JP2018074279A - Power supply device and optical communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a power supply device to be remotely controlled from a station device.SOLUTION: A power inserter 140 acquiring a video signal from a station device on a communication common carrier side via a V-ONU 130 includes: a photoelectric conversion unit 161 for generating a processing signal by receiving an optical data signal from the station device and converting the optical data signal into an electric signal; a line termination processing unit 162 for detecting a control signal for controlling the V-ONU 130 from the processing signal; a power generation unit 152 for generating power to be supplied to the V-ONU 130; and a power supply control unit 153 for controlling the supply of power to the V-ONU 130 according to the control signal.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a power supply apparatus and an optical communication system, and more particularly, to a power supply apparatus that supplies power to a video apparatus and an optical communication system including the power supply apparatus.

  A conventional coaxial power supply apparatus is installed in a subscriber's house and supplies power to a video apparatus installed outside the subscriber's house via a transmission medium such as a coaxial cable (for example, see Patent Document 1). ). In such a configuration, a signal from the station device installed in the station is received by the video device and transferred to the coaxial power feeding device. For this reason, it has been impossible to perform a remote operation in which the station device controls the coaxial power feeding device and stops power feeding to the video device.

JP 2012-4968 A

  Since the conventional coaxial power supply apparatus cannot directly receive the signal distributed by the station apparatus as described above, remote control that stops the power supply of the video apparatus from the station apparatus cannot be performed. For this reason, there has been a problem that the user cannot cancel the service other than removing the video device for the user who has canceled the data communication service or the video distribution service.

  SUMMARY OF THE INVENTION An object of the present invention is to enable remote control of a power feeding device from a station device.

  A power supply apparatus according to an aspect of the present invention is a power supply apparatus that acquires a video signal from a station device on a telecommunications carrier side via a video device, and receives an optical data signal from the station apparatus. A photoelectric conversion unit that generates a processing signal by converting the optical data signal into an electrical signal; a line termination processing unit that detects a control signal for controlling the video device from the processing signal; A power generation unit that generates power to be supplied to the video device, and a power supply control unit that controls supply of power to the video device according to the control signal.

  The optical communication system according to the first aspect of the present invention is for video that receives an optical video signal included in an optical signal from a station device on the side of a telecommunications carrier and converts the optical video signal into an electrical signal. An optical communication system comprising a device and a power feeding device that acquires a video signal based on an electrical signal converted by the video device, wherein the power feeding device receives an optical data signal from the station device. A photoelectric conversion unit that generates a processing signal by converting the optical data signal into an electrical signal; a line termination processing unit that detects a control signal for controlling the video device from the processing signal; According to the control signal, the first power or the power generation unit that generates the first power and the second power having a voltage lower than the first power as the power to be supplied to the video device. The second power is supplied to the video device. A power supply control unit that supplies power to the video device, a signal processing unit that converts the optical video signal into an electrical signal, and a power supply voltage detection unit that detects a voltage value of power supplied from the power supply device And a display unit, and when the voltage value indicates second power, a power supply voltage monitoring unit that causes the signal processing unit to stop processing and causes the display unit to display that processing has stopped. It is characterized by providing.

  The optical communication system according to the second aspect of the present invention is for video that receives an optical video signal included in an optical signal from a station device on the side of a telecommunications carrier and converts the optical video signal into an electrical signal. An optical communication system comprising a device and a power feeding device that acquires a video signal based on an electrical signal converted by the video device, wherein the power feeding device receives an optical data signal from the station device. A photoelectric conversion unit that generates a processing signal by converting the optical data signal into an electrical signal; a line termination processing unit that detects a control signal for controlling the video device from the processing signal; According to the control signal, the first power or the power generation unit that generates the first power and the second power having a voltage lower than the first power as the power to be supplied to the video device. The second power is supplied to the video device. And supplying the first power according to the control signal, the first pulse signal is generated using the voltage of the first power, and the second power is generated according to the control signal. A power supply control unit configured to generate a second pulse signal different from the first pulse signal by using the voltage of the second power when supplying the power; A signal processing unit that converts a video signal into an electrical signal, a power supply voltage detection unit that detects a voltage value of power supplied from the power supply device, a display unit, and the second pulse signal detected by the voltage value And a power supply voltage monitoring unit that causes the signal processing unit to stop processing and causes the display unit to display that the processing is stopped.

  According to one embodiment of the present invention, since a control signal can be detected from an optical signal from a station apparatus, the power feeding apparatus can be remotely controlled from the station apparatus.

It is a block diagram which shows roughly the structure of the optical communication system which concerns on Embodiment 1-4. FIG. 3 is a block diagram schematically showing a configuration of a power inserter in the first embodiment. 4 is a table showing a correspondence between an operation state of a power inserter in Embodiment 1 and a power feeding operation to a V-ONU. FIG. 10 is a block diagram schematically showing a configuration of a power inserter in a second embodiment. 10 is a table showing a relationship among an overcurrent detection signal, a voltage abnormality detection signal, a power supply control signal, and a failure signal in the second embodiment. FIG. 10 is a block diagram schematically showing a configuration of a power inserter in a third embodiment. It is a block diagram which shows roughly the structure of V-ONU in Embodiment 3 and 4. FIG. FIG. 10 is a block diagram schematically showing a configuration of a power inserter in a fourth embodiment. (A) And (B) is the schematic which shows the example of hardware constitutions.

Embodiment 1 FIG.
FIG. 1 is a block diagram schematically showing a configuration of an optical communication system 100 according to the first embodiment.
As shown in the figure, an optical communication system 100 includes an OLT (Optical Line Terminal) 110 as a station device installed in a telecommunications carrier's station, an optical multiplexer / demultiplexer 120, and a subscriber side (user side). It includes a V-ONU (Video Optical Network Unit) 130 that is an installed video device, a power inserter 140 as a coaxial power feeder, a video terminal 170, a data terminal 180, and a power supply device 190.

  The OLT 110 is a station-side optical terminator installed in a telecommunications carrier's office or the like in a subscriber network (public network) using a transmission medium 101 composed of an optical fiber cable and an optical coupler. The OLT 110 synthesizes optical signals to be transmitted to each subscriber and sends them to the optical line, or separates signals received from the optical line into signals for each subscriber.

The optical multiplexer / demultiplexer 120 is connected to the OLT 110 and the transmission medium 101 as an optical multiplexer that multiplexes a plurality of optical signals having different wavelengths and an optical demultiplexer that divides a plurality of optical signals having different wavelengths for each wavelength. Function. For example, the optical multiplexer / demultiplexer 120 receives an optical signal including an optical video signal multiplexed at different wavelengths from the OLT 110 and an optical data signal including a control signal. Then, the optical multiplexer / demultiplexer 120 separates the optical video signal and the optical data signal from the received optical signal. Further, the optical multiplexer / demultiplexer 120 transmits the separated optical video signal to the V-ONU 130 and transmits the separated optical data signal to the power inserter 140. The optical multiplexer / demultiplexer 120 transmits the optical data signal received from the V-ONU 130 to the OLT 110.
Here, the optical multiplexer / demultiplexer 120 can be configured by a WDM (Wavelength Division Multiplexers) coupler.
Although FIG. 1 shows an example in which the OLT 110 is connected to one optical multiplexer / demultiplexer 120, a plurality of optical multiplexers / demultiplexers 120 connected to the OLT 110 may be provided.

  The V-ONU 130 is a device that converts an optical video signal into an electrical signal and performs a demodulation process, and is a subscriber-side optical termination device installed in the subscriber's home HM. In FIG. 1, the V-ONU 130 is connected to the optical multiplexer / demultiplexer 120 through the optical fiber 102, and receives an optical video signal from the optical multiplexer / demultiplexer 120. The V-ONU 130 converts the received optical video signal, which is an optical signal, into an electrical signal, further demodulates the converted electrical signal, and transmits the demodulated signal to the power inserter 140 via the coaxial cable 103. Note that this demodulated signal includes a video signal from the OLT 110.

  The power inserter 140 is a power supply device that acquires a video signal from the OLT 110 via the V-ONU 130 and supplies power to the V-ONU 130. For example, the power inserter 140 receives power from a power supply device 190 such as an AC adapter, superimposes power on the coaxial cable 103, and supplies the power to the V-ONU 130. The power inserter 140 acquires a video signal based on the electrical signal converted from the optical video signal in the V-ONU 130, and the acquired video signal is transmitted to the video terminal 170 such as a television via the coaxial cable 105. Send to. Further, the power inserter 140 is connected to the optical multiplexer / demultiplexer 120 via the optical fiber 104, and receives an optical data signal from the optical multiplexer / demultiplexer 120. Then, the power inserter 140 transmits a data signal generated from the processed signal obtained by converting the received optical data signal into an electric signal to the data terminal 180 via the transmission medium 106.

  The video terminal 170 is a terminal that processes a video signal, and is connected to the power inserter 140 using the coaxial cable 105. The video terminal 170 is, for example, a television.

  The data terminal 180 is a terminal that processes a data signal, and is connected to the power inserter 140 using a transmission medium 106 such as a twisted pair cable. The data terminal 180 is, for example, a terminal such as an HGW (Home Gate Way) device, a VoIP (Voice over Internet Protocol) device, or a PC (Personal Computer). In the first embodiment, it is assumed that data terminal 180 is a PC.

Next, an operation of transferring a data signal in the optical communication system 100 according to Embodiment 1 will be described.
The OLT 110 transmits an optical signal including an optical data signal to the optical multiplexer / demultiplexer 120 via the transmission medium 101.
The optical multiplexer / demultiplexer 120 separates the optical data signal including the control signal from the optical signal. Then, the optical multiplexer / demultiplexer 120 transmits the separated optical data signal to the power inserter 140 connected by the optical fiber 104.
The power inserter 140 generates a processing signal by converting an optical data signal into an electrical signal. Then, the power inserter 140 generates a data signal by changing the processing signal to an appropriate format, and transmits the data signal to the data terminal 180 via the transmission medium 106.

Similarly, the power inserter 140 generates an optical data signal by converting the data signal received from the data terminal 180 into an optical signal after changing to an appropriate format, and the optical data signal is converted into an optical multiplexer / demultiplexer. 120.
The optical multiplexer / demultiplexer 120 wavelength-multiplexes the optical data signal received from the power inserter 140 and transmits it to the OLT 110.

  The OLT 110 and the power inserter 140 establish a communication link by using an MPCP (Multi Point Control Protocol) frame and an OAM (Operations, Administration, Maintenance) frame defined in IEEE 802.3. Further, after establishing the communication link, the OLT 110 monitors and controls the power inserter 140 using a control signal such as an OAM frame.

  In the first embodiment, the optical communication system 100 will be described based on the GE-PON system. However, the first embodiment is not limited to such a system.

FIG. 2 is a block diagram schematically showing a configuration of power inserter 140 in the first embodiment.
The power inserter 140 includes a power inserter function unit 150 and a line termination function unit 160.

The power inserter function unit 150 processes a demodulated signal transmitted from the V-ONU 130 and controls power supplied to the V-ONU 130.
The power inserter function unit 150 includes a filter unit 151, a power generation unit 152, a power supply control unit 153, and coaxial connectors 154 and 155.

The filter unit 151 generates a video signal by removing the DC voltage component from the demodulated signal received from the V-ONU 130 via the coaxial cable 103 and transmitting only the signal component, and the video signal is transmitted via the coaxial cable 155. Output to the terminal 170.
Note that the filter unit 151 may be provided in the V-ONU 130. In this case, the V-ONU 130 functions as a network device.

  The filter unit 151 supplies power to the V-ONU 130 by superimposing the power supplied from the power supply control unit 153 on the signal output from the coaxial connector 154.

The power generation unit 152 receives input of DC power PW1 (for example, DC12V) from the power supply device 190, and generates necessary power in the device. In addition, the power generation unit 152 generates power PW <b> 2 to be supplied to the V-ONU 130 and supplies the generated power PW <b> 2 to the power supply control unit 153.
The power supply control unit 153 controls the power PW2 supplied to the filter unit 151 in accordance with the power supply control signal SG1 given from the line termination function unit 160. Here, since the power supply control signal SG1 provided from the line termination function unit 160 corresponds to the control signal from the OLT 110, the power supply control unit 153 supplies power to the V-ONU 130 according to the control signal from the OLT 110. And the supply has been stopped.

The line termination function unit 160 processes the optical data signal received from the optical multiplexer / demultiplexer 120.
The line termination function unit 160 includes a photoelectric conversion unit 161, a line termination processing unit 162, and a network interface unit (NI / F unit) 163.

The photoelectric conversion unit 161 generates a processing signal by converting the optical data signal received from the optical multiplexer / demultiplexer 120 into an electrical signal, and provides this processing signal to the line termination processing unit 162.
Also, the photoelectric conversion unit 161 converts the processing signal given as an electrical signal from the line termination processing unit 162 into an optical data signal, and outputs the optical data signal to the optical multiplexer / demultiplexer 120.

The line termination processing unit 162 performs transmission / reception processing of a control signal used for establishing a communication link with the OLT 110 and a control signal for monitoring or controlling the power inserter 140 and the V-ONU 130. For example, the line termination processing unit 162 detects and extracts a necessary control signal from the processing signal supplied from the photoelectric conversion unit 161, and generates a data signal by changing the rest to an appropriate format. Then, the line termination processing unit 162 gives the data signal to the NI / F unit 163. Further, a necessary control signal is added to the data signal given from the NI / F unit 163, and the processing signal is generated by changing the data signal to an appropriate format. Then, the line termination processing unit 162 gives the processed signal to the photoelectric conversion unit 161.
Further, the line termination processing unit 162 detects subscription status information indicating whether or not the video delivery service provided by the communication carrier is subscribed based on the control signal delivered from the OLT 110, and detects the detected subscription status. In accordance with the information, the power supply control unit 153 is provided with a power supply control signal SG1. For example, the line termination processing unit 162 detects a control signal indicating whether or not the video distribution service provided by the communication carrier is subscribed, and based on the control signal, sends a power supply control signal SG1 to the power supply control unit 153. give.

  The NI / F unit 163 outputs the data signal given from the line termination processing unit 162 to the data terminal 180 via the transmission medium 106. Similarly, the NI / F unit 163 receives the data signal transmitted from the data terminal 180 via the transmission medium 106 and supplies the data signal to the line termination processing unit 162.

FIG. 3 is a table showing the correspondence between the operation state of the power inserter 140 and the power supply operation to the V-ONU 130.
The power inserter 140 has six states: power OFF, power ON, communication link incomplete, communication link complete, authentication incomplete, and authentication complete.
The subscription state of the video distribution service is determined by the subscription state information of the video distribution service received from the OLT 110 after the communication link with the OLT 110 is established. For this reason, the communication link with the OLT 110 is established, and the connection state information is not yet determined until it is received. Therefore, in the first embodiment, the power inserter 140 operates in the “subscription state” for the video viewing service until the subscription state information is received after the power is turned on. For this reason, the power supply control unit 153 supplies power to the V-ONU 130 until the power supply control signal from the line termination processing unit 162 indicates power supply stop.

If the video distribution service is in a subscription state, the line termination processing unit 162 provides the power supply control signal SG1 to the power supply control unit 153 as “1”: power supply, so that the DC power PW2 is supplied from the power supply control unit 153, Power is supplied to the V-ONU 130.
On the other hand, if the video distribution service is not subscribed, the line termination processing unit 162 gives the power supply control signal SG1 to the power supply control unit 153 as “0”: power supply stop, so that the DC power PW2 from the power supply control unit 153 is given. Becomes 0V, and power feeding stops.
By the operation as described above, when the subscription status information of the video distribution service received from the OLT 110 indicates non-subscription, the power supply to the V-ONU 130 is stopped, thereby making it impossible to view the video remotely. .

  Further, when reset control is performed from the OLT 110 to the power inserter 140 for maintenance or the like, the communication link between the power inserter 140 and the OLT 110 is in an incomplete state. Even in such a state, as shown in FIG. 3, the power inserter 140 operates as a “subscription state” for the video viewing service, so the video signal output to the video terminal 170 does not stop, and the user Can continue watching.

  In addition, as in the power-on state illustrated in FIG. 3, the power supply control unit 153 sets the initial value when no signal is input from the line termination processing unit 162 as the power supply state. For this reason, the photoelectric conversion unit 161 and the line termination processing unit 162 constituting the line termination function unit 160 are configured to be removable, and even when the line termination processing unit 162 is removed, the power supply control unit 153 is connected to the V− Power can be supplied to the ONU 130. Therefore, even in such a case, the user can continue viewing without stopping the video signal output to the video terminal 170.

Embodiment 2. FIG.
In the first embodiment, the line termination processing unit 162 detects the subscription state of the video viewing service from the OLT 110 using the OAM frame. If the subscription state of the video viewing service is not yet subscribed, the line termination processing unit 162 instructs the power supply control unit 153 to stop power supply using the power supply control signal SG1. In response to such an instruction, the power supply control unit 153 stops the output of the DC power PW2 input from the power generation unit 152 to the filter unit 151. The filter unit 151 stops the power supply to the V-ONU 130 by not applying the voltage of the DC power PW2 input from the power supply control unit 153 to the coaxial connector 154 of the coaxial cable 103 connected to the V-ONU 130.
In the second embodiment, the same effect as in the first embodiment can be obtained by adding a failure state to the subscription state of the video viewing service received by the OAM frame as a condition for stopping the power supply.

As shown in FIG. 1, the optical communication system 200 according to the second embodiment includes an OLT 110, an optical multiplexer / demultiplexer 120, a V-ONU 130, a power inserter 240, a video terminal 170, and a data terminal 180. And a power supply device 190.
The optical communication system 200 according to the second embodiment is configured in the same manner as the optical communication system 100 according to the first embodiment except for the power inserter 240.

FIG. 4 is a block diagram schematically showing the configuration of the power inserter 240 in the second embodiment.
The power inserter 240 includes a power inserter function unit 250 and a line termination function unit 260.

The power inserter function unit 250 processes the demodulated signal transmitted from the V-ONU 130 and controls the power supplied to the V-ONU 130.
The power inserter function unit 250 includes a filter unit 151, a power generation unit 252, a power supply control unit 253, and coaxial connectors 154 and 155.
The power inserter function unit 250 in the second embodiment is configured in the same manner as the power inserter function unit 150 in the first embodiment except for the power generation unit 252 and the power supply control unit 253.

The power generation unit 252 receives the DC power PW1 from the power supply device 190 and generates necessary power in the device.
The power generation unit 252 in the second embodiment includes a generation function unit 252a, a current determination unit 252b, and a voltage determination unit 252c.

The generation function unit 252a generates power PW2 to be supplied to the V-ONU 130, and the current determination unit 252b provided to the power supply control unit 253 monitors the current of the power PW2 supplied from the generation function unit 252a and uses the current PW2 as the current. Determine whether there is an abnormality. For example, when the current value of the power PW2 is equal to or higher than a predetermined threshold current value, the current determination unit 252b gives an alarm signal (overcurrent detection signal SG2) to the power supply control unit 253, thereby Notify detection.
The voltage determination unit 252c monitors the voltage of the power PW2 supplied from the generation function unit 252a and determines whether or not there is an abnormality in the voltage. For example, when the voltage value of the power PW2 is greater than or equal to a predetermined threshold voltage value, the voltage determination unit 252c gives an alarm signal (voltage abnormality detection signal SG3) to the power supply control unit 253, thereby Notify detection.

The power supply control unit 253 controls the power PW2 supplied to the filter unit 151.
The power supply control unit 253 in the second embodiment includes an alarm processing unit 253a and a power supply unit 253b.
The alarm processing unit 253a is based on the overcurrent detection signal SG2 from the current determination unit 252b, the voltage abnormality detection signal SG3 from the voltage determination unit 252c, and the power supply control signal SG1 and the failure signal SG4 from the line termination function unit 260. Then, it is determined whether or not to supply power to the V-ONU 130, and a power supply determination signal SG5 indicating the determination result is provided to the power supply unit 253b.

  The power supply unit 253b supplies and stops the power PW2 supplied to the filter unit 151 according to the power supply determination signal SG5 from the alarm processing unit 253a. For example, when the power supply determination signal SG5 indicates that power is supplied, the power supply unit 253b supplies power PW2 to the filter unit 151, and when the power supply determination signal SG5 indicates that power supply is stopped. Stops the power PW2 supplied to the filter unit 151.

The line termination function unit 260 processes the optical data signal received from the optical multiplexer / demultiplexer 120.
The line termination function unit 260 includes a photoelectric conversion unit 161, a line termination processing unit 262, and an NI / F unit 163.
The line termination function unit 260 in the second embodiment is configured in the same manner as the line termination function unit 160 in the first embodiment except for the line termination processing unit 262.

  The line termination processing unit 262 performs the same processing as the line termination processing unit 162 of the first embodiment, and also gives a failure signal SG4 to the alarm processing unit 253a when detecting its own failure. For example, the line termination processing unit 262 warns the failure signal SG4 when it detects a failure such as an LSI (Large-Scale Integrated circuit) and a memory constituting the line termination processing unit 262, and S / W. This is given to the processing unit 253a. Specifically, when the external memory connected to the LSI fails, the line termination processing unit 262 can detect the failure by detecting the failure of the memory by the external memory access error. Similarly, the line termination processing unit 262 can detect a failure by detecting a memory access error in the memory existing inside the LSI.

FIG. 5 is a table showing a relationship among overcurrent detection signal SG2, voltage abnormality detection signal SG3, power supply control signal SG1, and failure signal SG4 in the second embodiment.
As shown in FIG. 5, in the second embodiment, even when the power supply control signal SG1 indicates power supply “1”, the overcurrent detection signal SG2 indicates detection of overcurrent; and When the voltage abnormality detection signal SG3 indicates the detection of the voltage abnormality, the power supply to the V-ONU 130 is stopped.
On the other hand, when the power supply control signal SG1 indicates power supply “1”, power is supplied to the V-ONU 130 even if the failure signal SG4 indicates a failure of the line termination processing unit 162.

  As described above, according to the second embodiment, in addition to the effect that the output of the video signal can be stopped remotely, the apparatus failure can be detected autonomously and the power supply to the V-ONU 130 can be stopped. It is possible to provide a product that ensures safety in the event of a device failure.

Embodiment 3 FIG.
In the first embodiment, the line termination processing unit 162 detects the subscription state of the video viewing service from the OLT 110 using the OAM frame. If the subscription state of the video viewing service is not yet subscribed, the line termination processing unit 162 instructs the power supply control unit 153 to stop power supply using the power supply control signal SG1. In response to such an instruction, the power supply control unit 153 stops the output of the DC power PW2 input from the power generation unit 152 to the filter unit 151.
In Embodiment 3, the process in the V-ONU is controlled by changing the voltage of the power supplied to the V-ONU.

As shown in FIG. 1, the optical communication system 300 according to the third embodiment includes an OLT 110, an optical multiplexer / demultiplexer 120, a V-ONU 330, a power inserter 340, a video terminal 170, and a data terminal 180. And a power supply device 190.
The optical communication system 300 according to the third embodiment is configured in the same manner as the optical communication system 100 according to the first embodiment except for the V-ONU 330 and the power inserter 340.

FIG. 6 is a block diagram schematically showing a configuration of power inserter 340 in the third embodiment.
The power inserter 340 includes a power inserter function unit 350 and a line termination function unit 160.
The power inserter 340 in the third embodiment is configured in the same manner as the power inserter 140 in the first embodiment except for the power inserter function unit 350.

The power inserter function unit 350 processes the demodulated signal transmitted from the V-ONU 330 and controls the power supplied to the V-ONU 330.
The power inserter function unit 350 includes a filter unit 151, a power generation unit 352, a power supply control unit 353, and coaxial connectors 154 and 155.
The power inserter function unit 350 in the third embodiment is configured in the same manner as the power inserter function unit 150 in the first embodiment except for the power generation unit 352 and the power supply control unit 353.

The power generation unit 352 receives the DC power PW1 from the power supply device 190 and generates necessary power in the device.
The power generation unit 352 according to Embodiment 3 includes a first power generation unit 352d and a second power generation unit 352e.

The first power generation unit 352d generates DC power PW3 (first power) having a voltage in the power supply voltage range (for example, DC12V ± 10%) of the V-ONU 330, and supplies the DC power PW3 to the power supply control unit 353. . Here, the voltage in the power supply voltage range of the V-ONU 330 is a voltage necessary for the V-ONU 330 to process the optical signal from the OLT 110.
The second power generation unit 352e generates a DC power PW4 (second power) having an operating voltage (for example, DC5V) that is less than the lower limit of the power supply voltage of the V-ONU 330 and equal to or higher than the operating lower limit voltage of the V-ONU 330. The DC power PW4 is supplied to the power feeding control unit 353. Here, the operation lower limit voltage of the V-ONU 330 is a voltage at which the V-ONU 330 does not process the optical signal, or a voltage at which the signal processing can be stopped by a reset operation or the like. Furthermore, the operation lower limit voltage of the V-ONU 330 is also a voltage necessary for displaying that the process has stopped.

The power supply control unit 353 controls the DC power PW3 and PW4 supplied to the filter unit 151.
The power feeding control unit 353 in the third embodiment includes a switching unit 353c.
The switching unit 353c performs filtering between the DC power PW3 provided from the first power generation unit 352d and the DC power PW4 provided from the second power generation unit 352e in accordance with the power supply control signal SG1 from the line termination processing unit 162. The power supplied to the unit 151 is switched. For example, the switching unit 353c outputs DC power PW3 when the power supply control signal SG1 indicates power supply “1”, and outputs DC power PW4 when the power supply control signal SG1 indicates power supply stop “0”. To do.

FIG. 7 is a block diagram schematically showing the configuration of the V-ONU 330.
The V-ONU 330 includes a signal processing unit 331, a coaxial connector 332, a power supply voltage detection unit 333, a power supply voltage monitoring unit 334, and a display unit 335.

  The signal processing unit 331 converts the optical video signal from the optical multiplexer / demultiplexer 120 into an electrical signal, and further demodulates the converted electrical signal to generate a demodulated signal. Then, the signal processing unit 331 transmits the generated demodulated signal from the coaxial connector 332 to the power inserter 140 through the coaxial cable 103.

The coaxial connector 332 transmits and receives signals via the coaxial cable 103 and receives power from the power inserter 340.
The feed voltage detection unit 333 detects the voltage value of the power input to the coaxial connector 332.
The power supply voltage monitoring unit 334 monitors the voltage value detected by the power supply voltage detection unit 333. For example, the power supply voltage monitoring unit 334 determines that the detected voltage value is within the power supply voltage range of the V-ONU 330 or less than the power supply voltage lower limit value of the V-ONU 330 and equal to or higher than the operation lower limit voltage of the V-ONU 330. Determine whether the operating voltage. Then, when the detected voltage value is less than the lower limit value of the power supply voltage of the V-ONU 330 and the operating voltage is equal to or higher than the lower limit voltage of the operation of the V-ONU 330, the power supply voltage monitoring unit 334 notifies the signal processing unit 331. The process is stopped and the display unit 335 displays that the video is stopped. On the other hand, when the detected voltage value is within the power supply voltage range of the V-ONU 330, the power supply voltage monitoring unit 334 causes the signal processing unit 331 to perform processing and causes the display unit 335 to be in the video output state. Is displayed.

  The display unit 335 displays that the video is stopped. For example, the display unit 335 can be configured by an LED (Light Emitting Diode), and when this LED is lit, the video can be stopped. When the LED is turned off, it is assumed that the video output state is set.

  As described above, according to the third embodiment, in addition to the effect that the output of the video signal can be stopped remotely, the maintenance person can recognize that the V-ONU 330 is in the video stopped state by the LED or the like. Improves.

Embodiment 4 FIG.
In the first embodiment, the line termination processing unit 162 detects the subscription state of the video viewing service from the OLT 110 using the OAM frame. If the subscription state of the video viewing service is not yet subscribed, the line termination processing unit 162 instructs the power supply control unit 153 to stop power supply using the power supply control signal SG1. In response to such an instruction, the power supply control unit 153 stops the output of the DC power PW2 input from the power generation unit 152 to the filter unit 151.
In the fourth embodiment, processing in the V-ONU is controlled by generating a pulse signal using the voltage of the power supplied to the V-ONU.

As shown in FIG. 1, the optical communication system 400 according to the fourth embodiment includes an OLT 110, an optical multiplexer / demultiplexer 120, a V-ONU 430, a power inserter 440, a video terminal 170, and a data terminal 180. And a power supply device 190.
The optical communication system 400 according to the fourth embodiment is configured in the same manner as the optical communication system 100 according to the first embodiment except for the V-ONU 430 and the power inserter 440.

FIG. 8 is a block diagram schematically showing the configuration of the power inserter 440 in the fourth embodiment.
The power inserter 440 includes a power inserter function unit 450 and a line termination function unit 160.
The power inserter 440 in the fourth embodiment is configured in the same manner as the power inserter 140 in the first embodiment except for the power inserter function unit 450.

The power inserter function unit 450 processes the demodulated signal transmitted from the V-ONU 430 and controls the power supplied to the V-ONU 430.
The power inserter function unit 450 includes a filter unit 151, a power generation unit 452, a power supply control unit 453, and coaxial connectors 154 and 155.
The power inserter function unit 450 in the fourth embodiment is configured in the same manner as the power inserter function unit 150 in the first embodiment except for the power generation unit 452 and the power supply control unit 453.

The power generation unit 452 receives the input of the DC power PW1 from the power supply device 190, and generates necessary power in the device.
The power generation unit 452 in the fourth embodiment includes a first power generation unit 452d and a second power generation unit 452e.

The first power generation unit 452d generates DC power PW3 (first power) having a voltage in the power supply voltage range (for example, DC12V ± 10%) of the V-ONU 430, and supplies the DC power PW3 to the power supply control unit 453. .
The second power generation unit 452e generates DC power PW4 (second power) having an operating voltage (for example, DC5V) that is less than the lower limit of the power supply voltage of the V-ONU 430 and equal to or higher than the operating lower limit voltage of the V-ONU 430. The DC power PW4 is supplied to the power supply control unit 453.

The power supply control unit 453 controls the DC power PW5 supplied to the filter unit 151.
The power supply control unit 453 in the fourth embodiment includes a pulse generation unit 453d.
In response to the power supply control signal SG1 from the line termination processing unit 162, the pulse generation unit 453d is between the DC power PW3 provided from the first power generation unit 452d and the DC power PW4 provided from the second power generation unit 452e. The power supplied to the filter unit 151 is switched, and a pulse signal is generated using the voltage of the power supplied to the filter unit 151 in accordance with the power supply control signal SG1 from the line termination processing unit 162. For example, when the power supply control signal SG1 indicates power supply “1”, the pulse generation unit 453d outputs the DC power PW3 as the DC power PW5, and uses the voltage to output a pulse signal “01100011” indicating power supply. (First pulse signal) is generated. On the other hand, when the power supply control signal SG1 indicates the power supply stop “0”, the pulse generation unit 453d outputs the DC power PW4 as the DC power PW5 and uses the voltage to indicate “01110011” indicating the power supply stop. A pulse signal (second pulse signal) is generated.

As shown in FIG. 7, the V-ONU 430 in the fourth embodiment includes a signal processing unit 331, a coaxial connector 332, a power supply voltage detection unit 333, a power supply voltage monitoring unit 434, and a display unit 335. Prepare.
The V-ONU 430 in the fourth embodiment is configured in the same manner as the V-ONU 330 in the third embodiment except for the power supply voltage monitoring unit 434.

The power supply voltage monitoring unit 434 monitors the voltage value detected by the power supply voltage detection unit 333. For example, the power supply voltage monitoring unit 434 determines whether a pulse signal “01100011” indicating power supply or a pulse signal “01110011” indicating power supply stop is detected based on the detected voltage value.
When a pulse signal indicating power supply stop is detected, the power supply voltage monitoring unit 434 causes the signal processing unit 331 to stop the process and causes the display unit 335 to display that the video is in a stopped state. On the other hand, when a pulse signal indicating power feeding is detected, the power feeding voltage monitoring unit 434 causes the signal processing unit 331 to perform processing, and causes the display unit 335 to display that the video output state is set.

  Also in the fourth embodiment, for example, the display unit 335 can be configured by an LED. When the LED is turned on, the video is in a stopped state, and when the LED is turned off, the video is displayed. The output state can be assumed.

  According to the fourth embodiment, in addition to the effect that the output of the video signal can be stopped remotely, the output of the video signal can be restarted from a remote location.

  Signal processing of the power inserters 140, 240, 340, and 440 described above, the power supply control units 153, 253, 353, and 453, the line termination processing units 162 and 262, and the V-ONUs 330 and 430 Part or all of the unit 331, the power supply voltage detection unit 333, and the power supply voltage monitoring units 334 and 434 are, for example, a single circuit, a composite circuit, or a program as shown in FIG. A processor, a processor programmed in parallel, an ASIC (Application Specific Integrated Circuits), or an FPGA (Field Programmable Gate Array) can be used.

  Also, the filter unit 151 of the power inserters 140, 240, 340, and 440, the power supply control units 153, 253, 353, and 453, the line termination processing units 162 and 262, and the signal processing units 331 of the V-ONUs 330 and 430, For example, as illustrated in FIG. 9B, the power supply voltage detection unit 333 and the power supply voltage monitoring units 334 and 434 may include a memory 11 and a program stored in the memory 11. It can be configured by a processor 12 such as a CPU (Central Processing Unit) to be executed. Such a program may be provided through a network, or may be provided by being recorded on a recording medium.

  100, 200, 300, 400 Optical communication system, 110 OLT, 120 optical multiplexer / demultiplexer, 130, 330, 430 V-ONU, 331 signal processing unit, 332 coaxial connector, 333 power supply voltage detection unit, 334, 434 power supply voltage monitoring Unit, 335 display unit, 140, 240, 340, 440 power inserter, 150, 250, 350, 450 power inserter function unit, 151 filter unit, 152, 252, 352, 452 power generation unit, 252a generation function unit, 252b current Determination unit, 252c voltage determination unit, 352d, 452d first power generation unit, 352e, 452e second power generation unit, 153, 253, 353, 453 power supply control unit, 253a alarm processing unit, 253b power supply unit, 353c switching unit , 45 3d pulse generation unit, 154, 155 coaxial connector, 160, 260 line termination function unit, 161 photoelectric conversion unit, 162, 262 line termination processing unit, 163 NI / F unit, 170 video terminal, 180 data terminal, 190 power supply unit .

Claims (11)

A power supply device that acquires a video signal from a station device on a telecommunications carrier side via a video device,
A photoelectric conversion unit that receives the optical data signal from the station apparatus and converts the optical data signal into an electrical signal to generate a processing signal;
A line termination processing unit for detecting a control signal for controlling the video device from the processing signal;
A power generation unit that generates power to be supplied to the video device;
A power supply control unit configured to control supply of power to the video device in accordance with the control signal. The power supply apparatus according to claim 1, wherein the power supply control unit supplies and stops power supply to the video apparatus according to the control signal. The control signal indicates whether or not the video service provided by the communication carrier is subscribed,
The power supply control unit stops the supply of power to the video device when the control signal indicates that the video viewing service provided by the communication carrier is not subscribed. 2. The power supply apparatus according to 2. The power supply control unit supplies power to the video device until the control signal indicating that the video service provided by the communication carrier is not subscribed is detected. The electric power feeder as described in. The power generation unit
A generation function unit that generates electric power to be supplied to the video device;
A current determination unit that determines whether there is an abnormality in the current of the power generated by the generation function unit;
A voltage determination unit that determines whether or not there is an abnormality in the voltage of the power generated by the generation function unit,
5. The power supply control unit stops supply of power to the video device when it is determined that at least one of the current and the voltage is abnormal. 5. The power feeding device according to any one of the above. The power generation unit generates first power and second power having a voltage lower than the first power as power to be supplied to the video device,
The power supply apparatus according to claim 1, wherein the power supply control unit supplies the first power or the second power to the video apparatus according to the control signal. The first power is a voltage within a supply voltage range required for the video device to process an optical signal from the station device,
The power supply apparatus according to claim 6, wherein the second power is a voltage less than the power supply voltage range. When supplying the first power according to the control signal, the power supply control unit generates a first pulse signal using a voltage of the first power, and supplies the second power according to the control signal. 8. The power supply device according to claim 6, wherein when supplying, a second pulse signal different from the first pulse signal is generated by using a voltage of the second power. The control signal indicates whether or not the video service provided by the communication carrier is subscribed,
The power supply control unit supplies the first power to the video device when the control signal indicates that the video viewing service provided by the communication carrier is subscribed, and the communication carrier The second power is supplied to the video device when the control signal indicates that the video viewing service to be provided is not subscribed. 9. Power supply device. A video device that receives an optical video signal included in an optical signal from a station device on the telecommunications carrier side and converts the optical video signal into an electrical signal, and an electrical signal converted by the video device An optical communication system including a power supply device that acquires a video signal based on:
The power supply device
A photoelectric conversion unit that receives the optical data signal from the station apparatus and converts the optical data signal into an electrical signal to generate a processing signal;
A line termination processing unit for detecting a control signal for controlling the video device from the processing signal;
A power generation unit that generates first power and second power having a voltage lower than the first power as power to be supplied to the video device;
A power supply control unit that supplies the first power or the second power to the video device according to the control signal,
The video device is:
A signal processing unit for converting the optical video signal into an electrical signal;
A power supply voltage detection unit for detecting a voltage value of power supplied from the power supply device;
A display unit;
A power supply voltage monitoring unit that, when the voltage value indicates second power, causes the signal processing unit to stop processing and causes the display unit to display that processing has stopped. An optical communication system. A video device that receives an optical video signal included in an optical signal from a station device on the telecommunications carrier side and converts the optical video signal into an electrical signal, and an electrical signal converted by the video device An optical communication system including a power supply device that acquires a video signal based on:
The power supply device
A photoelectric conversion unit that receives the optical data signal from the station apparatus and converts the optical data signal into an electrical signal to generate a processing signal;
A line termination processing unit for detecting a control signal for controlling the video device from the processing signal;
A power generation unit that generates first power and second power having a voltage lower than the first power as power to be supplied to the video device;
When supplying the first power or the second power to the video apparatus according to the control signal, and supplying the first power according to the control signal, the voltage of the first power is set. The first pulse signal is used to supply the second power in accordance with the control signal, and the second power is used to generate a second pulse different from the first pulse signal. A power supply control unit for generating a pulse signal,
The video device is:
A signal processing unit for converting the optical video signal into an electrical signal;
A power supply voltage detection unit for detecting a voltage value of power supplied from the power supply device;
A display unit;
A power supply voltage monitoring unit that, when detecting the second pulse signal based on the voltage value, causes the signal processing unit to stop processing and causes the display unit to display that the processing has stopped. An optical communication system characterized by the above.

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