JP2004356807A - Optical signal transmission structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize cost reduction by optimizing the branching structure of an optical fiber. <P>SOLUTION: Transmission optical fibers 2<SB>1-4</SB>for transmitting optical signals supplied from an optical signal distributing source 1 are arranged along a plurality of optical signal distributing destinations α<SB>1-16</SB>. Optical branching devices 3<SB>1-16</SB>for branching and drawing optical signals from the optical fibers 2<SB>1-4</SB>are provided for the respective distributing destinations α<SB>1-16</SB>. The optical power supplied by the distributing source 1 is set at optical power necessary for the plurality of optical signal distributing destinations. The optical signal branching ratios of the respective optical branching devices 3<SB>1-16</SB>are individually set so that the optical signals can be distributed to the respective distributing destinations α<SB>1-16</SB>, in a state that the signals have the optical power necessary for the respective distributing destinations α<SB>1-16</SB>. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an optical signal transmission structure for distributing an optical signal output from an optical signal distribution source to a plurality of optical signal distribution destinations.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a joint reception system of broadcast radio waves in a high-rise building, it has been practiced to convert a broadcast radio wave into an optical signal and distribute it to a signal distribution destination (each home or the like) on each floor. In this case, the optical signal is distributed as follows and distributed to each floor. In the following description, a conventional distribution structure will be described by taking as an example a case where optical signals are distributed to each floor α _{1 to 16} of a 16-story high-rise building α.
[0003]
As shown in FIG. 2, a broadcast wave received by the receiver 100 is converted into an electric signal and then amplified by the amplifiers 101A and 101B. The amplified electric signal is transmitted to the RF signal distributor 102. After the electric signal is distributed by the RF signal distributor 102, each distributed output is converted into an optical signal by the E / O converters 103A to 103D. The E / O-converted optical signal is divided into four by the optical signal distributors 104A to 104D, respectively, and then transmitted from the optical signal distributors 104A to 104D to the optical fiber cable 105.
[0004]
The optical fiber cable 105 includes a plurality of (four, for example) four optical fiber ribbons 106, and the ground floor (the optical signal distributors 104A to 104A) extends along the hierarchical direction (the vertical direction of the building) of the high-rise building α. It is wired from the 104D installed floor) up to the top floor α _16.
[0005]
Each optical signal E / O-converted by each of the optical signal distributors 104A to 104D is transmitted to each core 107 of each optical fiber tape core 106.
[0006]
At each floor α _{1 to 16} of the high-rise building α, an arbitrary core wire 107 is cut from the optical fiber tape core wire 106, and a drawing optical fiber 108 is fusion-spliced to the cut portion. As a result, at each of the floors α _{1 to} α ₁₆ , an optical signal is extracted from an arbitrary cord 107 via the extraction optical fiber 108. The total number of cores of the optical fiber cable 105 is set to the number of floors of the high-rise building α so that the core 107 can be pulled out on all of the floors α _{1 to 16} .
[0007]
The optical signal extracted by the extraction optical fiber 108 is converted into an electric signal by the O / E converter 109 provided on each floor α _{1 to 16} and then transmitted to the final signal distribution destination (each dwelling unit, etc.) on that floor. Be drawn in. At this time, the optical power of the optical signal transmitted through each core wire 107 is set to an optical power that can be photoelectrically converted by the O / E converter 109 on the drop-in floor. The amplification factors of the amplifiers 101A and 101B are set so that an optical signal having such optical power is transmitted to each core wire 107. (See Non-Patent Document 1)
[0008]
[Non-patent literature]
Edited and published by Japan CATV Technical Association "Design of HFC System" p15, p30-p33
[0009]
[Problems to be solved by the invention]
In the conventional optical signal transmission structure, in order to distribute the optical power of the optical signal distributed to the optical signal distribution destinations of the respective floors α _{1 to 16 to} the optical power that can be photoelectrically converted by the O / E converter 109 on the pull-in floor. , Optical signal distributors 104A to 104D are required. However, since the optical signal distributors 104A to 104D are relatively expensive components, the installation cost of the optical signal transmission structure is increased accordingly.
[0010]
Further, in order to transmit the optical signals distributed by the optical signal distributors 104A to 104D to each of the floors α _{1 to 16} , the number of cores corresponding to the hierarchy (16 floors in the example of FIG. 2) is required. Further, the installation cost of the optical signal transmission structure has been increased.
[0011]
[Means for Solving the Problems]
In order to solve the above-described problem, the present invention provides an optical signal distribution source, a plurality of optical signal distribution destinations, and a plurality of optical signal distribution destinations, which are wired along an arrangement direction of the plurality of optical signal distribution destinations and output from the optical signal distribution source. A transmission optical fiber for transmitting an optical signal to be transmitted to the optical signal distribution destination; and an optical branch provided at each of the optical signal distribution destinations, for branching an optical signal from the transmission optical fiber and leading the optical signal to each optical signal branch destination. And a container. The optical signal distribution source supplies an optical signal having an optical power required at a plurality of optical signal distribution destinations to the transmission optical fiber. And the optical signal branching ratio of each of the optical splitters is individually set so that the optical signal is distributed to each of the optical signal distribution destinations in a state having the optical power required at each optical signal distribution destination. ing.
[0012]
This makes it possible to transmit an optical signal to a plurality of optical signal distribution destinations with a single transmission optical fiber, thereby reducing the number of transmission optical fibers required for transmission. In addition, it is possible to reduce the cost of the optical signal transmission structure by using a relatively inexpensive component called an optical splitter to distribute the optical power required at the optical signal distribution destination at each pull-in position. Further, since the distribution ratio at the time of distribution to each optical signal distribution destination can be implemented by adjusting the branch ratio of the optical branching device, the branching accuracy can be maintained high and the adjustment can be easily performed.
[0013]
The following are preferred embodiments of the present invention. The optical signal distribution destination includes an O / E converter that converts a transmitted optical signal into an electric signal. The optical signal distribution source supplies an optical signal having optical power that can be photoelectrically converted by the plurality of O / E converters to the transmission optical fiber. In addition, the light of each of the optical splitters is distributed so that the optical signal is distributed to each of the optical signal distribution destinations in a state where the optical signal has optical power that can be photoelectrically converted by the O / E converter of each optical signal distribution destination. The signal branch ratio is set individually.
[0014]
According to this, using a relatively inexpensive component such as an optical splitter, an optical signal is converted into an optical signal in a state having optical power that can be photoelectrically converted by an O / E converter provided at the optical signal distribution destination. By distributing them to each other, the cost of the optical signal transmission structure can be reduced.
[0015]
According to the present invention, when the optical signal distribution destination is each floor of a building having a plurality of levels, the signal distribution source receives a broadcast wave and converts the signal into an electric signal, and the signal is output from the receiver. The present invention can be suitably applied to a case having an E / O converter for converting the electric signal into an optical signal.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a wiring diagram showing an optical signal transmission structure according to one embodiment of the present invention.
[0017]
In the present embodiment, the present invention is implemented in a joint reception system of broadcast radio waves in a high-rise building. In the present embodiment, as in the conventional example, the optical signal transmission structure of the present invention will be described with an example of a configuration in which optical signals are distributed to each floor α _{1 to 16} which are optical signal distribution destinations of a 16-story high-rise building α. You. In the joint receiving system, a received broadcast wave is converted into an electric signal, then further converted into an optical signal, and distributed to each floor (optical signal distribution destination). At each floor, the optical signal to be distributed is converted into an electric signal and then supplied to the final signal distribution destination (each dwelling unit, etc.).
[0018]
Optical signal transmission structure of this embodiment includes a light signal distribution source 1, the first to fourth transmission optical fiber 2 _1-4, the optical fiber coupler 3 _1-12 which is an example of an optical branching device, O / E converters 10 _{1 to 16} .
[0019]
Optical signal distribution source 1 includes a receiving apparatus 4, a first amplifier 5, the coaxial cable 6, and the second amplifier 7, a distributor 8, and the E / O converter _{9 1-4.} The receiving device 4 receives a broadcast wave and converts it into an electric signal (RF signal). The first amplifier 5 amplifies the electric signal output from the receiving device 4. The receiving device 4 and the first amplifier 5 are usually installed on the roof of a high-rise building α. The coaxial cable 6 transmits the electric signal amplified by the first amplifier 5 from the rooftop to the distributor installation floor (normally, the ground floor α ₁ ). The second amplifier 7 is provided on the floor where the distributor is installed, and amplifies an electric signal attenuated by transmission. The distributor 8 distributes the electric signal amplified by the second amplifier 7 to a plurality of transmission paths (four paths in the figure). E / O converter 9 _1-4 is provided for each transmission path, the distributor 8 by for E / O converting an electrical signal to be distributed to each optical signal. Except for the receiving device 4, the first amplifier 5, and the coaxial cable 6, the optical signal distribution source 1 is installed on the ground floor (or the top floor) of the high-rise building α.
[0020]
Transmission optical fiber 2 _1-4 are al provided for each (4 pathway in the figure) the transmission path, each composed of a single optical fibers. Transmission optical fiber 2 _1-4 are wired along the hierarchy direction of high-rise buildings alpha (vertical direction).
[0021]
First transmission optical fiber 2 ₁ is wired E / O converter installed floor from (ground floor alpha ₁₎ to the fourth floor. First transmission optical fiber _{2 1} of the first E / O converter _{9 1} E / O converted optical signal E / O converter installed floor from (ground floor alpha ₁₎ to 4 floors alpha ₄ an optical fiber for transmitting, connected to the first E / O converter 9 ₁ on the ground floor alpha _1.
[0022]
Transmission optical fiber 2 of the _second is wired E / O converter installed floor from (ground floor alpha ₁₎ to 8 floors alpha _8. Second transmission optical fiber 2 ₂ is an optical fiber for transmitting a second E / O converter 9 ₂ optical signal E / O conversion at the fifth floor alpha ₁ to 8 floors alpha _8, ground downstairs alpha ₁ is connected to the second E / O converter _{9 2.}
[0023]
Third transmission optical fiber _{2 3} are wired E / O converter installed floor from (ground floor alpha ₁₎ to 12 floors alpha _12. Third transmission optical fiber 2 ₃ is an optical fiber for transmitting from the third E / O converter 9 ₃ E / O to be converted optical signal 9 floors alpha ₉ to 12 floors alpha _12, ground downstairs alpha ₁ is connected to a third E / O converter _{9 3.}
[0024]
Fourth transmission optical fiber _{2 4} are wired E / O converter installed floor from (ground floor alpha ₁₎ the top floor (16th floor) to alpha _16. Fourth transmission optical fiber _{2 4} is an optical fiber for transmitting the fourth E / O converter _{9 4} E / O to be converted optical signal 13 floors alpha ₁₃ the top floor (16th floor) to alpha ₁₆ there are, connected on the ground floor alpha ₁ to the fourth E / O converter _{9 4.}
[0025]
Optical fiber coupler _{3 1-12} 1F alpha ₁ to 3 floor alpha ₃ high-rise buildings _alpha, 5 floor alpha ₅ to 7-floor alpha _7, 9 floors alpha _{9 ~} 11 floors alpha _11, 13 floors alpha ₁₃ to 15 floors They are respectively provided to α _15. First to third optical fiber coupler _{3 13} is provided corresponding to the first transmission optical fiber _{2 1.} The first optical fiber coupler 3 ₁ is provided in the first floor alpha ₁ to the first transmission optical fiber 2 _1. The second optical fiber coupler 3 ₂ are provided in the second floor alpha ₂ to the first transmission optical fiber 2 _1. Third optical fiber coupler 3 ₃ are provided in the third floor alpha ₃ in the first transmission optical fiber 2 _1.
[0026]
The _{fourth to sixth} optical fiber couplers 34 _{to 6} are provided corresponding to the _second transmission optical fiber 22. Fourth optical fiber coupler 3 ₄ is provided on the fifth floor α at ₅ second transmission optical fiber 2 _2. Fifth optical fiber coupler ₃₅ is provided in the sixth floor alpha ₆ to the second transmission optical fiber 2 _2. Optical fiber coupler 3 ₆ 6 are provided in the 7th floor alpha ₇ to the second transmission optical fiber 2 _2.
[0027]
The _{seventh to ninth} optical fiber couplers 37 _{to 9} are provided corresponding to the _third transmission optical fiber 23. Optical fiber coupler 3 ₇ 7 are provided in the floor 9 alpha ₉ to the third transmission optical fiber 2 _3. Optical fiber coupler _{3 8} 8 are provided in the 10 floor alpha ₁₀ to the third transmission optical fiber _{2 3.} Optical fiber coupler _{3 9} 9 is provided in the third transmission optical fiber _{2 3} in 11 floor alpha _11.
[0028]
The _{tenth to twelfth} optical fiber couplers 310 _{to 12} are provided corresponding to the _fourth transmission optical fiber 24. The optical fiber coupler _{3 10} of the 10 are provided in the 13th floor alpha ₁₃ to the fourth transmission optical fiber _{2 4.} Optical fiber coupler _{3 11} of the 11 are provided in the 14th floor alpha ₁₄ to the fourth transmission optical fiber _{2 4.} Optical fiber coupler _{3 12} of the 12 are provided in the 15th floor alpha ₁₅ to the fourth transmission optical fiber _{2 4.}
[0029]
The fourth floor alpha _4, 8 floors alpha _8, 12 floors alpha _12, 16 floors alpha _16, the optical fiber coupler _{3 1-12} not provided. At these floors, the tips of the _{first to fourth} transmission optical fibers 21 _{to 4} are drawn out without branching.
[0030]
Each of the _{first to twelfth} optical fiber couplers 31 _{to 12} includes an extraction optical fiber 11. First to 12 optical fiber coupler _{3 1-12} of the first to fourth for transmitting drawer optical fiber 11 by fusion splicing to the first to fourth transmission optical fiber _{2 1-4} It is taken out from the optical fiber 2 _1-4 by branching the optical signal. At that time, by adjusting the stretching rate of the fusion splicing site, the branching ratio, that is, the optical power ratio of the optical signal branched from the _{first to fourth} transmission optical fibers 21 to 4 as the main line can be arbitrarily set. adjust. Optical fiber coupler _{3 1-12} of the first to 12, by adjusting the branching ratio, an optical signal having a photoelectric conversion can be optical power in the O / E converter _{10 1-16} floor alpha _1-16 diverts from the first to fourth transmission optical fiber _{2 1-4.}
[0031]
O / E converters _{10 1 to 16} is installed on each floor alpha _1-16, it is connected to the distal end or first to the leading end of the fourth transmission optical fiber _{2 1-4} drawer optical fiber 11 . O / E converters _{10 1 to 16,} or optical signals drawer optical fiber 11 is drawn from the transmission optical fiber _{2 1-4,} an optical signal remaining on the tip of the transmission optical fiber _{2 1-4} O / The signal is converted into an electric signal by E conversion.
[0032]
In the optical signal transmission structure of the present embodiment, the electric signal generated by the receiving operation and the electric conversion operation in the receiving device 4 is amplified by the first and second amplifiers 5 and 7 and then distributed by the distributor 8. Is done. Each of the distribution outputs distributed by the distributor 8 is converted into an optical signal by the E / O converters 9 _{1 to 4} , and then transmitted through the _{first to fourth} transmission optical fibers 21 _{to 4} . Optical signals transmitted through the first to fourth transmission optical fiber _{2 1-4} receives a branch operation by the optical fiber coupler _{3 1-12,} each floor alpha _{1 ~ 16} drawer optical fiber 11 and the first to the It is transmitted to the distal end of the fourth transmission optical fiber 2 _1-4. Optical signal transmitted to the tip of the drawer optical fiber 11 and the first to fourth transmission optical fiber _{2 1-4} is converted into an electric signal by the O / E converter _{10 1-16} floor alpha _1-16 Is done. The electric signals generated by the photoelectric conversion in each of the floors α _{1 to 16} are distributed _to the final distribution destination of each of the floors α _{1 to 16} after the distribution operation and the amplification operation are performed. In the drawing, reference numeral 20 denotes a configuration including an amplifier, a distributor, and each distribution destination. In FIG. 1, at each floor α _{1 to 16} , an electric signal converted from an optical signal is transmitted to a final distribution destination of a total of eight houses. Deliver to.
[0033]
In the optical signal transmission structure of the present embodiment having such a configuration, the amplification factor of the electric signal by the second amplifier 7 is set as follows. The O / E converters 10 _{1 to 16} have light receiving levels unique to the device. Here, the light receiving level means the optical power of the optical signal that enables the O / E converters 10 _{1 to 16} to perform O / E conversion on the input optical signal. Therefore, when an optical signal is drawn into each of the floors α _{1 to} α ₁₆ , the optical power of the branch optical signal to be drawn needs to be set to a value equal to or higher than the optical power corresponding to the light receiving level of the O / E converters 10 _{1 to 16.} is there.
[0034]
In this embodiment, branches from the transmission optical fiber 2 _1-4 a light signal transmitted upon transmitting the optical signal of the fourth order component in one transmission optical fiber 2 _1-4 each floor alpha _{1 ~ 16} It has a configuration. Therefore, the optical power of the optical signal transmitted by one transmission optical fiber 2 _1-4, it is necessary to set to a value corresponding to the light receiving level of 4 Kaibun O / E converters 10 _{1 to 16.}
[0035]
Therefore, the second amplifier 7, so that the optical power of the optical signal to be transmitted to the transmission optical fiber 2 _1-4 becomes a value corresponding to a light receiving level of the O / E converters 10 _{1 to 16} 4 Kaibun Is set to the amplification factor. The electric signal output of the second amplifier 7 after being 4 distributed by the distributor 8, each of the output distributor 8 is converted into an optical signal by the E / O converter 9 _1-4. Therefore, the amplification factor of the second amplifier 7 is set so that the output (optical signal) of each of the E / O converters 9 _{1 to 4} becomes a value corresponding to the light receiving levels of the O / E converters 10 _{1 to 16} for the fourth order. Is set.
[0036]
By setting the amplification factor of the second amplifier 7 as described above, the light receiving levels of the four-stage O / E converters 10 _{1 to 16} are provided _{to the first to fourth} transmission optical fibers _{21 to 4.} Is transmitted. By providing the optical fiber coupler _{3 1-16,} from the optical signal that transmits a transmission optical fiber _{2 1-4,} the optical signal having an optical power corresponding to the light receiving level of the O / E converters _{10 1 to 12} branches It is transmitted to the tip of the drawer optical fiber 11 and the transmission optical fiber 2 _{1 to 4.} A branching ratio of the optical fiber coupler 3 _1-12, as described above, arbitrarily set by adjusting the elongation of the optical fiber at the connection portion between the lead-out optical fiber 11 and the transmission optical fiber 2 _1-4 can do.
[0037]
Hereinafter, an example of a branching ratio of the optical fiber coupler _{3 1-12.} Here, description will be made assuming that O / E converters 10 _{1 to 16} having light receiving levels (+2.0 dBm or more) are provided on each floor α _{1 to 16} . In this case, the optical signal distribution source 1 supplies an optical signal having an optical power of + 9.0DBm the transmission optical fiber _{2 1-4.} Furthermore, 1,5,9,13 floor alpha _1, alpha _5, alpha _9, the optical fiber coupler ₃ 1 provided in alpha _13, 3 _5, 3 _{9, 3 13} branching ratio of the transmission optical fiber: Drawer Optical fiber = 2: 8. 2,6,10,14 floor _{α 2, α 6, α 10} , the optical fiber coupler ₃ is provided on _{α 14 2, 3 6, 3} 10, 3 14 branching ratio of the transmission optical fiber: drawer optical fiber = 7: 3. 3,7,11,15 floor alpha _3, alpha _7, alpha _11, the optical fiber coupler ₃ 3 provided on alpha _15, 3 _7, 3 _{11, 3 15} branching ratio of the transmission optical fiber: drawer optical fiber = 5: 5.
[0038]
By being set as described above, the O / E converters 10 ₁ , 10 ₅ , 10 ₉ , and 10 ₁₃ provided in the ₁ , ₅ , ₉ , and _13th- order α ₁ , α ₅ , α ₉ , and α ₁₃ have , +2.01 dBm. The O / E converters 10 ₂ , 10 ₆ , 10 ₁₀ , and 10 ₁₄ provided in the ₂ , ₆ , ₁₀ , and _14th- order α ₂ , α ₆ , α ₁₀ , and α ₁₄ have light having an optical power of +2.80 dBm. A signal is provided. The O / E converters 10 ₃ , 10 ₇ , 10 ₁₁ , 10 ₁₅ provided in the _third , _third , _seventh , and fifteenth order α ₃ , α ₇ , α ₁₁ , and α ₁₅ have light having an optical power of +3.47 dBm. A signal is provided. The O / E converters 10 ₄ , 10 ₈ , 10 ₁₂ , and 10 ₁₆ provided in the ₄ , ₈ , ₁₂ , and _16th- order α ₄ , α ₈ , α ₁₂ , and α ₁₆ have light having an optical power of +3.47 dBm. A signal is provided.
[0039]
In this manner, the optical power of the optical signal transmitted through the lead-out optical fiber 11, by maintaining the higher receiving level of the O / E converters _{10 1 to 16,} each of the O / E converter _{10 1-16} The input optical signal can be converted to an electric signal (RF signal) with high accuracy. After the electric signal converted by the O / E converters 10 _{1 to 16} is subjected to amplification processing and distribution processing, the electric signal is drawn into each final distribution destination (each dwelling unit in the case of an apartment house) on each floor α _{1 to 16.} It is.
[0040]
In the present embodiment, the 16-story high-rise building α is targeted for optical signal transmission, and furthermore, optical signals for four floors are transmitted by _one transmission optical fiber 21 _{to 4} . Therefore, number of layers (16), the value 16/4 = 4 divided by one transmission optical fiber _{2 1 -} transmission, hierarchical number ₄ (4), the number of the transmission optical fiber _{2 1-4} Set to (4).
[0041]
In the optical signal transmission structure of the present embodiment, the required minimum number of wires is that four _{first to fourth} transmission optical fibers 21 to 4 capable of transmitting four levels of optical signals per wire are wired. is delivering the optical signal to all floors alpha _{1 ~ 16} by the transmission optical fiber _{2 1-4.} Therefore, it is possible to reduce the cost by number reduction of the transmission optical fiber 2 _1-4.
[0042]
Further, first to fourth transmission optical fiber 2 _1-4 has not been only wiring E / O converter 9 _1-4 Installation floor from (ground floor alpha ₁₎ to floor that the wiring object, the floor without the wiring object does not exist _{to 4 1} 2 unnecessary transmission optical fiber. Therefore, the partial absence of wires excess transmission optical fiber 2 _1-4, costs can be reduced.
[0043]
More specifically, the first transmission optical fiber 2 ₁ of the upper floors than the fourth floor is wired up to the fourth floor not wired. The upper floors than 8 floor is wired transmission optical fiber 2 of the _second up to the 8th floor not wired. Third transmission optical fiber 2 ₃ of the upper floors than 12 floors are wired up to the 12th floor is not wired. Only the fourth transmission optical fiber 2 ₄ are wired to the 16th floor.
[0044]
In the present embodiment, the optical power of the single optical signal to be transmitted to the transmission optical fiber 2 _1-4, set the optical power that satisfies the light receiving level of 4 Kaibun the O / E converters 10 _{1 to 16} it is for the 16th floor of a tall building alpha, and wire four transmission optical fiber 2 _1-4. Such setting of the number of wirings is merely an example of the present invention, and any other setting may be used. For example, if the optical power of an optical signal to be transmitted through one transmission optical fiber is set to an optical power that satisfies the light receiving levels of the O / E converters 10 _{1 to 16} for six floors, a 16-story high-rise building It suffices to wire two transmission optical fibers to α. In this case, the setting of the optical power of the optical signal to be distributed to each floor [alpha] _{1 to 16} (setting of the branching ratio of the optical fiber coupler) is separately set. Even in this case, the optical signal branching ratios of the optical fiber couplers are individually set so as to be distributed to each floor α _{1 to 16} in a state where the O / E converter has optical power that can be photoelectrically converted.
[0045]
【The invention's effect】
As described above, according to the present invention, the structure of the optical signal transmission structure can be simplified and the cost can be reduced.
[Brief description of the drawings]
FIG. 1 is a wiring diagram illustrating an optical signal transmission structure according to an embodiment of the present invention.
FIG. 2 is a wiring diagram showing a conventional optical signal transmission structure.
[Explanation of symbols]
REFERENCE SIGNS LIST 1 optical signal distribution source 2 _{1 to 4} transmission optical fiber 3 _{1 to 16} optical fiber coupler 4 receiving device 5 first amplifier 6 coaxial cable 7 second amplifier 8 distributor 9 _{1 to 4} E / O converter 10 _{1 to 16} O / E converter 11 Leading optical fiber

Claims (4)

An optical signal distribution source;
A plurality of optical signal distribution destinations and a transmission optical fiber that is wired along the arrangement direction of the plurality of optical signal distribution destinations and transmits an optical signal output from the optical signal distribution source to the optical signal distribution destination;
An optical splitter that is provided at each of the optical signal distribution destinations and splits an optical signal from the transmission optical fiber and draws the optical signal into each optical signal branch destination;
With
The optical signal distribution source is to supply an optical signal having an optical power required by the plurality of optical signal distribution destinations to the transmission optical fiber,
In addition, the optical signal splitting ratio of each of the optical splitters is individually set so that the optical signal is distributed to each of the optical signal distribution destinations in a state where the optical signal has a necessary optical power at each optical signal distribution destination. ,
An optical signal transmission structure, characterized in that: The optical signal transmission structure according to claim 1,
The optical signal distribution destination includes an O / E converter that converts a transmitted optical signal into an electric signal,
The optical signal distribution source supplies an optical signal having an optical power that can be photoelectrically converted by the plurality of O / E converters to the transmission optical fiber,
In addition, the light of each of the optical splitters is distributed so that the optical signal is distributed to each of the optical signal distribution destinations in a state where the optical signal has optical power that can be photoelectrically converted by the O / E converter of each optical signal distribution destination. Set the signal splitting ratio individually,
An optical signal transmission structure, characterized in that: The optical signal transmission structure according to claim 1 or 2,
The optical signal distribution destination is each floor of a building having a plurality of levels,
An optical signal transmission structure, characterized in that: The optical signal transmission structure according to any one of claims 1 to 3,
The signal distribution source, a receiver that receives broadcast radio waves and converts it into an electric signal,
An E / O converter for converting the electric signal output from the receiver into an optical signal.
An optical signal transmission structure, characterized in that:

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