JP7680261B2 - Frequency conversion transmission system - Google Patents

Description

The present invention relates to a frequency conversion transmission system that enables the transmission of advanced wideband satellite digital broadcasts using existing receiving equipment.

The history of satellite broadcasting in Japan began with BS analog broadcasting, followed by BS digital broadcasting and 110° CS broadcasting. The frequency bands transmitting the corresponding BS/CS intermediate frequency signals (BS/CS-IF signals) were also successively updated, with the maximum transmission frequency expanded from 1335 MHz to 1550 MHz to 2150 MHz to 2602 MHz.
Furthermore, the regular broadcasting of advanced wideband digital satellite broadcasting (ISDB-S3, 4K8K broadcasting, BS/CS left-handed circular polarization broadcasting) began on December 1, 2018. Advanced wideband digital satellite broadcasting further adds BS/CS left-handed circular polarization IF signals in the frequency band of 2224 MHz to 3224 MHz. For this reason, in order to transmit BS/CS left-handed circular polarization IF signals of advanced wideband digital satellite broadcasting in a TV signal receiving equipment within a building such as a shared receiving equipment, all of the receiving equipment such as coaxial cables, amplifiers, splitters/distributors, receiver terminals, and serial units must be modified to equipment capable of transmitting the frequency band of 2224 MHz to 3224 MHz.

However, the maximum transmission frequencies of existing receiving equipment vary depending on when it was constructed, and upgrading all receiving equipment to equipment with a maximum transmission frequency of 3,224 MHz in order to receive advanced wideband satellite digital broadcasting would require significant renovation costs, and depending on the equipment, the change may be impossible or difficult.
Therefore, a frequency conversion transmission system has been proposed that can transmit broadcast channels (frequency bands) in BS/CS left-hand circular polarization IF signals even if the existing frequency bands that can be transmitted are up to 2150 MHz or 2602 MHz (see Patent Document 1).

FIG. 11 is a functional block diagram showing the configuration of a frequency conversion transmission system 100 capable of transmitting broadcast channels of BS/CS left-handed circular polarization IF signals that have been proposed in the past, and FIGS. 12(a), (b), and (c) show the transmission frequency arrangement for the frequency conversion transmission system 100 shown in FIG. 11.
As shown in these figures, the frequency conversion transmission system 100 includes a BS/CS antenna 111 and a UHF antenna 112. The received signals output from the BS/CS antenna 111 are a BS right-handed IF signal and a 110° CS right-handed IF signal, and a BS left-handed IF signal and a 110° CS left-handed IF signal, and their frequency bands are shown in Fig. 12(a). The received signals output from the UHF antenna 112 are UHF terrestrial digital signals, and their frequency bands are shown in Fig. 12(a). The received signals output from the BS/CS antenna 111 and the UHF antenna 112 are input to an input terminal (IN) a of the frequency conversion device 110. In the frequency converter 110, the signal received by the BS/CS antenna 111 is input to a splitter (DIM) a and split into a BS right-handed IF signal and a 110° CS right-handed IF signal, and a BS left-handed IF signal and a 110° CS left-handed IF signal. The split BS right-handed IF signal and the 110° CS right-handed IF signal are adjusted to a predetermined level by an amplifier (AMP) a and an attenuator (ATT) a. The split BS left-handed IF signal and the 110° CS left-handed IF signal are amplified to a predetermined level by an AMP b, and are split by a splitter (DIV) a.

The BS left-handed IF signal and the 110° CS left-handed IF signal distributed by the distributor (DIV) a are input to the bandpass filters (BPF) a1 to BPFm1, respectively, and the frequency band of the specified BS left-handed channel or CS left-handed channel is extracted for each channel. The extracted reception signal of the specified BS channel or CS channel is frequency-converted by the converters (CONV) a1 to CONVm1, respectively. CONVa1 to CONVm1 down-convert the frequency band of the BS left-handed channel or CS left-handed channel to the CATV band, which is a frequency band that can be transmitted by the shared receiving equipment line. For example, as shown in Figures 12(a) and (b), three BS left-handed channels and five CS left-handed channels in the frequency band of 2224.41 MHz to 3223.25 MHz are down-converted to the CATV band for each channel. In this case, since the CATV frequency band of 470 MHz to 770 MHz is used to transmit UHF terrestrial digital signals, the frequency band that can be used for down-conversion is the 90 MHz to 470 MHz frequency band.

The received signals of each of the BS left-handed circular polarization channel and CS left-handed circular polarization channel, which have been down-converted by CONVa1 to CONVm1, have unnecessary wave components removed by BPFa2 to BPFm2 to extract the frequency band for each channel, and the level is adjusted to a specified level by ATTa1 to ATTm1, and the received signals of all channels are mixed in mixer (MIX) a.
Also, the UHF terrestrial digital signal output from the UHF antenna 112 is input to INb of the frequency converter 110 and adjusted to a predetermined level by AMPc and ATTb. The down-converted BS left-handed channel and CS left-handed channel reception signals and the UHF terrestrial digital signal from ATTb are mixed in MIXc, and the reception signal mixed in MIXc and the BS right-handed IF signal and 110° CS right-handed IF signal from ATTa are mixed in MIXb and output from the frequency converter 110 via the output terminal OUTa. The transmission frequency arrangement of the reception signal output from the output terminal OUTa is as shown in FIG. 12(b). This received signal is transmitted to the shared receiving equipment line, amplified by booster (AMP) d, and then distributed to multiple parts by DIVb. Each distributed received signal is then distributed in turn by cascade-connected DIVa1 and DIVb1, and one of the distributed outputs of DIVb1 is brought into the apartment building 120.

A DIVc1 is provided in each house of the apartment building 120, and a signal distributed by the DIVc1 can be supplied to each room. A wall terminal Ta, a terminal device 122, and a television (TV) 123 are provided in each room, and a received signal brought into the house is distributed by the DIVc1, and one of the distributed signals is supplied to the wall terminal Ta. The wall terminal Ta and the INc of the terminal device 122 are connected by a cable, and a received signal having the transmission frequency arrangement shown in FIG. 12(b) is input to the INc.
In the terminal 122, the received signal having the transmission frequency arrangement shown in Fig. 12(b) input from INc is input to DIMb, and is demultiplexed into a BS right-handed IF signal and a 110° CS right-handed IF signal, a BS left-handed IF signal and a 110° CS left-handed IF signal, and a UHF digital terrestrial signal. The demultiplexed BS right-handed IF signal and a 110° CS right-handed IF signal are amplified to a predetermined level by AMPf. The demultiplexed BS left-handed IF signal and a 110° CS left-handed IF signal, and a UHF digital terrestrial signal are input to DIMc, and are demultiplexed into a BS left-handed IF signal and a 110° CS left-handed IF signal, and a UHF digital terrestrial signal. The demultiplexed BS left-handed IF signal and a 110° CS left-handed IF signal are amplified to a predetermined level by AMPg, and are distributed m by DIVc.

The BS left-handed IF signal and the 110° CS left-handed IF signal distributed by DIVc are input to BPFa3 to BPFm3, respectively, and the down-converted frequency bands of the left-handed and CS left-handed channels are extracted for each channel. The extracted BS and CS channel reception signals are frequency-converted for each channel by CONVa2 to CONVm2. CONVa2 to CONVm2 up-convert the BS left-handed and CS left-handed channels to return to their original frequency bands for each channel. For example, as shown in Figures 12(b) and (c), the frequency bands of the three BS left-handed channels and five CS left-handed channels transmitted in the CATV band up to 470 MHz are up-converted to return to the original frequency bands of 2224.41 MHz to 3223.25 MHz for each channel.

The reception signals of the BS left-handed circular polarization channel and the CS left-handed circular polarization channel up-converted by CONVa2 to CONVm2 are subjected to removal of unnecessary wave components by BPFa4 to BPFm4 to extract the frequency band for each channel, and the reception signals of all channels are mixed by MIXd. The reception signals of the BS left-handed circular polarization channel and the CS left-handed circular polarization channel up-converted and mixed by MIXd, and the BS right-handed circular polarization IF signal and the 110° CS right-handed circular polarization IF signal from AMPf are mixed by MIXe and output from OUTb of the terminal device 122. In addition, the UHF terrestrial digital signal separated by DIMc is amplified to a predetermined level by AMPh and output from OUTc of the terminal device 122. By connecting OUTb and OUTc of the terminal device 122 to the input terminal of the TV 123 with a cable, it is possible to receive UHF terrestrial digital signals, BS right-handed IF signals, 110° CS right-handed IF signals, BS left-handed IF signals, and 110° CS left-handed IF signals on the TV 123. In other words, it is possible to watch terrestrial digital broadcasting channels, BS right-handed and BS left-handed BS broadcasting channels, and 110° CS right-handed and 110° CS left-handed CS broadcasting channels on the TV 123.
In this way, the frequency conversion transmission system 100 is capable of transmitting broadcast channels (frequency bands) in BS/CS left-handed circular polarization IF signals even if the existing transmittable frequency band is up to 2150 MHz or 2602 MHz.

JP 2021-40291 A

In the conventional frequency conversion transmission system, even if the existing frequency band that can be transmitted is up to 2150 MHz or 2602 MHz, the broadcast channel (frequency band) of the BS/CS left-handed IF signal can be transmitted, but the terminal installed in front of the TV upconverts each channel, so the configuration of the upconverting converter becomes complicated. Normally, since the BPF extracts the frequency band for each channel, a BPF with a steep cutoff characteristic, such as a SAW (Surface Acoustic Wave) filter, is required for the number of channels to be upconverted, which causes the terminal to become expensive. As another method, the input signal may be converted into a digital signal collectively, and then the LSI (Large Scale Integration) that performs digital processing such as frequency conversion for each channel may be used for upconversion. However, the LSI must be equipped with not only a frequency conversion function but also functions such as a steep digital filter and an AD/DA converter, which makes the parts expensive, resulting in a problem of high terminal prices.
Furthermore, in the conventional frequency conversion transmission systems, only one frequency conversion device is required for an apartment building, and the cost per household is not that high. However, a terminal unit is required for each household that wishes to view the BS/CS left-handed circular polarization IF signal broadcast channels, which results in a large cost burden.

The present invention aims to provide an inexpensive frequency conversion transmission system that can transmit broadcast channels in BS/CS left-handed circular polarization IF signals, even if the existing frequency bands that can be transmitted are up to 2150 MHz or 2602 MHz.

The frequency conversion transmission system of the present invention is a frequency conversion transmission system in which a transmission unit and a reception unit are connected by a transmission path, and the transmission unit includes a first downconverter that downconverts a first frequency band of a UHF terrestrial digital signal of terrestrial digital broadcasting broadcast in the UHF band to a second frequency band that can be transmitted by the transmission path and is available lower than the frequency band of the UHF terrestrial digital signal, a second downconverter that downconverts a third frequency band of a first IF reception signal, which is a BS left-hand rotation or CS left-hand rotation intermediate frequency signal, to a fourth frequency band including the first frequency band downconverted by the first downconverter and available, and a third frequency band including the first frequency band downconverted by the first downconverter to a fourth frequency band including the first frequency band downconverted by the first downconverter to a fourth frequency band. The device is equipped with a mixing means for transmitting a mixed reception signal obtained by mixing a UHF terrestrial digital signal, a first IF reception signal of the fourth frequency band downconverted by the second downconverter, and a second IF reception signal which is an intermediate frequency signal of BS right-hand rotation and CS right-hand rotation, to the transmission path, and the receiving unit is equipped with an upconverter for returning the first IF reception signal of the fourth frequency band transmitted on the transmission path to the original first IF reception signal of the third frequency band, and the most important feature is that the UHF terrestrial digital signal of the second frequency band transmitted on the transmission path, the first IF reception signal of the third frequency band upconverted by the upconverter, and the second IF reception signal transmitted on the transmission path are output from the receiving unit.

In the frequency conversion transmission system of the present invention, one transmitting unit is installed in an apartment building, and the mixed receiving signal transmitted from the transmitting unit to the transmission path is drawn into each home in the apartment building, and a terminal device serving as the receiving unit installed in each home receives the mixed receiving signal.
Furthermore, in the frequency conversion transmission system of the present invention, the second downconverter has a first local oscillator and a second local oscillator which have different local oscillation frequencies, and by switching to the first local oscillator, the third frequency band of BS left-hand circular polarization is selected and downconverted to the fourth frequency band, and by switching to the second local oscillator, the third frequency band of CS left-hand circular polarization is selected and downconverted to the fourth frequency band.
Furthermore, in the frequency conversion transmission system of the present invention, the first downconverter has a plurality of first frequency conversion blocks, the first frequency band of the UHF terrestrial digital signal is divided into a plurality of frequency bands, and the second frequency band is divided into a plurality of frequency bands, and each divided frequency band of the first frequency band is downconverted to each divided frequency band of the second frequency band by the plurality of first frequency conversion blocks, and a guard band is provided between each divided frequency band of the second frequency band.
Furthermore, in the frequency conversion transmission system of the present invention, the booster provided in the transmission line has amplification means for amplifying a plurality of split reception signals obtained by splitting the mixed reception signal into signals in different frequency bands.
Furthermore, in the frequency conversion transmission system of the present invention, the output from the receiving unit is received by a digital broadcast receiving device, and the digital broadcast receiving device is capable of receiving UHF terrestrial digital signals in the second frequency band due to a pass-through function.

In the frequency conversion transmission system of the present invention, the transmission section down-converts the frequency band of the UHF terrestrial digital signal of the terrestrial digital broadcasting broadcast in the UHF band to an available frequency band that can be transmitted on the transmission path, down-converts the frequency band of the BS left-handed or CS left-handed IF reception signal to a frequency band including the available UHF band, and transmits the down-converted UHF terrestrial digital signal together. In the reception section, the down-converted IF reception signal is up-converted back to the frequency band of the IF reception signal in the original frequency band, and is output together with the transmitted UHF terrestrial digital signal. In this case, the UHF terrestrial digital signal is down-converted and transmitted, but the digital broadcast receiving device that receives the output of the reception section is capable of receiving the down-converted UHF terrestrial digital signal by the pass-through function.
As a result, in the frequency conversion transmission system of the present invention, since the frequency band of the UHF terrestrial digital signal and the frequency band of the BS left-handed or CS left-handed IF reception signal are down-converted, it is possible to down-convert multiple channels in the frequency band at once. Also, since the frequency band of the BS left-handed or CS left-handed IF reception signal is up-converted, it is possible to up-convert multiple channels in the frequency band at once. As a result, the configuration of the frequency conversion transmission system of the present invention is simplified and can be provided at low cost. Note that, in the frequency conversion transmission system of the present invention, even if the frequency band that can be transmitted by the existing transmission line is up to 2150 MHz or 2602 MHz, it is possible to transmit the BS left-handed or CS left-handed broadcasting channel.

1 is a functional block diagram showing a configuration of a frequency conversion transmission system according to an embodiment of the present invention; FIG. 13 is a diagram showing a configuration of a modified example of a U/V conversion unit in the frequency conversion transmission system according to an embodiment of the present invention. 11A and 11B are diagrams showing configurations of a modified example of CONV1 (CONV3) and another modified example in the frequency conversion transmission system according to the embodiment of the present invention. FIG. 11 is a diagram showing a configuration of a modified example of the BPF 1 in the frequency conversion transmission system according to the embodiment of the present invention. FIG. 2 is a diagram showing a transmission frequency arrangement in a frequency conversion transmission system according to an embodiment of the present invention. FIG. 11 is a diagram showing another transmission frequency arrangement in the frequency conversion transmission system according to the embodiment of the present invention. FIG. 11 is a diagram showing a configuration of a modified example of AMP4 (AMP5) in a frequency conversion transmission system according to an embodiment of the present invention. FIG. 11 is a diagram showing the configuration of another modified example of AMP4 (AMP5) in the frequency conversion transmission system according to the embodiment of the present invention. FIG. 2 is a diagram showing a transmission frequency arrangement in the UHF band in a frequency conversion transmission system according to an embodiment of the present invention. 1A and 1B are functional block diagrams showing the configuration of a frequency conversion transmission system according to an application example of the present invention, and diagrams showing an outline of a frequency arrangement. FIG. 1 is a functional block diagram showing a configuration of a conventional frequency conversion transmission system. FIG. 1 is a diagram showing a transmission frequency arrangement of a conventional frequency conversion transmission system.

In the frequency conversion transmission system of the present invention, the frequency band of the UHF terrestrial digital signal of the terrestrial digital broadcasting broadcast in the UHF band is down-converted to an available frequency band that can be transmitted on the transmission line and transmitted. The upper limit frequency of the frequency band that can be transmitted on the transmission line is set to 2150 MHz or 2602 MHz. Then, the frequency band of the BS left-handed or CS left-handed IF reception signal is down-converted to a frequency band including the down-converted and available UHF band and transmitted. In the receiving section, the frequency band of the IF reception signal transmitted on the transmission line is up-converted to return it to the original frequency band. The returned IF reception signal and the transmitted UHF terrestrial digital signal are input to a digital broadcast receiving device. Although the UHF terrestrial digital signal is down-converted, it is possible to receive the down-converted UHF terrestrial digital signal by the pass-through (registered trademark) function of the digital broadcast receiving device. As a result, the frequency conversion transmission system of the present invention can transmit BS left-handed or CS left-handed broadcasting channels even if the existing frequency band that can be transmitted is up to 2150 MHz or 2602 MHz. Furthermore, since multiple channels in a frequency band can be down-converted (up-converted) all at once, the configuration of the frequency conversion transmission system of the present invention is simplified, thereby achieving the object of the present invention of providing the frequency conversion transmission system of the present invention at low cost.
Pass-through (registered trademark) is a method of transmitting terrestrial digital broadcasting or satellite broadcasting without changing the modulation method, and includes a same-frequency pass-through method in which broadcasting is transmitted in the same frequency band when transmitting, and a frequency conversion pass-through method in which broadcasting is transmitted by changing the frequency band when transmitting. Naturally, digital broadcasting receivers can receive broadcasting transmitted in the same frequency band, but many digital broadcasting receivers support the frequency conversion pass-through method and can receive broadcasting that has been changed to a specified frequency band and transmitted. The present invention is premised on the fact that the digital broadcasting receiver supports the frequency conversion pass-through method.

The frequency conversion transmission system 1 of an embodiment of the present invention can transmit broadcast channels in BS/CS left-hand circular polarization IF signals even if the upper limit frequency of the frequency band that can be transmitted on the transmission path is up to 2150 MHz or 2602 MHz. FIG. 1 shows a functional block diagram showing the configuration of the frequency conversion transmission system 1 of an embodiment of the present invention, and FIGS. 5(a), (b), and (c) show the transmission frequency arrangement for the frequency conversion transmission system 1 shown in FIG. 1.
As shown in these figures, the frequency conversion transmission system 1 of the embodiment of the present invention is composed of a BS/CS antenna 11 and a UHF antenna 12, a frequency conversion device 10 as a transmitter, a common receiving facility line 30 as a transmission path, and a terminal device 22 as a receiver. The upper limit of the frequency band that can be transmitted in the common receiving facility line 30 is 2150 MHz or 2602 MHz, and the terminal device 22 is installed in each house of the apartment building 20. The received signals output from the BS/CS antenna 11 are a BS right-handed IF signal and a 110° CS right-handed IF signal, and a BS left-handed IF signal and a 110° CS left-handed IF signal, and the frequency bands are shown in Figure 5 (a) as BS right-handed, 110° CS right-handed, BS left-handed, and 110° CS left-handed. Figure 5 (a) shows the frequency arrangement of the received signals input to the frequency conversion device 10. In the frequency arrangement shown in Fig. 5(a), the frequency band of 90 MHz to 108 MHz is defined as the VHF-Lo band, the frequency band of 108 MHz to 170 MHz is defined as the MID band, the frequency band of 170 MHz to 222 MHz is defined as the VHF-Hi band, and the frequency band of 222 MHz to 470 MHz is defined as the super high band, all of which are frequency bands that can be transmitted through the common receiving equipment line 30. In addition, the received signal output from the UHF antenna 12 is a UHF terrestrial digital signal, and its frequency band is shown as UHF terrestrial digital in Fig. 5(a). The frequency band of the UHF terrestrial digital signal (UHF band) is defined as the frequency band of 470 MHz to 770 MHz, and is defined as the frequency band that can be transmitted through the common receiving equipment line 30. The received signal output from the BS/CS antenna 11 is input to an input terminal (IN) 1 of the frequency conversion device 10, and the received signal output from the UHF antenna 12 is input to an input terminal (IN) 2 of the frequency conversion device 10.

In the frequency converter 10, a signal received by a BS/CS antenna 11 input to IN1 is input to a splitter (DIM) 1 and split into a BS right-handed IF signal and a 110° CS right-handed IF signal, and a BS left-handed IF signal and a 110° CS left-handed IF signal. The split BS right-handed IF signal and the 110° CS right-handed IF signal are adjusted to a predetermined level by an amplifier (AMP) 1 and an attenuator (ATT) 1, and then input to a mixer (MIX) 1.
The demultiplexed BS left-handed IF signal in the frequency band of 2224.1 MHz to 2680.87 MHz and 110° CS left-handed IF signal in the frequency band of 2708.75 MHz to 3223.25 MHz are amplified to a predetermined level by AMP2, and unnecessary wave components are removed by band pass filter (BPF) 1. In this case, the pass band of BPF1 is selected to be either the frequency band of 2224.1 MHz to 2680.87 MHz or the frequency band of 2708.75 MHz to 3223.25 MHz. In other words, the selected BS left-handed IF signal or 110° CS left-handed IF signal passes through BPF1.

The frequency band of the BS left-handed IF signal or 110° CS left-handed IF signal selected by BPF1 is down-converted by converter (CONV) 1. In this case, the local oscillator (Lo) in CONV1 has a local oscillation frequency (Lo frequency) corresponding to the frequency band of the BS left-handed IF signal or 110° CS left-handed IF signal selected by BPF1, and when the BS left-handed IF signal is selected, the Lo frequency is 1911 MHz, and when the 110° CS left-handed IF signal is selected, the Lo frequency is 2454 MHz. As a result, when the BS left-handed IF signal is selected, the frequency band of the BS left-handed IF signal is down-converted to a frequency band of 313.41 MHz to 769.87 MHz, and when the 110° CS left-handed IF signal is selected, the frequency band of the 110° CS left-handed IF signal is down-converted to a frequency band of 254.75 MHz to 769.25 MHz. In this way, CONV1 down-converts multiple channels in the frequency band of the selected IF signal all at once. Also, CONV1 down-converts the BS left-handed IF signal or the 110° CS left-handed IF signal in a frequency band that exceeds the frequency band that can be transmitted by the selected common receiving equipment line 30 to a wideband frequency band of the super high band and UHF band, which are vacant frequency bands that can be transmitted by the common receiving equipment line 30. Figure 5 (b) shows the case where the 110° CS left-handed IF signal is selected.

The BS left-handed IF signal or the 110° CS left-handed IF signal down-converted by the CONV 1 is adjusted in level by the ATT 2 to a predetermined level and then input to a mixer (MIX) 2 .
Also, the UHF terrestrial digital signal output from the UHF antenna 12 input to IN2 is level-adjusted by AMP3 to a predetermined level and input to the U/V conversion unit 13. In the U/V conversion unit 13, the UHF terrestrial digital signal has unnecessary wave components removed by BPF2, which has a passband of 470 MHz to 770 MHz, and is input to CONV2. In CONV2, the frequency band of the UHF terrestrial digital signal is down-converted to the VHF band of VHF-Lo band or VFH-Hi band. Currently, there is no VHF broadcasting, so the VHF band is vacant. In CONV2, multiple channels in the frequency band of the UHF terrestrial digital signal are down-converted collectively. The UHF terrestrial digital signal down-converted to the VHF band by CONV2 is level-adjusted by ATT3 to a predetermined level and input to MIX2. In MIX2, the down-converted BS left-handed IF signal or 110° CS left-handed IF signal is mixed with the down-converted UHF terrestrial digital signal and input to MIX1. In MIX1, the BS right-handed IF signal and 110° CS right-handed IF signal from ATT1 are mixed with the mixed received signal from MIX2 and output from output terminal (OUT)1.

The frequency arrangement of the received signal output from OUT1 of the frequency conversion device 10, which is the transmitting section, is as shown in FIG. 5(b). This received signal is transmitted through the common receiving equipment line 30. In this case, the frequency band of the BS left-handed IF signal or the 110° CS left-handed IF signal is a wide band, but since it can be down-converted using a frequency band including the UHF band, it becomes possible to transmit the BS left-handed IF signal or the 110° CS left-handed IF signal. The received signal transmitted through the common receiving equipment line 30 is amplified by the booster (AMP) 4 and then distributed to multiple signals by the distributor (DIV) 2, and one of the distributed received signals is amplified by the booster (AMP) 5 and then distributed in sequence by the cascaded DIV3 and DIV4, and one of the distributed outputs of DIV4 is drawn into the house of the apartment house 20.
A DIV5 is provided in each house of the apartment building 20, and a signal distributed by the DIV5 can be supplied to each room. A wall terminal 21, a terminal unit 22, and a television (TV) 23 are provided in each room, and a received signal brought into the house is further distributed by the DIV5, and one of the distributed signals is supplied to the wall terminal 21. The wall terminal 21 and IN3 of the terminal unit 22 are then connected by a cable, and a received signal having the transmission frequency arrangement shown in Fig. 5(b) is input to IN3.

In the terminal device 22, the received signal having the transmission frequency arrangement shown in FIG. 5(b) input from IN3 is input to DIM6 and separated into a BS right-handed IF signal and a 110°CS right-handed IF signal, a BS left-handed IF signal or a 110°CS left-handed IF signal, and a UHF digital terrestrial signal. The separated BS right-handed IF signal and 110°CS right-handed IF signal are amplified to a predetermined level by AMP6 and input to MIX3. The separated BS left-handed IF signal or 110°CS left-handed IF signal, and a UHF digital terrestrial signal are amplified to a predetermined level by AMP7 and input to DIM7. In DIM7, the signal is separated into a BS left-handed IF signal or a 110°CS left-handed IF signal, and a UHF digital terrestrial signal. The demultiplexed BS left-handed IF signal or 110° CS left-handed IF signal is input to CONV3 and up-converted collectively so that the frequency band of the BS left-handed IF signal or 110° CS left-handed IF signal is the original frequency band. In this case, as shown in FIG. 5B, if the 110° CS left-handed IF signal is selected and down-converted to a frequency band of 254.75 MHz to 769.25 MHz and transmitted, the frequency band of the 110° CS left-handed IF signal is up-converted to a frequency band of 2708.75 MHz to 3223.25 MHz. In CONV3, multiple channels in the frequency band of the BS left-handed IF signal or 110° CS left-handed IF signal are up-converted collectively. The Lo frequency in CONV3 is set to 2454 MHz because it is the same frequency as the Lo frequency in CONV1 of the frequency conversion device 10.

The BS left-handed IF signal or 110°CS left-handed IF signal upconverted by CONV3 is input to MIX3 and mixed with the BS right-handed IF signal and 110°CS right-handed IF signal. The BS right-handed IF signal and 110°CS right-handed IF signal, as well as the BS left-handed IF signal or 110°CS left-handed IF signal mixed by MIX3 are output from OUT2 of the terminal device 22. The UHF terrestrial digital signal split by the DIM7 is output from OUT3 of the terminal device 22. By connecting OUT2 and OUT3 of the terminal device 22, which is the receiving unit, to the input terminal of the television (TV) 23 with a cable, the BS right-handed IF signal and 110°CS right-handed IF signal, the BS left-handed IF signal, or the 110°CS left-handed IF signal can be received by the TV 23. In addition, the transmitted UHF terrestrial digital signal is down-converted to a lower frequency band than the original frequency band, but can be received by the pass-through (registered trademark) function of the TV 23. In other words, it is possible to watch terrestrial digital broadcasting channels, BS right-hand and BS left-hand BS broadcasting channels, and CS right-hand and 110° CS left-hand CS broadcasting channels on the TV 23.

<Components>
FIG. 2 is a functional block diagram showing a configuration of a modified example of the U/V conversion unit 13 in the frequency conversion device 10.
The U/V conversion unit 13' of the modified example shown in Figure 2 divides the frequency band of the UHF terrestrial digital signal into a plurality of blocks, and down-converts each block to a different frequency band. The down-conversion frequency arrangement is shown in Figures 9(a) and (b), and the frequency conversion image of the down-conversion by the U/V conversion unit 13 and the U/V conversion unit 13' will be described with reference to Figures 9(a) and (b).
Fig. 9(a) shows an image of frequency conversion by the U/V conversion unit 13 shown in Fig. 1, and since the U/V conversion unit 13 converts the frequency using one local oscillator (Lo), it can be described as a 1Lo method. In the 1Lo method, as shown in Fig. 9(a), the frequency band of channels (ch) 16ch to 27ch of the UHF terrestrial digital signal is frequency converted by a Lo of 398MHz and down-converted to a frequency band of 90MHz to 162MHz. The down-converted frequency band is a frequency band consisting of the VHF-Lo band and the MID band.
In the modified U/V conversion unit 13', the UHF terrestrial digital signal is distributed by the DIV 13a, but the number of distributions is the same as the number of blocks into which the UHF terrestrial digital signal is divided. Each of the distribution signals distributed by the DIV 13a is input to the BPFs 2a to 2n. Each of the BPFs 2a to 2n has a passband for the frequency band of each divided block, and the UHF terrestrial digital signal of the frequency band of each block is output from each of the BPFs 2a to 2n. The UHF terrestrial digital signal of the frequency band of each block is input to the CONVs 2a to 2n and frequency-converted. In the CONVs 2a to 2n, the frequency band of each block is down-converted to a prescribed frequency band of the VHF band that is different from each other. The UHF terrestrial digital signals for each block down-converted by CONV2a to CONV2n are input to BPF3a to BPF3n, where unnecessary wave components are removed. The outputs from BPF3a to BPF3n are level-adjusted by ATT3a to ATT3n so that the UHF terrestrial digital signals for each block are at a predetermined level, and then input to MIX13b. In MIX13b, the UHF terrestrial digital signals for each block are mixed.

Fig. 9(b) shows an image of frequency conversion by the U/V conversion unit 13' of the modified example shown in Fig. 2, and since the U/V conversion unit 13' converts frequencies using multiple local oscillators (Lo), it can be described as a multiple Lo method. In the case shown in Fig. 9(a), the number of blocks is 3 (=n), the first block is made up of a frequency band including UHF channels 16ch to 18ch, the second block is made up of a frequency band including UHF channels 21ch to 24ch, and the third block is made up of a frequency band including UHF channels 23ch to 27ch, and the frequency band of the UHF digital terrestrial signal is divided into three. The UHF digital terrestrial signals of each block are input to CONV2a, CONV2b, and CONV2c, respectively, and are frequency converted. The Lo of CONV2a is set to 398MHz, and the frequency band of UHF channels 16ch to 18ch is down-converted to the frequency band of VHF-Lo band (VHF channels 1ch to 3ch) of 90MHz to 108MHz. The Lo of CONV2b (not shown) is set to 348MHz, and the frequency band of UHF channels 21ch to 24ch is down-converted to the frequency band of VHF channels 4ch to 7ch in the VHF-Hi band. The Lo of CONV2c (not shown) is set to 338MHz, and the frequency band of UHF channels 23ch to 27ch is down-converted to the frequency band of VHF channels 8ch to 12ch in the VHF-Hi band of 170MHz to 222MHz. In this case, each block performs frequency conversion by providing a guard band for each frequency arrangement. In addition, since the frequency allocation of VHF channels 7ch and 8ch overlap by 2MHz, 7ch and 8ch are used as guard bands. By providing guard bands in this way, a BPF with a steep cutoff characteristic is not required, and the frequency arrangement can be realized with inexpensive filter configurations of BPF2a to BPF2n and BPF3a to BPF3n. Note that UHF channels 24ch and 23ch, which are down-converted to VHF channels 7ch and 8ch, overlap by 2MHz, so they are shown as 24' and 23', and although some of the channels overlap, they are not received because the amplitude is cut by BPF3a to BPF3n, resulting in a large deviation and a poor C/N ratio.
As described above, in the case of a multiple Lo system in which the U/V conversion unit 13 is the modified U/V conversion unit 13' shown in Figure 2, the transmission frequency arrangement of the UHF terrestrial digital signal transmitted over the shared receiving equipment line 30 will be as shown in Figure 6 (b).

Next, FIG. 3A shows a functional block diagram illustrating a modified example of CONV1 (CONV3) in the frequency conversion device 10, and FIG. 3B shows a functional block diagram illustrating another modified example.
The modified CONV1' shown in Fig. 3(a) has two local oscillators Lo1 and Lo2, and the local oscillation frequency (Lo frequency) from Lo1 and Lo2 is switched by a switch (SW) 1 and supplied to the mixer. When the BS left-handed circular polarization IF signal is selected, SW1 is switched to the Lo1 side to supply 1911 MHz, which is the Lo frequency of Lo1, to the mixer, and the frequency band of the BS left-handed circular polarization IF signal is down-converted to a frequency band of 313.41 MHz to 769.87 MHz. When the 110° CS left-handed circular polarization IF signal is selected, SW1 is switched to the Lo2 side to supply 2454 MHz, which is the Lo frequency of Lo2, to the mixer, and the frequency band of the 110° CS left-handed circular polarization IF signal is down-converted to a frequency band of 254.75 MHz to 769.25 MHz. In this case, the frequency conversion image of the modified example CONV1' is as shown in FIGS.
In addition, the modified CONV3' has the same circuit configuration as the modified CONV1', and when the BS left-handed IF signal is selected, SW1 is switched to the Lo1 side, and the Lo frequency of Lo1, 1911 MHz, is supplied to the mixer, and the frequency band of the transmitted BS left-handed IF signal is up-converted to the original frequency band of 2224.1 MHz to 2680.87 MHz. In addition, when the 110° CS left-handed IF signal is selected, SW1 is switched to the Lo2 side, and the Lo frequency of Lo2, 2454 MHz, is supplied to the mixer, and the frequency band of the transmitted 110° CS left-handed IF signal is up-converted to the original frequency band of 2708.75 MHz to 3223.25 MHz. In this case, the frequency conversion image of the modified CONV3' is as shown in Figure 5 (b) (c).

In another modified example CONV1''(CONV3'') shown in FIG. 3(b), the local oscillator is composed of a PLL (Phase Locked Loop) having a VCO (Voltage Controlled Oscillator), and the Lo frequency from the VCO supplied to the mixer can be adjusted. This is to accommodate a case where the booster (AMP4, AMP5) inserted in the common receiving equipment line 30 is a UV booster that performs amplification operation only in the VHF and UHF frequency bands, and cannot perform amplification operation in other frequency bands including the super high band. In other words, in the modified example CONV1''(CONV3''), the Lo frequency is adjusted to set a frequency band including a desired channel that can be transmitted by AMP4 and AMP5 that are UV boosters.
6(a) and 6(b) show an image of frequency conversion of a satellite IF signal in another modified example CONV1". As shown in FIG. 6(a), in another modified example CONV1", the Lo frequency of the VCO can be adjusted between 1754 MHz and 1911 MHz and between 2238 MHz and 2454 MHz. This makes it possible to transmit a frequency band including a desired channel in a selected BS left-handed IF signal or a 110° CS left-handed IF signal over a common receiving facility line 30 with a UV booster inserted. For example, FIG. 6(a) shows an example in which a frequency band including 5 or 2 channels of a 110° CS left-handed IF signal is down-converted to the UHF band of 470 MHz to 770 MHz and transmitted over a common receiving facility line 30 with a UV booster inserted.
Furthermore, CONV3" of another modified example has the same circuit configuration as CONV1" of another modified example, and is capable of adjusting the Lo frequency from the VCO in the same frequency range as CONV1" of another modified example. In CONV3" of another modified example, the Lo frequency of the VCO is set to the same Lo frequency as the VCO of CONV1", and the frequency band of the BS left-handed circular polarization IF signal or 110° CS left-handed circular polarization IF signal including the desired channel that has been down-converted to the UHF band of 470 MHz to 770 MHz and transmitted is up-converted to the BS left-handed circular polarization IF signal or 110° CS left-handed circular polarization IF signal in the original frequency band.

Next, a functional block diagram showing a configuration of a modified BPF1 in the frequency conversion device 10 is shown in Fig. 4. The modified BPF1' shown in Fig. 4 has a BPF1a that passes a BS left-handed IF signal with a passband of 2224.1 MHz to 2680.87 MHz, and a BPF1b that passes a 110° CS left-handed IF signal with a passband of 2708.75 MHz to 3223.25 MHz, arranged in parallel, and has changeover switches (SW2, SW3) provided on the input and output sides of the BPF1a and BPF1b. By switching the SW2 and SW3 to the BPF1a side, the BS left-handed IF signal passes, and by switching the SW2 and SW3 to the BPF1b side, the 110° CS left-handed IF signal passes. In this case, SW2 and SW3 are switched in response to the selected BS left-handed or CS left-handed IF reception signal.
In this way, the modified BPF1' is equipped with BPF1a that passes the BS left-handed circular polarization IF signal and BPF1b that passes the 110° CS left-handed circular polarization IF signal, and by switching SW2 and SW3, the selected BS left-handed circular polarization IF signal or 110° CS left-handed circular polarization IF signal is allowed to pass.

Next, Fig. 7 shows a functional block diagram showing the configuration of a modified example of the booster (AMP4, AMP5) inserted in the common receiving facility line 30. The modified example AMP4'(AMP5') corresponds to a booster when the transmission frequency arrangement of the UHF terrestrial digital signal and the satellite IF signal transmitted through the common receiving facility line 30 is as shown in Fig. 5(b).
The AMP4'(AMP5') of the modified example shown in Fig. 7 is a CATV booster compatible with satellites, and has an AMP41 that amplifies the frequency band of satellite IF signals up to 2150 MHz or 2602 MHz, and an AMP42 that amplifies the CATV band, which is a frequency band that can be transmitted by cable television with a frequency band of 70 MHz to 770 MHz. Specifically, the received signal input to the input terminal IN of the AMP4'(AMP5') is split into satellite IF band and CATV band received signals by a splitter DIM41, and the satellite IF signal of the satellite IF band is amplified by the AMP41 and adjusted to a predetermined level by the ATT41. Also, the CATV band received signal is amplified by the AMP42 and adjusted to a predetermined level by the ATT42. The satellite IF signal amplified to a predetermined level from the ATT 41 and the CATV band reception signal amplified to a predetermined level from the ATT 42 are mixed in the MIX 41 and outputted from the output terminal OUT as a booster output.
As described above, the modified AMP4'(AMP5') operates as a satellite-compatible CATV booster in which the transmission frequency arrangement in the common receiving equipment line 30 is as shown in Fig. 5(b), and the AMP42 is designed as a high-output booster capable of withstanding the power of multiple waves, since it amplifies the received signal in the CATV band, which is considered to be a wide band. Also, the transmission frequency arrangement from the output terminal OUT is as shown in Fig. 5(b).

Next, Fig. 8 shows a functional block diagram showing the configuration of another modified example of the booster (AMP4, AMP5) inserted in the common receiving facility line 30. The other modified example AMP4"(AMP5") corresponds to a booster in which the U/V conversion unit 13 is the U/V conversion unit 13' of the modified example shown in Fig. 2, CONV1 is the CONV1" of the other modified example, and the transmission frequency arrangement of the UHF terrestrial digital signal and the satellite IF signal transmitted over the common receiving facility line 30 is as shown in Fig. 6(b).
Another modified example AMP4''(AMP5'') shown in Figure 8 is a satellite-compatible UV booster, and has an AMP51 that amplifies the frequency band of the satellite IF signal up to 2150 MHz or 2602 MHz, an AMP52 that amplifies the satellite IF signal down-converted to the UHF band of 470 MHz to 770 MHz, an AMP53 that amplifies the UHF terrestrial digital signal down-converted to the VHF-Hi band of 170 MHz to 222 MHz, and an AMP54 that amplifies the UHF terrestrial digital signal down-converted to the VHF-Lo band of 90 MHz to 108 MHz. Specifically, the received signal input to the AMP4"(AMP5") of the other modified example is split into satellite IF bands of BS right-handed IF signal and 110° CS right-handed IF signal by splitter DIM51, and the split satellite IF band received signal is amplified by AMP51 and adjusted to a predetermined level by ATT51. The received signal from which the satellite IF band is split is input to DIM52, and the BS left-handed IF signal or 110° CS left-handed IF signal that has been down-converted to the UHF band and transmitted is split, and the split satellite IF signal that has been down-converted to the UHF band and transmitted is amplified by AMP52 and adjusted to a predetermined level by ATT52. The received signal from which the satellite IF band and the satellite IF signal that have been down-converted to the UHF band and transmitted are split is input to DIM53, and the VHF-Hi band and VHF-Lo band are split. The UHF signal that has been down-converted to the branched VHF-Hi band and transmitted is amplified by the AMP 53 and adjusted to a predetermined level by the ATT 53, and the UHF signal that has been down-converted to the branched VHF-Lo band and transmitted is amplified by the AMP 54 and adjusted to a predetermined level by the ATT 54. The outputs from the ATT 53 and the ATT 54 are input to the MIX 53 and mixed. Then, the mixed output from the MIX 53 and the output from the ATT 52 are input to the MIX 52 and mixed. Furthermore, the mixed output from the MIX 52 and the output from the ATT 51 are input to the MIX 51, mixed, and output from the output terminal OUT as a booster output.
As described above, the AMP4"(AMP5") of the other modified example operates as a satellite-compatible UV booster, and the AMP51 to AMP54 each amplify the received signals of a predetermined frequency band that is divided into multiple bands, thereby reducing the burden on each of the AMP51 to AMP54. Also, the transmission frequency arrangement of the output terminal OUT is as shown in FIG. 6(b).

<Frequency conversion transmission system according to an example of application of the present invention>
The frequency conversion transmission system 2 of the application example of the present invention is applied to, for example, an area where it is difficult to receive digital terrestrial broadcasting and where digital terrestrial broadcasting is received jointly. Fig. 10(a) shows a functional block diagram showing the configuration of the frequency conversion transmission system 2 of the application example of the present invention, and Fig. 10(b) shows an outline of the frequency arrangement of the received signals output from MIX1 and MIX2 in the frequency conversion transmission system 2.
As shown in these figures, the frequency conversion transmission system 2 of the application example of the present invention is composed of a BS/CS antenna 11a, a frequency conversion device 10a, and one or more terminals 22a, 22b, ..., and the frequency conversion transmission system 2 of the application example of the present invention is installed in a house 20a. A CATV line is drawn from a community receiving facility (not shown) to the house 20a, and the frequency band that can be transmitted by the community receiving facility is at least a frequency band of 90 MHz to 222 MHz. In the community receiving facility, a UHF terrestrial digital signal is received by a UHF antenna installed at a point where the terrestrial digital broadcasting station can be seen and the frequency band of the received UHF terrestrial digital signal is down-converted to a frequency band of 90 MHz to 222 MHz and transmitted by the CATV line. This CATV line is drawn into each house in an area where it is difficult to receive the terrestrial digital broadcasting, and the pass-through (registered trademark) function of the digital broadcasting receiving device makes it possible to watch the UHF broadcasting whose frequency band has been down-converted at each house.

In the frequency conversion transmission system 2 of the application example of the present invention, the received signal output from the BS/CS antenna 11a is input to IN1 of the frequency conversion device 10a. The received signals input to IN1 are the BS right-handed IF signal and the 110° CS right-handed IF signal, and the BS left-handed IF signal and the 110° CS left-handed IF signal, and their frequency bands are shown as BS right-handed, 110° CS right-handed, BS left-handed, and 110° CS left-handed in the above-mentioned Figure 5 (a). In addition, the received signal from the CATV line is input to IN2 of the frequency conversion device 10a, and the UHF terrestrial digital signal down-converted to the frequency band of 90 MHz to 222 MHz is input to IN2.

The frequency converter 10a functions as the frequency converter 10 described above, and the down-converted and level-adjusted BS left-handed IF signal or 110° CS left-handed IF signal is input to MIX2. In MIX2, the down-converted BS left-handed IF signal or 110° CS left-handed IF signal is mixed with the down-converted UHF terrestrial digital signal transmitted over the CATV line and input to MIX1. The frequency arrangement of the mixed output from MIX2 is as shown in the upper part of Figure 10(b), and is a mixed output of the UHF terrestrial digital signal in the frequency band of 90 MHz to 222 MHz transmitted over the CATV line and the BS left-handed IF signal or 110° CS left-handed IF signal down-converted to the frequency band of 254.75 MHz to 770 MHz. The mixed output of MIX2 is input to MIX1, where the BS right-handed IF signal and 110° CS right-handed IF signal from ATT1 are mixed with the mixed received signal from MIX2 and output from OUT1. The frequency arrangement of the mixed output from MIX1, which is the received signal output from OUT1 of the frequency conversion device 10a, is as shown in the lower part of Figure 10(b), and is a mixed output of the BS left-handed IF signal or 110° CS left-handed IF signal down-converted to the frequency band of 254.75 MHz to 770 MHz, and the BS right-handed IF signal and 110° CS right-handed IF signal in the frequency band of 1032 MHz to 2071 MHz or 1032 MHz to 2681 MHz. Note that the UHF terrestrial digital signal in the frequency band of 90 MHz to 222 MHz is omitted in the lower part of Figure 10(b).

The received signal output from OUT1 of the frequency conversion device 10a is distributed to a distributor (DIV) 10 installed in the house 20a, and one of the distributed outputs is input to terminal 22a via wall terminal 21a, and the other of the distributed outputs is input to terminal 22b via wall terminal 21b. Each of the other distributed outputs can also be input to other terminals. The terminals 22a and 22b are installed on the first and second floors of the house 20a or in different rooms, and the number of terminals installed varies depending on the number of floors and rooms in the house 20a. In the example shown in FIG. 10, two terminals 22a and 22b are installed in the house 20a.

The terminals 22a and 22b function as the terminal 22 described above, outputting a mixed signal of the BS left-handed IF signal or 110°CS left-handed IF signal upconverted to the original frequency band, and the BS right-handed IF signal and 110°CS right-handed IF signal, which are supplied to the TVs 23a and 23b, which are digital broadcasting receivers. Also, the UHF terrestrial digital signal of the frequency band sent via the CATV line is output and supplied to the TVs 23a and 23b. The TVs 23a and 23b can receive the BS right-handed and BS left-handed IF signals, the 110°CS right-handed and 110°CS left-handed IF signals, and can receive the UHF terrestrial digital signal of the frequency band sent via the CATV line by the pass-through function. That is, TVs 23a and 23b can be used to watch digital terrestrial broadcasting channels, BS right- and left-handed BS broadcasting channels, and CS broadcasting channels with 110° CS right and 110° CS left rotation. Also, if three or more terminals are installed in house 20a, digital terrestrial broadcasting channels, BS right- and left-handed BS broadcasting channels, and CS broadcasting channels with 110° CS right and 110° CS left rotation can be viewed on the digital broadcasting receivers connected to each terminal.

As described above, in the frequency conversion transmission system according to the embodiment of the present invention, even if the transmission path only supports the frequency of the BS/CS-IF right-handed received signal, the BS-IF left-handed or CS-IF left-handed received signal can be transmitted by down-converting the BS-IF left-handed or CS-IF left-handed received signal. In this case, the frequency conversion device serving as the transmitting unit down-converts the frequency band of the UHF terrestrial digital signal to a lower frequency band that can be transmitted on the transmission path, and the frequency band of the BS-IF left-handed or CS-IF left-handed received signal is down-converted to a frequency band including the frequency band of the UHF terrestrial digital signal that is thus vacant, and transmitted to the receiving unit. In the terminal device installed in the house serving as the receiving unit, the frequency band of the down-converted BS-IF left-handed or CS-IF left-handed received signal is up-converted to the original frequency band, and the down-converted and transmitted UHF terrestrial digital signal is supplied as is to the digital receiving device. The down-converted and transmitted UHF terrestrial digital signal can be received by the pass-through function of the digital receiving device, and since multiple channels in the frequency band are down-converted (up-converted) collectively, the configuration of the frequency conversion transmission system of the present invention is simplified and can be provided at low cost. In addition, the frequency conversion transmission system of the present invention does not require a BPF with a steep cutoff characteristic for extracting the frequency band for each channel, so the frequency conversion transmission system of the present invention can be provided at a lower cost.
In the frequency conversion transmission system of the present invention described above, even if the configurations of the U/V conversion unit 13, the converters (CONV) 1, 3, and the bandpass filter (BPF) 1 are modified as shown in Figures 2 to 4, the simplicity of the configuration of the frequency conversion transmission system of the present invention is maintained, so that the frequency conversion transmission system of the present invention can be provided at low cost.

1, 2 Frequency conversion transmission system, 10, 10a Frequency conversion device, 11, 11a BS/CS antenna, 12 UHF antenna, 13 U/V conversion unit, 20 Apartment house, 20a House, 21, 21a, 21b Wall terminal, 22, 22a, 22b Terminal device, 30 Community reception equipment line, 100 Frequency conversion transmission system, 110 Frequency conversion device, 111 BS/CS antenna, 112 UHF antenna, 120 Apartment house, 122 Terminal device

Claims (7)

A frequency conversion transmission system in which a transmitter and a receiver are connected by a transmission line,
The transmission unit is
a first down converter that down-converts a first frequency band of a UHF terrestrial digital signal of terrestrial digital broadcasting broadcast in the UHF band to a second frequency band that is a frequency band that can be transmitted through the transmission path and is lower than the frequency band of the UHF terrestrial digital signal;
a second downconverter that downconverts a third frequency band of a first IF reception signal, which is a BS left-handed circular polarization or CS left-handed circular polarization intermediate frequency signal, to a fourth frequency band including the first frequency band that has been vacated by downconversion by the first downconverter;
a mixing means for transmitting a mixed reception signal obtained by mixing a UHF terrestrial digital signal down-converted to the second frequency band by the first down-converter, a first IF reception signal of the fourth frequency band down-converted by the second down-converter, and a second IF reception signal which is an intermediate frequency signal of BS right-hand rotation and CS right-hand rotation, to the transmission path;
The receiving unit is
an up-converter that converts the first IF received signal of the fourth frequency band transmitted through the transmission line back into the original first IF received signal of the third frequency band;
A frequency conversion transmission system characterized in that a UHF terrestrial digital signal in the second frequency band transmitted over the transmission path, a first IF reception signal in the third frequency band upconverted by the upconverter, and the second IF reception signal transmitted over the transmission path are output from the receiving unit. The frequency conversion transmission system according to claim 1, characterized in that one transmitting unit is installed in an apartment building, the mixed reception signal transmitted from the transmitting unit to the transmission line is drawn into each house in the apartment building, and a terminal device serving as the receiving unit installed in each house receives the mixed reception signal. The frequency conversion transmission system according to claim 1, characterized in that the second downconverter has a first local oscillator and a second local oscillator having different local oscillation frequencies, and by switching to the first local oscillator , the third frequency band of BS left-hand circular polarization is selected and down-converted to the fourth frequency band, and by switching to the second local oscillator , the third frequency band of CS left-hand circular polarization is selected and down-converted to the fourth frequency band. The frequency conversion transmission system according to claim 1, characterized in that the local oscillation frequency in the second downconverter is adjustable, and the local oscillation frequency is adjusted so that a frequency band including a desired channel is downconverted to a frequency range that can be transmitted by a booster provided in the transmission path. The frequency conversion transmission system according to claim 1, characterized in that the first downconverter has a plurality of first frequency conversion blocks, the first frequency band of the UHF terrestrial digital signal is divided into a plurality of frequency bands, and the second frequency band is divided into a plurality of frequency bands, each divided frequency band of the first frequency band is downconverted to each divided frequency band of the second frequency band by the plurality of first frequency conversion blocks, and a guard band is provided between each divided frequency band of the second frequency band. The frequency conversion transmission system according to claim 1, characterized in that the booster provided in the transmission path has an amplifier means for amplifying each of a plurality of split reception signals obtained by splitting the mixed reception signal into different frequency bands. The frequency conversion transmission system according to claim 1, characterized in that the output from the receiving unit is received by a digital broadcast receiving device, and the digital broadcast receiving device is capable of receiving the UHF terrestrial digital signal in the second frequency band by a pass-through function.

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