JP3209232U - Filter device and retransmission system - Google Patents

Abstract

[PROBLEMS] To provide a filter device capable of improving the convenience of a provider who performs retransmission and realizing low cost regarding retransmission of 4K / 8K satellite broadcasting. A filter device 3 includes a first filter unit 301 that extracts a signal in a frequency band of BS right-handed broadcasting from a high-frequency input signal input to an input terminal T1, and the high-frequency input signal input to the input terminal T1. A second filter unit 302 for extracting a signal in the frequency band of CS right-handed broadcasting from the third filter unit 303 for extracting a signal in the frequency band of BS left-handed broadcasting from the high-frequency input signal input to the input terminal T1, A fourth filter unit 304 that extracts a signal in a frequency band of CS left-handed broadcasting from the high-frequency input signal input to the input terminal T1, a first filter unit 301, a filter unit 302, a third filter unit 303, Each output can be switched on and off with each of the fourth filter units 304 as a minimum unit. [Selection] Figure 3

Description

  The present invention relates to a filter device and a retransmission system including the filter device.

  Conventionally, a base station owned by a cable television company that receives a digital terrestrial broadcast signal or a satellite broadcast signal and retransmits the broadcast signal to a subscriber via a coaxial cable or an optical cable has a retransmission system. Installed. For example, Patent Document 1 discloses a retransmission system called a head end that receives a satellite broadcast signal and transmits it via a cable transmission path.

  Currently, 2K broadcast, which is full high-definition resolution, is performed in satellite broadcasting, and BS right-handed broadcasting and 110-degree CS right-handed broadcasting exist in 2K satellite broadcasting. The frequency band of BS right-handed broadcasting is 1032 MHz to 1489 MHz, and the frequency band of 110-degree CS right-handed broadcasting is 1595 MHz to 2071 MHz. In addition, as a retransmission method in cable television broadcasting, there is a so-called pass-through method in which a broadcast signal included in a received broadcast carrier wave is retransmitted as it is without being subjected to modulation processing. In a pass-through retransmission system, a satellite broadcast signal is received using an antenna capable of receiving a 2K satellite broadcast signal, and is retransmitted as it is without being subjected to modulation processing.

  The antenna receives broadcast signals of BS right-handed broadcasting and 110-degree CS right-handed broadcasting. However, for 110 degree CS right-handed broadcasts, there were many cases in which it was not possible to obtain a retransmission agreement permitting retransmission. In such a case, the cable TV operator uses a filter in the re-transmission system to transmit the 110-degree CS right-handed broadcast out of the BS right-handed broadcast and 110-degree CS right-handed broadcast signals received by the antenna. The signal in the frequency band was cut, and the broadcast signal of BS right-handed broadcasting was extracted and retransmitted.

JP-A-2005-73034

  Here, in 2018, practical broadcasting of 4K or 8K satellite broadcasting having a resolution higher than 2K resolution is scheduled. 4K or 8K satellite broadcasting is scheduled to be broadcast by BS left-handed broadcasting and 110 degree CS left-handed broadcasting.

  Corresponding to the scheduled start of 4K or 8K satellite broadcasting, the cable TV operator uses the antenna that can receive the conventional 2K satellite broadcasting signal in the re-transmission system as well as the satellite broadcasting signal of 4K and 8K as well as 2K. It is assumed that modification will be made to replace the antenna with a receivable antenna. In this case, in addition to BS right-handed broadcasting and 110-degree CS right-handed broadcasting, broadcast signals of BS left-handed broadcasting and 110-degree CS left-handed broadcasting can be received by the antenna. However, regarding retransmission of 110-degree CS left-handed broadcasting, It is expected that there are many cases where consent to resend cannot be obtained. Therefore, for 110 degree CS left-handed broadcasting, it is required to set a retransmission system so as not to perform retransmission.

  In addition, even if the resent consent cannot be obtained, it is assumed that the resend consent is obtained after that, and if this is done, it is necessary to change the setting for not retransmitting the 110-degree CS left-handed broadcast so that it can be retransmitted. May occur.

  In addition to the above situation, it is expected that it will be necessary to cope with changes in various situations, such as a change in the situation of whether or not consent to re-transmission of BS left-handed broadcasting is obtained.

  In view of the above situation, the present invention can improve the convenience of operators who perform retransmission and realize low cost for retransmission of 4K / 8K satellite broadcasts for which practical broadcasting is scheduled in the future. An object of the present invention is to provide a filter device and a retransmission system including the same.

In order to achieve the above object, a filter device according to an aspect of the present invention includes:
An input terminal;
The frequency of BS right-handed broadcasting from a high-frequency input signal including BS right-handed circularly polarized signal, CS right-handed circularly polarized signal, BS left-handed circularly polarized signal, and CS left-handed circularly polarized signal input to the input terminal. A first filter unit for extracting a band signal;
A second filter unit that extracts a signal in a frequency band of CS right-handed broadcasting from the high-frequency input signal input to the input terminal;
A third filter unit for extracting a signal in a frequency band of BS left-handed broadcasting from the high-frequency input signal input to the input terminal;
A fourth filter unit that extracts a signal in a frequency band of CS left-handed broadcasting from the high-frequency input signal input to the input terminal;
An output terminal for outputting a high-frequency output signal generated by combining the output signals of the first filter unit, the second filter unit, the third filter unit, and the fourth filter unit;
The first filter unit, the second filter unit, the third filter unit, and the fourth filter unit are each configured as a minimum unit, and each output can be switched on and off (first configuration).

In the first configuration,
The first filter part is
A first frequency converter that converts a high frequency signal to an intermediate frequency signal;
A first bandpass filter or a lowpass filter;
A second frequency converter that converts the frequency of the intermediate frequency signal input from the first frequency converter through the first band pass filter or the low pass filter into a high frequency signal;
The second filter part is
A third frequency converter that converts a high-frequency signal into an intermediate-frequency signal;
A second bandpass filter;
A fourth frequency converter that converts the frequency of the intermediate frequency signal input from the third frequency converter through the second bandpass filter into a high-frequency signal;
The third filter part is
A fifth frequency converter for converting a high frequency signal to an intermediate frequency signal;
The third bandpass filter;
A sixth frequency converter that converts the frequency of the intermediate frequency signal input from the fifth frequency converter through the third bandpass filter into a high-frequency signal;
The fourth filter part is
A seventh frequency converter for converting a high-frequency signal to an intermediate-frequency signal;
A fourth bandpass filter or a highpass filter;
And an eighth frequency converter that converts the intermediate frequency signal input from the seventh frequency converter through the fourth bandpass filter or the highpass filter into a high frequency signal. 2 configuration).

  Further, in the first or second configuration, the input terminal and the output terminal at which each of the first filter unit, the second filter unit, the third filter unit, and the fourth filter unit is disposed. It is good also as providing the switch arrange | positioned at each signal path | route between them (3rd structure).

In addition, a retransmission system according to one aspect of the present invention includes:
An antenna capable of receiving BS right-handed broadcasting, CS right-handed broadcasting, BS left-handed broadcasting, and CS left-handed broadcasting;
A filter device having any one of the above-described configurations to which a first high-frequency input signal based on a high-frequency broadcast signal output from the antenna is input;
A first transmitter that transmits a first high-frequency output signal output from the filter device;
(Fourth configuration).

In the fourth configuration, a distributor for distributing a signal based on the high-frequency broadcast signal to the first high-frequency input signal and the second high-frequency input signal;
A filter unit for extracting a signal in the frequency band of the BS right-handed broadcasting from the input second high-frequency input signal;
It is good also as providing further the 2nd transmission part which transmits the signal of the frequency band of the said BS right-handed broadcasting output from the said filter part (5th structure).

  According to the present invention, regarding the retransmission of 4K / 8K satellite broadcasts for which practical broadcasts are scheduled in the future, it is possible to improve the convenience of operators who perform retransmissions and to reduce costs.

It is a block diagram which shows the whole structure of the retransmission system which concerns on one Embodiment of this invention. It is a figure which shows the frequency band of the satellite broadcast signal which can be received with the antenna in one Embodiment of this invention. It is a figure which shows the state which cut | disconnected the signal of each frequency band of CS right-handed broadcasting and CS left-handed broadcasting from the satellite broadcast signal shown to FIG. 2A. It is a figure which shows the state which cut the signal of each frequency band of CS right-handed broadcasting, BS left-handed broadcasting, and CS left-handed broadcasting from the satellite broadcast signal shown to FIG. 2A. It is a figure which shows the state which cut the signal of the frequency band of CS right-handed broadcasting from the satellite broadcast signal shown to FIG. 2A. It is a figure which shows the structure of the filter apparatus which concerns on one Embodiment of this invention. It is a figure which shows the structure which concerns on the modification containing the filter apparatus which concerns on one Embodiment of this invention.

  An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an overall configuration of a retransmission system according to an embodiment of the present invention.

  The re-transmission system 15 shown in FIG. 1 receives satellite broadcast, terrestrial digital broadcast, and FM broadcast signals, and retransmits them directly to the subscriber side via a transmission line using an optical cable without performing modulation processing. This is a so-called through-pass system. The re-transmission system 15 supports re-transmission of 2K, 4K, and 8K satellite broadcasts, as will be described later.

  The re-transmission system 15 is installed in a base station owned by a cable television operator that performs a re-transmission service. As shown in FIG. 1, the retransmission system 15 includes an antenna ANT1, a booster 1, a distributor 2, a filter device 3, a mixer 4, an optical transmitter 5, an optical amplifier 6, and a low-pass filter 7. A TV broadcast signal processing unit 8, an audio signal processing unit 9, a mixer 10, a distributor 11, a mixer 12, an optical transmitter 13, and an optical amplifier 14.

  The antenna ANT1 can receive a BS right-hand circularly polarized signal and a 110-degree CS right-hand circularly polarized signal that are 2K satellite broadcast signals, and a BS left-hand circularly polarized signal that is a 4K or 8K satellite broadcast signal. 110 degree CS left-handed circularly polarized signal can be received.

  The frequency band of the BS right-hand circularly polarized signal is 1032 MHz or more and 1489 MHz or less (hereinafter, the first frequency band). The frequency band of the 110-degree CS right-hand circularly polarized signal is 1595 MHz or more and 2071 MHz (hereinafter, the second frequency band). The frequency band of the BS left-hand circularly polarized signal is 2224 MHz or more and 2643 MHz or less (hereinafter, the third frequency band). The frequency band of the 110-degree CS left circularly polarized signal is 2748 MHz or more and 3224 MHz or less (fourth frequency band). In addition, 4K and 8K broadcasts are scheduled to be performed on some channels of BS right-handed broadcasting. The antenna ANT1 outputs a high-frequency broadcast signal RF composed of the above satellite broadcast signals.

  The booster 1 amplifies the high frequency broadcast signal RF output from the antenna ANT1. The distributor 2 distributes the amplified high-frequency broadcast signal output from the booster 1 to the high-frequency input signal RFIN1 and the high-frequency input signal RFIN2. A high frequency input signal RFIN 1 output from one output terminal of the distributor 2 is input to the filter device 3. A high frequency input signal RFIN 2 output from the other output terminal of the distributor 2 is input to the low pass filter 7.

  The filter device (block filter) 3 includes a BS right-handed circularly polarized signal, a 110-degree CS right-handed circularly-polarized signal, a BS left-handed circularly-polarized signal, and a 110-degree CS left-handed circularly polarized wave in the input high-frequency input signal RFIN1. By selecting ON / OFF of the signal output for each frequency band of the wave signal, a high frequency output signal RFOUT1 (first high frequency output signal) is generated and output.

  As shown in FIG. 2A, the high-frequency output signal RFIN1 input to the filter device 3 includes signals in each band from the first frequency band to the fourth frequency band. Here, for example, if the cable television operator has not obtained a re-transmission agreement of 110 degree CS right-handed broadcasting and 110 degree CS left-handed broadcasting, the filter device 3 will receive the 110 degree CS right-handed circularly polarized signal. And 110 degree CS left-handed circularly polarized signal are set to cut signals in each frequency band, and the output high-frequency output signal RFOUT1 includes a BS right-handed circularly polarized signal and a BS left-handed circularly polarized signal. It will be. That is, as shown in FIG. 2B, each signal in the second frequency band and the fourth frequency band is cut.

  The filter device 3 having such a function realizes low cost by a specific configuration described in detail later.

  On the other hand, the low-pass filter 7 cuts signals of each frequency band of the 110-degree CS right-hand circularly polarized signal, the BS left-hand circularly-polarized signal, and the 110-degree CS left-hand circularly-polarized signal from the input high-frequency input signal RHIN2. Then, a signal in a relatively low frequency band of the BS right-hand circularly polarized signal is extracted and output as a high-frequency output signal RFOUT2. That is, as shown in FIG. 2C, each signal in the second to fourth frequency bands is cut.

  The TV broadcast signal processing unit 8 performs predetermined processing on the input terrestrial digital broadcast signal SIN1. The frequency band of the terrestrial digital broadcast signal SIN1 is 90 MHz or more and 770 MHz or less. The TV broadcast signal processing unit 8 includes, for example, a plurality of OFDM signal processors corresponding to each channel of terrestrial digital broadcasting, and removes unnecessary signals and adjusts the output level. The audio signal processing unit 9 performs predetermined processing on the input FM broadcast audio signal SIN2. The frequency band of the FM broadcast audio signal SIN2 is 70 MHz or more and 90 MHz or less.

  The mixer 10 mixes the signal output from the TV broadcast signal processing unit 8 and the signal output from the audio signal processing unit 9. The frequency band of the signal after mixing by the mixer 10 is 70 MHz to 770 MHz. The distributor 11 distributes the mixed signal output from the mixer 10 into the output signal SOUT1 and the output signal SOUT2. The output signal SOUT1 is input to the mixer 4. The output signal SOUT2 is input to the mixer 12.

  The mixer 4 mixes the high-frequency output signal RFOUT1 output from the filter device 3 and the output signal SOUT1 output from the distributor 11. The optical transmitter 5 converts the mixed signal output from the mixer 4 from an electric signal to an optical signal.

  At least one optical cable CB1 is connected to the output side of the optical amplifier 6. The optical amplifier 6 amplifies the optical signal output from the optical transmitter 5 and branches the optical signal according to the number of optical cables CB1. The optical transmitter 5 and the optical amplifier 6 constitute an example of the first transmission unit.

  The optical signal branched by the optical amplifier 6 and transmitted through the transmission line by the optical cable CB1 is transmitted to the terminal device on the subscriber side. The transmitted optical signal is converted into an electrical signal by a terminal device and sent to a television set installed in a dwelling unit or the like. This makes it possible to view video and audio by satellite broadcasting, terrestrial digital broadcasting, and FM broadcasting with a television device or the like.

  For example, as described above, the 110-degree CS broadcast retransmission agreement is not obtained, and the high-frequency output signal RFOUT1 output from the filter device 3 includes the BS right-hand circularly polarized signal and the BS left-hand circularly-polarized signal. In this case, it becomes possible to view 2K, 4K, and 8K satellite broadcast images by BS broadcasting with a television apparatus or the like.

  On the other hand, the mixer 12 mixes the high-frequency output signal RFOUT2 (second high-frequency output signal) output from the low-pass filter 7 with the output signal SOUT2 output from the distributor 11. The optical transmitter 13 converts the mixed signal output from the mixer 12 from an electric signal to an optical signal.

  At least one optical cable CB2 is connected to the output side of the optical amplifier. The optical amplifier 14 amplifies the optical signal output from the optical transmitter 13 and branches the optical signal according to the number of optical cables CB2. The optical transmitter 13 and the optical amplifier 14 constitute an example of the second transmission unit.

  The optical signal branched by the optical amplifier 14 and transmitted through the transmission line by the optical cable CB2 is transmitted to the terminal device on the subscriber side. The transmitted optical signal is converted into an electrical signal by a terminal device and sent to a television set installed in a dwelling unit or the like. This makes it possible to view video and audio by satellite broadcasting, terrestrial digital broadcasting, and FM broadcasting with a television device or the like. In particular, since the frequency band of the BS right-hand circularly polarized signal is extracted by the low-pass filter 7, a 2K satellite broadcast image can be viewed.

  Here, in the configuration of the retransmission system 15, the low-pass filter 7, the TV broadcast signal processing unit 8, the audio signal processing unit 9, the mixer 10, the mixer 12, the optical transmitter 13, and the optical amplifier 14 are included in the retransmission system. The existing head end is constructed before building 15.

  An antenna capable of receiving a BS right-hand circularly polarized signal and a 110-degree CS right-hand circularly polarized signal is connected to the existing head end. Since the cable television business operator has not obtained the 110-degree CS broadcast re-transmission agreement, a low-pass filter 7 is provided at the existing head end. The BS right-hand circularly polarized signal is extracted by cutting the 110-degree CS right-hand circularly polarized signal by the low-pass filter 7. As a result, the 2K BS satellite broadcast can be retransmitted by the optical transmitter 13 and the optical amplifier 14.

  Thereafter, in order to cope with retransmission of 4K and 8K satellite broadcasts, the existing antenna is replaced with the antenna ANT1, and the booster 1, the distributor 2, the filter device 3, the mixer 4, the optical transmitter 5, and the optical amplifier 6 and the re-transmission system 15 are constructed by performing a modification to newly install the distributor 11. As a result, it is possible to add a new function for retransmitting 4K and 8K satellite broadcasts while maintaining the function for retransmitting 2K satellite broadcasts by the existing head end.

  When a subscriber who has received 2K satellite broadcast re-transmission from the existing head end changes the terminal device to a device compatible with 4K and 8K satellite broadcast re-transmission and desires to receive the re-transmission Can be handled by changing the connection of the optical cable corresponding to the subscriber from the optical amplifier 14 to the optical amplifier 6. In this way, it becomes easy for cable television operators to respond to subscribers' requirements, and it becomes possible to set a new fee system in response to retransmission of 4K and 8K satellite broadcasts. .

  Note that some cable television operators may not have an existing head end. In this case, the distributor 2, the low-pass filter 7, the distributor 11, the mixer 12, and the optical component of the configuration shown in FIG. A re-transmission system may be newly constructed from a configuration other than the transmitter 13 and the optical amplifier 14.

  Next, a specific configuration of the filter device 3 will be described. FIG. 3 is a diagram illustrating a configuration example of the filter device 3.

  As shown in FIG. 3, the filter device 3 includes a first filter unit 301, a second filter unit 302, a third filter unit 303, a fourth filter unit 304, switches SW1 to SW4, and CPUs 31 to 34. , Termination resistors R1 to R4, an input terminal T1, and an output terminal T2.

  The first filter unit 301 includes an amplifier 301A, a mixer 301B, a local oscillator 301C, an amplifier 301D, a bandpass filter 301E, an amplifier 301F, a mixer 301G, and an amplifier 301H. The input terminal T1 is commonly connected to one end of the resistor R1 and one end of the switch SW1. The other end of the resistor R1 is connected to the ground terminal. The other end of the switch SW1 is connected to the input end of the amplifier 301A. The CPU 31 controls the first filter unit 301 and controls on / off of the switch SW1.

  When the switch SW1 is turned on, the high frequency input signal RFIN1 input to the input terminal T1 is input to the amplifier 301A via the switch SW1, and is amplified by the amplifier 301A. The high frequency signal amplified by the amplifier 301A is frequency-converted (down-converted) to an intermediate frequency signal by the mixer 301B and the local oscillator 301C, and is amplified by the amplifier 301D. The mixer 301B and the local oscillator 301C constitute an example of a first frequency converter. From the intermediate frequency signal amplified by the amplifier 301D, a signal other than the band obtained by frequency-converting the first frequency band is cut by the bandpass filter 301E, and the signal in the band is extracted.

  The signal extracted by the band pass filter 301E is amplified by the amplifier 301F. The signal amplified by the amplifier 301F is frequency-converted (up-converted) into a high-frequency signal by the mixer 301G and the local oscillator 301C, and is amplified by the amplifier 301H. The mixer 301G and the local oscillator 301C constitute an example of a second frequency converter.

  Accordingly, if the switch SW1 is on, the first filter unit 301 extracts and outputs a signal in the first frequency band from the high-frequency input signal RFIN1 (output on state). When the switch SW1 is turned off, the input terminal T1 is terminated by the resistor R1, and the output of the first filter unit 301 is turned off.

  In the first filter unit 301, the high-frequency input signal RFIN1 is once converted into an intermediate frequency signal, and then a signal in a predetermined frequency band is extracted by the band-pass filter 301E. Can be extracted. The same applies to the second filter unit 302 to the fourth filter unit 304 described below.

  In the first filter unit 301, a low pass filter may be provided instead of the band pass filter 301E.

  The second filter unit 302 includes an amplifier 302A, a mixer 302B, a local oscillator 302C, an amplifier 302D, a bandpass filter 302E, an amplifier 302F, a mixer 302G, and an amplifier 302H. The input terminal T1 is commonly connected to one end of the resistor R2 and one end of the switch SW2. The other end of the resistor R2 is connected to the ground terminal. The other end of the switch SW2 is connected to the input end of the amplifier 302A. The CPU 32 controls the second filter unit 302 and controls on / off of the switch SW2.

  When the switch SW2 is turned on, the high frequency input signal RFIN1 input to the input terminal T1 is input to the amplifier 302A via the switch SW2 and amplified by the amplifier 302A. The high frequency signal amplified by the amplifier 302A is frequency-converted (down-converted) to an intermediate frequency signal by the mixer 302B and the local oscillator 302C, and is amplified by the amplifier 302D. The mixer 302B and the local oscillator 302C constitute an example of a third frequency converter. From the intermediate frequency signal amplified by the amplifier 302D, a signal other than the band obtained by frequency conversion of the second frequency band is cut by the band pass filter 302E, and the signal in the band is extracted.

  The signal extracted by the band pass filter 302E is amplified by the amplifier 302F. The signal amplified by the amplifier 302F is frequency-converted (up-converted) into a high-frequency signal by the mixer 302G and the local oscillator 302C, and amplified by the amplifier 302H. The mixer 302G and the local oscillator 302C constitute an example of a fourth frequency converter.

  Thus, if the switch SW2 is on, the second filter unit 302 extracts and outputs a signal in the second frequency band from the high-frequency input signal RFIN1 (output on state). When the switch SW2 is turned off, the input terminal T1 is terminated by the resistor R2, and the output of the second filter unit 302 is turned off.

  The third filter unit 303 includes an amplifier 303A, a mixer 303B, a local oscillator 303C, an amplifier 303D, a bandpass filter 303E, an amplifier 303F, a mixer 303G, and an amplifier 303H. The input terminal T1 is commonly connected to one end of the resistor R3 and one end of the switch SW3. The other end of the resistor R3 is connected to the ground terminal. The other end of the switch SW3 is connected to the input end of the amplifier 303A. The CPU 33 controls the third filter unit 303 and controls on / off of the switch SW3.

  When the switch SW3 is turned on, the high frequency input signal RFIN1 input to the input terminal T1 is input to the amplifier 303A via the switch SW3 and amplified by the amplifier 303A. The high frequency signal amplified by the amplifier 303A is frequency-converted (down-converted) to an intermediate frequency signal by the mixer 303B and the local oscillator 303C, and is amplified by the amplifier 303D. The mixer 303B and the local oscillator 303C constitute an example of a fifth frequency converter. From the intermediate frequency signal amplified by the amplifier 303D, a signal other than the band obtained by frequency-converting the third frequency band is cut by the band pass filter 303E, and the signal in the band is extracted.

  The signal extracted by the band pass filter 303E is amplified by the amplifier 303F. The signal amplified by the amplifier 303F is frequency-converted (up-converted) into a high-frequency signal by the mixer 303G and the local oscillator 303C, and amplified by the amplifier 303H. The mixer 303G and the local oscillator 303C constitute an example of a sixth frequency converter.

  Thus, if the switch SW3 is on, the third filter unit 303 extracts and outputs a signal in the third frequency band from the high-frequency input signal RFIN1 (output on state). When the switch SW3 is turned off, the input terminal T1 is terminated by the resistor R3, and the output of the third filter unit 303 is turned off.

  The fourth filter unit 304 includes an amplifier 304A, a mixer 304B, a local oscillator 304C, an amplifier 304D, a bandpass filter 304E, an amplifier 304F, a mixer 304G, and an amplifier 304H. The input terminal T1 is commonly connected to one end of the resistor R4 and one end of the switch SW4. The other end of the resistor R4 is connected to the ground terminal. The other end of the switch SW4 is connected to the input end of the amplifier 304A. The CPU 34 controls the fourth filter unit 304 and controls on / off of the switch SW4.

  When the switch SW4 is turned on, the high frequency input signal RFIN1 input to the input terminal T1 is input to the amplifier 304A via the switch SW4 and amplified by the amplifier 304A. The high frequency signal amplified by the amplifier 304A is frequency-converted (down-converted) to an intermediate frequency signal by the mixer 304B and the local oscillator 304C, and is amplified by the amplifier 304D. The mixer 304B and the local oscillator 304C constitute an example of a seventh frequency converter. From the intermediate frequency signal amplified by the amplifier 304D, a signal other than the band obtained by frequency-converting the fourth frequency band is cut by the band pass filter 304E, and the signal in the band is extracted.

  The signal extracted by the band pass filter 304E is amplified by the amplifier 304F. The signal amplified by the amplifier 304F is frequency-converted (up-converted) into a high-frequency signal by the mixer 304G and the local oscillator 304C, and amplified by the amplifier 304H. The mixer 304G and the local oscillator 304C constitute an example of an eighth frequency converter.

  Accordingly, if the switch SW4 is on, the fourth filter unit 304 extracts and outputs a signal in the fourth frequency band from the high frequency input signal RFIN1 (output on state). When the switch SW4 is turned off, the input terminal T1 is terminated by the resistor R4, and the output of the fourth filter unit 304 is turned off.

  In the fourth filter unit 304, a high pass filter may be provided instead of the band pass filter 304E.

  The high frequency signals output from the amplifiers 301H, 302H, 303H, and 304H are synthesized and output from the output terminal T2 as a high frequency output signal RFOUT1.

  Here, the CPUs 31 to 34 are controlled by the control unit 20. A PC (personal computer) 25 is connected to the control unit 20. The PC 25 and the control unit 20 are connected via, for example, a LAN or USB.

  The PC 25 displays a selection screen for selecting ON / OFF of each of the switches SW1 to SW4 by executing predetermined software. In the selection screen, when the on / off of the switches SW1 to SW4 is selected and determined by the operation of the PC 25 by the user, a command signal corresponding to the selection result is sent from the PC 25 to the control unit 20.

  The control unit 20 transmits a command to each of the CPUs 31 to 34 in accordance with the received command signal. The CPUs 31 to 34 turn on and off each of the switches SW1 to SW4 according to the received command.

  As a result, among the switches SW1 to SW4, the signal of the frequency band of the system corresponding to the switch selected to be turned on by the operation of the PC 25 appears in the high frequency output signal RFOUT1, and the frequency band of the system corresponding to the switch selected to be off. Does not appear in the high-frequency output signal RFOUT1.

  For example, if the cable TV operator cannot agree to retransmit 110-degree CS right-handed broadcasting and 110-degree CS left-handed broadcasting, the switch SW2 and the switch SW4 are selected by the operation of the PC 25, and the switches SW1 and SW3 are switched. Select On. As a result, the outputs of the second filter unit 302 and the fourth filter unit 304 are turned off, and the high frequency output signal RFOUT1 is changed to the second frequency band by turning on the outputs of the first filter unit 301 and the third filter unit 303. And the signal of the 4th frequency band is cut, and it becomes the signal from which the signal of the 1st frequency band and the 3rd frequency band was extracted. That is, as shown in FIG. 2B, in the high-frequency output signal RFOUT1, signals in the frequency band of 110 degree CS right-handed broadcasting and 110 degree CS left-handed broadcasting are cut, and signals in the frequency bands of BS right-handed broadcasting and BS left-handed broadcasting are cut. It will be in the extracted state.

  In addition, even if the cable television operator cannot obtain the retransmission agreement for 110 degree CS right-handed broadcasting and 110 degree CS left-handed broadcasting as described above, for example, the agreement for retransmission of 110 degree CS left-handed broadcasting can be obtained thereafter. In this case, if the switch SW4 is turned on by operating the PC 25, the output of the fourth filter unit 304 is turned on, and a signal in the fourth frequency band appears in the high-frequency output signal RFOUT1. That is, as shown in FIG. 2D compared to FIG. 2B, a signal in the frequency band of 110 degree CS left-handed broadcasting appears. As a result, the 110-degree CS left-handed broadcast can be retransmitted.

  As described above, regarding the retransmission of 4K / 8K satellite broadcasts that are scheduled for practical broadcasts in the future, the operator who performs the retransmission can easily switch whether or not to retransmit each broadcast by the filter device 3. , The convenience will be high.

  Further, as a method different from this embodiment, a channel processor is provided corresponding to each channel in BS right-handed broadcasting, 110-degree CS right-handed broadcasting, BS left-handed broadcasting, and 110-degree CS left-handed broadcasting, By switching on / off the output of the channel processor, it may be possible to switch whether or not to retransmit for each broadcast as in the present embodiment. However, in this method, it is necessary to provide as many channel processors as the number of channels, and the cost becomes very high. In addition, the size and power consumption of the retransmission system also increase.

  Compared to this, the filter device 3 of the present embodiment turns the output on and off with each of the first filter unit 301 to the fourth filter unit 304 as the minimum unit, so that the cost can be greatly reduced, and In addition, the size and power consumption of the retransmission system can be reduced.

  Instead of switching on / off the output of the filter unit by turning on / off the switch as in the above embodiment, an embodiment in which the on / off of the output of the filter unit is switched by turning on / off the power supply of the filter unit may be adopted.

  In the first filter unit 301, for example, AGC (Automatic Gain Control) may be performed by variably controlling the gain of the amplifier 301H according to the output level of the amplifier 301H. The same applies to the second filter unit 302 to the fourth filter unit 304. As a result, an appropriate level signal can be input to the optical transmitter 5 (FIG. 1). The set value of the output level at this time can be designated by the PC 25.

  Further, the frequency characteristics (F characteristics) of each output level of the first filter unit 301 to the fourth filter unit 304 may be adjusted in consideration of signal attenuation due to the cable transmission path.

  Next, FIG. 4 is a diagram illustrating a configuration according to a modification including the filter device 3. In the configuration shown in FIG. 4, an operation switch unit 28 is further provided with respect to the configuration shown in FIG. 3 described above.

  The operation switch unit 28 has a hard switch corresponding to each of the CPUs 31 to 34. By operating the hard switch, the CPUs 31 to 34 turn off the switches SW1 to SW4 without depending on a command from the control unit 20. That is, the switches SW1 to SW4 can be forcibly turned off by the operation switch unit 28, and the output of the filter unit of the system corresponding to the switch that has been turned off can be turned off.

  As another modification, only the operation switch unit 28 is provided without providing the PC 25 and the control unit 20, and the switches SW1 to SW4 are turned on / off according to the switching of the hard switch in the operation switch unit 28. Also good.

  As mentioned above, although embodiment of this invention was described, as long as it is in the range of the meaning of this invention, embodiment can be variously deformed.

DESCRIPTION OF SYMBOLS 1 Booster 2 Distributor 3 Filter apparatus 4 Mixer 5 Optical transmitter 6 Optical amplifier 7 Low pass filter 8 TV broadcast signal processing part 9 Audio | voice signal processing part 10 Mixer 11 Divider 12 Mixer 13 Optical transmitter 14 Optical amplifier 15 Re Transmission system 31-34 CPU
301 First filter unit 302 Second filter unit 303 Third filter unit 304 Fourth filter unit 301A, 302A, 303A, 304A Amplifier 301B, 302B, 303B, 304B Mixer 301C, 302C, 303C, 304C Local oscillator 301D, 302D, 303D , 304D Amplifier 301E, 302E, 303E, 304E Band pass filter 301F, 302F, 303F, 304F Amplifier 301G, 302G, 303G, 304G Mixer 301H, 302H, 303H, 304H Amplifier 20 Control unit 25 PC
28 Operation switch part ANT1 Antenna CB1, CB2 Optical cable SW1-SW4 Switch R1-R4 Resistance T1 Input terminal T2 Output terminal

Claims (5)

An input terminal;
The frequency of BS right-handed broadcasting from a high-frequency input signal including BS right-handed circularly polarized signal, CS right-handed circularly polarized signal, BS left-handed circularly polarized signal, and CS left-handed circularly polarized signal input to the input terminal. A first filter unit for extracting a band signal;
A second filter unit that extracts a signal in a frequency band of CS right-handed broadcasting from the high-frequency input signal input to the input terminal;
A third filter unit for extracting a signal in a frequency band of BS left-handed broadcasting from the high-frequency input signal input to the input terminal;
A fourth filter unit that extracts a signal in a frequency band of CS left-handed broadcasting from the high-frequency input signal input to the input terminal;
An output terminal for outputting a high-frequency output signal generated by combining the output signals of the first filter unit, the second filter unit, the third filter unit, and the fourth filter unit;
A filter device, wherein each output can be switched on and off with each of the first filter unit, the second filter unit, the third filter unit, and the fourth filter unit as a minimum unit. The first filter part is
A first frequency converter that converts a high frequency signal to an intermediate frequency signal;
A first bandpass filter or a lowpass filter;
A second frequency converter that converts the frequency of the intermediate frequency signal input from the first frequency converter through the first band pass filter or the low pass filter into a high frequency signal;
The second filter part is
A third frequency converter that converts a high-frequency signal into an intermediate-frequency signal;
A second bandpass filter;
A fourth frequency converter that converts the frequency of the intermediate frequency signal input from the third frequency converter through the second bandpass filter into a high-frequency signal;
The third filter part is
A fifth frequency converter for converting a high frequency signal to an intermediate frequency signal;
The third bandpass filter;
A sixth frequency converter that converts the frequency of the intermediate frequency signal input from the fifth frequency converter through the third bandpass filter into a high-frequency signal;
The fourth filter part is
A seventh frequency converter for converting a high-frequency signal to an intermediate-frequency signal;
A fourth bandpass filter or a highpass filter;
The eighth frequency conversion unit according to claim 1, further comprising: an eighth frequency conversion unit configured to frequency-convert the intermediate frequency signal input from the seventh frequency conversion unit via the fourth bandpass filter or the high-pass filter into a high-frequency signal. Filter device.   A switch disposed in each signal path between the input terminal and the output terminal where each of the first filter unit, the second filter unit, the third filter unit, and the fourth filter unit is disposed; The filter apparatus of Claim 1 or Claim 2 provided. An antenna capable of receiving BS right-handed broadcasting, CS right-handed broadcasting, BS left-handed broadcasting, and CS left-handed broadcasting;
The filter device according to any one of claims 1 to 4, wherein a first high-frequency input signal based on a high-frequency broadcast signal output from the antenna is input;
A first transmitter that transmits a first high-frequency output signal output from the filter device;
Retransmission system comprising. A distributor for distributing a signal based on the high-frequency broadcast signal to the first high-frequency input signal and the second high-frequency input signal;
A filter unit for extracting a signal in the frequency band of the BS right-handed broadcasting from the input second high-frequency input signal;
The retransmission system according to claim 4, further comprising: a second transmission unit that transmits a signal in the frequency band of the BS right-handed broadcasting output from the filter unit.

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