KR101366214B1 - optical transmitter for transmitting broadcasting signal through optical subscriber network - Google Patents

Abstract

The present invention relates to an optical transmission device for transmitting a broadcast signal through an optical subscriber network, comprising: an all-optical conversion module for converting and outputting an RF broadcast signal received through an RF broadcast signal receiving terminal and an optical signal; An optical splitter for distributing an optical signal into a monitoring optical signal and a transmission optical signal, an optical transmitting processor for transmitting and transmitting an optical signal for transmission distributed by the optical splitter through an optical subscriber network, and a monitoring optical beam distributed in the optical splitter It is provided with a diagnostic module for converting the signal into an electrical signal for diagnosing the optical signal for transmission converted to all light. According to the optical transmission device for transmitting a broadcast signal through the optical subscriber network, the optical signal transmission state after converting the RF broadcast signal into an optical signal can be monitored by itself, so that the processing of the broadcast signal transmission failure can be easily performed. Can be.

Description

Optical transmitter for transmitting broadcast signal through optical subscriber network

The present invention relates to an optical transmission device for transmitting a broadcast signal through an optical subscriber network, and more particularly, to an optical transmission device for transmitting a broadcast signal through an optical subscriber network capable of monitoring a state of a broadcast signal converted into an optical signal. It is about.

The current telecommunications and broadcasting network infrastructure is divided into several parts. Broadcasting has been developed into terrestrial, CATV and satellite broadcasting networks, and communication has been divided into various types of communication networks, including wired and wireless, in terms of location and performance. This network structure does not meet the expectations of consumers expecting convergence services that integrate broadcasting and communication in the current network where multimedia services are mainstream, and the demand and expectation for an integrated network structure that can implement this is increasing.

In addition, Fiber To The Home (FTTH) or Fiber To The FTTC, such as a Passive Optical Network (PON) with a point-to-multipoint structure, is a future subscriber access network to provide more bandwidth and more services to subscribers at lower cost. Curb) type network structure is emerging.

On the other hand, a device capable of integrating and servicing CATV and satellite broadcasting through an optical cable is disclosed in Korean Patent No. 10-0687708.

However, the apparatus has a disadvantage in that the transmitting side cannot monitor the transmission state by the transmitting side on whether the optical signal transmitted to the receiving side by all-optical conversion at the optical transmitting side is normally converted or the intensity of the converted optical signal has an appropriate level. .

The present invention has been made to solve the above problems, and provides an optical transmission device for transmitting a broadcast signal through an optical subscriber network that supports monitoring the status of a broadcast signal converted into an optical signal by itself. There is this.

In order to achieve the above object, an optical transmission device for transmitting a broadcast signal through an optical subscriber network according to the present invention includes an all-optical conversion module for converting and outputting an RF broadcast signal received through an RF broadcast signal receiving terminal; An optical splitter for distributing the optical signal output from the all-optical conversion module into a monitoring optical signal and a transmission optical signal; An optical transmission processor for transmitting and transmitting the transmission optical signal distributed by the optical splitter through an optical subscriber network; And a diagnostic module for converting the monitoring optical signal distributed by the optical splitter into an electrical signal to diagnose the transmission optical signal that has been converted into all-optical.

The diagnostic module includes a photoelectric conversion unit for converting the monitoring optical signal distributed by the optical splitter into an electrical signal; And a broadcast signal extraction unit for extracting a broadcast signal from the electrical signal converted by the photoelectric conversion unit and providing the broadcast signal through a monitoring broadcast output terminal.

The diagnostic module may further include: a broadcast channel separator for separating a broadcast signal of a set channel among broadcast signals extracted by the broadcast signal extractor; An image reproducing unit which generates an image signal from the broadcasting signal separated by the broadcasting channel separating unit; And a display unit for displaying the video signal output from the video reproducing unit.

The diagnostic module may further include a diagnostic information generation unit configured to generate main diagnostic information including optical power of the optical signal for transmission from a voltage level of an electrical signal output from the photoelectric conversion unit; And a data processing unit configured to receive and process the information generated by the diagnostic information generation unit. The optical transmission processing unit may further include receiving side monitoring information of the transmission optical signal received from the optical receiver receiving the transmission optical signal. It is preferable to further include a line management module for receiving through the processing of the receiving-side monitoring information provided to the data processing unit.

The line management module may include: a sub processor configured to receive and process the reception side monitoring information provided from the optical transmission processor; An optical signal processor for data processing the reception side monitoring information output from the sub processor and providing the data to the data processor; And a light path monitoring unit for monitoring a light path state from the reception side monitoring optical signal output from the sub processing unit and providing the monitoring result to the data processing unit.

According to the optical transmission device for transmitting a broadcast signal through the optical subscriber network according to the present invention, it is possible to monitor the optical signal transmission status after converting the RF broadcast signal into an optical signal, thereby facilitating the processing of the broadcast signal transmission failure. Can be done.

1 is a block diagram showing an optical transmission device for transmitting a broadcast signal through an optical subscriber network according to the present invention.

Hereinafter, an optical transmission apparatus for transmitting a broadcast signal through an optical subscriber network according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in more detail.

1 is a block diagram showing an optical transmission device for transmitting a broadcast signal through an optical subscriber network according to the present invention.

Referring to FIG. 1, an optical transmission device 100 for transmitting a broadcast signal through an optical subscriber network according to the present invention includes an all-optical conversion module 110, an optical splitter 120, a diagnostic module 130, and a line management module 150. ).

The main body 101 of the optical transmission device 100 is provided with two RF broadcast signal receiving terminals 103 and 104 and a monitoring broadcast output terminal 107.

Reference numeral 105 is an original signal output terminal provided to monitor the output signal of the RF signal processing unit 113 to be described later.

 In the illustrated example, the RF broadcast signal receiving terminals 103 and 104 are connected to receive satellite broadcast signals and CATV broadcast signals, respectively, and may be connected to receive broadcast signals different from the illustrated example. Of course.

The all-optical conversion module 110 outputs from the RF amplifiers 111 and 112 and the RF amplifiers 111 and 112 to amplify the RF broadcast signals received through the RF broadcast signal reception terminals 103 and 104, respectively. An RF signal processor 113 for processing a signal to be processed and an all-optical converter 115 for converting a signal processed by the RF signal processor 113 into an optical signal.

Here, the RF signal processing unit 113 is a frequency band of 50 ~ 2150MHz band CATV RF broadcast signal of the 50 ~ 870MHz band and the satellite RF signal of the 950 ~ 2150MHz band respectively output from the RF amplifier 111, 112 It can be constructed to combine and output to the all-optical converter 115.

The optical splitter 120 divides and outputs the optical signal output from the all-optical converter 115 into an optical signal for monitoring and an optical signal for transmission.

Here, the monitoring optical signal and the transmission optical signal are the same signal.

The optical transmitter 125 transmits and processes the optical signal for transmission distributed by the optical splitter 120 to the optical receiver 200 through an optical subscriber network formed through the optical cable.

In addition, the optical transmission processing unit 125 separates an upstream signal transmitted from the optical receiver 200 to the optical transmission apparatus 100 and provides it to the line management module 150 to be described later, and the optical signal through the line management module 150. The optical signal for data transmitted to the receiver 200 may be constructed to transmit to the optical receiver 200.

Here, the wavelength of the optical signal for transmission and the optical signal for data generated by the optical splitter 120 may be applied differently.

The optical transmitter 125 transmits an optical signal for transmission and an optical signal for data to be transmitted to the optical receiver 200 by the sub processor 151 to be described later, and transmits an upward signal received from the optical receiver 200. The optical signal for data may be separated and transmitted to the sub processor 151.

The diagnosis module 130 converts the optical signal for monitoring distributed by the optical splitter 120 into an electrical signal so as to diagnose the all-converted transmission optical signal.

The diagnostic module 130 generates a photoelectric conversion unit 131, a broadcast signal extraction unit 133, a broadcast channel separation unit 135, an image reproducing unit 137, a display unit 139, a data processing unit 140, and diagnostic information generation. The unit 143 is provided.

The photoelectric conversion unit 131 converts the optical signal for monitoring distributed by the optical splitter 120 into an electrical signal.

The broadcast signal extractor 133 extracts a broadcast signal from the electrical signal converted by the photoelectric converter 131 and provides the same through the monitoring broadcast output terminal 107.

Here, the broadcast signal extractor 133 performs a process of removing a DC component included in the RF broadcast signal or matching an impedance with respect to the RF broadcast signal, which is an electrical signal converted by the photoelectric converter 131. Can be constructed to

Here, when an external indicator (not shown) is connected to the monitoring broadcast output terminal 107, the broadcast can be reproduced and viewed.

The broadcast channel separator 135 separates the broadcast signal of the set channel among the broadcast signals extracted by the broadcast signal extractor 133 and outputs the broadcast signal to the image reproducing unit 137.

The video player 137 generates a video signal from the broadcast signal separated by the broadcast channel separator and outputs the video signal to the display unit 139.

The display unit 139 displays an image signal output from the image reproducing unit 137 and displays display information provided to the data processing unit 140.

Here, the image signal generated by the image reproducing unit 137 may be constructed to be controlled by the data processing unit 140 and selectively displayed on the display unit 139.

The diagnostic information generator 143 generates main diagnostic information including the optical power of the optical signal for transmission from the voltage level of the electrical signal output from the photoelectric conversion unit 131, and generates the generated main diagnostic information into the data processor 140. To provide.

The diagnostic information generator 143 includes an RF signal measuring unit 144 for measuring an RF broadcast signal, which is an electrical signal output from the photoelectric conversion unit 131, and an optical power measuring unit 145.

The RF signal measuring unit 144 diagnoses according to a set quality measuring method such as a signal-to-noise ratio, an image-to-audio ratio, an automatic gain control lever, and provides the diagnosis result to the data processor 140.

The optical power measuring unit 145 measures the voltage level of the electrical signal output from the photoelectric conversion unit 131, calculates the optical power level at the time of all-optical conversion from the measured voltage level, and outputs the calculated result to the data processor 140. To provide.

The data processing unit 147 receives the information generated by the diagnostic information generating unit 143 and stores and processes the information itself, or sets the diagnostic information to a management server (not shown) connected through the communication module 147 or at a management server. Can be built to provide upon request.

The line management module 150 receives the reception side monitoring information of the transmission optical signal received from the optical receiver 200 receiving the transmission optical signal through the optical transmission processing unit 125 and processes the reception side monitoring information. It is provided to the data processor 140.

The line management module 150 includes a sub processor 151, a data optical signal processor 153, and a light path monitor 155.

The sub processor 151 receives and monitors the reception side monitoring information transmitted from the optical receiver 200 through the optical transmitter processor 125 and provided by the optical transmitter processor 125 to the data optical signal processor 153 and the optical path. Branching to the monitoring unit 155 is provided.

In addition, the sub processor 151 processes the data optical signal to be transmitted from the optical signal processor 153 to the optical receiver 200 to be transmitted to the optical receiver 200 through the optical transmitter 125. do.

The data optical signal processor 153 converts the reception side monitoring information output from the sub processor 151 into an electrical signal and decodes the data, and provides the decoded information to the data processor.

In addition, the data optical signal processor 153 may be configured to convert the communication data information provided from the data processor 140 into an optical signal and transmit the converted optical signal to the optical receiver 200 through the sub processor 151.

The optical path monitoring unit 155 measures the optical power level from the reception side monitoring optical signal transmitted from the optical receiver 200 and output from the sub processing unit 151, and compares the measured optical power level with the set reference level. It monitors whether the state is normal and provides the monitoring result to the data processing unit 140.

The data processor 140 collects the information provided by the optical path monitoring unit 155, the reception side monitoring information read by the data optical signal processing unit 153, and the information generated by the diagnostic information generation unit 143 described above. Processing the general information on the optical transmission state from the collected information, and displays some of the processed information through the display unit 139, and transmits the management history information to the management server.

The optical transmission apparatus 100 may monitor the state of converting the RF broadcast signal into an optical signal by itself, so that the broadcast transmission side may be easily processed by the optical transmission side.

110: all-optical conversion module 120: optical splitter
130: diagnostic module 150: line management module

Claims (5)

delete An all-optical conversion module converting the RF broadcast signal received through the RF broadcast signal receiving terminal into an optical signal and outputting the optical signal;
An optical splitter for distributing the optical signal output from the all-optical conversion module into a monitoring optical signal and a transmission optical signal;
An optical transmission processor for transmitting and transmitting the transmission optical signal distributed by the optical splitter through an optical subscriber network;
And a diagnostic module for converting the monitoring optical signal distributed by the optical splitter into an electrical signal to diagnose the transmission optical signal that has been converted into all-optical.
The diagnostic module
A photoelectric conversion unit converting the monitoring optical signal distributed by the optical splitter into an electrical signal;
And a broadcast signal extracting unit extracting a broadcast signal from the electrical signal converted by the photoelectric conversion unit and providing the broadcast signal through a monitoring broadcast output terminal. The method of claim 2, wherein the diagnostic module
A broadcast channel separator for separating a broadcast signal of a set channel among the broadcast signals extracted by the broadcast signal extractor;
An image reproducing unit which generates an image signal from the broadcasting signal separated by the broadcasting channel separating unit;
And a display unit for displaying the video signal output from the video reproducing unit. The method of claim 3, wherein the diagnostic module
A diagnostic information generation unit for generating main diagnostic information including optical power of the optical signal for transmission from a voltage level of an electrical signal output from the photoelectric conversion unit;
And a data processor configured to receive and process the information generated by the diagnostic information generator.
A line management module which receives reception side monitoring information of the transmission optical signal received from the optical receiver for receiving the transmission optical signal through the optical transmission processing unit and processes the reception side monitoring information and provides it to the data processing unit; The optical transmission device for transmitting a broadcast signal through an optical subscriber network, characterized in that it further comprises. The method of claim 4, wherein the track management module
A sub processor which receives and processes the reception side monitoring information provided by the optical transmission processor;
An optical signal processor for data processing the reception side monitoring information output from the sub processor and providing the data to the data processor;
And an optical path monitoring unit for monitoring the optical path state from the receiving side monitoring optical signal output from the sub processing unit and providing the monitoring result to the data processing unit. Device.

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