JP4463944B2 - CATV system, down converter and up converter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a CATV system that transmits a BS reception signal from a BS antenna that receives a transmission radio wave from a broadcasting satellite (BS) to a terminal side together with a terrestrial television broadcast signal, and a BS reception signal to a terminal in this CATV system. The present invention relates to a down converter and an up converter suitable for transmission to the side.
[0002]
[Prior art]
Conventionally, the headend is provided with a television receiving antenna that receives a terrestrial television broadcast signal and a BS antenna that receives a transmission radio wave from a broadcasting satellite (BS), and the reception signal from each of these reception antennas is shared. A CATV system configured to transmit to a terminal side via a transmission line (generally a coaxial cable) is known.
[0003]
By the way, in order to transmit the received signal using a coaxial cable or the like to the receiving part of the BS antenna, the transmission wave in the tens of GHz band normally transmitted from the BS is frequency-converted (down to about 1 GHz to 2 GHz). Converters are provided for conversion, but the received signals from these BS antennas (BS received signals) are designed so that transmission equipment such as amplifiers installed on the transmission line can transmit terrestrial television broadcast signals. In addition, the existing CATV system has a problem that it cannot be transmitted.
[0004]
In addition, since the BS reception signal has a higher frequency than the terrestrial television broadcast signal, even if a transmission device installed on the transmission line can transmit the BS reception signal, the BS reception signal flows through the transmission line. As a result, the transmission loss caused by the transmission increases, and in order to transmit the BS received signal at an appropriate level, there is a problem that an expensive amplifier having a high level amplification characteristic is required.
[0005]
Therefore, in order to be able to transmit a BS reception signal even in an existing CATV system designed to transmit a terrestrial television broadcast signal, and to transmit a BS reception signal with low loss, In addition, a down-converter that once drops the BS reception signal to the frequency band of the television broadcast signal is provided, and the BS reception signal (hereinafter referred to as BS intermediate frequency signal) frequency-converted by this down converter is transmitted to the terminal side. Is considered.
[0006]
[Problems to be solved by the invention]
By the way, in the existing CATV system, the frequency band that can be transmitted is generally 70 MHz to 770 MHz, and among these, the VHF band (90 to 222 MHz) is mainly allocated to terrestrial analog broadcast signals. Since 25 MHz is allocated to the pilot signal, the frequency bands that can be allocated for transmission of the BS intermediate frequency signal are limited to 70 to 90 MHz, 222 to 451.25 MHz, and 451.25 to 770 MHz. And since the bandwidth of the BS reception signal is about 300 MHz, only 451.25 to 770 MHz can accommodate the BS intermediate frequency signal.
[0007]
However, in the near future, the UHF band (above 470 MHz) will be allocated to terrestrial digital broadcast signals, and the UHF band (especially in the vicinity of 470 MHz) needs to be kept as much as possible. The intermediate frequency signal cannot fit in the UHF band.
[0008]
That is, as described above, when the BS reception signal is frequency-converted to the BS intermediate frequency signal for transmission using the down converter, the frequency conversion is performed if the entire BS reception signal is frequency-converted with the channel arrangement as it is. The subsequent BS intermediate frequency signal cannot flow on the transmission line of the existing CATV system.
[0009]
On the other hand, in order to solve such a problem, for example, among the BS received signals having all 8 channels (1, 3, 5, 7, 9, 11, 13, 15 channels) as shown in FIG. BS received signals for 4 channels (1, 3, 13, 15 channels) for BS digital broadcasting in various frequency bands are converted into BS intermediate frequency signals of 253 to 407 MHz, for example, as shown in FIG. As shown in FIG. 10 (c), a system is considered in which the signals for the four channels are collectively converted in the terminal-side upconverter as shown in FIG. 10 (c).
[0010]
However, as apparent from comparison between FIG. 10 (a) and FIG. 10 (c), when frequency conversion is performed in this manner in the up-converter on the terminal side, the channel arrangement of the BS received signal becomes the original BS received signal. It will be different from the channel arrangement. For this reason, a commercially available BS tuner that receives the signal from the BS antenna as it is cannot be used as a BS tuner (in this case, a BS digital tuner) that finally receives the BS reception signal. It will be necessary to prepare a BS tuner dedicated to the CATV system.
[0011]
The present invention has been made in view of these problems. In a CATV system in which a signal transmission frequency is set in accordance with terrestrial television broadcasting, a BS reception signal can be transmitted. An object of the present invention is to be able to receive BS broadcasts using the BS tuner.
[0012]
[Means for solving the problems and effects of the invention]
In order to achieve such an object, the CATV system according to the present invention includes, as described in claim 1, one or continuous BS reception signals from the BS antenna in the down converter on the head end side. Two or more groups of BS received signals for a plurality of channels are extracted, and the BS received signals of each group are each in a frequency region from the VHF band to the UHF band allocated for television broadcast signals, and the television broadcast The frequency is converted into a BS intermediate frequency signal of a predetermined frequency band that does not overlap with the signal, and is transmitted onto the transmission line. Then, in the up-converter on each subscriber side, the BS intermediate frequency signal of each group transmitted from the head end is frequency-converted to the BS received signal in the original frequency band, and the BS received signal after frequency conversion is converted. Are mixed and sent to the subscriber side terminal.
[0013]
For this reason, in the CATV system according to the present invention, the channel arrangement of the BS reception signal finally transmitted from the up converter to the subscriber terminal is the same as the channel arrangement of the original BS intermediate frequency signal. Therefore, the subscriber side terminal can receive the BS broadcast using the existing BS tuner.
[0014]
By the way, the CATV system according to the present invention frequency-converts the BS reception signal of each group extracted from the BS reception signals from the BS antenna into a BS intermediate frequency signal of any frequency band in the down converter. For example, as described in claim 2, the first group of BS reception signals are transmitted to the VHF band terrestrial television broadcast and the UHF band terrestrial television broadcast. Frequency-converted into a BS intermediate frequency signal in the intermediate band between the frequency band allocated to the BS and the second group of BS received signals to the BS in the frequency band allocated to the UHF band terrestrial television broadcasting It may be configured to perform frequency conversion to an intermediate frequency signal.
[0015]
When configured in this manner, a part of the BS intermediate frequency signal is accommodated in the intermediate band, so that a free space for the terrestrial digital broadcast signal is within the frequency band assigned to the terrestrial television broadcast in the UHF band. A frequency band can be secured. For this purpose, a part of the BS received signal is stored in the intermediate band, so the larger the number of channels that can be stored in the intermediate band, the better. Specifically, since the frequency bandwidth for one channel of the BS reception signal is less than 40 MHz, it can accommodate five channels (if the frequency of the pilot signal is changed to a frequency outside the intermediate band) , Can accommodate 6 channels). For this reason, even when all 8 channels of BS received signals are transmitted, only 3 channels (or 2 channels) can be accommodated in the frequency band allocated to terrestrial television broadcasting in the UHF band. Occupies only a little less than 120 MHz (or 80 MHz), so that it does not become a major obstacle to the transmission of terrestrial digital broadcast signals.
[0016]
In addition, when not transmitting all 8 channels of BS reception signals but only 4 channels for BS digital broadcasting, for example, as described in claim 3, the first group of BS channels is transmitted. The received signal and the second group of BS received signals may be frequency-converted into BS intermediate frequency signals having different frequencies in the intermediate band.
[0017]
In the case of such a configuration, the BS intermediate frequency signal does not occupy the frequency band assigned to the terrestrial television broadcast in the UHF band, so that there is no problem for the transmission of the terrestrial digital broadcast signal.
In the down converter provided on the head end side in the CATV system according to the present invention, specifically, as described in claim 4, the BS received signal extracting means includes a BS received signal from the BS antenna. Two or more groups of BS reception signals for one or a plurality of continuous channels are extracted from among them, and a plurality of first frequency conversion units extract the BS reception signals of each group extracted by the BS reception signal extraction unit, respectively. The transmission signal mixing means converts the frequency into a BS intermediate frequency signal in a predetermined frequency band that does not overlap with the television broadcast signal in the frequency region from the VHF band to the UHF band allocated for the television broadcast signal. The frequency-converted BS intermediate frequency signal and other TV broadcast signal input from the outside are mixed and sent to the transmission line. . Further, the first reference signal generating means generates a plurality of reference signals necessary for the plurality of first frequency converting means to convert the BS reception signals of each group into BS intermediate frequency signals of a predetermined frequency band. It is configured.
[0018]
By the way, the first reference signal generating means that constitutes the down converter can arbitrarily specify how the plurality of reference signals are specifically generated. For example, as described in claim 5, a plurality of reference signals are generated. The first frequency converting means may comprise a plurality of oscillators that respectively generate a plurality of reference signals necessary for frequency converting the BS received signals of each group to BS intermediate frequency signals of a predetermined frequency band. As described in Item 6, the reference signal required for the first oscillator to frequency-convert one of the plurality of frequency converting means to convert the BS reception signal of a specific group into a BS intermediate frequency signal of a predetermined frequency band. And the first multiplying / dividing means multiplies or divides the reference signal generated by the first oscillator, so that the other frequency converting means converts the BS received signals of other groups into a predetermined frequency band. Do System may further be configured so as to generate a reference signal required.
[0019]
In the case of such a configuration, the configuration of the first reference signal generating means is simpler than the case where a plurality of reference signals are generated by dedicated oscillators, and the frequency and phase between each reference signal are simplified. It is difficult for the deviation to occur.
Instead of separately providing an oscillator for generating a pilot signal, one of a plurality of reference signals generated by the first reference signal generating means may be used as the pilot signal. In the case of such a configuration, the configuration of the CATV system can be simplified.
[0020]
In the CATV system according to the present invention, the up-converter provided on each subscriber side, specifically, as described in claim 7, the BS intermediate frequency signal extracting means includes a transmission signal from the head end. The BS intermediate frequency signal of each group is extracted from the BS, and a plurality of second frequency conversion means outputs the BS intermediate frequency signal of each group extracted by the BS intermediate frequency signal extraction means from the BS antenna, respectively. Frequency-converted into a BS received signal in the original frequency band, and the BS received signal mixing means mixes the plurality of BS received signals frequency-converted by the plurality of second frequency converting means to the subscriber side terminal. It is configured to send out. In addition, the second reference signal generating means uses a plurality of second frequency conversion means as reference signals to be used for frequency conversion of the BS intermediate frequency signals of each group into the original BS reception signals, and the head end side down converters A reference signal having the same frequency as that of the reference signal used for frequency conversion of the BS reception signal of the group to the BS intermediate frequency signal is generated.
[0021]
By the way, the second reference signal generating means constituting the up-converter can arbitrarily generate a plurality of reference signals in any specific manner. For example, as described in claim 8, a plurality of reference signals are generated. The second frequency converting means may comprise a plurality of oscillators each generating a plurality of reference signals necessary for frequency converting the BS intermediate frequency signals of each group to the original BS received signals. The second oscillator generates a reference signal necessary for one of a plurality of second frequency conversion means to convert the BS intermediate frequency signal of a specific group into the original BS received signal. The second multiplying / dividing unit multiplies or divides the reference signal generated by the second oscillator, so that the other frequency converting unit converts the BS intermediate frequency signal of another group into the original BS received signal. Necessary to convert Better and are configured so as to generate a quasi-signal.
[0022]
In the case of such a configuration, the configuration of the second reference signal generating means is simpler than the case where a plurality of reference signals are generated by dedicated oscillators, and the frequency and phase between each reference signal are simplified. It is difficult for the deviation to occur.
When one of the plurality of reference signals generated by the first reference signal generating means constituting the down converter provided on the head end side is used as the pilot signal, the second reference signal generating means Instead of generating a reference signal by two oscillators, this pilot signal is used as a reference signal as it is, and another reference signal is generated by multiplying or dividing the pilot signal by a multiplying / dividing means. May be. In the case of such a configuration, the configuration of the upconverter can be simplified.
[0023]
Further, in the CATV system according to the present invention, the up-converter provided on each subscriber side may be attached or built in for each terminal device, or as described in claim 10, as a single unit on the transmission line. It may be installed, or as described in claim 11, it may be configured to be installable on the transmission line as one of transmission devices for transmitting a transmission signal to the terminal side. The transmission equipment is a branching device, a branching amplifier, a distributor, a distribution amplifier, an extension amplifier, a tap-off, etc. installed on the transmission line.
[0024]
Thus, when the up converter is provided on the transmission line, the number is significantly reduced as compared with the case where the up converter is provided for each terminal device. For example, when a distributor is installed at the end of the extension amplifier and a plurality of (for example, 24) terminal devices are connected to the end of the extension amplifier, a plurality of (24) up-converters are provided for each terminal device. Although it is necessary, if it is provided between the extension amplifier and the distributor, or if it is built in the extension amplifier, one is sufficient. Therefore, it is very economical. However, it is necessary to transmit a signal from the up converter to each terminal device through a transmission line capable of transmitting the BS intermediate frequency signal, that is, a transmission line capable of transmitting up to about 1340 MHz.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
First, the overall configuration of the CATV system of this embodiment will be described. FIG. 1 is a block diagram for explaining the overall configuration of the CATV system.
[0026]
As shown in FIG. 1, the CATV system of this embodiment is configured to be able to transmit a signal of 70 to 770 MHz, sends a broadcast signal from the head end 1, and transmits a transmission line (specifically, trunk line, branch line, distribution line). , Lead-in line) 6 and a branching amplifier 2, an extension amplifier 3, a tap-off 4 and a protector 5 provided on the transmission line 6, a broadcast signal is supplied to the subscriber's home of the CATV system.
[0027]
Next, the head end constituting the CATV system will be described. FIG. 2 is a block diagram for explaining the configuration of the head end.
As shown in FIG. 2, the head end 1 is a terrestrial broadcast signal transmitted from a ground station, specifically, an analog broadcast signal in a VHF band (90 to 108, 170 to 222 MHz) and a UHF band (470 to 770 MHz). A terrestrial broadcast receiving antenna 11 for receiving broadcast signals (analog and digital), and a receiving amplifier 12 for amplifying the terrestrial broadcast signal received by the terrestrial broadcast receiving antenna 11 to a predetermined level, A BS antenna 14 that receives a satellite broadcast signal transmitted from a broadcast satellite, converts the frequency into a BS received signal of 1030 to 1337 MHz, and outputs the BS received signal; a receiving amplifier 15 for amplifying the BS received signal to a predetermined level; BS in a frequency band (70 to 770 MHz) where a BS received signal can be transmitted in the CATV system A down-converter unit 20 that converts the frequency into a frequency signal. The terrestrial broadcast signal and the BS intermediate frequency signal frequency-converted by the down-converter unit 20 are mixed by the mixer 13 and output from the output terminal Tout. Is. Although not shown, the head end 1 is also provided with a pilot signal generator for generating a 451.25 MHz pilot signal used for level adjustment of the transmission signal in the branching amplifier 2 and the like. The pilot signal is mixed with the terrestrial broadcast signal and the BS intermediate frequency signal frequency-converted by the down-converter unit 20 and output from the output terminal Tout.
[0028]
In the down-converter unit 20, first, the BS received signal is divided into two by the distributor 21 and input to band-pass filters (hereinafter referred to as “BPF”) 22 and 26. The passable frequency band of the BPF 22 is 1030 to 1145 MHz, and the passable frequency band of the BPF 26 is 1145 to 1337 MHz. For this reason, the BPF 22 outputs BS intermediate frequency signals of 1030 to 1145 MHz corresponding to channels 1, 3 and 5 of all 8 channels of satellite broadcasting. Similarly, the BPF 26 outputs 7, 9, 11, BS reception signals of 1145 to 1337 MHz corresponding to the 13th and 15th channels are output. The output signal from the BPF 22 is input to the mixer 23, and the output signal from the BPF 26 is input to the mixer 27. A second reference signal output from the local oscillator 29 having an oscillation frequency of 446 MHz is input to the mixer 23 via an amplifier 30 and a BPF 31 (passable frequency: 446 MHz), and a second reference signal is input to the mixer 27. The first reference signal generated by multiplying the signal by 2 in the multiplier circuit 32 is input via the BPF 33 (passable frequency: 892 MHz).
[0029]
Then, the mixer 23 converts the frequency of the BS received signal of 1030 to 1145 MHz using the second reference signal of 446 MHz, and inputs it to the BPF 24 (passable frequency band: 584 to 699 MHz). Then, the BPF 24 outputs a BS intermediate frequency signal of 584 to 699 MHz (hereinafter referred to as a “second BS intermediate frequency signal”) obtained by lowering the frequency of the BS reception signal corresponding to the first, third, and fifth channels by 446 MHz. Become. Similarly, the mixer 27 frequency-converts the BS received signal of 1145 to 1337 MHz using the first reference signal of 892 MHz, and inputs it to the BPF 28 (passable frequency band: 253 to 445 MHz). Then, the BPF 28 outputs a BS intermediate frequency signal of 253 to 445 MHz (hereinafter referred to as “first BS intermediate frequency signal”) obtained by lowering the frequency of the BS reception signal corresponding to the channels 7, 9, 11, 13, and 15 by 892 MHz. Will be. The second BS intermediate frequency signal and the first BS intermediate frequency signal are mixed by the mixer 25 and then input to the mixer 13. As described above, the second BS intermediate frequency signal and the first BS intermediate frequency signal are mixed with the terrestrial broadcast signal by the mixer 13, and output terminal Tout. Is output from. The frequency distribution of the BS intermediate frequency signal, the first BS intermediate frequency signal, and the second BS intermediate frequency signal is as shown in FIG.
[0030]
When a transmission signal in which the terrestrial broadcast signal, the first BS intermediate frequency signal, and the second BS intermediate frequency signal are mixed is transmitted to the subscriber's house, the upconverter 40 at the subscriber's house uses the first BS intermediate frequency signal and the first BS signal. The 2BS intermediate frequency signal is returned to the BS reception signal, and terrestrial broadcasting and satellite broadcasting are viewed.
[0031]
Next, the up converter 40 will be described. FIG. 4 is a block diagram for explaining the configuration of the up-converter.
As shown in FIG. 4, in the up-converter 40, the transmission signal input from the input terminal Tin has a branching device 41 that branches a part of the signal, and a low-pass filter (hereinafter, “0” to 770 MHz). LPF ”) and output from the output terminal Tout1.
[0032]
The transmission signal branched by the branching unit 41 is input to the distributor 44 through the amplifier 43, divided into two by the distributor 44, and input to the BPFs 45 and 50, respectively. Since the passable frequency band of the BPF 45 is 584 to 699 MHz and the passable frequency band of the BPF 50 is 253 to 445 MHz, the second BS intermediate frequency signal is output from the BPF 45, and the first BS intermediate frequency signal is output from the BPF 50. Is output. The second BS intermediate frequency signal output from the BPF 45 is input to the mixer 46, and the first BS intermediate frequency signal output from the BPF 50 is input to the mixer 51. Similarly to the down-converter unit 20 of the head end 1, the mixer 46 receives a fourth reference signal output from the local oscillator 53 having an oscillation frequency of 446 MHz via an amplifier 54 and a BPF 55 (passable frequency: 446 MHz). The third reference signal generated by multiplying the fourth reference signal by 2 in the multiplication circuit 56 is input to the mixer 51 via the BPF 57 (passable frequency: 892 MHz).
[0033]
Then, the mixer 46 converts the frequency of the second BS intermediate frequency signal of 584 to 699 MHz using the fourth reference signal of 446 MHz and inputs it to the BPF 47 (passable frequency band: 1030 to 1145 MHz). For this reason, the BPF 47 outputs BS received signals of 1030 to 1145 MHz corresponding to the 1, 3, and 5 channels. Similarly, the mixer 51 converts the frequency of the first BS intermediate frequency signal of 253 to 445 MHz using the third reference signal of 892 MHz, and inputs it to the BPF 52 (passable frequency band: 1145 to 1337 MHz). From the BPF 52, BS reception signals of 1145 to 1337 MHz corresponding to the 7, 9, 11, 13, and 15 channels are output. The BS received signals of 1030 to 1145 MHz corresponding to the 1, 3, 5 channels and the BS received signals of 1145 to 1337 MHz corresponding to the 7, 9, 11, 13, and 15 channels are mixed by the mixer 48 to obtain a high-pass filter. (Hereinafter referred to as "HPF") 49 (passable frequency band: 1030 MHz or higher) is output from the output terminal Tout2.
[0034]
Then, the output signal from the output terminal Tout1 is directly input to a television receiver (not shown), and the output signal from the output terminal Tout2, that is, the BS reception signal is received via the BS tuner (not shown). Is input to the machine.
In this embodiment, BPF 22 and BPF 26 correspond to the BS received signal extraction means, and the local oscillator 29, amplifier 30, BPF 31, multiplier circuit 32, and BPF 33 correspond to the first reference signal generation means. The local oscillator 29 corresponds to the first oscillator described above, the multiplier circuit 32 corresponds to the first multiplier / divider means described above, and the mixer 23, BPF 24, mixer 27, and BPF 28 serve as the first frequency converter means described above. The mixer 13 and the mixer 25 correspond to the transmission signal mixing means, the BPF 45 and BPF 50 correspond to the BS intermediate frequency signal extraction means, the local oscillator 53, the amplifier 54, the BPF 55, the multiplication circuit 56, The BPF 57 corresponds to the above-mentioned second reference signal generating means, the local oscillator 53 among them corresponds to the above-mentioned second oscillator, and the multiplication circuit 56 includes the above-mentioned second multiplication / Corresponds to the peripheral unit, a mixer 46, BPF47, mixer 51, BPF 52 corresponds to a second frequency converting means described above, the mixer 48 corresponds to a BS reception signal mixing means described above.
[0035]
Then, the effect of the CATV system of a present Example is demonstrated.
According to the CATV system of the present embodiment, the BS intermediate frequency signal of 1145 to 1337 MHz corresponding to the channels 7, 9, 11, 13, and 15 is the first reference signal of 892 MHz in the down converter unit 20 of the head end 1. Is converted into the first BS intermediate frequency signal of 253 to 445 MHz, and the BS intermediate frequency signal of 1030 to 1145 MHz corresponding to the 1, 3, and 5 channels is 584 to 699 MHz using the second reference signal of 446 MHz. The frequency is converted into the second BS intermediate frequency signal. For this reason, the occupation rate in the UHF band of the 2nd BS intermediate frequency signal can be suppressed, and the vacant frequency band for terrestrial digital broadcasting signals can be secured more widely.
[0036]
In addition, the down-converter unit 20 does not generate the first reference signal and the second reference signal by a dedicated local oscillator, but generates a second reference signal of 446 MHz by a single local oscillator 29, and a multiplier circuit 32. Since the 892 MHz signal obtained by multiplying the second reference signal by 2 is used as the first reference signal, the first reference signal and the second reference signal are generated by dedicated oscillators. The configuration is simpler than that. Therefore, with a simple configuration, it is possible to transmit the BS intermediate frequency signal within the frequency band of 70 to 770 MHz while ensuring a wide free frequency band for the terrestrial digital broadcast signal.
[0037]
Similarly to the down-converter unit 20 of the head end 1, the up-converter 40 does not generate the third reference signal and the fourth reference signal by dedicated oscillators, but uses a single local oscillator 53 to generate a fourth 446 MHz signal. Since the reference signal is generated and the 892 MHz signal obtained by multiplying the fourth reference signal by 2 by the multiplying circuit 32 is used as the third reference signal, the third reference signal and the fourth reference signal are respectively dedicated. The configuration is simple as compared with the case of generating by an oscillator. Therefore, the first BS intermediate frequency signal and the second BS intermediate frequency signal can be returned to the original BS intermediate frequency signal with a simple configuration.
[0038]
[Second Embodiment]
First, the overall configuration of the CATV system of this embodiment is the same as that of the CATV system of the first embodiment shown in FIG. That is, the CATV system of the present embodiment is configured to be able to transmit a signal of 70 to 770 MHz, sends a broadcast signal from the head end, and transmits on a transmission line (specifically, trunk line, branch line, distribution line, lead-in line) and transmission line. A broadcast signal is supplied to a subscriber's home of the CATV system via a branch amplifier, an extension amplifier, a tap-off, and a protector provided in the CATV system.
[0039]
Next, the head end constituting the CATV system will be described. FIG. 5 is a block diagram for explaining the configuration of the head end.
As shown in FIG. 5, the head end 101 has a terrestrial broadcast receiving antenna 11, a receiving amplifier 12, a BS antenna 14, a receiving amplifier 15, and a frequency band (70) at which a BS received signal can be transmitted in the CATV system. Down-converter unit 120 that converts the frequency to a BS intermediate frequency signal of ˜770 MHz), and the terrestrial broadcast signal and the BS intermediate frequency signal that has been frequency-converted by the down-converter unit 120 are mixed by the mixer 13, The signal is output from the output terminal Tout. That is, the head end 101 has the same configuration as the head end 1 of the first embodiment except for the down converter 120.
[0040]
In the down-converter unit 120, first, the BS reception signal is divided into two by the distributor 121 and input to the BPFs 122 and 126, respectively. The passable frequency band of the BPF 122 is 1030 to 1107 MHz, and the passable frequency band of the BPF 126 is 1260 to 1337 MHz. Therefore, the BPF 122 outputs 1030 to 1107 MHz BS reception signals corresponding to the 1 and 3 channels in the satellite broadcasting of all 8 channels, and similarly, the BPF 126 outputs 1260 to 1 corresponding to the 13 and 15 channels. A 1337 MHz BS reception signal is output. An output signal from the BPF 122 is input to the mixer 123, and an output signal from the BPF 126 is input to the mixer 127. The fifth reference signal output from the local oscillator 129 having an oscillation frequency of 1437 MHz is input to the mixer 123 via the amplifier 130 and the BPF 131 (passable frequency: 1437 MHz), and the mixer 127 is input to the oscillation frequency of 1690 MHz. The sixth reference signal output from the local oscillator 132 is input via the amplifier 133 and the BPF 134 (passable frequency: 1690 MHz).
[0041]
Then, the mixer 123 frequency-converts the BS received signal of 1030 to 1107 MHz using the first reference signal of 1437 MHz and inputs it to the BPF 124 (passable frequency band: 330 to 407 MHz). Then, from the BPF 124, a BS intermediate frequency signal of 330 to 407 MHz (hereinafter referred to as “third BS intermediate frequency signal”) obtained by subtracting the frequency of the BS reception signal corresponding to the first and third channels from the frequency (1437 MHz) of the first reference signal. ) Will be output. Similarly, the mixer 127 converts the frequency of the BS reception signal of 1260 to 1337 MHz using the sixth reference signal of 1690 MHz and inputs it to the BPF 128 (passable frequency band: 253 to 330 MHz). Then, from the BPF 128, a BS intermediate frequency signal of 253 to 330 MHz (hereinafter referred to as a “fourth BS intermediate frequency signal”) obtained by subtracting the frequency of the BS reception signal corresponding to the 13th and 15th channels from the frequency of the sixth reference signal (1690 MHz). ) Will be output. The third BS intermediate frequency signal and the fourth BS intermediate frequency signal are mixed by the mixer 125 and then input to the mixer 13. As described above, the third BS intermediate frequency signal and the fourth BS intermediate frequency signal are mixed with the terrestrial broadcast signal by the mixer 13, and output terminal Tout. Is output from. The frequency distribution of the BS reception signal, the third BS intermediate frequency signal, and the fourth BS intermediate frequency signal is as shown in FIG.
[0042]
When a transmission signal in which the terrestrial broadcast signal, the third BS intermediate frequency signal, and the fourth BS intermediate frequency signal are mixed is transmitted to the subscriber's home, the upconverter 140 is installed at the subscriber's home as in the first embodiment. Thus, the third BS intermediate frequency signal and the fourth BS intermediate frequency signal are returned to the BS reception signal, and the terrestrial broadcast and the satellite broadcast are viewed.
[0043]
Next, the up converter 140 will be described. FIG. 7 is a block diagram for explaining the configuration of the up-converter.
As shown in FIG. 7, in the up-converter 140, the transmission signal input from the input terminal Tin has a branching device 141 that branches a part of the signal and a low-pass filter (hereinafter referred to as “passable frequency band” of 0 to 770 MHz). LPF ”) and output from the output terminal Tout1.
[0044]
The transmission signal branched by the branching unit 141 is input to the distributor 144 via the amplifier 143, divided into two by the distributor 144, and input to the BPFs 145 and 150, respectively. Since the passable frequency band of the BPF 145 is 330 to 407 MHz and the passable frequency band of the BPF 150 is 253 to 330 MHz, the third BS intermediate frequency signal is output from the BPF 145 and the fourth BS intermediate frequency signal is output from the BPF 150. Is output. The third BS intermediate frequency signal output from the BPF 145 is input to the mixer 146, and the fourth BS intermediate frequency signal output from the BPF 150 is input to the mixer 151. Similarly to the down-converter unit 120 of the head end 101, the mixer 146 receives a seventh reference signal output from the local oscillator 153 having an oscillation frequency of 1437 MHz via an amplifier 154 and a BPF 155 (passable frequency: 1437 MHz). The eighth reference signal input from the local oscillator 156 having an oscillation frequency of 1690 MHz is input to the mixer 151 via the amplifier 157 and the BPF 158 (passable frequency: 1690 MHz).
[0045]
Then, the mixer 146 converts the frequency of the third BS intermediate frequency signal of 330 to 407 MHz using the seventh reference signal of 1437 MHz and inputs it to the BPF 147 (passable frequency band: 1030 to 1107 MHz). For this reason, the BPF 147 outputs 1030 to 1107 MHz BS reception signals corresponding to the first and third channels. Similarly, the mixer 151 performs frequency conversion on the fourth BS intermediate frequency signal of 253 to 330 MHz using the eighth reference signal of 1690 MHz, and inputs it to the BPF 152 (passable frequency band: 1260 to 1337 MHz), and from the BPF 152, BS reception signals of 1260 to 1337 MHz corresponding to the 13th and 15th channels are output. The BS received signals of 1030 to 1107 MHz corresponding to the 1st and 3rd channels and the BS received signals of 1260 to 1337 MHz corresponding to the 13th and 15th channels are mixed by the mixer 148, and then a high pass filter (hereinafter referred to as “HPF”). It is output from the output terminal Tout2 via 149 (passable frequency band: 1030 MHz or more).
[0046]
As in the first embodiment, an output signal from the output terminal Tout1 is directly input to a television receiver (not shown), and an output signal from the output terminal Tout2, that is, a BS reception signal, is a BS tuner (see FIG. (Not shown) to the television receiver.
[0047]
In this embodiment, BPF 122 and BPF 126 correspond to the BS received signal extraction means, and local oscillator 129, amplifier 130, BPF 131, local oscillator 132, amplifier 133, and BPF 134 correspond to the first reference signal generation means. The mixer 123, the BPF 124, the mixer 127, and the BPF 128 correspond to the first frequency conversion means, the BPFs 145 and 150 correspond to the BS intermediate frequency signal extraction means, and the mixer 13 and the mixer 125 transmit the transmission. Corresponding to the signal mixing means, the local oscillator 153, the amplifier 154, the BPF 155, the local oscillator 156, the amplifier 157, and the BPF 158 correspond to the aforementioned second reference signal generating means, and the mixer 146, the BPF 147, the mixer 151, and the BPF 152 are the aforementioned first reference signal generating means. The mixer 148 corresponds to the two-frequency conversion means, and the BS It corresponds to signal the signal mixing means.
[0048]
Then, the effect of the CATV system of a present Example is demonstrated.
According to the CATV system of this embodiment, the BS received signal of 1030 to 1107 MHz corresponding to channels 1 and 3 is 330 to 407 MHz using the first reference signal of 1437 MHz in the down converter 120 of the head end 1. The 1260 to 1337 MHz BS received signal corresponding to the 13th and 15th channels is frequency converted to the 4th BS intermediate frequency signal of 253 to 330 MHz using the first reference signal of 1690 MHz. The Since the upconverter 140 returns the third BS intermediate frequency signal and the fourth BS intermediate frequency signal to the original BS received signal, the channel arrangement of the BS received signal after frequency conversion in the upconverter 140 is the original BS received signal. It is the same as the channel arrangement. For this reason, the subscriber side terminal can correctly receive the BS broadcast using the existing BS tuner.
[0049]
Although two embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and it is needless to say that the present invention may be implemented in various modes.
For example, in the first embodiment, since the pilot signal frequency is 451.25 MHz, BS intermediate frequency signals for 6 channels cannot be accommodated in the intermediate band. When the frequency is changed to, for example, 80 MHz, BS intermediate frequency signals for 6 channels can be stored. Therefore, it is possible to secure a wider vacant frequency band for terrestrial digital broadcast signals. On the contrary, if there is no problem in the transmission of the terrestrial digital broadcast signal, the number of channels contained in the intermediate band may be 1 to 4.
[0050]
In the first embodiment, the pilot signal generator generates a 451.25 MHz pilot signal and the local oscillator 29 generates the 446 MHz second reference signal. However, the local oscillator 29 generates the pilot signal. The second reference signal may be used as a pilot signal. In addition, in the case of such a configuration, the up converter 40 uses the pilot signal as it is as the fourth reference signal instead of generating the fourth reference signal by the local oscillator 53, and uses the pilot circuit by the multiplication circuit 56. The third reference signal may be obtained by multiplying the signal by two.
[0051]
In the first and second embodiments, the up-converter 40 and the up-converter 140 are individually installed in the subscriber premises, but various transmission devices (for example, boosters, branch / distributors) in each subscriber premises. It may be built in.
In the first embodiment and the second embodiment, the upconverter 40 and the upconverter 140 are provided in each subscriber's house, but the extension is performed on the transmission line 6, for example, as shown in FIG. An up converter 59 may be installed between the amplifier 3 and the tap-off 4. In the first and second embodiments, the terrestrial broadcast signal is output from the output terminal Tout1, and the BS reception signal is output from the output terminal Tout2. However, FIG. As shown, when the upconverter 59 is installed on the transmission line 6, a mixer is installed in front of the LPF 42 and the HPF 49 so that the terrestrial broadcast signal, the BS received signal, and the output are output from one output terminal. Need to be configured (not shown).
[0052]
When the up-converter 59 is installed between the extension amplifier 3 and the tap-off 4 in this way, the number of up-converters is significantly larger than when an up-converter is provided for each subscriber house. Less and very economical. However, it is necessary to transmit a signal from the up-converter 59 to each subscriber's house through a transmission line capable of transmitting a BS reception signal, that is, a transmission line capable of transmitting up to about 1340 MHz.
[0053]
Also, as shown in FIG. 8 (a), it is not installed on the transmission line 6 alone, but is built in a branching device, branching amplifier, distributor, distribution amplifier, extension amplifier, tap-off, etc. installed on the transmission line 6. May be. FIG. 8B is a block diagram of the CATV system when the up-converter is built in the extension amplifier, and FIG. 9 is a block diagram for explaining the configuration of the up-converter built-in extension amplifier shown in FIG. FIG. The extension converter 60 with a built-in up converter is a modification of the up converter 40 of the first embodiment.
[0054]
As shown in FIG. 9, in the extension converter 60 with built-in up-converter, the transmission signal input from the input terminal Tin receives an equivalent amplifier 61, an attenuator 62, an amplifier 63, an automatic gain controller 64, an amplifier 65, a branching device 66, LPF 67 (passable frequency band: 0 to 770 MHz) is output from the output terminal Tout via the mixer 68. The equivalent amplifier 61, the attenuator 62, and the automatic gain controller 64 are well known and will not be described.
[0055]
The transmission signal branched by the branching device 66 is divided into two by the distributor 69 and input to the BPFs 70 and 74, respectively. Since the passable frequency band of the BPF 70 is 584 to 699 MHz and the passable frequency band of the BPF 74 is 253 to 445 MHz, the second BS intermediate frequency signal is output from the BPF 70, and the first BS intermediate frequency signal is output from the BPF 74. The second BS intermediate frequency signal is input to the mixer 71, and the first BS intermediate frequency signal is input to the mixer 75. A fourth reference signal output from the local oscillator 77 having an oscillation frequency of 446 MHz is input to the mixer 71 via an amplifier 78 and a BPF 79 (passable frequency: 446 MHz), and a fourth reference signal is input to the mixer 75. Is multiplied by 2 in the multiplier circuit 80, and the third reference signal is input via the BPF 81 (passable frequency: 892 MHz).
[0056]
Then, the mixer 71 frequency-converts the second BS intermediate frequency signal using the fourth reference signal, and inputs it to the BPF 72 (passable frequency band: 1030 to 1145 MHz). Then, the BS reception signal of 1030 to 1145 MHz corresponding to the 1, 3, and 5 channels is output from the BPF 72. Similarly, the mixer 75 frequency-converts the first BS intermediate frequency signal using the third reference signal and inputs the converted signal to the BPF 76 (passable frequency: 1145 to 1337 MHz). From the BPF 76, 7, 9, 11, 13, BS reception signals of 1145 to 1337 MHz corresponding to 15 channels are output. The BS reception signals of 1030 to 1145 MHz corresponding to the 1, 3, and 5 channels and the BS reception signals of 1145 to 1337 MHz corresponding to the 7, 9, 11, 13, and 15 channels are mixed by the mixer 73, and the amplifier 82 is mixed. , An automatic gain controller 83, an amplifier 84, an HPF 85 (passable frequency band: 1030 MHz or more), and a mixer 68, and output from an output terminal Tout.
[0057]
When the up-converter is built in the extension amplifier in this way, the number of up-converters is significantly reduced compared to the case where the up-converter is provided for each subscriber's house, which is very economical. . However, it is necessary to transmit signals from the extension amplifier 60 with built-in upconverter to each subscriber's house through a transmission line capable of transmitting the BS reception signal, that is, a transmission line capable of transmitting up to about 1340 MHz.
[Brief description of the drawings]
FIG. 1 is a block diagram for explaining an overall configuration of a CATV system according to a first embodiment.
FIG. 2 is a block diagram for explaining a configuration of a head end according to the first embodiment;
FIG. 3 is a frequency distribution diagram of a BS reception signal, a first BS intermediate frequency signal, and a second BS intermediate frequency signal according to the first embodiment.
FIG. 4 is a block diagram for explaining a configuration of an up-converter according to the first embodiment.
FIG. 5 is a block diagram for explaining a configuration of a head end according to a second embodiment;
FIG. 6 is a frequency distribution diagram of a BS reception signal, a third BS intermediate frequency signal, and a fourth BS intermediate frequency signal according to the second embodiment.
FIG. 7 is a block diagram for explaining a configuration of an up-converter according to a second embodiment.
FIG. 8 is a block diagram for explaining an overall configuration of a CATV system according to a modified example.
FIG. 9 is a block diagram for explaining a configuration of a modified example of an extension amplifier with a built-in up-converter.
FIG. 10 is a frequency distribution diagram of a conventional BS reception signal and BS intermediate frequency signal.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1,101 ... Head end 2 ... Branch amplifier 3 ... Extension amplifier 4 ... Tap-off 5 ... Guard 6 ... Transmission line 11 ... Terrestrial broadcast receiving antenna 12, 15 ... Reception amplifier 13, 25, 48, 68, 73, 125, 148 ... Mixer 14 ... BS antenna 20, 120 ... Downconverter unit 21, 44, 69, 121, 144 ... Distributor 22, 24, 26, 28, 31, 33, 45, 47, 50, 52, 55, 57 , 70, 72, 74, 76, 79, 81, 122, 124, 126, 128, 131, 134, 145, 147, 150, 152, 155, 158... BPF (band pass filter) 23, 27, 46, 51 , 71, 75, 123, 127, 146, 151... Mixers 29, 53, 77, 129, 132, 153, 156... Local oscillators 30, 43,. 4,63,65,78,82,84,130,133,143,154,157 ... amplifier 32,56,80 ... multiplier circuit 40, 140 ... up converter
41, 66, 141 ... branching device 42, 67, 142 ... LPF (low pass filter) 49, 85, 149 ... HPF (high pass filter) 59 ... up converter 60 ... extension amplifier with built-in up converter 61 ... equivalent amplifier
62 ... Attenuator 64, 83 ... Automatic gain controller Tin ... Input terminal Tout, Tout1, Tout2 ... Output terminal.

Claims (11)

Receives radio waves transmitted from broadcast satellites, and receives the received radio waves in a predetermined frequency band lower than the original frequency and higher than the broadcast frequencies of the VHF band and UHF band assigned to the terrestrial television broadcast. A BS antenna that converts the frequency into a signal and outputs the signal is provided at the head end, and a BS reception signal from the BS antenna and other TV broadcast signals are transmitted to a plurality of subscriber terminals via a common transmission line. In the CATV system that
Two or more groups of BS reception signals for one or a plurality of continuous channels are extracted from the BS reception signals from the BS antenna on the head end side, and the BS reception signals of each group are extracted from the television broadcast signals. Down-converted into a BS intermediate frequency signal of a predetermined frequency band that does not overlap with the television broadcast signal in the frequency region from the VHF band to the UHF band allocated for use, and is sent out on the transmission line A converter,
The BS intermediate frequency signal of each group transmitted from the head end on the transmission line on each subscriber side is frequency-converted into a BS reception signal of the original frequency band output from the BS antenna, respectively. A CATV system comprising an up-converter that mixes and transmits the frequency-converted BS reception signal to a subscriber-side terminal. The down converter is
The BS received signals of the first group extracted from the BS received signals from the BS antenna are assigned to the frequency band assigned to the VHF terrestrial television broadcast and the UHF terrestrial television broadcast. Frequency conversion to BS intermediate frequency signal in the intermediate band between the frequency band,
The second group of BS received signals extracted from the BS received signals from the BS antenna is frequency-converted to a BS intermediate frequency signal in a frequency band assigned to the UHF band terrestrial television broadcast. The CATV system according to claim 1. The down converter allocates the BS reception signal of the first group and the BS reception signal of the second group extracted from the BS reception signals from the BS antenna, respectively, to the terrestrial television broadcasting in the VHF band. The frequency conversion is performed in an intermediate band between a frequency band assigned to a terrestrial television broadcast in the UHF band and a BS intermediate frequency signal having a different frequency from each other. CATV system. The CATV system according to any one of claims 1 to 3, wherein the down converter is provided on the head end side.
BS received signal extraction means for extracting two or more groups of BS received signals for one or a plurality of continuous channels from the BS received signals from the BS antenna;
The BS received signal of each group extracted by the BS received signal extracting means overlaps the television broadcast signal in the frequency region from the VHF band to the UHF band allocated for the television broadcast signal, respectively. A plurality of first frequency conversion means for converting the frequency into a BS intermediate frequency signal of a predetermined frequency band that does not occur;
Transmission signal mixing means for mixing a plurality of BS intermediate frequency signals frequency-converted by the plurality of first frequency conversion means and other television broadcast signals inputted from the outside and sending them on the transmission line;
First reference signal generation means for generating a plurality of reference signals necessary for the plurality of first frequency conversion means to frequency-convert the BS reception signals of each group into BS intermediate frequency signals of a predetermined frequency band;
A down converter characterized by comprising: The first reference signal generating means includes
The plurality of first frequency conversion means includes a plurality of oscillators that respectively generate a plurality of reference signals necessary for frequency conversion of the BS reception signals of each group into BS intermediate frequency signals of a predetermined frequency band. The down converter according to claim 4. The first reference signal generating means includes
A first oscillator for generating a reference signal necessary for frequency-converting a BS received signal of a specific group into a BS intermediate frequency signal of a predetermined frequency band, one of the plurality of frequency converting means;
By multiplying or dividing the reference signal generated by the oscillator, another frequency converting means generates a reference signal necessary for frequency conversion of BS received signals of other groups in a predetermined frequency band. A frequency dividing means;
The down converter according to claim 4, further comprising: The CATV system according to any one of claims 1 to 3, wherein the up-converter is provided on a transmission line on each subscriber side,
BS intermediate frequency signal extracting means for extracting the BS intermediate frequency signal of each group from the transmission signal from the head end;
A plurality of second frequency converting means for frequency-converting the BS intermediate frequency signals of each group extracted by the BS intermediate frequency signal extracting means into BS received signals of the original frequency band output from the BS antenna; ,
BS reception signal mixing means for mixing a plurality of BS reception signals frequency-converted by the plurality of second frequency conversion means and sending them to the subscriber side terminal;
As a reference signal used by the plurality of second frequency conversion means to frequency-convert the BS intermediate frequency signal of each group into the original BS reception signal, the head end side down converter converts the BS reception signal of each group. Second reference signal generation means for generating a reference signal having the same frequency as the reference signal used for frequency conversion to the BS intermediate frequency signal;
An upconverter characterized by comprising: The second reference signal generating means includes
The plurality of second frequency conversion means includes a plurality of oscillators that respectively generate a plurality of reference signals necessary for frequency conversion of the BS intermediate frequency signals of each group to the original BS reception signals. The up converter according to claim 7. The second reference signal generating means includes
A second oscillator for generating a reference signal required for frequency conversion of a specific group of BS intermediate frequency signals to an original BS received signal, wherein one of the plurality of second frequency converting means;
By multiplying or dividing the reference signal generated by the oscillator, another frequency converting means generates a reference signal necessary for frequency conversion of the BS intermediate frequency signal of another group to the original BS received signal. A multiplication / division means;
8. The upconverter according to claim 7, further comprising: The upconverter according to any one of claims 7 to 9, wherein the upconverter is installed alone on the transmission line. 10. The up-converter according to claim 7, wherein the up-converter is configured to be installed on the transmission line as one of transmission devices that transmit the transmission signal to a terminal side. converter.

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