satellite communication frequency converter 4 also has various configurations. For example, there is a configuration using an OMT (Orthogonal Polarization Separation Demultiplexer) for separating vertical polarization and horizontal polarization. In this case, it is only necessary to supply the operating voltage of +15 V to the frequency converter 4 for satellite communication. There is also a configuration in which a voltage of +11 V is used to operate a probe for receiving vertical polarization and a voltage of +15 V is used for operating a probe for receiving horizontal polarization. Such a satellite communication frequency converter 4 needs to be supplied with both voltages of + 11V and + 15V. Regardless of the configuration of the frequency converter 4 for satellite communication, the switch 90 is used to supply the first intermediate frequency signals of the vertical polarization and the horizontal polarization to the input terminals 40V and 40H. Is provided.
[0050]
The operating voltage to the satellite broadcast receiving frequency converter 8 is such that a DC voltage externally supplied to the output terminal 80 is supplied via the one-branch unit 82, the mixer 78, the input terminal 76, and the mixer 14. You. Therefore, these are of the electric conduction type.
[0051]
In the block converter 16, both the vertical and horizontal polarized first intermediate frequency signals are frequency-converted to a third intermediate frequency signal and then to a second intermediate frequency signal. That is, frequency conversion is performed twice. This is because, as is clear from FIG. 3, the frequency band of the vertically polarized second intermediate frequency signal partially overlaps the frequency band of vertically and horizontally polarized first intermediate frequency signals. This is because, when the frequency conversion is performed on such a frequency band in the conversion, the quality of the second intermediate frequency signal deteriorates. Therefore, frequency conversion is once performed on a low frequency band of the UHF band having a frequency considerably different from that of the first intermediate frequency signal so that such quality deterioration does not occur, and then frequency conversion is performed on the second intermediate frequency signal. ing.
[0052]
【The invention's effect】
As described above, according to the first aspect of the present invention, the first vertically polarized wave corresponding to the vertically polarized digital satellite communication signal composed of a plurality of continuous channels transmitted from the plurality of vertically polarized transponders. The intermediate frequency signal is converted to a vertically polarized second intermediate frequency signal at a block frequency by the converting means. The same applies to the first intermediate frequency signal of horizontal polarization. Therefore, it is not necessary to perform frequency conversion for each channel, so that the circuit configuration of the satellite communication joint receiving facility can be simplified and the cost can be reduced. In addition, the second intermediate frequency signals of the vertical and horizontal polarizations are frequency-converted to a higher frequency band than the satellite broadcast intermediate frequency signal so as not to overlap each other. Therefore, the frequency does not overlap with any of the FM broadcast signal, the UHF band broadcast signal, the VHF band broadcast signal, the joint viewing signal, and the satellite broadcasting intermediate frequency signal, so that each terminal of the joint viewing reception facility receives any signal. It is possible. In particular, in the case where an existing building joint reception facility can receive digital satellite communication signals, there is no need to change the existing equipment at all, and digital satellite communication signals can be received at low cost.
[0053]
further,The frequency bands and bandwidths of the vertically and horizontally polarized third intermediate frequency signals obtained by frequency-converting the vertically and horizontally polarized first intermediate frequency signals by the first frequency conversion means are exactly the same. Therefore, the frequency bands of the respective channels constituting the third intermediate frequency signals of these vertical and horizontal polarizations are also the same, and even if there is an interfering wave at a frequency corresponding to the boundary of each channel, the influence is not affected. Absent. Moreover, the frequency band of the third intermediate frequency signal of the vertical and horizontal polarizations is less than half the lower limit frequency of the first intermediate frequency signal of the vertical polarization and the horizontal polarization. The generation of the second harmonic does not adversely affect the first intermediate frequency signal.
[0054]
The third intermediate frequency signals of these vertical and horizontal polarizations are frequency-converted by the second frequency conversion means into second intermediate frequency signals of vertical and horizontal polarization. In this frequency conversion, the second local oscillation signal for vertical and horizontal polarization has a frequency difference between the vertical and horizontal polarization so that the frequencies of the second intermediate frequency signals of vertical and horizontal polarization do not overlap. The frequency band of the polarized third intermediate frequency signal and the center frequency difference between the transponders are selected so as to be combined. Therefore, when mixing the vertically and horizontally polarized second intermediate frequency signals, they do not adversely affect each other. Also, since the second local oscillation signal for vertical and horizontal polarization has a higher frequency than the second intermediate frequency signal for vertical and horizontal polarization, even if an image signal is generated, each intermediate frequency signal It does not adversely affect.
[0055]
Claim 2In the invention of the first aspect, the first intermediate frequency signal of the vertical and horizontal polarizations is converted into a second intermediate frequency signal of the vertical and horizontal polarizations having a frequency higher than that of the satellite broadcast intermediate frequency signal and not overlapping with each other. Since the digital satellite communication receiving tuner capable of receiving the converted second intermediate frequency signal of vertical and horizontal polarization is provided, each terminal can watch each program of the digital satellite communication signal.
[0056]
The tuner for digital satellite communication reception used in the joint receiving facility may be used in a mode for receiving and demodulating the first intermediate frequency signal of vertically polarized wave and horizontally polarized wave in case of individual reception in a general home. Preferably, it is desirable to use the second intermediate frequency signal of the vertical and horizontal polarization in a mode of receiving and demodulating the second intermediate frequency signal for use in a joint receiving facility. In a digital satellite communication reception tuner that can be used in either mode, it is necessary to determine which mode to use. Meanwhile, a digital satellite communication signal in a specific frequency band transmitted from a specific transponder includes, for example, a specific signal that has not been scrambled. This specific signal is included in both the first intermediate frequency signal and the second intermediate frequency signal. Therefore,Claim 3According to the invention, if the tuner can receive the specific signal included in the first intermediate frequency signal, it can be understood that the tuner is used in a general household, so that the reception mode is set to the general home and the second mode is set. If the specific signal included in the intermediate frequency signal can be received, it is known that the tuner is used in the joint receiving facility, and the joint receiving facility reception mode is automatically set. Therefore, in this tuner, it is not necessary to set the reception mode each time, and the setting operation becomes easy.
[0057]
There are various configurations of a frequency converter for satellite communication used in a satellite communication joint receiving facility. For example, in order to receive vertically and horizontally polarized digital satellite communication signals, respectively, it is necessary to supply voltages of different magnitudes, and a voltage of the same magnitude is required to receive both. There is something that needs to be supplied. It is uncertain which configuration will be used.Claim 4According to the invention, since the voltage can be switched and supplied to the frequency converter for satellite communication, the use of the frequency converter for satellite communication of any configuration can be supported.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of one embodiment of a satellite communication joint receiving facility according to one embodiment of the present invention.
FIG. 2 is a block diagram of a block converter used in the satellite communication joint receiving facility.
FIG. 3 is a diagram showing a relationship between a satellite broadcast intermediate frequency signal and satellite communication first to third intermediate frequency signals in the satellite communication joint receiving facility.
[Explanation of symbols]
2 Satellite communication receiving antenna
4 Frequency converter for satellite communication
6. Satellite broadcast receiving antenna
8 Frequency converter for satellite broadcasting
10 UHF band and VHF band television broadcast and FM broadcast receiving antennas
16 Block Converter
18 Transmission means
26 terminals
34 Digital satellite communication reception tuner
54V 54H first frequency converter
60V 60H first local oscillator
64V 64H second frequency converter
70V 70H Second local oscillator
78 mixer
82 Power supply circuit
86 switch

Claims (4)

Mixing means for receiving at least one of a UHF band broadcast signal, a VHF band broadcast signal, a signal for a joint reception facility, and a satellite broadcast intermediate frequency signal;
A vertically and horizontally polarized digital satellite communication signal composed of a plurality of channels each having a same frequency bandwidth and a partially shifted frequency band transmitted from the same communication satellite while maintaining their frequency relations The entirety of the vertically and horizontally polarized first intermediate frequency signals, each of which has been frequency-converted, is converted to a second intermediate frequency of vertically and horizontally polarized waves having a frequency band higher than that of the satellite broadcast intermediate frequency signal and mutually non-overlapping frequency bands. Converting means for performing block frequency conversion for performing frequency conversion on the signal at once, and supplying these second intermediate frequency signals of vertical and horizontal polarization to the mixing means;
Transmitting means for transmitting the output signal of the mixing means to a plurality of terminals,
Equipped,
The first vertically-polarized intermediate frequency signal is obtained by converting a vertically-polarized digital satellite communication signal including a plurality of continuous channels transmitted from a plurality of vertically-polarized transponders of the communication satellite into a satellite communication frequency converter. Is a wideband signal frequency-converted by
The first intermediate frequency signal of the horizontal polarization is obtained by converting a horizontal polarization digital satellite communication signal composed of a plurality of continuous channels transmitted from a plurality of transponders for horizontal polarization of the communication satellite into the frequency conversion signal for the satellite communication. Is a wideband signal frequency-converted by the
The conversion means comprises: first frequency conversion means for vertical and horizontal polarization for frequency-converting a first intermediate frequency signal of vertical and horizontal polarization to a third intermediate frequency signal of vertical and horizontal polarization; A first local oscillation means for vertical and horizontal polarization, respectively supplying a first local oscillation signal for vertical and horizontal polarization to the conversion means,
The vertical and the first local oscillation signal for the horizontal polarization, vertical and higher frequency than the first intermediate frequency signal of the horizontally polarized wave, and the frequency band of the vertical and the third intermediate frequency signal of the horizontally polarized wave vertical And a frequency that is set to a frequency band equal to or less than 下限 of the lower limit frequency of the first intermediate frequency signal of horizontal polarization , and further, the frequency difference between the two is the third intermediate frequency signal of vertical and horizontal polarization. Are selected so as to correspond to the shift of the frequency band of the channel in the vertically and horizontally polarized digital satellite communication signal, so that the frequency band and the frequency bandwidth are the same,
The conversion means further includes second frequency conversion means for vertical and horizontal polarization for frequency-converting the third intermediate frequency signal of vertical and horizontal polarization to the second intermediate frequency signal of vertical and horizontal polarization, and A second local oscillation means for vertical and horizontal polarization, respectively, for supplying second local oscillation signals for vertical and horizontal polarization to the second frequency conversion means, respectively.
The second local oscillation signal for vertical and horizontal polarization has a higher frequency than the second intermediate frequency signal for vertical and horizontal polarization, and the frequency difference between both is the third intermediate frequency signal for vertical and horizontal polarization. A satellite communication joint receiving facility that is selected so as to combine the frequency bandwidth of the transponder with the transmission center frequency difference between the transponders. 2. The satellite communication joint receiving facility according to claim 1, further comprising a digital satellite communication receiving tuner for receiving and demodulating the second intermediate frequency signals of vertical and horizontal polarization, respectively. 2. The satellite communication reception facility according to claim 1, wherein the digital satellite communication reception tuner provided in the terminal receives a specific frequency band of the first intermediate frequency signal and a specific frequency band of the second intermediate frequency signal. A satellite communication joint receiving facility which determines whether a specific signal is identified from the signal and sets a reception mode corresponding to the first intermediate frequency signal or the second intermediate frequency signal. 2. A satellite communication joint receiving facility according to claim 1, wherein said conversion means has a built-in power supply for said satellite communication frequency converter, and said power supply has a voltage corresponding to each of said differently configured satellite communication frequency converters. A satellite communication joint receiving facility configured to be able to switch and supply.

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