JP5823189B2 - Optical receiver system - Google Patents

Description

  The present invention relates to an optical receiving system for receiving an optical signal in an optical transmission system.

  In recent years, with the progress of optical communication technology, optical transmission systems using optical cables have become widespread. According to this optical transmission system, since repeatless transmission of about several tens of kilometers is possible, the transmission system can be easily widened. This optical transmission system generally includes an optical transmitter that is arranged on the sender side and an optical receiver (optical terminal unit, ONU: Optical Network Unit) that is arranged on the receiver side. Connected via a long-distance transmission line. In the optical transmission system configured as described above, on the transmission side, an electrical signal mixed with a television signal or an announcement broadcast signal is converted into an optical signal by an optical transmitter, and the optical signal is transmitted via an optical cable. On the other hand, on the receiving side, this optical signal is received via an optical receiver, converted into an RF signal or an FM signal, and the RF signal is output to a television receiver, and the RF signal or FM signal is sent to a notification broadcast receiver. For example (see Patent Document 1).

JP 2008-236442 A

  By the way, in the conventional optical transmission system as described above, the optical receiving system for receiving the optical signal is merely a wired output of the RF signal or FM signal obtained by converting the optical signal. Therefore, a television receiver or notification broadcast receiver having an RF signal or FM signal input terminal can receive an RF signal or FM signal output from a conventional optical reception system, but an RF signal or FM signal input terminal. A mobile phone or mobile terminal that does not have a signal cannot receive an RF signal or an FM signal output by wire from a conventional optical receiving system. As a result, when a signal for a one-segment partial reception service for mobile phones and mobile terminals (hereinafter referred to as “one-segment” if necessary) is included in the RF signal output by wire from the conventional optical reception system. Even so, it was not possible to use 1Seg on mobile phones and mobile terminals. For example, in areas or buildings where it is difficult to receive 1Seg broadcast waves, even if a conventional optical reception system is installed, 1Seg cannot be used with a mobile phone or mobile terminal. There was a possibility.

  An object of the present invention is to provide an optical reception system that enables one-segment broadcasting to be used by a mobile phone or a mobile terminal even in an area or building where it is difficult to receive one-segment broadcasting waves. And

In order to solve the above-described problems and achieve the object, the optical reception system according to claim 1 includes a photoelectric conversion unit that converts an optical signal transmitted via an optical transmission path into an RF signal, and the photoelectric conversion unit. An optical receiver having an RF output terminal for outputting the RF signal converted by the unit by wire, and an FM output terminal for outputting the FM signal acquired from the RF signal by wire, and converted by the photoelectric conversion unit An antenna that wirelessly transmits one or both of an RF signal and an FM signal acquired from the RF signal, and the antenna includes a backup power source for wirelessly transmitting the signal even during a power failure .

  An optical receiving system according to a second aspect is the optical receiving system according to the first aspect, wherein an RF input terminal that receives an RF signal output from the RF output terminal in a wired manner and an FM output terminal are provided. An FM input terminal that receives an input of an FM signal output by wire, an RF signal input to the RF input terminal, an output terminal that outputs an FM signal input to the FM input terminal, and the RF input terminal Or a switching unit that selectively switches one of the FM input terminals and connects to the output terminal, and the antenna outputs the RF signal or FM signal output from the output terminal. Is transmitted wirelessly.

  The optical reception system according to claim 3 is the optical reception system according to claim 1, wherein the antenna includes an RF signal branched from between the photoelectric conversion unit and the RF output terminal and the photoelectric conversion. One or both of the FM signals branched from between the unit and the FM output terminal are wirelessly transmitted.

  An optical reception system according to claim 4 is the optical reception system according to any one of claims 1 to 3, further comprising power supply means for supplying electric power to the optical receiver, wherein the photoelectric conversion unit When the power is supplied from the power supply means to the optical receiver, the power is used in the reverse bias mode, and the power is not supplied from the power supply means to the optical receiver. In the non-bias mode, the optical receiver is configured by using a photodiode, and the optical receiver converts the RF signal converted by the photoelectric conversion unit into power supplied to the optical receiver from the power supply unit. When the optical receiver is supplied with power from the power supply means, the RF signal amplified by the amplification means is amplified. Is output from the RF output terminal in a wired manner, and an FM signal acquired from the RF signal converted by the photoelectric conversion unit is output in a wired manner from the FM output terminal, and power is supplied from the power supply means to the optical receiver. When not supplied, only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal by wire.

The optical receiving system according to claim 5 is the optical receiving system according to claim 2 , further comprising power supply means for supplying power to the optical receiver, wherein the photoelectric conversion unit is connected to the optical receiver. When power is supplied from the power supply means, the power is used in a reverse bias mode, and when power is not supplied to the optical receiver from the power supply means, it is used in a biasless mode. The optical receiver is configured to amplify the RF signal converted by the photoelectric conversion unit using the power supplied from the power supply means to the optical receiver, Amplifying means for outputting to the RF output terminal, and when power is supplied from the power supply means to the optical receiver, the RF signal amplified by the amplifying means is supplied to the RF output terminal; The FM signal acquired from the RF signal converted by the photoelectric conversion unit is wired from the FM output terminal, and power is not supplied from the power supply means to the optical receiver. Only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal in a wired manner, the power supply means supplies power to the switch, and the switching means When power is supplied from the power supply means to the switch, the RF input terminal is connected to the output terminal, and when power is not supplied from the power supply means to the switch, The FM input terminal is connected to the output terminal.

  Thus, according to the optical receiving system of the first aspect, the optical receiving system is converted by the photoelectric conversion unit that converts the optical signal transmitted through the optical transmission path into the RF signal, and the photoelectric conversion unit. An optical receiver having an RF output terminal for outputting a wired RF signal and an FM output terminal for outputting an FM signal obtained from the RF signal, an RF signal converted by the photoelectric conversion unit, and the RF signal Since it has an antenna that wirelessly transmits one or both of the acquired FM signals, it can receive RF signals wirelessly transmitted from the antenna even in areas or buildings where it is difficult to receive one-seg broadcast waves By doing so, 1Seg can be used with a mobile phone or a mobile terminal.

  According to the optical receiving system of claim 2, the optical receiving system includes an RF input terminal that receives an input of an RF signal output from the RF output terminal in a wired manner, and an FM that is output in a wired manner from the FM output terminal. Either an FM input terminal that receives a signal input, an RF signal that is input to the RF input terminal, an output terminal that outputs an FM signal that is input to the FM input terminal, or an RF input terminal or an FM input terminal And a switch having a switching means for selectively switching and connecting to the output terminal, and the antenna wirelessly transmits the RF signal or FM signal output from the output terminal. Instead, the antenna can be arranged at an arbitrary position.

  According to the optical reception system of claim 3, the antenna includes an RF signal branched from between the photoelectric conversion unit and the RF output terminal, and an FM branched from between the photoelectric conversion unit and the FM output terminal. Since one or both of the signals are transmitted wirelessly, even in areas or buildings where it is difficult to receive one-seg broadcast waves, receiving RF signals transmitted wirelessly from the antenna enables mobile phones or mobile One Seg can be used on the body terminal. It is also possible to use FM radio broadcasting using an FM receiver.

  According to the optical receiver system of claim 4, when the optical receiver is supplied with power from the power supply means, the optical receiver outputs the RF signal amplified by the amplification means to the RF output. When the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal in a wired manner and power is not supplied from the power supply means to the optical receiver, Since only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output by wire from the FM output terminal, FM radio broadcasting is used on a mobile phone or mobile terminal equipped with an FM receiver even when no power is supplied. It becomes possible.

  According to the optical receiving system of claim 5, when the power is supplied from the power supply means to the switch, the switching means connects the RF input terminal to the output terminal and from the power supply means. When power is not supplied to the switch, the FM input terminal is connected to the output terminal, so that the switch can be automatically operated according to the presence or absence of power supply from the power supply means. Thus, it is possible to eliminate the trouble of manual operation and to prevent malfunction during manual operation.

1 is a configuration diagram of an optical reception system according to Embodiment 1. FIG. FIG. 3 is a circuit diagram of the switch according to the first embodiment. 3 is a configuration diagram of an optical reception system according to Embodiment 2. FIG.

  Hereinafter, embodiments of an optical receiving system according to the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited by these embodiments.

[Embodiment 1]
First, the first embodiment will be described. This Embodiment 1 is a form provided with a switch.

(Constitution)
FIG. 1 is a configuration diagram of an optical reception system according to the first embodiment. As shown in FIG. 1, the optical reception system 1 includes an optical receiver 10, a switching device 20, a branching device 30, an antenna 40, and a power inserter 50 (shown as “PI” in FIG. 1). In the first embodiment, the television receiver 60 and the notification broadcast receiver 70 are wired to the optical receiver 10 via the switcher 20 and the branching device 30. The notification broadcast receiver 70 and the television receiver 60 can be configured in the same manner as in the prior art, and thus detailed description thereof is omitted. In addition, since the optical receiver 10, the branching device 30, and the power inserter 50 can be basically configured in the same manner as the conventional one, only the configuration particularly related to the present embodiment will be described below. Other detailed explanation is omitted.

(Configuration-optical receiver)
The optical receiver 10 is a non-feed-type optical receiver capable of outputting a signal without supplying power for driving the device, and is a photodiode 11 (hereinafter referred to as “PD” as necessary). , An amplifier 12, an RF output terminal 13, and an FM output terminal 14. The PD 11 is a photoelectric conversion unit that converts an optical signal transmitted via an optical transmission path into an RF signal. When power is supplied from the power inserter 50 to the optical receiver 10, the PD 11 performs reverse processing using the power. When the optical receiver 10 is not supplied with power from the power inserter 50, the bias mode is used. The amplifier 12 is an amplifying unit that amplifies the RF signal converted by the PD 11 using the power supplied from the power inserter 50 to the optical receiver 10 and outputs the amplified signal to the RF output terminal 13. The RF output terminal 13 outputs the RF signal converted by the PD 11 in a wired manner. The FM output terminal 14 outputs the FM signal acquired from the RF signal by wire.

  When power is supplied from the power inserter 50 to the optical receiver 10, the optical receiver 10 receives the power supplied from the power inserter 50 via the RF output terminal 13, and receives the received power. The optical signal is converted into an RF signal by the PD 11 in the reverse bias mode, and the RF signal is amplified by the amplifier 12. In this case, the optical receiver 10 outputs the RF signal amplified by the amplifier 12 from the RF output terminal 13 by wire, and outputs the FM signal acquired from the RF signal converted by the PD 11 from the FM output terminal 14 by wire. To do.

  On the other hand, when the optical receiver 10 is not supplied with power from the power inserter 50, the optical receiver 10 receives only the FM signal acquired from the RF signal converted by the PD 11 in the no-bias mode as the FM output terminal 14. To output in a wired manner.

  As a specific circuit configuration of the non-feed-type optical receiver 10, for example, configurations disclosed in Japanese Unexamined Patent Application Publication Nos. 2010-068195 and 2010-093778 can be applied. Note that the case where power is supplied to the optical receiver 10 from the power inserter 50 usually means that there is no power failure, and the case where power is not supplied to the optical receiver 10 from the power inserter 50 is normal. Means the time of a power failure, but the latter case may include a time when the power inserter 50 breaks down, a time when the power inserter 50 is unplugged by mistake, and the like even during a non-power failure. Hereinafter, a state in which power is supplied to the target device is referred to as “power supply”, and a state in which power is not supplied to the target device is referred to as “no power supply” regardless of the cause.

(Configuration-Switcher)
FIG. 2 is a circuit diagram of the switcher 20. As shown in FIG. 2, the switcher 20 includes an RF input terminal 21, an FM input terminal 22, an output terminal 23, a relay 24, and a choke coil 25. The RF input terminal 21 is an input terminal that receives an input of an RF signal output from the RF output terminal 13 by wire, and is connected to the RF output terminal 13 of the optical receiver 10 via a coaxial cable 80, for example. The FM input terminal 22 is an input terminal that receives an input of an FM signal output from the FM output terminal 14 by wire, and is connected to the FM output terminal 14 of the optical receiver 10 via a coaxial cable 81. The output terminal 23 is an output terminal that outputs the RF signal input to the RF input terminal 21 or the FM signal input to the FM input terminal 22 by wire, and is connected to the branching device 30 via the coaxial cable 82. . The relay 24 is a switching unit that selectively switches one of the RF input terminal 21 and the FM input terminal 22 and connects it to the output terminal 23. The coil 24 a of the relay 24 is connected to the output terminal 23, and a direct current is supplied via the output terminal 23 from the power inserter 50 arranged on the downstream side of the switcher 20. The relay 24 connects the RF input terminal 21 to the output terminal 23 when power is supplied, and connects the FM input terminal 22 to the output terminal 23 when power is not supplied. Therefore, it is possible to automatically operate the changeover switch according to the presence or absence of power supply from the power inserter 50. The choke coil 25 is for cutting an alternating current component with respect to the coil line of the relay 24, and is connected between the output terminal 23 and the coil 24 a of the relay 24. However, when the driving current of the relay 24 is small, a simple coil may be used instead of the choke coil 25. Further, when the AC component can be cut by the coil 24a of the relay 24, the choke coil 25 may be omitted. Further, the relay 24 and the choke coil 25 may be omitted, and a manual mechanical switch may be provided as a switching unit. In this case, switching of the mechanical switch is manually performed at an arbitrary timing by a user or a maintenance person.

(Configuration-Branch)
Returning to FIG. 1, the branching device 30 is for branching the RF signal or FM signal output from the switcher 20 in a wired manner to the antenna 40, the notification broadcast receiver 70, and the television receiver 60. As this branching device 30, a known branching device can be used. In the example of FIG. 1, the notification broadcast receiver 70 is connected to the main line system of the branching device 30 via the power inserter 50 and the coaxial cables 84 and 85, and the coaxial cable 83 is connected to the branching system of the branching device 30. An antenna 40 is connected to the television receiver 60, and a television receiver 60 is connected to the television receiver 60 through a coaxial cable 86. Since the output level of the FM signal from the optical receiver 10 when no power is supplied is very small, the notification broadcast receiver 70 is connected to the trunk line system with less signal loss compared to the branch system, and the FM signal is output from the branch unit 30. By suppressing the loss to a minimum, a decrease in the S / N ratio of the FM signal input to the notification broadcast receiver 70 is suppressed. Note that the trunk line system is a so-called Dentsu that can pass a DC voltage.

(Configuration-Antenna)
The antenna 40 is used to wirelessly transmit an RF signal or FM signal output from the output terminal 23 of the switcher 20 and branched to the antenna 40 by the branching device 30. The antenna 40 is connected to the branching device 30 via a coaxial cable 83. As the antenna 40, a known omnidirectional antenna or a directional antenna can be used. The antenna 40 is driven by being supplied with a power inserter 50 or an external power source, and is provided with a backup power source such as a battery so that a signal can be output even during a power failure.

(Configuration-Power Inserter)
The power inserter 50 is a power supply unit that supplies power to the optical receiver 10 and the switcher 20. The power inserter 50 is connected between the branching device 30 and the notification broadcast receiver 70 via coaxial cables 84 and 85. In the first embodiment, the notification broadcast receiver 70 is connected to the trunk line system of the branching device 30, and the trunk line system of the branching device 30 is in electrical communication. Therefore, by arranging the power inserter 50 in the preceding stage of the notification broadcast receiver 70, it becomes possible to supply power to the optical receiver 10 via the trunk line system of the branching device 30. In addition, about the specific structure of the power inserter 50, since it can comprise similarly to the past, the detailed description is abbreviate | omitted.

(Operation)
Next, the operation of the optical reception system 1 configured as described above will be described. First, during power feeding, the relay 24 of the switcher 20 connects the RF input terminal 21 to the output terminal 23. In this state, the power supplied from the power inserter 50 is input to the output terminal 23 of the switcher 20 via the trunk line system of the branching device 30, and the RF output terminal of the optical receiver 10 via the RF input terminal 21. 13 is input. As a result, power is supplied to the optical receiver 10. The RF signal converted from the optical signal by the PD 11 of the optical receiver 10 is amplified by the amplifier 12 and output from the RF output terminal 13 by wire. The RF signal output from the RF output terminal 13 by wire is input to the RF input terminal 21 of the switcher 20, output from the output terminal 23 by wire, and sent to the notification broadcast receiver 70 via the trunk line system of the branching device 30. It is input to the antenna 40 and the television receiver 60 through the branch system of the branching device 30. As a result, notification broadcast by the notification broadcast receiver 70 and television reception by the television receiver 60 become possible. In addition, the antenna 40 wirelessly transmits the input RF signal (one-segment broadcasting RF signal included therein). As a result, even in areas or buildings where it is difficult to receive 1Seg broadcast waves, 1Seg can be used with mobile phones and mobile terminals.

  On the other hand, when no power is supplied, the relay 24 of the switcher 20 connects the FM input terminal 22 to the output terminal 23. In this state, the optical receiver 10 outputs only the FM signal acquired from the RF signal converted from the optical signal by the PD 11 from the FM output terminal 14 in a wired manner. The FM signal output from the FM output terminal 14 by wire is input to the FM input terminal 22 of the switcher 20, output from the output terminal 23 by wire, and sent to the notification broadcast receiver 70 via the trunk line system of the branching device 30. It is input to the antenna 40 and the television receiver 60 through the branch system of the branching device 30. As a result, notification broadcast by the notification broadcast receiver 70 is possible even when no power is supplied. The antenna 40 wirelessly transmits the input FM signal. This makes it possible to use FM radio broadcasting on a mobile phone or mobile terminal equipped with an FM receiver when no power is supplied.

(effect)
As described above, according to the first embodiment, the optical receiving system 1 converts the optical signal transmitted via the optical transmission path into the RF signal, and the RF that outputs the RF signal converted by the PD 11 by wire. One of the optical receiver 10 having the output terminal 13 and the FM output terminal 14 for outputting the FM signal acquired from the RF signal by wire, the RF signal converted by the PD 11 and the FM signal acquired from the RF signal, or Since both are provided with an antenna 40 for wireless transmission, a mobile phone can be obtained by receiving an RF signal wirelessly transmitted from the antenna 40 even in an area or building where it is difficult to receive a one-segment broadcast wave. And 1Seg can be used on mobile terminals.

  Further, the optical receiving system 1 includes an RF input terminal 21 that receives an input of an RF signal output from the RF output terminal 13 and an FM input terminal 22 that receives an input of the FM signal output from the FM output terminal 14. One of the RF input terminal 21 and the FM input terminal 22, and the output terminal 23 that outputs the RF signal input to the RF input terminal 21 or the FM signal input to the FM input terminal 22 by wire. Since the antenna 40 wirelessly transmits the RF signal or FM signal output from the output terminal 23, the installation position of the optical receiver 10 is provided. Regardless, the antenna 40 can be arranged at an arbitrary position.

  When the optical receiver 10 is supplied with power from the power inserter 50, the optical receiver 10 outputs the RF signal amplified by the amplifier 12 from the RF output terminal 13 in a wired manner, and also by the PD 11 The FM signal acquired from the converted RF signal is output from the FM output terminal 14 in a wired manner, and is acquired from the RF signal converted by the PD 11 when the optical receiver 10 is not supplied with power from the power inserter 50. Since only the FM signal is output by wire from the FM output terminal 14, it is possible to use FM radio broadcasting on a mobile phone or mobile terminal equipped with an FM receiver even when there is no power supply.

  In addition, when power is supplied from the power inserter 50 to the switching device 20, the relay 24 connects the RF input terminal 21 to the output terminal 23, and power is not supplied from the power inserter 50 to the switching device 20. In this case, since the FM input terminal 22 is connected to the output terminal 23, the change-over switch can be automatically operated according to the presence or absence of power supply from the power inserter 50, and a mechanical switch is provided and operated manually. It is possible to save labor and to prevent malfunction during manual operation.

[Embodiment 2]
Next, a second embodiment will be described. In the second embodiment, the antenna wirelessly transmits one or both of an RF signal branched from between the photoelectric conversion unit and the RF output terminal and an FM signal branched from between the photoelectric conversion unit and the FM output terminal. It is a form to do. The configuration of the second embodiment is substantially the same as the configuration of the first embodiment, unless otherwise specified. The same configuration as that of the first embodiment is used in the first embodiment. The same reference numerals and / or names as those used are attached as necessary, and description thereof is omitted.

(Constitution)
FIG. 3 is a configuration diagram of the optical reception system 1 according to the second embodiment. As shown in FIG. 3, in the optical receiving system 1 according to the second embodiment, the switcher 20 and the branching device 30 are omitted from the optical receiving system 1 according to the first embodiment shown in FIG. The broadcast receiver 70 is wired to the FM output terminal 14 of the optical receiver 10 via a coaxial cable 87, and the television receiver 60 is wired to the RF output terminal 13 via coaxial cables 88 and 89. Has been. The power inserter 50 is connected between the optical receiver 10 and the television receiver 60 via coaxial cables 88 and 89. The power inserter 50 and the optical receiver 10 are electrically connected, and power can be supplied from the power inserter 50 to the optical receiver 10 via the coaxial cable 88. The power inserter 50 may be provided not between the optical receiver 10 and the television receiver 60 but between the optical receiver 10 and the notification broadcast receiver 70.

(Configuration-Antenna)
The antenna 40 wirelessly transmits one or both of an RF signal branched from between the PD 11 and the RF output terminal 13 and an FM signal branched from between the PD 11 and the FM output terminal 14. Specifically, as shown in FIG. 3, the RF signal amplified by the amplifier 12 and the FM signal acquired from the RF signal converted by the PD 11 are mixed and input to the antenna 40. The antenna 40 is driven by being supplied with a power inserter 50 or an external power source, and is provided with a backup power source such as a battery so that a signal can be output even during a power failure. When power is supplied, both the RF signal and the FM signal are transmitted wirelessly, and only the FM signal is transmitted during a power failure. This wireless transmission signal can be switched by monitoring the power supply state from a supply source such as the power inserter 50.

(Configuration-operation)
Next, the operation of the optical reception system 1 configured as described above will be described. First, at the time of power feeding, the power supplied from the power inserter 50 is input to the RF output terminal 13 of the optical receiver 10 via the coaxial cable 88. As a result, power is supplied to the optical receiver 10. The RF signal converted from the optical signal by the PD 11 of the optical receiver 10 is amplified by the amplifier 12 and output from the RF output terminal 13 by wire. An RF signal output by wire from the RF output terminal 13 is input to the television receiver 60. As a result, television reception by the television receiver 60 becomes possible. Further, the FM signal acquired from the RF signal converted from the optical signal by the PD 11 is output from the FM output terminal 14 in a wired manner. The FM signal output by wire from the FM output terminal 14 is input to the notification broadcast receiver 70. As a result, the notification broadcast by the notification broadcast receiver 70 becomes possible. Further, the RF signal amplified by the amplifier 12 and the FM signal acquired from the RF signal converted from the optical signal by the PD 11 are mixed and input to the antenna 40. The antenna 40 wirelessly transmits the input signal. In this case, since the level of the RF signal amplified by the amplifier 12 is sufficiently higher than the level of the FM signal acquired from the RF signal converted from the optical signal by the PD 11, the signal wirelessly transmitted from the antenna 40 is changed. An RF signal for included one-segment broadcasting can be received by a mobile phone or a mobile terminal. As a result, even in areas or buildings where it is difficult to receive 1Seg broadcast waves, 1Seg can be used with mobile phones and mobile terminals. Note that the setting on the antenna 40 side can be switched so as to stop the wireless transmission of the RF signal even during power feeding.

  On the other hand, the RF signal is not output from the RF output terminal 13 because the amplifier 12 does not operate when no power is supplied. On the other hand, the FM signal acquired from the RF signal converted from the optical signal by the PD 11 is output from the FM output terminal 14 by wire. The FM signal output by wire from the FM output terminal 14 is input to the notification broadcast receiver 70. As a result, notification broadcast by the notification broadcast receiver 70 is possible even when no power is supplied. Further, the FM signal acquired from the RF signal converted from the optical signal by the PD 11 is also input to the antenna 40. The antenna 40 wirelessly transmits the input FM signal. This makes it possible to use FM radio broadcasting on a mobile phone or mobile terminal equipped with an FM receiver when no power is supplied.

(effect)
As described above, according to the second embodiment, the antenna 40 has one or both of the RF signal branched from between the PD 11 and the RF output terminal 13 and the FM signal branched from between the PD 11 and the FM output terminal 14. Therefore, even in areas or buildings where it is difficult to receive 1Seg broadcast waves, by receiving the RF signal transmitted wirelessly from the antenna 40, the mobile phone or mobile terminal can Will be available. It is also possible to use FM radio broadcasting using an FM receiver.

[Modifications to Embodiments]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention may be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can do. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved.

(Specific circuit configuration)
As specific circuit configurations of the optical receiver 10 and the switching device 20, in addition to the circuit configurations exemplified in the respective embodiments, as long as the above-described functions can be achieved, known circuit configurations are used. Can be applied.
(Appendix)
The optical receiving system of Appendix 1 includes a photoelectric conversion unit that converts an optical signal transmitted via an optical transmission path into an RF signal, an RF output terminal that outputs the RF signal converted by the photoelectric conversion unit via a wire, An optical receiver having an FM output terminal that outputs an FM signal acquired from the RF signal by wire, and one or both of an RF signal converted by the photoelectric conversion unit and an FM signal acquired from the RF signal. An antenna for wireless transmission.
The optical reception system of appendix 2 is the optical reception system of appendix 1, wherein an RF input terminal that receives an input of an RF signal output from the RF output terminal in a wired manner and an FM that is output in a wired manner from the FM output terminal An FM input terminal for receiving a signal input, an RF signal input to the RF input terminal or an output terminal for outputting an FM signal input to the FM input terminal by wire, and the RF input terminal or the FM input terminal. A switching unit that selectively switches one of them and connects to the output terminal, and the antenna wirelessly transmits the RF signal or the FM signal output from the output terminal.
The optical reception system of appendix 3 is the optical reception system of appendix 1, wherein the antenna includes an RF signal branched from between the photoelectric conversion unit and the RF output terminal, and the photoelectric conversion unit and the FM output terminal. One or both of the FM signals branched from between are wirelessly transmitted.
The optical reception system according to appendix 4 is the optical reception system according to any one of appendices 1 to 3, further comprising power supply means for supplying power to the optical receiver, wherein the photoelectric conversion unit includes the optical receiver. When the power is supplied from the power supply means, the power is used in the reverse bias mode. When the power is not supplied to the optical receiver from the power supply means, the bias is not applied. Used, configured using a photodiode, the optical receiver amplifies the RF signal converted by the photoelectric conversion unit using the power supplied from the power supply means to the optical receiver, Amplifying means for outputting to the RF output terminal; and when the optical receiver is supplied with power from the power supply means, the RF signal amplified by the amplifying means is output to the RF output terminal. An FM signal obtained from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal in a wired manner, and power is not supplied from the power supply means to the optical receiver. In this case, only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal by wire.
The optical receiving system according to appendix 5 is the optical receiving system according to appendices 2 and 4, wherein the power supply means supplies power to the switch, and the switching means supplies power from the power supply means to the switch. Is connected to the output terminal, and when power is not supplied from the power supply means to the switch, the FM input terminal is connected to the output terminal. To do.
(Additional effects)
According to the optical reception system described in appendix 1, the optical reception system includes a photoelectric conversion unit that converts an optical signal transmitted through the optical transmission path into an RF signal, and a wired RF signal converted by the photoelectric conversion unit. An optical receiver having an RF output terminal that outputs an RF signal and an FM output terminal that outputs an FM signal acquired from the RF signal by wire, an RF signal converted by the photoelectric conversion unit, and an FM signal acquired from the RF signal 1 or both of the antennas for wireless transmission, even in areas or buildings where it is difficult to receive one-seg broadcast waves, by receiving RF signals transmitted wirelessly from the antenna, 1Seg can be used on telephones and mobile terminals.
According to the optical reception system of appendix 2, the optical reception system includes an RF input terminal that receives an input of an RF signal output from the RF output terminal by wire, and an input of the FM signal that is output from the FM output terminal by wire. An FM input terminal that receives the signal, an RF signal input to the RF input terminal, an output terminal that outputs the FM signal input to the FM input terminal in a wired manner, and either the RF input terminal or the FM input terminal. And an antenna that wirelessly transmits the RF signal or FM signal output from the output terminal, so that the antenna can be connected regardless of the installation position of the optical receiver. Can be placed at any position.
According to the optical reception system of appendix 3, the antenna is configured to transmit one of an RF signal branched from between the photoelectric conversion unit and the RF output terminal and an FM signal branched from between the photoelectric conversion unit and the FM output terminal. Or, since both are wirelessly transmitted, even in areas or buildings where it is difficult to receive 1Seg broadcast waves, by receiving the RF signal transmitted wirelessly from the antenna, the mobile phone or mobile terminal 1Seg can be used. It is also possible to use FM radio broadcasting using an FM receiver.
According to the optical receiver system described in appendix 4, when the optical receiver is supplied with power from the power supply unit, the optical receiver wired the RF signal amplified by the amplification unit from the RF output terminal. When the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal in a wired manner and power is not supplied from the power supply means to the optical receiver, the photoelectric conversion unit Since only the FM signal acquired from the RF signal converted by the wireless communication is output from the FM output terminal by wire, it is possible to use FM radio broadcasting on a mobile phone or mobile terminal equipped with an FM receiver even when there is no power supply. It becomes.
According to the optical receiving system described in appendix 5, when the power is supplied from the power supply unit to the switch, the switching unit connects the RF input terminal to the output terminal, and the power supply unit to the switch. When power is not supplied, the FM input terminal is connected to the output terminal, so that the changeover switch can be operated automatically according to the presence or absence of power supply from the power supply means, and a mechanical switch is provided. Manual operation can be saved, and malfunction during manual operation can be prevented.

1 Optical receiver system 10 Optical receiver 11 Photodiode (PD)
12 amplifier 13 RF output terminal 14 FM output terminal 20 switch 21 RF input terminal 22 FM input terminal 23 output terminal 24 relay 24a coil 25 choke coil 30 branching device 40 antenna 50 power inserter (PI)
60 TV receiver 70 Notification broadcast receiver 80-89 Coaxial cable

Claims (5)

A photoelectric conversion unit that converts an optical signal transmitted through an optical transmission path into an RF signal, an RF output terminal that outputs the RF signal converted by the photoelectric conversion unit by wire, and an FM signal acquired from the RF signal An optical receiver having an FM output terminal for outputting
An antenna that wirelessly transmits one or both of an RF signal converted by the photoelectric conversion unit and an FM signal acquired from the RF signal ;
The antenna includes a backup power source for wirelessly transmitting a signal even during a power failure,
Optical receiver system. An RF input terminal that receives an input of an RF signal output from a wire from the RF output terminal, an FM input terminal that receives an input of an FM signal output from the FM output terminal via a wire, and an input to the RF input terminal A switch for selectively switching between an output terminal for outputting an RF signal or an FM signal input to the FM input terminal in a wired manner and an RF input terminal or the FM input terminal for connection to the output terminal And a switch having means,
The antenna wirelessly transmits an RF signal or an FM signal output from the output terminal.
The optical receiving system according to claim 1. The antenna wirelessly transmits one or both of an RF signal branched from between the photoelectric conversion unit and the RF output terminal and an FM signal branched from between the photoelectric conversion unit and the FM output terminal.
The optical receiving system according to claim 1. Power supply means for supplying power to the optical receiver;
When the power is supplied from the power supply means to the optical receiver, the photoelectric conversion unit is used in a reverse bias mode using the power, and the power is supplied from the power supply means to the optical receiver. If not, it is configured with a photodiode, used in no-bias mode,
The optical receiver is:
Amplifying means for amplifying the RF signal converted by the photoelectric conversion unit using the power supplied from the power supply means to the optical receiver, and outputting the amplified signal to the RF output terminal;
When power is supplied to the optical receiver from the power supply unit, the RF signal amplified by the amplification unit is output from the RF output terminal in a wired manner, and the RF signal converted by the photoelectric conversion unit is output. The FM signal acquired from the signal is output from the FM output terminal by wire,
When power is not supplied from the power supply means to the optical receiver, only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal in a wired manner.
The optical receiving system according to any one of claims 1 to 3. Power supply means for supplying power to the optical receiver;
When the power is supplied from the power supply means to the optical receiver, the photoelectric conversion unit is used in a reverse bias mode using the power, and the power is supplied from the power supply means to the optical receiver. If not, it is configured with a photodiode, used in no-bias mode,
The optical receiver is:
Amplifying means for amplifying the RF signal converted by the photoelectric conversion unit using the power supplied from the power supply means to the optical receiver, and outputting the amplified signal to the RF output terminal;
When power is supplied to the optical receiver from the power supply unit, the RF signal amplified by the amplification unit is output from the RF output terminal in a wired manner, and the RF signal converted by the photoelectric conversion unit is output. The FM signal acquired from the signal is output from the FM output terminal by wire,
When power is not supplied from the power supply means to the optical receiver, only the FM signal acquired from the RF signal converted by the photoelectric conversion unit is output from the FM output terminal by wire,
The power supply means supplies power to the switch;
When the power is supplied from the power supply means to the switch, the switching means connects the RF input terminal to the output terminal, and the power is supplied from the power supply means to the switch. If not, connect the FM input terminal to the output terminal;
The optical receiving system according to claim 2 .

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