JP2007013329A - Signal path changeover switch and signal path switching method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal path changeover switch and a signal path switching method that utilizes a frequency band of an unreceived broadcast signal for communication and reduces the effect on a communication signal due to an insertion loss of a filter. <P>SOLUTION: The signal path changeover switch includes: an input terminal for receiving an external input signal; an output terminal connected to a transmission/reception circuit for communication; a signal detection means 12 for detecting whether or not the externally received signal includes a signal with a predetermined prescribed frequency band other than predetermined communication signal band for communication; a prescribed-frequency band width suppression filter 15 for suppressing a signal with a prescribed frequency band; a bypass path 18 provided in parallel with the prescribed-frequency band width suppression filter 15; and control circuits 13, 14 that allow the signal with the prescribed frequency band to pass through the prescribed-frequency band width suppression filter 15 when the signal with the prescribed frequency band exists or allow the input signal to pass through the bypass path 18 when the externally received signal includes a signal with the predetermined prescribed frequency band on the basis of a result of the detection by the signal detection means 12. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a signal path switch and a signal path switching method. For example, the present invention relates to a signal path changeover switch and a signal path changeover method used in a filter circuit provided in order to remove a disturbed / affected communication modem.

  It is necessary for the communication device not to interfere with other signals and to avoid interference from other signals. For this reason, the communication device is added with a filter that passes the frequency band used for the communication signal and attenuates the frequency band of other signals.

  FIG. 10 shows a configuration of a communication system using a cable television network as an example of a general communication system. 10 (a) and 10 (b) show a configuration diagram of a CATV communication system when BS / CS broadcasting is received from an antenna separately from a cable television network, and FIG. 10 (c) shows BS / CS broadcasting. FIG. 2 shows a configuration diagram of a CATV communication system when the broadcast data is sent as a broadcast signal of a cable television network. FIG. 10 (d) shows a configuration diagram of the CATV communication system when broadcasting data for BS / CS broadcasting is not transmitted. The same reference numerals are used for the same components.

  In the communication system of FIG. 10A, a BS / CS broadcast signal is received from the BS / CS antenna 101. Then, a broadcast signal other than the BS / CS broadcast is received from the CATV network 102. The BS / CS broadcast signal and the broadcast signal transmitted from the CATV network 102 are mixed by the mixer 105. The mixed signal is mixed with the communication signal 104 by the mixer 106 and input to the CATV modem 107. The CATV modem 107 demultiplexes the mixed signal into a broadcast signal and a communication signal, and the broadcast signal is input to the television 108 and the communication signal is input to the personal computer 109 via different coaxial cables. . The mixer 106 may be a distributor or a branching device.

  Here, the BS / CS broadcast signal received by the BS / CS antenna 101 is a signal in a frequency band of 1030 MHz or more. A broadcast signal transmitted from the CATV network 102 is a signal having a frequency of 770 MHz or less. Then, a frequency band not used for these broadcast signals, that is, a signal having a frequency of 770 MHz to 1030 MHz is used as the communication signal 104.

  The CATV modem 107 is used for transmission / reception to / from the personal computer 109 so that the communication signal used for transmission / reception of the personal computer 109 is not disturbed by the broadcast signal and does not interfere with the broadcast signal. A BPF (band pass filter) is provided in the signal path.

  FIG. 11 shows a configuration diagram of the BPF 111 provided in the CATV modem 107. A signal from the coaxial cable input 116 connected to the mixer 106 is configured to be input to the transmission / reception circuit unit 117 through the BPF 111. As shown in FIG. 11, the BPF 111 includes an HPF 112 (high pass filter) and an LPF 113 (low pass filter).

  FIG. 12 shows the attenuation characteristics of the HPF 112 and the LPF 113. The LPF 113 attenuates signals in the frequency band of 1030 MHz or higher received by the BS / CS antenna 101, and the HPF 112 attenuates signals in the frequency band of 770 MHz or lower transmitted from the CATV network 102.

  As broadcast signals, signals in the CATV broadcast band 121 and the BS / CS signal band 122 are used. Then, the frequency band of these broadcast signals is attenuated by the BPF 111, and the communication signal band 123 that is not used for these broadcast signals is used for the communication signals.

  FIG. 10B shows a configuration diagram of a CATV communication system having another configuration in the case where BS / CS broadcasting similar to FIG. 10A is received from an antenna separately from the cable television network.

  In this case, the television 108 is not connected to the CATV modem 107 but is connected to the demultiplexer 110 that demultiplexes the signal from the mixer 106. The duplexer 110 demultiplexes the broadcast signal from the signal mixed by the mixer 106 and causes the television 108 to receive a signal of 770 MHz or lower and a signal of 1030 MHz or higher. Further, the duplexer 110 demultiplexes the communication signal from the signal mixed by the mixer 106, and a signal of 825 MHz to 975 MHz is input from the duplexer 110 to the CATV modem 107. Then, similarly to the case of FIG. 10A, the BPF 111 provided in the CATV modem 107 is passed, and only the communication signal band 123 that is not used for the broadcast signal is passed.

  On the other hand, in the communication system of FIG. 10C, a BS / CS broadcast signal is sent from the CATV network 120 as a signal in the frequency band (770 MHz or less) of the broadcast signal. In the communication system configured as shown in FIG. 10 (c), as in the case of FIGS. 10 (a) and 10 (b), it is connected to the personal computer 109 via the CATV modem 107 provided with the BPF 111. The

  The communication system in FIG. 10 (d) shows a configuration without a signal for BS / CS broadcasting. Similarly to FIG. 10 (b), the television 108 demultiplexes the signal from the mixer 106. Connected to the device 110. In this case, the demultiplexer 110 demultiplexes the broadcast signal from the signal mixed by the mixer 106, but does not include a BS / CS broadcast signal of 1030 MHz or higher, so only the signal of 770 MHz or lower is included. The television 108 will receive it. Further, the duplexer 110 is the same duplexer as in FIG. 10B, and demultiplexes the communication signal from the signal mixed by the mixer 106, and a signal of 825 MHz to 975 MHz is output from the duplexer 110. Input to the CATV modem 107. Then, as in the case of FIGS. 10A to 10C, the BPF 111 provided in the CATV modem 107 is passed, and only the communication signal band 123 that is not used for the broadcast signal is passed.

  Here, the communication system of FIG. 10 (d) has been described with a configuration without a signal for BS / CS broadcasting, but with the configuration of FIG. 10 (d), the communication system for BS / CS broadcasting is as shown in FIG. 10 (c). Even when the signal is transmitted from the CATV network in a broadcast signal frequency band (770 MHz or less), the same operation as described above is performed. That is, in this case, the duplexer 110 causes the television 108 to receive only a signal of 770 MHz or less including a signal for BS / CS broadcasting.

  Even if the same CATV modem 107 is connected to the antenna coaxial cable terminal arranged on the wall of a different house, or the antenna coaxial cable terminal arranged on a different wall even in the same house, Even if the same CATV modem 107 is connected, the connection configuration differs as shown in FIGS. 10A to 10D depending on the antenna coaxial cable terminal to be connected.

  Further, since the terrestrial broadcast signal uses the same frequency band of 770 MHz or less as the CATV broadcast band, the terrestrial broadcast signal is replaced with the CATV modem in place of the broadcast signal from the CATV network in FIGS. Even with the configuration input to 107, it is possible to display television broadcasts and transmit and receive communications with these configurations.

  10 (a) to 10 (d), the communication signal 104 is transmitted / received through a route different from that of the CATV network. However, the communication signal is superimposed on the broadcast signal via the CATV network. Even in a configuration in which transmission and reception are performed, the same operation is performed. Thus, when communication signals are transmitted and received through the CATV network, the communication system of FIGS. 10A to 10D has a configuration without the mixer 106.

  Note that, as in the communication system of FIG. 10C, a BS / CS broadcast signal may be sent from the CATV network as a CATV broadcast band signal, but in this specification, the signal is sent from the CATV network. Regardless of whether it is received or not, the frequency of the original BS / CS broadcast signal when received from the BS / CS antenna is described as “BS / CS signal band”.

There is also a filter circuit that switches a switch in a control circuit and selects a filter to be passed depending on the frequency band used for communication (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 64-71222

  However, when a conventional CATV modem having a BPF is used, the communication signal always passes through the BPF even when there is no need to attenuate signals other than the frequency band of the communication signal. There was an effect on communication signals due to insertion loss.

  For example, in the case of the communication system having the configuration shown in FIG. 10B, a broadcast signal (a signal of 770 MHz or lower and 1030 MHz or higher) does not flow from the duplexer 110 to the CATV modem 107. However, it is not necessary to pass the BPF, but the BPF in the CATV modem 107 is always passed.

  In order to obtain a desired cut-off characteristic with the configuration of the BPF 111 including the HPF 112 and the LPF 113 as shown in FIG. 12, it is common on the circuit to have an insertion loss of about 1.5 [dB]. Due to the influence of the insertion loss caused by the two filters, HPF 112 and LPF 113, the communicable distance has been shortened.

  In addition, when using a BPF that passes only a vacant frequency band between the conventional CATV broadcast band and the BS / CS signal band, it actually receives a broadcast signal out of the frequency band allocated as a broadcast signal. Unusable frequency band could not be used for communication.

  The frequency bands assigned as broadcast signals are frequency bands of 770 MHz or less and 1030 MHz or more. For example, in the case of the communication system configured as shown in FIG. 10C, only the frequency band of 770 MHz or less is used as the broadcast signal. used. That is, in this case, the frequency band of 1030 MHz or higher is not used for the broadcast signal. However, if the BPF 111 as shown in FIG. 11 is provided on the communication signal path, the frequency band of 1030 MHz or more is attenuated as shown in FIG. Cannot be used as

  That is, although the frequency band of 1030 MHz or higher is not used for the broadcast signal, only the signal of the communication signal band 123 can be used for communication, so the frequency use efficiency of the communication signal is poor. .

  The present invention solves the above-described conventional problems, and an object of the present invention is to provide a signal path switching switch and a signal path switching method that can suppress a filter insertion loss and increase a communication distance.

  Another object of the present invention is to provide a signal path switching switch and a signal path switching method that allow communication with high frequency use efficiency.

In order to solve the above-described problem, the first aspect of the present invention provides:
An input terminal to which an externally input signal is input;
An output terminal connected to a transmission / reception circuit for communication;
Signal detecting means for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication, in the signal input from the outside;
A predetermined frequency band suppression filter connected between the input terminal and the output terminal and suppressing a signal of the predetermined frequency band;
A bypass path that is provided in parallel with the predetermined frequency band suppression filter and does not pass through the predetermined frequency band suppression filter;
Based on the detection result of the signal detection means, when there is a signal in the predetermined frequency band, the signal passes through the predetermined frequency band suppression filter, and when there is no signal in the predetermined frequency band, the signal passes through the bypass path. And a control circuit for controlling the signal path.

The second aspect of the present invention
The predetermined frequency band determined in advance is a BS frequency band or a CS frequency band,
The predetermined frequency band suppression filter is the signal path switch according to the first aspect of the present invention, which is a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band.

The third aspect of the present invention
The predetermined frequency bands determined in advance are a BS frequency band and a CS frequency band,
The predetermined frequency band suppression filter is configured by a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band, and a second low-pass filter that suppresses signals in the CS frequency band, which are arranged in parallel. And
The control circuit passes the first low-pass filter when there is a signal in the BS frequency band, and passes the second low-pass filter when there is no signal in the BS frequency band and there is a signal in the CS frequency band. The signal path changeover switch according to the first aspect of the present invention is configured to pass through the bypass path when there is no signal in either the BS frequency band or the CS frequency band through the filter.

The fourth aspect of the present invention is
A first high-pass filter that suppresses a signal in the CATV frequency band between the input terminal or the output terminal and the bypass path, and a signal in a frequency band that is less than a predetermined frequency in the CATV frequency band. 2 high-pass filters are provided in parallel,
The signal detection means also detects whether there is a signal in a frequency band equal to or higher than the predetermined frequency in the CATV frequency band in the signal input from the outside,
Based on the detection result of the signal detection means, the control circuit passes the first high-pass filter when there is a signal having a frequency band equal to or higher than the predetermined frequency in the CATV frequency band, and passes the CATV frequency band. When there is no signal in a frequency band equal to or higher than the predetermined frequency, the signal path selector switch according to the second or third aspect of the present invention passes the second high-pass filter.

The fifth aspect of the present invention provides
The signal path changeover switch according to the first aspect of the present invention, wherein a signal in the communication signal band and a signal other than the communication signal band are input to the input terminal.

The sixth aspect of the present invention provides
An input terminal to which an externally input signal is input;
An output terminal connected to a transmission / reception circuit for communication;
Signal detecting means for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication, in the signal input from the outside;
A specific frequency suppression path provided between the input terminal and the output terminal for suppressing a signal of the predetermined frequency band;
A specific frequency passing path that is provided between the input terminal and the output terminal and that allows the signal in the predetermined frequency band to pass through for use in communication as well as the signal in the communication signal band;
Based on the detection result of the signal detection means, when there is a signal of the predetermined frequency band, the specific frequency suppression path is passed, and when there is no signal of the predetermined frequency band, the specific frequency passage path is It is a signal path changeover switch provided with the control circuit to let it pass through.

The seventh aspect of the present invention
The predetermined frequency band determined in advance is a frequency band equal to or higher than a predetermined frequency in the CATV frequency band,
The specific frequency suppression path is a path that passes through a first high-pass filter that suppresses a signal in the CATV frequency band;
The specific frequency passing path is a path that passes through a second high-pass filter that suppresses a signal in a frequency band less than the predetermined frequency in the CATV frequency band, instead of passing through the first high-pass filter. This is a signal path switch according to the present invention.

In addition, the eighth aspect of the present invention
The predetermined frequency band determined in advance is a BS frequency band,
The specific frequency suppression path is a path that passes through a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band,
The specific frequency passing path is the signal path switching switch according to the sixth aspect of the present invention, which is a path that passes through a second low-pass filter that suppresses a signal in the CS frequency band, instead of passing through the first low-pass filter.

The ninth aspect of the present invention provides
The input terminal is connected to the duplexer by a coaxial cable;
In the signal path changeover switch according to the sixth aspect of the present invention, only the signal in the communication signal band is input to the input terminal as a result of the demultiplexing by the duplexer.

The tenth aspect of the present invention is
An external signal input step for inputting a signal input from the outside;
A signal detecting step for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication in the signal input from the outside;
When it is detected in the signal detection step that there is a signal in the predetermined frequency band, it is passed through a predetermined frequency band suppression filter that suppresses the signal in the predetermined frequency band, and it is detected that there is no signal in the predetermined frequency band. Sometimes, a signal path control step for passing a bypass path that is provided in parallel with the predetermined frequency band suppression filter and does not pass through the predetermined frequency band suppression filter;
A signal path switching method comprising: a communication signal output step of outputting the communication signal passed in the signal path control step to a transmission / reception circuit for communication.

The eleventh aspect of the present invention is
An external signal input step for inputting a signal input from the outside;
A signal detecting step for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication in the signal input from the outside;
When it is detected in the signal detection step that there is a signal in the predetermined frequency band, the signal is passed through a specific frequency suppression path for suppressing the signal in the predetermined frequency band, and when it is detected that there is no signal in the predetermined frequency band. A signal path control step of passing a signal of the predetermined frequency band together with the signal of the communication signal band and passing a specific frequency passing path that can be used for the communication;
A signal path switching method comprising: a communication signal output step of outputting the communication signal passed in the signal path control step to a transmission / reception circuit for communication.

  According to the present invention, it is possible to provide a signal path switching switch and a signal path switching method capable of increasing a communication distance by suppressing insertion loss of a filter.

  In addition, according to the present invention, it is possible to provide a signal path switching switch and a signal path switching method that enable communication with high frequency use efficiency.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram of a filter circuit according to the first embodiment of the present invention. This filter circuit is a circuit provided in the CATV modem 107 of the communication system as shown in FIG. 10, and is a circuit provided in place of the BPF described in the conventional example.

  With reference to FIG. 1, the configuration of the filter circuit of the first embodiment will be described together with its operation.

  The filter circuit of the first embodiment includes an HPF 11, a BS / CS signal detection circuit 12, changeover switches 13 and 14, an LPF 15, and a bypass path 18. The BS / CS signal detection circuit 12 corresponds to an example of the signal detection means of the present invention. Further, the configuration in which the functional parts that control the changeover switches 13 and 14 of the BS / CS signal detection circuit 12 and the changeover switches 13 and 14 are combined is an example of the control circuit of the present invention. The LPF 15 corresponds to an example of the predetermined frequency band suppression filter of the present invention.

  The HPF 11 removes the interference / affected interference in the CATV broadcast band by attenuating the frequency band (770 MHz or less) used for the broadcast signal from the CATV network among the signals from the coaxial cable input 16.

  The BS / CS signal detection circuit 12 detects the frequency of the signal after being input from the coaxial cable input 16 and passing through the HPF 11. The BS / CS signal detection circuit 12 transmits a control signal for switching the changeover switches 13 and 14 to the changeover switches 13 and 14 according to the detection result. The BS / CS signal detection circuit 12 may detect a signal from the coaxial cable input 16 before passing through the HPF 11 instead of a signal after passing through the HPF 11.

  In accordance with a control signal from the BS / CS signal detection circuit 12, the changeover switches 13 and 14 pass the LPF 15 through the path of the signal from the HPF 11 to the transmission / reception circuit unit 17 after passing through the HPF 11, or the bypass path not through the LPF 15 18 is switched. The LPF 15 is a filter that attenuates the BS / CS signal band (1030 MHz or more).

  The portion where the signal from the coaxial cable input 16 of the HPF 11 is input is an example of the input terminal of the present invention, and the portion connected to the transmission / reception circuit portion 17 of the changeover switch 14 is an example of the output terminal of the present invention. .

  When the BS / CS signal detection circuit 12 detects a signal in the BS / CS signal band, the BS / CS signal detection circuit 12 transmits a control signal for allowing the LPF 15 to pass to the changeover switches 13 and 14. When no signal in the BS / CS signal band is detected, a control signal that passes through the bypass path 18 is transmitted to the changeover switches 13 and 14.

  FIG. 2 shows the attenuation characteristics when the filter circuit of the first embodiment is used.

  The HPF 11 suppresses the CATV broadcast band 21 signal (a signal of 770 MHz or less).

  When the signal of the BS / CS signal band 22 is detected, the BS / CS signal detection circuit 12 performs control so that the signal that has passed through the HPF 11 passes through the LPF 15. The signal in the BS / CS signal band 22 is suppressed by the LPF 15. The transmission / reception circuit unit 17 transmits and receives communication signals using the frequency of the communication signal band 23 that has not been attenuated by the HPF 11 and the LPF 15.

  On the other hand, when a signal in the BS / CS signal band 22 is not detected, the BS / CS signal detection circuit 12 performs control so that the signal passing through the HPF 11 passes through the bypass path 18 without passing through the LPF 15. . In this case, since the BS / CS signal band 22 is not attenuated, the transmission / reception circuit unit 17 can transmit and receive communication signals using the frequency band 24 including the BS / CS signal band 22.

  The communication signal band 23 corresponds to an example of a communication signal band predetermined for communication according to the present invention. In the first embodiment, the BS / CS signal band 22 corresponds to an example of a predetermined frequency band determined in advance of the present invention.

  The path passing through the HPF 11 and the LPF 15 of the filter circuit of the first embodiment is an example of the specific frequency suppression path of the present invention, and the path passing through the HPF 11 and the bypass path 18 is the specific frequency passing path of the present invention. This is an example.

  Moreover, the process in which a signal including a broadcast signal is input from the coaxial cable input 16 to the HPF 11 corresponds to an example of an external signal input step of the present invention. The process in which the BS / CS signal detection circuit 12 detects the signal in the BS / CS signal band 22 corresponds to an example of the signal detection step of the present invention. The process of switching the changeover switches 13 and 14 by the control signal from the BS / CS signal detection circuit 12 corresponds to an example of the signal path control step of the present invention. Moreover, the process which sends the signal which passed the filter circuit of this Embodiment 1 to the transmission / reception circuit part 17 is an example of the communication signal output step of this invention.

  For example, when the filter circuit of the first embodiment is provided in the CATV modem 107 of each communication system of FIGS. 10A to 10D, the signal input from the coaxial cable input 16 is the communication of FIG. Although the system is controlled to pass through the LPF 15, the communication system of FIGS. 10B to 10D is controlled to pass through the bypass path 18 without passing through the LPF 15.

  In order to obtain a desired cutoff characteristic with the configuration of the conventional BPF 111 in which the HPF 112 and the LPF 113 are combined as shown in FIG. 11, the insertion loss of about 1.5 dB in each of the HPF 112 and the LPF 113 is from the viewpoint of circuit implementation. It is common. In the coaxial cable (5C-FB), the insertion loss in the 900 MHz band is 0.15 [dB / m]. Therefore, when the filter circuit of the first embodiment is used, in the case of the communication system configured as shown in FIGS. 10B to 10D, only the HPF 11 is passed, and therefore the conventional BPF 111 is passed. Compared to the case, the communication distance in the coaxial cable (5C-FB) is improved by about 10 m.

  Further, if the CATV modem 107 in the communication system of FIGS. 10A and 10C is provided with the filter circuit of the first embodiment, communication is transmitted and received in the communication signal band 23 in the communication system of FIG. In the communication system of FIG. 10C, communication is transmitted and received in the frequency band 24 including the BS / CS signal band.

  As described above, when the BS / CS signal band 22 is not used for a broadcast signal, the frequency band used for communication can be expanded and communication can be performed, so that the frequency use efficiency is improved.

  As described above, by using the filter circuit according to the first embodiment, when a signal in the BS / CS signal band is not received, only the HPF 11 is passed without passing through the LPF 15, so insertion by a filter is performed. The loss can be reduced and the communication distance can be increased. Further, the BS / CS signal band can be used for communication.

  When the CATV modem 107 is provided with the filter circuit according to the first embodiment, the BS / CS signal detection circuit 12 causes the BS • CS signal detection circuit 12 to detect the BS • CS signal when the CATV modem 107 is connected to a broadcasting / communication terminal installed on a wall or the like. Since the presence / absence of a signal in the CS signal band is detected and the communication signal path is automatically selected, the above-described effects are automatically obtained according to the connection state.

(Embodiment 2)
FIG. 3 is a block diagram of the filter circuit according to the second embodiment of the present invention. Similar to the filter circuit of the first embodiment, this filter circuit is a circuit provided in the CATV modem 107 of the communication system as shown in FIG. In addition, the same code | symbol is used for the same component as Embodiment 1. FIG.

  With reference to FIG. 3, the configuration of the filter circuit of the second embodiment will be described together with its operation.

  The filter circuit according to the second embodiment includes an HPF 11, a BS / CS signal detection circuit 32, changeover switches 33 and 34, LPFs 35 and 36, and a bypass path 38. The BS / CS signal detection circuit 32 is an example of the signal detection means of the present invention. Further, the configuration in which the functional parts that control the changeover switches 33 and 34 of the BS / CS signal detection circuit 32 and the changeover switches 33 and 34 are combined is an example of the control circuit of the present invention. The LPF 35 and the LPF 36 correspond to an example of the predetermined frequency band suppression filter of the present invention. The LPF 35 corresponds to an example of the first low-pass filter of the present invention, and the LPF 36 corresponds to an example of the second low-pass filter of the present invention.

  The HPF 11 removes the interference / affected interference in the CATV broadcast band by attenuating the frequency band (770 MHz or less) used for the broadcast signal from the CATV network among the signals from the coaxial cable input 16.

  The BS / CS signal detection circuit 32 detects the frequency of the signal after being input from the coaxial cable input 16 and passing through the HPF 11. The BS / CS signal detection circuit 32 transmits a control signal for switching the changeover switches 33 and 34 to the changeover switches 33 and 34 according to the detection result. The BS / CS signal detection circuit 32 may detect a signal from the coaxial cable input 16 before passing through the HPF 11 instead of a signal after passing through the HPF 11.

  Unlike the BS / CS signal detection circuit 12 of the first embodiment, the BS / CS signal detection circuit 32 distinguishes whether a signal of a frequency of 1030 MHz or higher is a signal in the BS signal band or a signal in the CS signal band. It can be detected. The CS signal band is a higher frequency band than the BS signal band.

  Depending on the control signal from the BS / CS signal detection circuit 32, the change-over switches 33 and 34 pass the LPF 35 or the LPF 36 through the signal path from the HPF 11 to the transmission / reception circuit unit 17 after passing through the HPF 11. Whether to pass the bypass path 38 through which neither the LPF 35 nor the LPF 36 passes is switched. The LPF 35 is a filter that attenuates the BS signal band and the CS signal band (1030 MHz or more), and the LPF 36 is a filter that attenuates the CS signal band.

  The portion where the signal from the coaxial cable input 16 of the HPF 11 is input is an example of the input terminal of the present invention, and the portion connected to the transmission / reception circuit portion 17 of the changeover switch 34 is an example of the output terminal of the present invention. .

  When detecting a signal in the BS signal band, the BS / CS signal detection circuit 32 transmits a control signal for allowing the LPF 35 to pass to the changeover switches 33 and 34. When a signal in the CS signal band that is higher in frequency than the BS signal band is detected, a control signal that passes through the LPF 36 is transmitted to the changeover switches 33 and 34. When no signal in the BS / CS signal band is detected, a control signal that passes through the bypass path 38 is transmitted to the changeover switches 33 and 34.

  FIG. 4 shows the attenuation characteristics when the filter circuit of the second embodiment is used.

  The HPF 11 suppresses the CATV broadcast band 21 signal (a signal of 770 MHz or less).

  When the signal of the BS signal band 41 is detected, the BS / CS signal detection circuit 32 performs control so that the signal that has passed through the HPF 11 passes through the LPF 35. The LPF 35 suppresses signals in the BS signal band 41 and the CS signal band 42. The transmission / reception circuit unit 17 transmits and receives communication signals using the frequency of the communication signal band 23 that has not been attenuated by the HPF 11 and the LPF 35.

  When a signal in the CS signal band 42 is detected, the BS / CS signal detection circuit 32 performs control so that the signal that has passed through the HPF 11 passes through the LPF 36. The BS signal band 41 is not attenuated by the LPF 36, and the signal in the CS signal band 42 is suppressed. The transmission / reception circuit unit 17 can transmit and receive communication signals using the frequency band 43 that has not been attenuated by the HPF 11 and the LPF 36.

  If neither signal in the BS signal band 41 nor the CS signal band 42 is detected, the BS / CS signal detection circuit 32 indicates that the signal that has passed through the HPF 11 does not pass through the LPF 35 and the LPF 36 and bypass path 38. Control to pass through. In this case, since the BS signal band 41 and the CS signal band 42 are not attenuated, the transmission / reception circuit unit 17 can transmit and receive communication signals using the frequency band 44 including the BS signal band 41 and the CS signal band 42. it can.

  The communication signal band 23 corresponds to an example of a communication signal band predetermined for communication according to the present invention. In the second embodiment, the BS signal band 41 and the CS signal band 42 correspond to an example of a predetermined frequency band determined in advance of the present invention. The path passing through the HPF 11 and the LPF 35 in the filter circuit of the second embodiment is an example of the specific frequency suppression path of the present invention, and the path passing through the HPF 11 and the LPF 36 and the path passing through the HPF 11 and the bypass path 38. However, both are examples of the specific frequency passing path of the present invention.

  Moreover, the process in which a signal including a broadcast signal is input from the coaxial cable input 16 to the HPF 11 corresponds to an example of an external signal input step of the present invention. The processing in which the BS / CS signal detection circuit 32 detects the signals in the BS signal band 41 and the CS signal band 42 corresponds to an example of the signal detection step of the present invention. The process of switching the selector switches 33 and 34 by the control signal from the BS / CS signal detection circuit 32 corresponds to an example of the signal path control step of the present invention. The process of sending the signal that has passed through the filter circuit of the second embodiment to the transmission / reception circuit unit 17 corresponds to an example of the communication signal output step of the present invention.

  As described above, communication can be performed by appropriately extending the frequency band used for communication according to which frequency band the broadcast signal uses, so that frequency use efficiency is improved.

  Further, when the filter circuit according to the second embodiment is used, when neither the BS signal band nor the CS signal band is received, the LPF 35 and the LPF 36 do not pass, and only the HPF 11 passes. Compared with the case of passing through the BPF 111, the communication distance in the coaxial cable (5C-FB) is improved by about 10 m.

  For example, if the CATV modem 107 of each communication system of FIGS. 10A to 10D is provided with the filter circuit of the second embodiment, the same as in the first embodiment, the filters of FIGS. In the configuration, the insertion loss due to the filter is reduced and the communication distance is increased.

  Similarly to the first embodiment, in FIG. 10C, the BS / CS signal band can also be used for communication. In the case of the second embodiment, even in the communication system configured as shown in FIG. 10A, when only the signal of the CS signal band is received from the BS / CS antenna, the BS signal band is communicated. It becomes possible to use it.

  As described above, by using the filter circuit of the second embodiment, when no signal in the BS / CS signal band is received, the insertion loss due to the filter can be reduced, so the communication distance is increased. be able to. If no signal in the BS / CS signal band is received, the BS / CS signal band can be used for communication. If only the signal in the CS signal band is received, the signal passes through the LPF 36. It is possible to use the BS signal band of the area for communication.

  In the second embodiment, the LPF 35 is a filter that attenuates the BS signal band 41 and the CS signal band 42, but may be a filter that attenuates only the BS signal band 41 without attenuating the CS signal band 42. In that case, when a signal in the BS signal band 41 is detected, the two frequency bands of the communication signal band 23 and the CS signal band 42 can be used for communication.

  In the second embodiment, the LPF 36 is a filter that attenuates the CS signal band 42. However, the LPF 36 may be a filter that attenuates an arbitrary frequency or more in the BS / CS signal band. In that case, the BS / CS signal detection circuit 32 detects the presence or absence of a signal in a frequency band before and after the arbitrary frequency, and performs the same operation as described above.

(Embodiment 3)
FIG. 5 shows a block diagram of the filter circuit according to the third embodiment of the present invention. Similar to the filter circuit of the first embodiment, this filter circuit is a circuit provided in the CATV modem 107 of the communication system as shown in FIG. In addition, the same code | symbol is used for the same component as Embodiment 1. FIG.

  With reference to FIG. 5, the configuration of the filter circuit according to the third embodiment will be described together with its operation.

  The filter circuit according to the third embodiment includes HPFs 55 and 56, a broadcast signal detection circuit 52, changeover switches 53 and 54, and an LPF 57. The broadcast signal detection circuit 52 is an example of the signal detection means of the present invention. Further, a configuration in which the functional parts that control the changeover switches 53 and 54 of the broadcast signal detection circuit 52 and the changeover switches 53 and 54 are combined corresponds to an example of the control circuit of the present invention.

  The HPF 55 attenuates the frequency band (770 MHz or less) used for the broadcast signal from the CATV network among the signals from the coaxial cable input 16, thereby removing the interfered / interfered in the CATV broadcast band.

  The HPF 56 is a filter for attenuating a frequency band lower than a predetermined frequency of a frequency band used for a broadcast signal from the CATV network among signals from the coaxial cable input 16.

  The broadcast signal detection circuit 52 detects the frequency of the signal input from the coaxial cable input 16. Then, the broadcast signal detection circuit 52 transmits a control signal for switching the changeover switches 53 and 54 to the changeover switches 53 and 54 according to the detection result.

  The change-over switches 53 and 54 switch whether the signal path from the coaxial cable input 16 to the LPF 57 passes through the HPF 55 or the HPF 56 in accordance with a control signal from the broadcast signal detection circuit 52. The LPF 57 is a filter that attenuates the BS / CS signal band (1030 MHz or more).

  Note that the portion where the signal from the coaxial cable input 16 of the changeover switch 53 is input is an example of the input terminal of the present invention, and the portion connected to the transmission / reception circuit portion 17 of the LPF 57 is an example of the output terminal of the present invention. .

  When the broadcast signal detection circuit 52 detects a signal having a predetermined frequency or higher in the CATV broadcast band, the broadcast signal detection circuit 52 transmits a control signal that allows the HPF 55 to pass to the changeover switches 53 and 54. When a signal having a predetermined frequency or higher is not detected in the CATV broadcast band, a control signal that passes through the HPF 56 is transmitted to the changeover switches 53 and 54.

  FIG. 6 shows the attenuation characteristics when the filter circuit of the third embodiment is used.

  The LPF 57 suppresses signals in the BS / CS signal band 22 (signals of 1030 MHz or higher).

  The broadcast signal detection circuit 52 controls the signal from the coaxial cable input 16 to pass through the HPF 55 when a signal having a predetermined frequency or higher is detected in the CATV broadcast band 21. The HPF 55 suppresses the CATV broadcast band 21 signal. The transmission / reception circuit unit 17 transmits and receives communication signals using the frequency of the communication signal band 23 that has not been attenuated by the HPF 55 and the LPF 57.

  On the other hand, when a signal having a predetermined frequency or higher is not detected in the CATV broadcast band, the broadcast signal detection circuit 52 controls so that the signal from the coaxial cable input 16 passes through the HPF 56. The HPF 56 suppresses signals in a frequency band below a predetermined frequency in the CATV broadcast band 21. In this case, since a frequency band of a predetermined frequency or higher in the CATV broadcast band 21 is not attenuated, the transmission / reception circuit unit 17 can transmit and receive communication signals using the frequency band 61 including the frequency band. .

  The communication signal band 23 corresponds to an example of a communication signal band predetermined for communication according to the present invention. In the third embodiment, a frequency band of a predetermined frequency or higher in the CATV broadcast band 21 corresponds to an example of a predetermined frequency band determined in advance of the present invention. Further, the path passing through the HPF 55 and the LPF 57 of the filter circuit of the third embodiment is an example of the specific frequency suppression path of the present invention, and the path passing through the HPF 56 and the LPF 57 is an example of the specific frequency passing path of the present invention. It hits.

  Further, the process of inputting a signal including a broadcast signal from the coaxial cable input 16 to the changeover switch 53 corresponds to an example of an external signal input step of the present invention. The process in which the broadcast signal detection circuit 52 detects a signal having a predetermined frequency or higher in the CATV broadcast band 21 corresponds to an example of the signal detection step of the present invention. Further, the process of switching the changeover switches 53 and 54 by the control signal from the broadcast signal detection circuit 52 corresponds to an example of the signal path control step of the present invention. The process of sending the signal that has passed through the filter circuit of the third embodiment to the transmission / reception circuit unit 17 corresponds to an example of the communication signal output step of the present invention.

  Depending on the broadcasting station, only a part of the CATV broadcasting band (frequency band of 770 MHz or less) may be used for broadcasting.

  For example, when the CATV modem 107 of the communication system of FIGS. 10A and 10C is provided with the filter circuit of the third embodiment, the CATV broadcast band (a frequency band of 770 MHz or less of the CATV network 102 or the CATV network 120). ), The high-frequency band part of the CATV broadcast band can be used for communication.

  When the filter circuit according to the third embodiment is used, when only a part of the CATV broadcast band is used for a broadcast signal in this way, the high frequency band of the CATV broadcast band that is not used for broadcast is used. Since the communication can be performed by expanding the frequency band used for communication, the frequency use efficiency is improved.

  The predetermined frequency used by the broadcast signal detection circuit 52 for determination of detection may be set to an appropriate frequency according to the frequency band used for the broadcast signal for each broadcast station.

(Embodiment 4)
FIG. 7 shows a block diagram of a filter circuit according to the fourth embodiment of the present invention. Similar to the filter circuit of the first embodiment, this filter circuit is a circuit provided in the CATV modem 107 of the communication system as shown in FIG. In addition, the same code | symbol is used for the same component as Embodiment 3. FIG.

  With reference to FIG. 7, the configuration of the filter circuit of the fourth embodiment will be described together with its operation.

  The filter circuit according to the fourth embodiment includes a broadcast signal detection circuit 72, changeover switches 53, 54, 75, and 76, HPFs 55 and 56, LPF 79, and a bypass path 80. The broadcast signal detection circuit 72 is an example of the signal detection means of the present invention. In addition, a configuration in which the functional part that controls the changeover switches 53, 54, 75, and 76 of the broadcast signal detection circuit 72 and the changeover switches 53, 54, 75, and 76 is an example of the control circuit of the present invention. The LPF 79 is an example of the predetermined frequency band suppression filter of the present invention. The HPF 55 corresponds to an example of the first high-pass filter of the present invention, and the HPF 56 corresponds to an example of the second high-pass filter of the present invention.

  Since the changeover switches 53 and 54 and the HPFs 55 and 56 have the same configuration as in the third embodiment, description thereof is omitted.

  The broadcast signal detection circuit 72 detects the frequency of the signal input from the coaxial cable input 16. Then, the broadcast signal detection circuit 72 transmits a control signal for switching the change-over switches 53, 54, 75, 76 to the change-over switches 53, 54, 75, 76 in accordance with the detection result. The broadcast signal detection circuit 72 has a function of detecting the presence / absence of a signal in the BS / CS broadcast signal band in addition to the function of the broadcast signal detection circuit 52 of the third embodiment detecting the frequency of the signal in the CATV broadcast band. ing.

  Since the control method and operation for the selector switches 53 and 54 are the same as those in the third embodiment, the description thereof is omitted.

  The changeover switches 75 and 76 pass the signal path from the signal that has passed through the HPF 55 or the HPF 56 to the transmission / reception circuit unit 17 according to the control signal from the broadcast signal detection circuit 72, or do not pass through the LPF 79. Whether to pass the bypass path 80 is switched. The LPF 79 is a filter that attenuates the BS / CS signal band (1030 MHz or more).

  The portion where the signal from the coaxial cable input 16 of the changeover switch 53 is input is an example of the input terminal of the present invention, and the portion connected to the transmission / reception circuit portion 17 of the changeover switch 76 is the output terminal of the present invention. An example.

  When the signal in the BS / CS signal band is detected, the broadcast signal detection circuit 72 transmits a control signal for allowing the LPF 79 to pass to the changeover switches 75 and 76. If a signal in the BS / CS signal band is not detected, a control signal that passes through the bypass path 80 is transmitted to the changeover switches 75 and 76.

  FIG. 8 shows the attenuation characteristics when the filter circuit of the fourth embodiment is used.

  The broadcast signal detection circuit 72 controls the changeover switches 53, 54, 75, and 76 in accordance with the frequency of the broadcast signal to be detected, so that the frequency band of the signal that passes through the filter circuit of the fourth embodiment. To control. Then, the frequency band that can be used for communication is expanded from the communication signal band 23 to the frequency band 81, the frequency band 82, or the frequency band 83 according to the frequency of the detected broadcast signal.

  The communication signal band 23 corresponds to an example of a communication signal band predetermined for communication according to the present invention. In the fourth embodiment, the frequency band of the CATV broadcast band 21 that is equal to or higher than the predetermined frequency and the BS / CS signal band are both examples of the predetermined frequency band of the present invention. .

  Further, the process of inputting a signal including a broadcast signal from the coaxial cable input 16 to the changeover switch 53 corresponds to an example of an external signal input step of the present invention. Moreover, the process in which the broadcast signal detection circuit 72 detects a signal of a predetermined frequency or more in the BS / CS signal band and the CATV broadcast band 21 corresponds to an example of the signal detection step of the present invention. Further, the process of switching the changeover switches 53, 54, 75, and 76 by the control signal from the broadcast signal detection circuit 72 corresponds to an example of the signal path control step of the present invention. The process of sending the signal that has passed through the filter circuit of the fourth embodiment to the transmission / reception circuit unit 17 is an example of the communication signal output step of the present invention.

  As described above, communication can be performed by appropriately extending the frequency band used for communication according to which frequency band the broadcast signal uses, so that frequency use efficiency is improved.

  In addition, when the filter circuit according to the fourth embodiment is used, when the signal in the BS / CS signal band is not received, only the HPF 55 or the HPF 56 is passed. The communication distance in the coaxial cable (5C-FB) is improved by about 10 m.

  As described above, by using the filter circuit of the fourth embodiment, the insertion loss due to the filter can be reduced when a signal in the BS / CS signal band is not received, so the communication distance is increased. Can do. In addition, when a signal in the BS / CS signal band is not received, the BS / CS signal band can be used for communication, and only a broadcast signal having a predetermined frequency or less is received in the CATV broadcast band 21. In this case, the pass band of the HPF 56 in the CATV broadcast band 21 can be used for communication.

(Embodiment 5)
FIG. 9 shows a block diagram of a filter circuit according to the fifth embodiment of the present invention. Similar to the filter circuit of the first embodiment, this filter circuit is a circuit provided in the CATV modem 107 of the communication system as shown in FIG. In addition, the same code | symbol is used for the same component as Embodiment 3. FIG.

  The configuration of the filter circuit of the fifth embodiment will be described together with its operation using FIG.

  The filter circuit of the fifth embodiment includes a broadcast signal detection circuit 92, changeover switches 53, 54, 95, 96, HPFs 55, 56, LPFs 99, 100, and a bypass path 90. The broadcast signal detection circuit 92 is an example of the signal detection means of the present invention. Further, a configuration in which the functional part that controls the change-over switches 53, 54, 95, and 96 of the broadcast signal detection circuit 92 and the change-over switches 53, 54, 95, and 96 is an example of the control circuit of the present invention. LPF99 and LPF100 correspond to an example of the predetermined frequency band suppression filter of the present invention. The HPF 55 corresponds to an example of the first high-pass filter of the present invention, and the HPF 56 corresponds to an example of the second high-pass filter of the present invention.

  Since the changeover switches 53 and 54 and the HPFs 55 and 56 have the same configuration as in the third embodiment, description thereof is omitted.

  The broadcast signal detection circuit 92 detects the frequency of the signal input from the coaxial cable input 16. Then, the broadcast signal detection circuit 92 transmits a control signal for switching the change-over switches 53, 54, 95, 96 to the change-over switches 53, 54, 95, 96 according to the detection result. The broadcast signal detection circuit 92 has a function of detecting the presence or absence of signals in the BS broadcast signal band and the CS broadcast signal band in addition to the function of the broadcast signal detection circuit 52 of the third embodiment detecting the frequency of the CATV broadcast band signal. Also have. Then, unlike the broadcast signal detection circuit 72 of the fourth embodiment, the broadcast signal detection circuit 92 can detect whether a signal having a frequency of 1030 MHz or higher is a signal in the BS signal band or a signal in the CS signal band. It is like that.

  Since the control method and operation for the selector switches 53 and 54 are the same as those in the third embodiment, the description thereof is omitted.

  The change-over switches 95 and 96 allow the signal path from the signal that has passed through the HPF 55 or HPF 56 to the transmission / reception circuit unit 17 to pass through the LPF 99 or the LPF 100 in accordance with the control signal from the broadcast signal detection circuit 92. Or whether to pass through the bypass path 90 through which neither the LPF 99 nor the LPF 100 passes. The LPF 99 is a filter that attenuates the BS signal band and the CS signal band, and the LPF 100 is a filter that attenuates the CS signal band.

  The portion where the signal from the coaxial cable input 16 of the changeover switch 53 is input is an example of the input terminal of the present invention, and the portion connected to the transmission / reception circuit portion 17 of the changeover switch 96 is the output terminal of the present invention. An example.

  When the broadcast signal detection circuit 92 detects a signal in the BS signal band, the broadcast signal detection circuit 92 transmits a control signal that passes through the LPF 99 to the changeover switches 95 and 96. When a signal in the CS signal band that is higher in frequency than the BS signal band is detected, a control signal that passes through the LPF 100 is transmitted to the changeover switches 95 and 96. When neither signal in the BS signal band nor the CS signal band is detected, a control signal that passes through the bypass path 90 is transmitted to the changeover switches 95 and 96.

  Thus, the broadcast signal detection circuit 92 passes through the filter circuit of the fifth embodiment by controlling the changeover switches 53, 54, 95, and 96 according to the frequency of the detected broadcast signal. Control the frequency band of the signal. As in the other embodiments, the frequency band that can be used for communication can be expanded according to the frequency of the detected broadcast signal.

  In the fifth embodiment, all of the frequency band, the BS signal band, and the CS signal band that are equal to or higher than a predetermined frequency in the CATV broadcast band are examples of the predetermined frequency band determined in advance of the present invention. It hits.

  In this way, communication can be performed by appropriately extending the frequency band used for communication according to which frequency band the broadcast signal uses, so that frequency use efficiency is improved.

  In addition, when the filter circuit according to the fifth embodiment is used, when the signal in the BS / CS signal band is not received, only the HPF 55 or the HPF 56 is passed. The communication distance in the coaxial cable (5C-FB) is improved by about 10 m.

  As described above, by using the filter circuit of the fifth embodiment, when no signal in the BS / CS signal band is received, the insertion loss due to the filter can be reduced, so the communication distance is increased. be able to.

  When the BS / CS signal band signal is not received, the BS / CS signal band can be used for communication. When only the CS signal band signal is received, the pass band of the LPF 100 is received. The BS signal band can be used for communication. In the CATV frequency band, when only a broadcast signal having a frequency lower than a predetermined frequency is received, the CATV frequency band in the pass band of the HPF 56 can be used for communication.

  In the configuration of the fifth embodiment shown in FIG. 9, even when the bypass path 90 is not provided, an effect that a frequency band not receiving a signal can be used for communication can be obtained. In that case, the path passing through the HPF 55 and the LPF 99 is an example of the specific frequency suppression path of the present invention, and the other path is an example of the specific frequency passing path of the present invention.

  Note that the frequency band used in terrestrial broadcasting is the same frequency band of 770 MHz or less as the frequency band used for broadcasting signals in the CATV network. Therefore, in each embodiment, the case where the broadcast signal is transmitted through the CATV network has been described. However, the present invention can be applied as it is even when the broadcast signal from the ground broadcast is received from the antenna.

The filter circuit of each embodiment has a configuration in which an HPF (high-pass filter) is disposed on the coaxial cable input side and an LPF (low-pass filter) is disposed on the transmission / reception circuit unit side.
An LPF may be disposed on the coaxial cable input side, and an HPF may be disposed on the transmission / reception circuit unit side.

  As described above, the signal path switching switch and the signal path switching method according to the present invention are such that the filter circuit is associated with both the case where the broadcast is received and the case where the broadcast is not received. When the presence / absence of reception is detected and the BS / CS signal is detected, the switch is switched by the control signal. In addition to the HPF, the LPF is allowed to pass, and when the BS / CS signal is not detected, the switch is switched. The filter circuit is configured to bypass the LPF and pass only the HPF.

  When the BS / CS is not received by using the signal path switch and the signal path switching method of the present invention, the frequency band of the BS / CS can be used for communication, and the BPF is inserted. As compared with the filter, the insertion loss of the filter can be kept low.

  INDUSTRIAL APPLICABILITY The signal path switch and the signal path switching method according to the present invention can reduce the insertion loss due to the filter and increase the communication distance, and can use a frequency band not receiving broadcast as the frequency band of the communication signal. Thus, it has an effect of performing communication with high frequency use efficiency, and is useful for a communication system using a TV coaxial cable.

1 is a block diagram of a filter circuit according to a first embodiment of the present invention. The figure which shows the attenuation | damping characteristic at the time of using the filter circuit of Embodiment 1 of this invention Block diagram of a filter circuit according to a second embodiment of the present invention The figure which shows the attenuation | damping characteristic at the time of using the filter circuit of Embodiment 2 of this invention Block diagram of a filter circuit according to a third embodiment of the present invention The figure which shows the attenuation | damping characteristic at the time of using the filter circuit of Embodiment 3 of this invention Block diagram of a filter circuit according to a fourth embodiment of the present invention The figure which shows the attenuation | damping characteristic at the time of using the filter circuit of Embodiment 4 of this invention Block diagram of a filter circuit according to a fifth embodiment of the present invention (A) Configuration diagram of CATV communication system when BS / CS broadcast is received from antenna separately from cable TV network, (b) Other when receiving BS / CS broadcast from antenna separately from cable TV network Configuration diagram of CATV communication system with configuration, (c) Configuration diagram of CATV communication system when broadcasting data of BS / CS broadcast is sent as broadcast signal of cable television network, (d) BS / CS broadcasting Configuration diagram of CATV communication system when broadcast data is not sent Configuration diagram of BPF provided in a conventional CATV modem The figure which shows the attenuation | damping characteristic of BPF provided in the conventional CATV modem

Explanation of symbols

11, 55, 56 HPF
12, 32 BS / CS signal detection circuit 13, 14, 33, 34, 53, 54, 75, 76, 95, 96 Changeover switch 15, 35, 36, 57, 99, 100 LPF
52, 72, 92 Broadcast signal detection circuit

Claims (11)

An input terminal to which an externally input signal is input;
An output terminal connected to a transmission / reception circuit for communication;
Signal detecting means for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication, in the signal input from the outside;
A predetermined frequency band suppression filter connected between the input terminal and the output terminal and suppressing a signal of the predetermined frequency band;
A bypass path that is provided in parallel with the predetermined frequency band suppression filter and does not pass through the predetermined frequency band suppression filter;
Based on the detection result of the signal detection means, when there is a signal in the predetermined frequency band, the signal passes through the predetermined frequency band suppression filter, and when there is no signal in the predetermined frequency band, the signal passes through the bypass path. A signal path changeover switch comprising a control circuit for controlling the signal path. The predetermined frequency band determined in advance is a BS frequency band or a CS frequency band,
The signal path selector switch according to claim 1, wherein the predetermined frequency band suppression filter is a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band. The predetermined frequency bands determined in advance are a BS frequency band and a CS frequency band,
The predetermined frequency band suppression filter is configured by a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band, and a second low-pass filter that suppresses signals in the CS frequency band, which are arranged in parallel. And
The control circuit passes the first low-pass filter when there is a signal in the BS frequency band, and passes the second low-pass filter when there is no signal in the BS frequency band and there is a signal in the CS frequency band. The signal path changeover switch according to claim 1, wherein the signal path changeover switch is allowed to pass through the bypass path when there is no signal in either the BS frequency band or the CS frequency band. A first high-pass filter that suppresses a signal in the CATV frequency band between the input terminal or the output terminal and the bypass path, and a signal in a frequency band that is less than a predetermined frequency in the CATV frequency band. 2 high-pass filters are provided in parallel,
The signal detection means also detects whether there is a signal in a frequency band equal to or higher than the predetermined frequency in the CATV frequency band in the signal input from the outside,
Based on the detection result of the signal detection means, the control circuit passes the first high-pass filter when there is a signal having a frequency band equal to or higher than the predetermined frequency in the CATV frequency band, and passes the CATV frequency band. 4. The signal path switch according to claim 2, wherein when there is no signal in a frequency band equal to or higher than the predetermined frequency, the second high-pass filter is passed. 5.   The signal path switch according to claim 1, wherein a signal in the communication signal band and a signal other than the communication signal band are input to the input terminal. An input terminal to which an externally input signal is input;
An output terminal connected to a transmission / reception circuit for communication;
Signal detecting means for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication, in the signal input from the outside;
A specific frequency suppression path provided between the input terminal and the output terminal for suppressing a signal of the predetermined frequency band;
A specific frequency passing path that is provided between the input terminal and the output terminal and that allows the signal in the predetermined frequency band to pass through for use in communication as well as the signal in the communication signal band;
Based on the detection result of the signal detection means, when there is a signal of the predetermined frequency band, the specific frequency suppression path is passed, and when there is no signal of the predetermined frequency band, the specific frequency passage path is A signal path changeover switch comprising a control circuit for passing through. The predetermined frequency band determined in advance is a frequency band equal to or higher than a predetermined frequency in the CATV frequency band,
The specific frequency suppression path is a path that passes through a first high-pass filter that suppresses a signal in the CATV frequency band;
The specific frequency passing path is a path that passes through a second high-pass filter that suppresses a signal in a frequency band less than the predetermined frequency in the CATV frequency band, instead of passing through the first high-pass filter. 6. The signal path switch according to 6. The predetermined frequency band determined in advance is a BS frequency band,
The specific frequency suppression path is a path that passes through a first low-pass filter that suppresses signals in the BS frequency band and the CS frequency band,
The signal path selector switch according to claim 6, wherein the specific frequency passing path is a path that passes through a second low-pass filter that suppresses a signal in the CS frequency band, instead of passing through the first low-pass filter. The input terminal is connected to the duplexer by a coaxial cable;
The signal path switch according to claim 6, wherein only the signal of the communication signal band is input to the input terminal as a result of the demultiplexing by the duplexer. An external signal input step for inputting a signal input from the outside;
A signal detecting step for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication in the signal input from the outside;
When it is detected in the signal detection step that there is a signal in the predetermined frequency band, it is passed through a predetermined frequency band suppression filter that suppresses the signal in the predetermined frequency band, and it is detected that there is no signal in the predetermined frequency band. Sometimes, a signal path control step for passing a bypass path that is provided in parallel with the predetermined frequency band suppression filter and does not pass through the predetermined frequency band suppression filter;
A signal path switching method, comprising: a communication signal output step of outputting the communication signal passed in the signal path control step to a transmission / reception circuit for communication. An external signal input step for inputting a signal input from the outside;
A signal detecting step for detecting whether or not there is a signal of a predetermined frequency band other than a predetermined communication signal band for communication in the signal input from the outside;
When it is detected in the signal detection step that there is a signal in the predetermined frequency band, the signal is passed through a specific frequency suppression path for suppressing the signal in the predetermined frequency band, and when it is detected that there is no signal in the predetermined frequency band. A signal path control step of passing a signal of the predetermined frequency band together with the signal of the communication signal band and passing a specific frequency passing path that can be used for the communication;
A signal path switching method, comprising: a communication signal output step of outputting the communication signal passed in the signal path control step to a transmission / reception circuit for communication.

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