KR101249927B1 - Optical receiving apparatus of satellite broadcasting - Google Patents

Abstract

PURPOSE: An optical receiving apparatus of satellite broadcasting is provided to be directly connected to a set-top box for satellite broadcasting, and convert optical signals into satellite broadcasting signals without an additional power supplying device. CONSTITUTION: A detecting unit(11) receives optical signals of satellite broadcasting from an optical signal dividing unit and converts the optical signals into electric signals. An amplifying unit(12) revises the intensity of the optical signals to be converted into satellite broadcasting signals. A bias tee(13) transmits the satellite broadcasting signals received from the amplifying unit to a set-top box for satellite broadcasting. The bias tee is supplied with DC power source by the set-top box. A voltage converting unit(14) supplies power outputted from the bias tee to the detecting unit and the amplifying unit. [Reference numerals] (1) Satellite broadcasting optical receiving device; (11) Detecting unit; (12) Amplifying unit; (14) Voltage converting unit; (15) Light input unit; (AA) Satellite broadcasting optical signal; (BB) Bending-reinforced optical fiber; (CC,DD,GG) Satellite broadcasting signal; (EE,HH) DC power source; (FF) Power supply;

Description

Optical receiving apparatus of satellite broadcasting

The present invention relates to an optical receiver for satellite broadcasting, and more particularly, to a satellite broadcast optical receiver for receiving a satellite broadcast signal from a satellite broadcast optical signal transmitted through an optical fiber transmission path.

Satellite broadcasting is a broadcasting service that receives a broadcast signal shot by a ground station and receives and transmits it to a satellite broadcasting antenna on the ground. The satellite broadcasting antenna includes a low noise block-converter (LBN) for receiving a high frequency signal transmitted from a satellite and converting the high frequency signal into an intermediate frequency (IF) region. The satellite broadcast signal received by the satellite broadcast antenna and converted into IF is applied to a set-top box (STB) to provide a broadcast service to a subscriber.

Satellite broadcasting has the advantage that service can be opened by providing independent satellite antennas to subscribers without building wired infrastructure, which requires a large investment cost and maintenance cost. On the other hand, the use of a high-frequency signal with a strong straightness between the satellite and the satellite broadcasting antenna, there is a disadvantage that the service opening is difficult when the shadowed area is generated by the surrounding features. In addition, due to the characteristics of the satellite signal transmission process that is transmitted through the atmosphere, it is frequently encountered that the service is interrupted due to the inability to receive normal satellite signals in bad weather such as snow / rain.

In order to solve this problem, a satellite broadcast optical repeater is used abroad to convert a satellite broadcast signal received through a satellite antenna into a satellite broadcast optical signal and transmit it to a receiver using an optical fiber transmission path. However, the existing satellite broadcasting optical relay receiver requires a separate power supply, which makes it difficult to install a home, and is difficult to wire in a home because it is connected to a set-top box using a coaxial cable having a large tension. On the other hand, the following patent document is a technology of a satellite broadcast receiver accompanying the above problem.

Korea Patent Registration 10-0512943

An object of the present invention is to provide a satellite broadcast optical reception apparatus for receiving a satellite broadcast optical signal and providing a satellite broadcast signal to a set-top box without a separate power supply.

In the optical broadcasting apparatus for satellite broadcasting according to the present invention for achieving the above technical problem, a satellite broadcasting signal received through a satellite antenna is amplified into an optical signal of satellite broadcasting, the optical signal received through an optical fiber transmission path is an optical signal A satellite broadcasting optical receiver for receiving the satellite broadcasting optical signal when the satellite broadcasting optical signal is separated by a splitter, the apparatus comprising: a detector for receiving the satellite broadcasting optical signal from the optical signal separator and converting the satellite broadcasting optical signal into an electrical signal; An amplifier for receiving and amplifying the electrical signal from the detector, correcting the signal strength, and converting the signal into a satellite broadcast signal; A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box; And a voltage converter configured to output the power output from the bias tee to the detector and the amplifier to supply power.

When the satellite broadcast signal received through the satellite antenna is amplified by the optical signal of the satellite broadcast, the optical receiver of another satellite broadcast according to the present invention receives the optical signal through an optical fiber transmission path and communicates from the received optical signal. An optical receiver for satellite broadcasting, comprising an optical signal separator for separating an optical signal and a broadcast optical signal, comprising: a detector for converting the broadcast optical signal separated by the optical signal separator into an electrical signal; An amplifier for amplifying the electrical signal received from the detector and correcting the signal to convert the signal into a satellite broadcast signal; A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box; And a voltage converter configured to output the power output from the bias tee to the detector and the amplifier to supply power.

In the present invention, the optical receiver of the satellite broadcast may further include an optical input unit for receiving an optical signal from the outside, and outputs the received optical signal through the bending reinforcing fiber to remove the bending loss.

Here, the satellite set-top box has an input dynamic range of 40 dB or more, and the satellite broadcast signal transmitted to the satellite set-top box is included in an input area of the input dynamic range, and the optical receiver of the satellite broadcast is There is no need for a separate automatic level control device to compensate for level variations in the satellite broadcast signal.

The optical receiver of the satellite broadcast may include a power detector configured to detect power of the electrical satellite broadcast signal converted by the detector; And a controller configured to determine an amplification factor by using the power value received from the power detector, wherein the amplifying unit amplifies the electric satellite broadcast signal using the amplification factor, according to the power of the satellite broadcast signal. By implementing automatic level control to compensate for the level variation of the satellite set top box can transmit a signal of a satellite broadcast of a certain size.

The detection unit may include: an optical signal separator for wavelength-demultiplexing the optical signals of the broadcasting and the communication, and separating the optical signals of the broadcasting and communications into a satellite broadcasting optical signal and an optical communication signal; And a photoelectric converter that receives the satellite broadcast optical signal from the optical signal separator and converts the satellite broadcast optical signal into an electrical satellite broadcast signal, thereby supporting compact manufacturing of the device and minimizing optical fibers and optical components exposed to the outside. It is possible to reduce the reception disturbance of the optical signal of the satellite broadcast by the user and to install the device in the home.

In addition, the detection unit has two optical input and output optical fibers by using a bent reinforced optical fiber, and having an SC connector (Subscriber Connector) or SC connector-Adapter as an optical fiber connector to which the optical input and output optical fiber is connected Support miniaturization of the device.

Furthermore, the satellite broadcasting optical receiver includes: a radio frequency (RF) connector for transmitting a satellite broadcast signal to the satellite set top box and receiving power from the satellite set top box; Two optical fiber adapters for receiving an optical signal and transmitting the separated optical communication signal to the optical communication device; A case accommodating an internal component of the light receiving device; An alarm indicator for indicating an error of the satellite broadcast optical signal and the converted satellite broadcast signal; And a cover for protecting the optical fiber adapter.

According to an aspect of the present invention, an optical receiver for satellite broadcasting can be implemented in the form of receiving a satellite broadcasting optical signal without a separate power supply, converting it into a satellite broadcasting signal, and directly connecting to a set-top box, and using a bending-reinforced optical fiber. Therefore, it is possible to miniaturize, and it can be built in the premises to provide satellite broadcasting service stably regardless of the reduction of the radio wave reception intensity in the shadow area or the reception performance due to bad weather.

The following drawings attached to this specification are illustrative of preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to.
1 is a schematic block diagram of a satellite broadcasting system using an optical receiver for satellite broadcasting according to an embodiment of the present invention.
2 is a schematic block diagram of an optical receiver for satellite broadcasting according to an embodiment of the present invention.
3 is a schematic block diagram of an optical receiver for satellite broadcasting including an optical signal separator according to another embodiment of the present invention.
FIG. 4 is a block diagram in which a power control function of a satellite broadcast signal is included in the optical receiver of the satellite broadcast of FIG. 2.
FIG. 5 is a block diagram in which a power control function of a satellite broadcast signal is included in the optical receiver of the satellite broadcast of FIG. 3.
6 is a schematic block diagram of a detector of the optical receiver of the satellite broadcast of FIGS. 3 and 5.
FIG. 7 is a schematic view illustrating the shape of the detector of FIG. 6.
8A to 8J are diagrams for describing an external appearance of the optical receiver of the satellite broadcast of FIGS. 2 and 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 shows a schematic configuration of a satellite broadcasting system 100 using an optical receiver 1 of satellite broadcasting according to an embodiment of the present invention.

Satellite broadcasting system 100 according to an embodiment of the present invention is a satellite optical converter (2), optical amplifying combiner (3), optical fiber transmission line (4), optical signal separator (5), satellite broadcasting optical receiver ( 1), a satellite set top box 6 and a display device 7.

The satellite optical converter 2 converts the satellite broadcast signal received through the satellite antenna of the ground station into a satellite broadcast optical signal. The optical signal of the satellite broadcast output from the satellite optical converter 2 is input to the optical amplifying combiner 3.

The optical amplifying combiner 3 amplifies the input satellite broadcasting optical signal, separates the amplified satellite broadcasting optical signal into two or more signals, and then multiplexes the wavelengths of the satellite broadcasting optical signal and the optical communication signal to broadcast / communication optical signal. Create Here, the optical communication signal may be a signal transmitted through a high-speed Internet facility such as Fiber To The Home (FTTH), and the broadcast / communication optical signal refers to a signal in which a satellite broadcast optical signal and an optical communication signal are multiplexed in wavelength.

The optical fiber transmission path 4 is a transmission medium for transmitting the broadcast / communication optical signal generated by the optical amplification combiner 3 to the optical signal separator 5. Here, the distance between the optical amplifying combiner 3 and the optical signal separator 5 may vary from subscriber to subscriber. The intensity of the satellite broadcast optical signal inputted to the optical receiver 1 of the satellite broadcast via the optical signal separator 5 may vary from subscriber to subscriber.

The optical signal separator 5 demultiplexes the broadcast / communication optical signal into a satellite broadcast optical signal and an optical communication signal. Then, the separated satellite broadcast optical signal is transmitted to the optical receiver 1 of satellite broadcast.

The optical receiver 1 of the satellite broadcast restores the received optical signal of the satellite broadcast to the satellite broadcast signal. A detailed description of the optical receiver 1 of the satellite broadcast will be described later with reference to FIGS. 2 to 6.

The satellite set top box 6 receives the satellite broadcast signal recovered from the optical receiver 1 of satellite broadcast. The satellite set-top box 6 converts the satellite broadcast signal into a signal that can be displayed by the display device 7 and transmits the signal to the display device 7.

In general, the satellite set top box 6 includes a function of supplying power to the LNB of the satellite antenna via a connector connected to the satellite antenna. In addition, even if the size of the satellite broadcasting signal received from the satellite antenna changes depending on the satellite antenna installation environment and weather conditions, the input dynamic range has an input dynamic range of 40 dB or more.

The display device 7 (eg, a TV) interprets the satellite broadcast signal received from the satellite set top box 6 and displays it on the screen.

FIG. 2 shows a schematic internal configuration of the optical receiver 1 of the satellite broadcast in FIG. 1.

The optical receiver 1 for satellite broadcasting according to an embodiment of the present invention includes a detector 11, an amplifier 12, a bias tee 13, and a voltage converter 14. . The optical receiving apparatus 1 may further include an optical input unit 15 using a bend-insensitive fiber.

The detector 11 receives the satellite broadcast optical signal separated by the optical signal separator 5, converts the satellite broadcast optical signal into an electrical satellite broadcast signal, and outputs the converted satellite signal to the amplifier 12.

Here, the optical input unit 15 transmits the satellite broadcast optical signal output from the optical signal separator 5 to the detection unit 11 by using the bending-reinforced optical fiber, thereby miniaturizing the satellite receiver optical receiver 1. It can solve the bending loss (bending loss) problem of the satellite broadcasting optical signal that may occur when the implementation. The deflection loss refers to the radiation loss generated by the bending of the optical fiber. The light input unit 15 is an optional component and may be added or omitted as necessary.

The amplifier 12 amplifies the electrical signal converted by the detector 11 and corrects the signal strength to restore the satellite broadcast signal. In this case, the restored satellite broadcast signal may be a signal of an intermediate frequency band.

The bias tee 13 receives the satellite broadcast signal from the amplifier 12 and transmits the satellite broadcast signal to the satellite set top box 6, receives DC power from the satellite set top box 6, and outputs the DC power to the voltage converter 14. do.

Here, since the satellite set-top box 6 includes a function of supplying power to the LNB of the satellite antenna through the connector connected with the satellite antenna as described above with reference to FIG. (1) receives power from the satellite set-top box 6 without a separate power supply, it is possible to receive the satellite broadcast optical signal and restore the satellite broadcast signal.

In addition, as described above with reference to FIG. 1, since the distance of the optical fiber transmission path 4 between the optical amplifying combiner 3 and the optical signal splitter 5 is different for each subscriber, it is input to the optical receiver 1 of satellite broadcasting. The strength of the satellite broadcast optical signal is also different for each subscriber. Here, in order to provide a stable satellite broadcast service, it is preferable that the strength of the satellite broadcast signal transmitted from the optical receiver 1 of the satellite broadcast to the satellite set top box 6 is constant. However, as described in FIG. 1, since the satellite set top box 6 has the input dynamic range of 40 dB or more, the strength of the satellite broadcast optical signal is not limited between the satellite optical converter 2 and the optical receiver 1 of the satellite broadcast. Maintain constant values without fluctuations unless they occur. Therefore, when the satellite broadcast signal converted by the optical receiver 1 of the satellite broadcast is included in the input range of the satellite set top box 6, a separate automatic level control device for compensating for the level variation of the satellite broadcast signal Does not need to be implemented in an optical receiver of a satellite broadcast.

3 shows a schematic internal configuration of an optical receiver 1 of satellite broadcasting including an optical signal separator 5 according to another embodiment of the present invention.

The optical broadcasting apparatus 101 of the satellite broadcasting according to another embodiment of the present invention further includes the optical signal separator 5 of FIG. 1 in the optical receiving apparatus 1 of the satellite broadcasting of FIG. 2.

If the optical signal separator 5 is embedded in the optical receiver 101 of satellite broadcasting, the optical fiber and optical components exposed to the outside may be minimized to reduce the obstacles to the optical signal reception of the satellite broadcasting by the user. It is possible to install the indoor light receiving apparatus 101 of the broadcast.

If the optical signal separator 5 is located outside, since optical fiber connection points are increased in the home, the failure of optical signal reception due to a user error may occur. For example, when the user touches the connection portion of the optical connector, the connector may be pulled out or broken and a failure may occur. In addition, the external optical signal separator 5 is likely to be damaged and must be protected by a separate case. Therefore, the optical receiver 1 of FIG. 2 can also be installed indoors. However, since the optical receiver 101 of FIG. 3 has an optical signal separator 5 built in, the stability is further improved from the risk of signal reception failure or damage. Is strengthened.

In addition, when the optical signal splitter 5 uses the bending-reinforced optical fiber as the optical fiber for optical input / output, the deflection loss of the satellite broadcast optical signal that may occur when the optical receiver 101 of the satellite broadcast is miniaturized. You can solve the problem.

Alternatively, the light input unit 15 of FIG. 2 may be applied to the light receiving device 101 of FIG. 3. For example, when the optical receiving device 101 receives a broadcast / communication optical signal from the outside by the optical input unit 15, the optical input unit 15 bends the received optical signal through an optical fiber splitter built through an enhanced optical fiber. Output as (5). Of course, the bending strengthened optical fiber solves the problem of bending loss. The optical signal separator 5 separates the communication optical signal from the input optical signal, and outputs the broadcast optical signal to the detection unit 11. The detection unit 11 then converts the broadcast optical signal into an electrical signal of satellite broadcasting.

4 is a schematic internal configuration in which the power reception function of the satellite broadcast signal is further included in the optical receiver 1 of the satellite broadcast in FIG. 2.

The optical broadcast receiver 1 of the satellite broadcast according to an embodiment of the present invention may further include a power detector 15 and a controller 16 in the optical broadcast receiver 1 of FIG. 2.

The power detector 15 detects the power of the electrical satellite broadcast signal converted by the detector 11. The controller 16 adjusts the amplification factor using the power information detected by the power detector 15. In this case, the amplifier 12 amplifies the electrical satellite broadcast signal using the adjusted amplification factor. Through the power detector 15 and the control unit 16, the satellite broadcasting optical receiver 1 implements automatic level control for compensating for the level variation of the satellite broadcasting signal according to the power of the satellite broadcasting optical signal. 6) can transmit satellite broadcasting signals of a certain size.

FIG. 5 illustrates a schematic internal configuration in which the optical receiver 101 of FIG. 3 further includes a power control function of a satellite broadcast signal.

The satellite broadcasting light receiving apparatus 101 according to another embodiment of the present invention may further include a power detector 15 and a controller 16 in the satellite broadcasting optical receiving apparatus 101 of FIG. 3.

First, when the optical signal separator 5 is embedded in the optical receiver 101 of the satellite broadcast, the optical signal and optical components exposed to the outside can be minimized to reduce the reception disturbance of the optical signal of the satellite broadcast by the user. It is possible to install the indoor receiver of the optical receiver 101 of satellite broadcasting.

In addition, by using the bending-reinforced optical fiber as the optical input and output optical fiber of the optical signal separator 5, the problem of the bending loss of the satellite broadcasting optical signal which may occur when the optical receiver 101 of the satellite broadcasting is miniaturized I can solve it.

FIG. 6 shows a schematic block diagram of the configuration of the detector 111 in the optical receivers 1 and 101 of the satellite broadcast of FIGS. 3 and 5.

The detector 111 may include the optical signal separator 5 of FIG. 1. When the optical signal separator 5 is included in the detection unit 111, the optical signal separator 5 demultiplexes the broadcast / communication optical signal into wavelengths, and separates the satellite broadcast optical signal into a satellite broadcast optical signal and an optical communication signal. Transfer to photoelectric converter 112. The photoelectric converter 112 converts the satellite broadcast optical signal separated by the optical signal separator 5 into an electrical satellite broadcast signal.

As described above, the optical signal separator 5 and the detector 111, which are optical elements, are implemented as one optical component, thereby making it possible to manufacture the optical receivers 1 and 101 for compact satellite broadcasting. In addition, by minimizing the optical fiber and optical components exposed to the outside to reduce the reception disturbance of the optical signal of the satellite broadcast by the user, it is possible to install the indoor receiver of the optical reception device (1, 101) of the satellite broadcast.

In this case, the detection unit 111 is preferably implemented in the optical sub-assembly (OSA) of the receptacle type (receptacle type) that can be directly coupled to the optical fiber. In this case, since the detector 111 directly wavelength demultiplexes the broadcast / communication optical signal and receives the satellite broadcast optical signal without a separate pigtail, the optical fiber bending of the detector 111 is performed. Can solve the problem of signal loss.

Alternatively, the detection unit 111 may implement the pigtail by using the bending reinforcement optical fiber. Through this, it is possible to manufacture the optical receivers 1 and 101 of the compact satellite broadcast, and to minimize the signal loss due to the bending of the optical fiber of the detector 111.

FIG. 7 schematically illustrates the shape of the detector 111 of FIG. 6.

The detector 111 includes an optical signal separator 5 as described with reference to FIG. 6 so that the optical receivers 1 and 101 of satellite broadcasting can be miniaturized. Thus, the detector 111 has two light input and output optical fibers. In order to solve the bending loss problem of the optical fiber that may occur when the solid state of the optical receivers 1 and 101 of the satellite broadcast, the optical input and output optical fibers of the detector 111 may be implemented as the bending-enhanced optical fiber.

7 (a) is an embodiment of the shape of the detector 111 according to the present invention. Referring to FIG. 7A, the shape of the detector 111 of the present invention includes an optical signal separator 5 and implements two light input / output optical fibers 113 by using a bending-reinforced optical fiber. And the optical fiber connector (connector) can be implemented by the SC connector 114 which is mainly used in the construction of FTTH.

7B is another embodiment of the shape of the detector 111 according to the present invention. Referring to FIG. 7B, the shape of the detection unit 111 of FIG. 7B is a shape of the SC connector-adapter 115 instead of the SC connector 114 in the embodiment of FIG. 7A. Use integrated light input and output terminals. By using the SC connector-adapter 115 instead of the SC connector 114, the optical receivers 1 and 101 of satellite broadcasting can be made more compact.

7C is another embodiment of the shape of the detector 111 according to the present invention. Referring to FIG. 7C, the shape of the detector 111 of FIG. 7C includes one SC connector-adapter 115 integrated light input / output terminal independently configured in the embodiment of FIG. 7B. It is implemented with an integrated light input and output terminal of the SC connector-adapter 116. By using one SC connector adapter 116 instead of two SC connector adapters 115, the satellite receivers of optical receivers 1 and 101 can be implemented at a lower cost and a smaller size.

8A to 8J schematically illustrate the external appearance of the optical receivers 1 and 101 of the satellite broadcast of FIGS. 2 and 3.

The shape of the satellite broadcasting optical receivers 1, 101 of the present invention is an RF connector 201 that transmits a satellite broadcast signal to the satellite set top box 6 and receives DC power from the satellite set top box 6, and broadcast / Two optical fiber adapters 202 for receiving communication optical signals and separating the optical communication signals and providing them to the optical communication device, and a case 203 for protecting internal components of the optical reception devices 1 and 101 of satellite broadcasting. ).

The RF connector 201 is preferably opposite to the RF connector type of the satellite set top box 6 so as to be directly connected to the satellite set top box 6 without a separate coaxial cable. For example, when the RF connector of the satellite set-top box 6 is a female type, the RF connector 201 of the optical receivers 1 and 101 of the satellite broadcasting is configured as a male type. When the RF connector of the satellite set-top box 6 is male, the RF connector 201 of the optical receivers 1 and 101 of the satellite broadcast is configured as a female type. The optical receivers 1 and 101 of the satellite broadcast may further include an alarm indicator 204 for displaying an error of the satellite broadcast optical signal or the converted satellite broadcast signal.

As described above, various embodiments of the shape of the optical receivers 1 and 101 of the satellite broadcast will be described with reference to FIGS. 8A to 8J.

Fig. 8A shows an embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to Figure 8a, the shape of the satellite broadcasting optical receiver of the present invention receives an RF connector 201, a broadcast / communication optical signal that can be directly connected to the RF connector for satellite broadcast signal reception of the satellite set-top box (6) And a case 203 for protecting the internal components of the optical receivers 1 and 101 of the satellite broadcast, and two optical fiber adapters 202 for separating and providing the optical communication signal to the optical communication device. In addition, the optical receivers 1 and 101 of the satellite broadcast may further include an alarm indicator 204 for displaying an error of the satellite broadcast optical signal or the converted satellite broadcast signal. In addition, the cover 205 for protecting the optical fiber adapter 202 connected to the optical reception device (1, 101) of satellite broadcasting may be further included. Here, in one embodiment of the external appearance of the optical receivers 1 and 101 of the satellite broadcast of FIG. 8A, the connection direction of the RF connector 201 and the connection direction of the optical fiber are perpendicular to each other in order to improve convenience of optical fiber fastening. desirable. In addition, it is preferable to configure a two-stage structure in the form of a one-stage RF connector 201 and a two-stage optical fiber adapter 202 for compact manufacturing.

8B shows another embodiment of the external appearance of the optical receivers 1 and 101 for satellite broadcasting according to the present invention. Referring to FIG. 8B, unlike FIG. 8A, the fastening direction of the optical fiber and the connection direction of the RF connector 201 are parallel to each other. In addition, referring to FIG. 8B, the RF connector 201 is configured to be biased in one direction of the optical receivers 1 and 101 of satellite broadcasting so as not to interfere with the connection of other connectors at the rear of the satellite set top box 6. Can be.

8C shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8C, in order to improve convenience of optical fiber fastening, it is preferable that the fastening direction of the optical fiber and the connection direction of the RF connector 201 have an intermediate angle between vertical and horizontal. In addition, unlike FIG. 8A or FIG. 8B, it is preferable to configure two optical fiber adapters 202 and RF connectors 201 in the same stage. In addition, the RF connector 201 may be configured to be biased in one direction of the optical receivers 1 and 101 of the satellite broadcast so as not to interfere with the connection of other connectors on the rear side of the satellite set top box 6.

8D shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8D, unlike FIG. 8C, unlike FIG. 8C, two optical fiber adapters 202 are stacked in two stages, but it is preferable to configure the same in the same stage as the RF connector 201.

Fig. 8E shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8E, unlike FIG. 8C, unlike FIG. 8C, the coupling direction of the optical fiber and the connection direction of the RF connector 201 are perpendicular to each other, and two optical fiber adapters 202 and RF connector 201 are configured at the same stage. It is preferable. In addition, the RF connector 201 may be configured to be biased in one direction of the optical receivers 1 and 101 of the satellite broadcast so as not to interfere with the connection of other connectors on the rear side of the satellite set top box 6.

8F shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8F, unlike FIG. 8E, FIG. 8F is configured by stacking two optical fiber adapters 202 in two stages, but preferably in the same stage as the RF connector 201.

Fig. 8G shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8G, unlike FIG. 8E, FIG. 8G shows that the optical fiber fastening direction and the RF connector 201 are horizontal to each other, and the two optical fiber adapters 202 and RF connector 201 are configured at the same stage. It is preferable. In addition, the RF connector 201 may be configured to be biased in one direction of the optical receivers 1 and 101 of the satellite broadcast so as not to interfere with the connection of other connectors on the rear side of the satellite set top box 6.

Fig. 8H shows another embodiment of the appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8H, unlike FIG. 8G, two optical fiber adapters 202 are stacked in two stages. However, FIG. 8H is preferably configured in the same stage as the RF connector 201.

Fig. 8I shows another embodiment of the appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8I, FIG. 8I illustrates a direction in which a coupling direction of an optical fiber and a connection direction of the RF connector 201 are vertical, and two optical fiber adapters 202 and RF connectors 201 are configured at the same stage, unlike FIG. 8E. It is preferable that the optical receivers 1 and 101 of the satellite broadcast have a long length in the fastening direction of the optical fiber. In addition, the RF connector 201 may be configured to be biased in one direction of the optical receivers 1 and 101 of the satellite broadcast so as not to interfere with the connection of other connectors on the rear side of the satellite set top box 6.

8J shows another embodiment of the external appearance of the optical receivers 1 and 101 of satellite broadcasting according to the present invention. Referring to FIG. 8J, unlike FIG. 8I, two optical fiber adapters 202 are stacked in two stages. However, FIG. 8J is preferably configured in the same stage as the RF connector 201.

In the above-described embodiment, the term "~ part" is not used to mean a hardware division of the optical receivers 1 and 101 of satellite broadcasting. Accordingly, a plurality of constituent parts may be integrated into one constituent part, and one constituent part may be divided into a plurality of constituent parts. Also, the constituent unit may mean a hardware constituent unit, but may mean a constituent unit of software. Therefore, it should be understood that the present invention is not particularly limited by the term "part ".

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It goes without saying that various modifications and variations are possible within the scope of equivalence of the scope.

1, 101: optical receiver 5: optical signal separator
11 detection unit 12 amplification unit
13: bias tee 14: voltage converter

Claims (8)

When the satellite broadcast signal received through the satellite antenna is amplified by the optical signal of the satellite broadcast, and the optical signal received through the optical fiber transmission path is separated into a satellite broadcast optical signal by an optical signal separator, receiving the satellite broadcast optical signal In the optical receiver for satellite broadcasting,
A detector which receives the satellite broadcast optical signal from the optical signal separator and converts the optical signal into an electrical signal;
An amplifier for receiving and amplifying the electrical signal from the detector, correcting the signal strength, and converting the signal into a satellite broadcast signal;
A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box; And
A voltage converter configured to supply power by outputting the power output from the bias tee to the detector and the amplifier,
The satellite set top box has an input dynamic range of 40 dB or more, and the satellite broadcast signal transmitted to the satellite set top box is included in an input area of the input dynamic region, thereby compensating for level fluctuations of the satellite broadcast signal. An optical receiver for satellite broadcasting, characterized in that no automatic level control device is required. When the satellite broadcast signal received through the satellite antenna is amplified by the optical signal of the satellite broadcast, an optical signal separator for receiving the optical signal through the optical fiber transmission path, and separating the communication optical signal and the broadcast optical signal from the received optical signal In the optical receiver for satellite broadcasting to be built in,
A detector for converting the broadcast optical signal separated by the optical signal separator into an electrical signal;
An amplifier for amplifying the electrical signal received from the detector and correcting the signal to convert the signal into a satellite broadcast signal;
A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box; And
A voltage converter configured to supply power by outputting the power output from the bias tee to the detector and the amplifier,
The satellite set top box has an input dynamic range of 40 dB or more, and the satellite broadcast signal transmitted to the satellite set top box is included in an input area of the input dynamic region, thereby compensating for level fluctuations of the satellite broadcast signal. An optical receiver for satellite broadcasting, characterized in that no automatic level control device is required. When the satellite broadcast signal received through the satellite antenna is amplified by the optical signal of the satellite broadcast, and the optical signal received through the optical fiber transmission path is separated into a satellite broadcast optical signal by an optical signal separator, receiving the satellite broadcast optical signal In the optical receiver for satellite broadcasting,
A detector which receives the satellite broadcast optical signal from the optical signal separator and converts the optical signal into an electrical signal;
An amplifier for receiving and amplifying the electrical signal from the detector, correcting the signal strength, and converting the signal into a satellite broadcast signal;
A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box;
A voltage converter configured to supply power by outputting the power output from the bias tee to the detector and the amplifier;
A power detector for detecting power of the electrical satellite broadcast signal converted by the detector; And
Including a control unit for determining the amplification rate by using the power value received from the power detector,
The amplifying unit amplifies the electric satellite broadcasting signal using the amplification ratio, and implements automatic level control to compensate for the level variation of the satellite broadcasting signal according to the power of the satellite broadcasting optical signal. An optical receiver for satellite broadcasting, characterized by transmitting a signal. When the satellite broadcast signal received through the satellite antenna is amplified by the optical signal of the satellite broadcast, an optical signal separator for receiving the optical signal through the optical fiber transmission path, and separating the communication optical signal and the broadcast optical signal from the received optical signal In the optical receiver for satellite broadcasting to be built in,
A detector for converting the broadcast optical signal separated by the optical signal separator into an electrical signal;
An amplifier for amplifying the electrical signal received from the detector and correcting the signal to convert the signal into a satellite broadcast signal;
A bias tee receiving the satellite broadcast signal from the amplifier and transmitting the satellite broadcast signal to a satellite set top box and receiving DC power from the satellite set top box;
A voltage converter configured to supply power by outputting the power output from the bias tee to the detector and the amplifier;
A power detector for detecting power of the electrical satellite broadcast signal converted by the detector; And
Including a control unit for determining the amplification rate by using the power value received from the power detector,
The amplifying unit amplifies the electric satellite broadcasting signal using the amplification ratio, and implements automatic level control to compensate for the level variation of the satellite broadcasting signal according to the power of the satellite broadcasting optical signal. An optical receiver for satellite broadcasting, characterized by transmitting a signal. The method according to any one of claims 1 to 4,
And an optical input unit for receiving an optical signal from the outside and outputting the received optical signal through the bending reinforcing fiber to remove bending loss. The method according to claim 2 or 4,
Wherein:
An optical signal separator for wavelength-demultiplexing the optical signals of the broadcasting and communication to separate the satellite broadcasting optical signals and the optical communication signals; And
A photoelectric converter configured to receive the satellite broadcast optical signal from the optical signal separator and convert the satellite broadcast optical signal into an electrical satellite broadcast signal
It supports compact manufacturing of the device, including minimizing the optical fiber and optical components exposed to the outside to reduce the reception disturbance for the optical signal of satellite broadcasting by the user, and to enable the installation of the device in the home Satellite broadcasting optical receiver The method according to claim 6,
Wherein:
It has two optical input and output optical fiber by using a bending-reinforced optical fiber, and has an SC connector (Subscriber Connector) or SC connector-Adapter as the optical fiber connector to which the optical input and output optical fiber is connected to support the miniaturization of the device. An optical receiver for satellite broadcasting. The method according to any one of claims 1 to 4,
A radio frequency (RF) connector for transmitting a satellite broadcast signal to the satellite set top box and receiving power from the satellite set top box;
Two optical fiber adapters for receiving an optical signal and transmitting the separated optical communication signal to the optical communication device;
A case accommodating an internal component of the light receiving device;
An alarm indicator for indicating an error of the satellite broadcast optical signal and the converted satellite broadcast signal; And
Cover for protecting the optical fiber adapter
Apparatus for receiving a satellite broadcast, characterized in that it has an appearance including a.

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