JP5969425B2 - Video communication system, video signal transmitting apparatus and video signal receiving apparatus - Google Patents

Description

  The present invention relates to a technique for distributing video.

  In recent years, services for distributing video signals such as digital broadcasting to each home by optical communication have become widespread. As a method of distributing a video signal, for example, a video signal output from a V-OLT (Video Optical Line Terminal) and a data signal output from a GE-OLT (Gigabit Ethernet Optical Line Terminal) are used as a WDM (Wavelength Division Divide). Is multiplexed to the optical wavelength, transmitted to the user's home via an optical fiber, converted into an electrical video signal and a data signal by a GV-ONU (GV Optical Network Unit) installed in the user's home, and the video signal is converted to a coaxial cable. Input via TV.

JP 2011-114469 A

  As described above, when an RF signal is transmitted by optical communication, it is difficult to provide a viewing restriction only for a specific program (frequency). As a method of removing only a specific frequency, there is a method of synthesizing an anti-phase signal in the user's home, but in order to synthesize an anti-phase signal, it is necessary to grasp the phase of the RF signal at the time to limit viewing, It is necessary to synchronize the time with the video signal transmission side. Conventionally, the time is synchronized between the GE-OLT on the station side that performs data communication and the GV-ONU in the user's home, but the GE-OLT and the V-OLT are configured as separate devices, Since the output of the optical signal was multiplexed with the optical wavelength by the WDM splitter, the time was not synchronized between the V-OLT and GV-ONU that transmit the video signal.

  The present invention has been made in view of the above, and an object of the present invention is to restrict viewing of a program distributed by optical communication.

  A video communication system according to a first aspect of the present invention is a video communication system including a video signal transmitting device that distributes video signals having a plurality of program frequencies by optical communication and a video signal receiving device that receives the video signals. The video signal transmitting device receives a program viewing restriction request, receives a viewing restriction program and a viewing restriction time from the program viewing restriction request, and a frequency for obtaining frequency information corresponding to the viewing restriction program. Information acquiring means; demodulating means for inputting the video signal and demodulating into demodulated waves of each frequency; designated wave extracting means for extracting a designated wave corresponding to the frequency information from the demodulated wave; and the video signal receiving apparatus A phase calculation means for obtaining a current phase of the designated wave and calculating a phase at the viewing limit time; Transmitting means for transmitting program viewing restriction information including time and the phase to the video signal receiving device, wherein the video signal receiving device demodulates the received video signal into demodulated waves of each frequency. Receiving means for receiving the program viewing restriction information and acquiring the frequency information, the viewing restriction time and the phase from the program viewing restriction information, and a system time synchronized with the video signal transmitting device is the viewing restriction time. A phase-phase wave generating means for generating an anti-phase wave corresponding to the viewing-restricted program based on the frequency information and the phase, and a composition for synthesizing and outputting the demodulated wave and the anti-phase wave And means.

  A video signal transmitting apparatus according to a second aspect of the present invention is a video signal transmitting apparatus that distributes a video signal composed of a plurality of program frequencies to a video signal receiving apparatus by optical communication, receives a program viewing restriction request, Receiving means for acquiring a viewing restricted program and a viewing restricted time from a program viewing restriction request, frequency information obtaining means for obtaining frequency information corresponding to the viewing restricted program, and inputting the video signal into a demodulated wave of each frequency A demodulating means for demodulating, a designated wave extracting means for extracting a designated wave corresponding to the frequency information from the demodulated wave, a system time synchronized with the video signal receiving device, and obtaining a current phase of the designated wave A phase calculating means for calculating a phase at the viewing limit time, and transmitting the frequency information, the viewing limit time and the program viewing limit information including the phase to the video signal receiving device. And having a transmission means.

  A video signal receiving apparatus according to a third aspect of the present invention is a video signal receiving apparatus for receiving a video signal composed of frequencies of a plurality of programs distributed by optical communication by the video signal transmitting apparatus, wherein the received video signal is Demodulating means for demodulating into a frequency demodulated wave; receiving means for receiving program viewing restriction information; receiving frequency information corresponding to the viewing restricted program from the program viewing restriction information; viewing restriction time; An anti-phase wave generating means for generating an anti-phase wave corresponding to the viewing-restricted program based on the frequency information and the phase when the system time synchronized with the video signal transmission device becomes the viewing-restricted time; Combining means for combining and outputting the demodulated wave and the antiphase wave.

  ADVANTAGE OF THE INVENTION According to this invention, viewing restrictions of the program delivered by optical communication can be performed.

1 is an overall view showing a configuration of a video communication system in the present embodiment. It is the figure which illustrated the relationship between the program stored in a program database, and frequency information. It is a figure which shows the example of the packet which transmits program viewing restrictions information. It is a sequence diagram which shows the flow of a process of GV-OLT. It is a sequence diagram which shows the flow of a process of a control part. It is a sequence diagram which shows the flow of a process of GV-ONU. It is a flowchart which shows the flow of a process of GV-OLT. It is a flowchart which shows the flow of a process of GV-ONU.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is an overall view showing a configuration of a video communication system according to the present embodiment. The video communication system shown in FIG. 1 includes a GV-OLT 1 disposed in a telecommunications carrier station and a GV-ONU 2 disposed in a user's home. The GV-OLT 1 is configured by integrating a GE-OLT 11 that transmits and receives a data signal and a V-OLT 12 that transmits a video signal as one apparatus. GV-OLT1 and GV-ONU2 are connected by an optical line. Although not shown, a plurality of GV-ONUs 2 are connected to one GV-OLT1. The GV-OLT 1 wavelength-multiplexes the data signal received from the network by the GE-OLT 11 and the video signal received from the HE (Head End) 3 by the V-OLT 12 and transmits the multiplexed signal to the GV-ONU 2. The HE 3 converts an RF signal such as digital broadcast received by the antenna into an optical signal and transmits it to the GV-OLT 1. The GV-ONU 2 separates the optical signal received from the GV-OLT 1 into a data signal and a video signal, converts the video signal into an electrical signal, and transmits the electrical signal to the TV 5 via a coaxial cable. In the video communication system according to the present embodiment, the user transmits information on a program that the user wants to restrict viewing from the terminal 4 or the like, and the program viewing restriction information that restricts viewing of the program designated by GV-OLT1 is transmitted to GV-ONU2. The GV-ONU 2 limits the viewing for each program by generating a signal having an opposite phase at the frequency of the program specified by the program viewing restriction information and combining it with the video signal. Hereinafter, GV-OLT1 and GV-ONU2 will be described.

  GV-OLT1 is a system time accurately synchronized with GE-OLT11, V-OLT12, control unit 13 that generates and transmits program viewing restriction information based on program viewing restrictions requested by the user, and GV-ONU2. 14 and a WDM splitter for wavelength multiplexing the data signal and the video signal.

  The control unit 13 includes a program database 131, an RF signal demodulation unit 132, a designated wave extraction unit 133, and a frequency / phase calculation unit 134.

  The program database 131 stores program-specific parameters such as frequency and amplitude for each program (channel). FIG. 2 shows an example of data stored in the program database 131. Since the user transmits information such as program start / end times and channels for the program for which viewing is restricted, the program database 131 obtains the frequency and amplitude of the viewing restricted program from the received information, and the designated wave extraction unit To 133. In the program database 131, program-specific parameters for each program are stored in advance.

  The RF signal demodulating unit 132 demodulates the batch RF signal that is a video signal transmitted from the V-OLT 12 to the GV-ONU 2 and converts the demodulated RF signal into an electrical signal, and the RF signal returned to each frequency is designated wave extracting unit 133. Send to.

  The designated wave extraction unit 133 extracts the designated wave corresponding to the viewing restricted program from the RF signal demodulated by the RF signal demodulating unit 132 using the frequency information corresponding to the viewing restricted program and the band pass filter.

  The frequency / phase calculation unit 134 uses the system time 14 to obtain the current phase from the extracted designated wave and the frequency and amplitude of the viewing-restricted program, calculates the phase at the time when viewing is desired, and the viewing-restricted program Is transmitted to the GV-ONU 2 with the frequency information, the viewing restriction time, and the phase information in the viewing restriction time corresponding to. The phase θ of the designated wave is obtained using the following equation (1).

θ = 2πft (1)
Here, f represents the frequency of the designated wave, and t represents time.

  FIG. 3 is a diagram illustrating an example of a packet for transmitting program viewing restriction information transmitted to the GV-ONU 2. At the head of the packet, an LLID (Logical Link ID) for identifying the user's GV-ONU 2 is described. The data type is described after the Ethernet header part and the IPv6 header part. After the data type, data corresponding to the data type is described. The data to be described includes, for example, frequency information of the viewing-restricted program, viewing-restricted time, and phase / reverse phase information of the viewing-restricted program at the viewing-restricted time.

  The GV-ONU 2 includes a GE-ONU 21 that transmits / receives a data signal, a V-ONU 22 that receives a video signal, an RF signal generator 23 that generates an anti-phase RF signal of a viewing-restricted program, an anti-phase RF signal and a V-ONU 22. Includes a synthesizing unit 24 for synthesizing the demodulated RF signal, and a WDM splitter for separating the data signal and the video signal. Further, the GE-ONU 21 includes a system time 211 that is accurately synchronized with the GV-OLT1.

  A signal transmitted from the GV-OLT 1 is separated into a data signal and a video signal by a WDM splitter. The GE-ONU 21 receives a data signal and transfers a packet that is not a program viewing restriction information packet to a network device in the user's home. When the program viewing restriction information packet is received, information such as frequency information, viewing restriction time, and phase of the viewing restricted program is extracted and transmitted to the RF signal generator 23.

  The V-ONU 22 inputs the video signal, demodulates it, and inputs the RF signal returned to each frequency to the synthesis unit 24.

  When the system time 211 reaches the viewing restriction time, the RF signal generator 23 generates an antiphase wave corresponding to the viewing restricted program and inputs it to the synthesis unit 24.

  The synthesizing unit 24 synthesizes the RF signal returned to each frequency and the anti-phase wave, cancels only the viewing-restricted program, and transmits it to the TV 5.

  Next, the operation of the video communication system in the present embodiment will be described.

  FIG. 4 is a sequence diagram showing a flow of processing of the GV-OLT 1 when a program viewing restriction request is received from the terminal 4.

  When the user inputs information on a program whose viewing is to be restricted to the terminal 4, the terminal 4 sends a program viewing restriction request describing the information on the program whose viewing is to be restricted to the IP address and VLAN-ID of the GV-ONU 2 in the user's home. (Step S101).

  The GE-OLT 11 receives the program viewing restriction request, and extracts the LLID indicating the destination GV-ONU 2 from the destination IP address and VLAN-ID (step S102). Further, the viewing restricted program and the viewing restricted time are extracted from the program viewing restriction request (step S103), and are transmitted to the control unit 13 as program viewing restriction information (step S104).

  FIG. 5 is a sequence diagram showing the flow of processing of the control unit 13.

  When receiving the program viewing restriction information from the GE-OLT 11 (step S104), the control unit 13 acquires frequency information corresponding to the viewing restriction program from the program database 131 (step S105), and converts the viewing restriction program into frequency information. The program viewing restriction information is transmitted to the designated wave extraction unit 133 (step S106).

  Further, the RF signal demodulator 132 receives the RF signal collected from the V-OLT 12 (step S107), demodulates it to each frequency (step S108), and transmits the demodulated wave to the designated wave extractor 133 (step). S109).

  The designated wave extraction unit 133 extracts a designated wave corresponding to the frequency information designated by the program viewing restriction information from the demodulated wave received from the RF signal demodulation unit 132 (step S110), and only the designated wave is a frequency / phase calculation unit. It transmits to 134 (step S111).

  The frequency / phase calculation unit 134 acquires the system time 14 (step S112), obtains the current phase from the designated wave and frequency information, and calculates the phase at the viewing limit time (step S113).

  Then, the frequency / phase calculation unit 134 transmits the program viewing restriction information describing the frequency information, viewing restriction time, phase information, etc. of the viewing restricted program to the GV-ONU 2 (step S114).

  Note that the V-OLT 12 always transmits the batched RF signals received from the HE 3 to the GV-ONU 2 (step S115).

  FIG. 6 is a sequence diagram showing a process flow of the GV-ONU 2.

  When the GV-ONU 2 receives the program viewing restriction information (step S114), the RF signal generator 23 acquires the system time 211 from the GE-ONU 21 (step S201).

  When the system time 211 is the viewing restriction time, frequency information and phase information are extracted from the received program viewing restriction information, and an antiphase wave is generated and transmitted to the synthesis unit 24 (steps S202 and S203).

  On the other hand, when receiving the batched RF signal (step S115), the V-ONU 22 demodulates the RF signal to each frequency and transmits the demodulated wave to the synthesizer 24 (steps S204 and S205).

  The synthesizer 24 synthesizes the demodulated wave and antiphase wave of each frequency (step S206), and transmits the RF signal from which the viewing-restricted program is removed to the TV 5 (step S207).

  Next, the processing flow of GV-OLT1 in the present embodiment will be described.

  FIG. 7 is a flowchart showing a flow of GV-OLT processing in the present embodiment.

  When receiving the packet, the GE-OLT 11 extracts the LLID of the transfer destination from the packet (step S31), and determines whether or not the packet requests a program viewing restriction (step S32).

  If it is not a packet requesting program viewing restriction (No in step S32), the packet is transferred according to the extracted LLID (step S39).

  If the packet is a request for program viewing restriction (Yes in step S32), the viewing restricted program and the viewing restricted time are extracted from the received packet (step S33), and frequency information corresponding to the viewing restricted program is obtained from the program database 131. Obtain (step S34).

  The RF signal demodulator 132 demodulates the batch RF signal transmitted by the HE 3 to each frequency (step S35).

  The designated wave extraction unit 133 extracts a designated wave corresponding to the viewing restricted program from the demodulated wave demodulated by the RF signal demodulation unit 132 (step S36).

  The frequency / phase calculation unit 134 acquires the system time 14, obtains the current phase from the frequency information corresponding to the designated wave and the viewing-restricted program, calculates the phase at the viewing-restricted time (step S37), and the frequency information and viewing-restricted. The program viewing restriction information describing the time, phase information, etc. is transmitted to the GV-ONU 2 corresponding to the LLID extracted in step S31 (step S38).

  Next, the process flow of the GV-ONU in the present embodiment will be described.

  FIG. 8 is a flowchart showing a process flow of the GV-ONU in the present embodiment.

  When receiving the program viewing restriction information, the GE-ONU 21 extracts frequency information, viewing restriction time, and phase information from the program viewing restriction information (step S41).

  When the system time 211 is the viewing restriction time (Yes in step S42), the RF signal generator 23 uses the frequency information and the phase information extracted from the program viewing restriction information to reverse the phase of the designated frequency corresponding to the viewing restriction program. A wave is generated and transmitted to the synthesis unit 24 (step S43).

  The V-ONU 22 demodulates the collected RF signal to each frequency and transmits it to the synthesis unit 24 (step S44).

  The synthesizer 24 combines the anti-phase wave corresponding to the viewing-restricted program and the RF signal demodulated to each frequency (step S45), and transmits the RF signal from which the viewing-restricted program is removed to the TV 5 (step S46).

  As described above, according to the present embodiment, the control unit 13 of the GV-OLT 1 demodulates the video signal, calculates the phase at the viewing restriction time of the viewing restricted program using the system time 14, and GV-ONU 2. When the system time 211 of the GV-ONU 2 synchronized with the system time 14 of the GV-OLT 1 reaches the viewing limit time, the RF signal generator 23 of the GV-ONU 2 generates an anti-phase wave of the viewing limited program, The synthesizing unit 24 synthesizes the RF signal obtained by demodulating the video signal and the anti-phase wave, so that the GV-ONU 2 can accurately grasp the phase of the RF signal and cancel the viewing-restricted program. Can be done. As a result, the user can restrict viewing of a specific program without replacing the TV 5.

1 ... GV-OLT
11 ... GE-OLT
12 ... V-OLT
DESCRIPTION OF SYMBOLS 13 ... Control part 131 ... Program database 132 ... RF signal demodulation part 133 ... Designated wave extraction part 134 ... Frequency and phase calculation part 14 ... System time 2 ... GV-ONU
21 ... GE-ONU
211 ... System time 22 ... V-ONU
23 ... RF signal generator 24 ... Synthesizer 3 ... HE
4 ... Terminal 5 ... TV

Claims (3)

A video communication system comprising a video signal transmitting device for distributing video signals having a frequency of a plurality of programs by optical communication and a video signal receiving device for receiving the video signals,
The video signal transmission device includes:
Receiving means for receiving a program viewing restriction request and obtaining a viewing restricted program and a viewing restriction time from the program viewing restriction request;
Frequency information acquisition means for acquiring frequency information corresponding to the viewing restricted program;
Demodulating means for inputting the video signal and demodulating the demodulated wave of each frequency;
A designated wave extracting means for extracting a designated wave corresponding to the frequency information from the demodulated wave;
Phase calculation means for referring to a system time synchronized with the video signal receiving device, obtaining a current phase of the designated wave, and calculating a phase at the viewing limit time;
Transmission means for transmitting program viewing restriction information including the frequency information, the viewing restriction time and the phase to the video signal receiving device,
The video signal receiving device is:
Demodulation means for demodulating the received video signal into demodulated waves of each frequency;
Receiving means for receiving the program viewing restriction information and obtaining the frequency information, the viewing restriction time and the phase from the program viewing restriction information;
An anti-phase wave generating means for generating an anti-phase wave corresponding to the viewing-restricted program based on the frequency information and the phase when the system time synchronized with the video signal transmission device becomes the viewing-restricted time;
A video communication system comprising: a synthesizing unit that synthesizes and outputs the demodulated wave and the antiphase wave. A video signal transmitting device that distributes a video signal having a frequency of a plurality of programs to a video signal receiving device by optical communication,
Receiving means for receiving a program viewing restriction request and obtaining a viewing restricted program and a viewing restriction time from the program viewing restriction request;
Frequency information acquisition means for acquiring frequency information corresponding to the viewing restricted program;
Demodulating means for inputting the video signal and demodulating the demodulated wave of each frequency;
A designated wave extracting means for extracting a designated wave corresponding to the frequency information from the demodulated wave;
Phase calculation means for referring to a system time synchronized with the video signal receiving device, obtaining a current phase of the designated wave, and calculating a phase at the viewing limit time;
Transmitting means for transmitting program viewing restriction information including the frequency information, the viewing restriction time and the phase to the video signal receiving device;
A video signal transmitting apparatus comprising: A video signal receiving device for receiving a video signal composed of frequencies of a plurality of programs distributed by optical communication by a video signal transmitting device,
Demodulation means for demodulating the received video signal into demodulated waves of each frequency;
Receiving means for receiving program viewing restriction information and obtaining frequency information corresponding to the viewing restricted program, viewing restriction time and phase in the viewing restriction time from the program viewing restriction information;
An anti-phase wave generating means for generating an anti-phase wave corresponding to the viewing-restricted program based on the frequency information and the phase when the system time synchronized with the video signal transmitting device becomes the viewing-restricted time;
Combining means for combining and outputting the demodulated wave and the anti-phase wave;
A video signal receiving apparatus comprising:

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