JP2000022642A - Optical transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical transmission system capable of executing two- way communication without adoption of a control system for timings. SOLUTION: An outgoing optical signal Ld emitted from a center terminal station 1 is sent to subscriber terminals 51...5n via a relay optical fiber transmission line 2 and pluralities of branch optical fiber transmission lines 4 and electric signals S1...Sn sent from the subscriber terminals 51...5n are sent to a termination terminal station 6, where they are converted into an incoming optical signal Lu, which is sent to the center terminal station 1 via an optical transmission medium in this system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for performing bidirectional optical transmission via an optical transmission medium.

[0002]

2. Description of the Related Art In recent years, with the spread of the Internet, the growth of personal computers has been remarkable. This means that a new communication terminal has emerged alongside the phone,
An FT that can flexibly provide services for the multimedia era, where not only voice but also various information such as data and video signals are exchanged via a computer
It is important to make the access network symbolized by TH (Fiber To The Home).

FIG. 8 shows an example of economical realization of the opticalization of the access network ("Easy Optical Access System": Telecommunications Association). In FIG. 8, the downstream optical signal Ld emitted from the center terminal 1 is:
The light propagates through the relay optical fiber transmission line 2, is branched by the star coupler 3, and is sent directly to each subscriber 5a through the branch optical fiber transmission line 4 connected to the branched end.
Downlink optical signal L passing through the other branch optical fiber transmission line 4
d is sent to a curb 8a having an optical receiving device 81 and an optical transmitting device 83, and an electric signal received by the optical receiving device 81 is transmitted through a distributor 82 to a second subscriber 9c.
sent to a.

On the other hand, the upstream optical signal Lu emitted from the subscriber 5a or the upstream optical signal Lu obtained by converting the electric signal transmitted from the second subscriber 9a by the curb 8a is transmitted to the branch optical fiber transmission line 4, the star. The signal is sent to the center terminal 1 via the coupler 3 and the relay optical fiber transmission line 2. Such an optical access system comprises a center terminal 1 and a subscriber 5.
a or an optical fiber transmission line 2
As a result, since the downstream optical signal Ld and the upstream optical signal Lu are transmitted, there is a feature that the cost is reduced.

[0005]

However, when the upstream optical signal Lu emitted from the subscriber 5a or the curb 8a reaches one relay optical fiber transmission line 2 through a plurality of branch optical fiber transmission lines 4. , A plurality of upstream optical signals Lu
Collide with each other, so that the optical signals cannot be separated by the center terminal 1, and reception becomes impossible. For this reason, a transmission method is adopted in which the upstream optical signal Lu is transmitted at a shifted timing so that the optical signals transmitted from each subscriber 5a or the curb 8a do not collide with each other. When such a timing control method is employed, the system becomes complicated, the effective transmission capacity decreases, and the cost increases.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problem and to provide an optical transmission system capable of two-way communication without employing a timing control method.

[0007]

SUMMARY OF THE INVENTION An optical transmission system according to the present invention provides a bidirectional optical transmission between a center terminal having an optical transmission device and an optical reception device and a plurality of subscriber terminals via an optical transmission medium. In the signal transmission system, the optical transmission medium is connected to one relay optical fiber transmission line having one end connected to the center terminal station, and to be branched to the other end of the relay optical fiber transmission line. A plurality of branch optical fiber transmission lines, the subscriber terminal includes an optical receiver connected to the branch optical fiber transmission line, and an electric signal transmitting unit coupled to one end of the transmission unit for transmitting the electric signal. And
An output terminal is connected to the branch optical fiber transmission line, and an input terminal is further provided with a terminal terminal having an optical transmitter coupled to the other end of the transmission means. The electric signal transmitted to the subscriber terminal via the transmission medium and emitted from the subscriber terminal is sent to the terminal station, converted into an upstream optical signal, and converted into the optical signal through the optical transmission medium. It is transmitted to a station.

According to the optical transmission system of the present invention, the optical signal emitted from the center terminal passes through one relay optical fiber transmission line, is then branched into a plurality of branch optical fiber transmission lines, and is added to each subscribed optical fiber transmission line. Sent to the user terminal. On the other hand, the electric signal emitted from each subscriber terminal is once sent to the terminating terminal, converted into an optical signal, and sent out to the branch optical fiber transmission line connected to the terminating terminal. Is sent to the center terminal. Each signal emitted from a plurality of subscriber terminals is sent to the terminal terminal once, and then transmitted from the terminal terminal via one branch optical fiber transmission line. There is no collision.

In the optical transmission system according to the present invention, the terminal terminal is additionally provided with an optical receiving device connected to the branch optical fiber transmission line, and the terminal terminal receives an upstream signal when the terminal terminal does not receive a downstream optical signal. Preferably, an optical signal is transmitted. If the terminating terminal transmits an upstream optical signal during a time period when each subscriber terminal is receiving a downstream optical signal, the upstream optical signal reflected from a star coupler or an optical fiber transmission line may be mixed into each subscriber terminal. There is. In a time zone in which the downstream optical signal is not received even if the upstream optical signal is reflected, the subscriber terminal can confirm the destination of the signal, so that there is no erroneous reception, and the quality of the optical transmission system is improved. .

[0010] In the optical transmission system of the present invention, it is preferable that the wavelength of the downstream optical signal emitted from the center terminal is different from the wavelength of the upstream optical signal emitted from the terminal terminal. When reflection occurs from the star coupler or the optical fiber transmission line as described above, an upstream optical signal due to the reflection may be mixed into each subscriber terminal. If the wavelengths of the upstream optical signal and the downstream optical signal are different, it is possible to separate the two by using a filter that passes only the wavelength of the downstream optical signal even if the reflected upstream optical signal reaches each subscriber terminal. And at the same time, two-way communication is possible.

In the optical transmission system according to the present invention, an optical receiving device connected to the branch optical fiber transmission line, an input terminal connected to the optical receiving device, and an output terminal connected to one or more second subscriber terminals. Preferably, a curb is provided having a distributed device and the second subscriber terminal has receiving means connected to the distributing device and transmitting means coupled to the terminating end station via transmitting means. The curb can receive the downstream optical signal via the branch optical fiber transmission line, and can distribute and send the received electric signal to a number of second subscriber terminals.
Further, since the electric signal sent from each second subscriber terminal is once sent to the terminating terminal, and then sent out to the branch optical fiber transmission line, the number of subscribers can be added at low cost. In the optical transmission system of the present invention, it is preferable that the transmission means between the subscriber terminal or the second subscriber terminal and the terminal station is a telephone line or a wireless line. Since the signal emitted from each subscriber is voice, image, data, or the like transmitted only by each subscriber, the signal can be transmitted through a telephone line or a wireless line, and the cost is low.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the optical transmission system according to the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.

FIG. 1 is a diagram showing a configuration of an optical transmission system according to the present embodiment. An optical signal L is bidirectionally transmitted between a center terminal 1 and a plurality of subscriber terminals 5 via an optical transmission medium.
1 shows a system for transmitting d and Lu.

The optical transmission medium includes one relay optical fiber transmission line 2 and a plurality of branch optical fiber transmission lines 4 _1.
Are connected to one input terminal and a plurality of output terminals of the star coupler 3, respectively. The center terminal 1 is connected to the optical fiber transmission line 2 via an optical multiplexer / demultiplexer 13. The subscriber terminals 5 ₁ ... 5n and the terminating terminal 6 are connected to the respective branch optical fiber transmission lines 4 ₁ . The output terminals of the subscriber terminals 5 ₁ ... 5n and the terminating terminal 6 are connected by transmission means 7.

The star coupler 3 divides light incident from one input terminal from n output terminals and outputs the light evenly.
Light incident from one of the output terminals is a light member output from one of the input terminals. The optical fiber transmission line 2 or the branch optical fiber transmission line 4 connected to the star coupler 3 is generally, but not limited to, a single mode optical fiber or a multimode optical fiber.

The center terminal 1 includes an optical transmitting device 11 for transmitting a downstream optical signal Ld to the relay optical fiber transmission line 2 and an optical receiving device 12 for receiving an upstream optical signal Lu transmitted from the relay optical fiber transmission line 2. As described later, when the wavelengths of the downstream optical signal Ld and the upstream optical signal Lu are different, they are transmitted and received via a wavelength filter, and when the wavelengths are the same, via an optical multiplexer / demultiplexer 13 composed of a 3 dB coupler.

The subscriber terminal 5 includes an optical receiving device 51 for receiving the downstream optical signal Ld, and transmitting means 52 for transmitting the electrical signals S ₁ ... Sn of the subscriber such as voice, image or data.
And As the transmitting means 52, a telephone, a personal computer or a PHS is generally used.

The terminal station 6 is a subscriber terminal 5 ₁ ... 5n
A supply 62 supplies an electric signal S ₁ · · · Sn in a predetermined order sent from the electrical signal supplied S ₁ · · · S
optical transmitter 61 for converting n into an upstream optical signal Lu and sending it out
And Here, the electric signals S ₁ ... Sn are transmitted to the terminating terminal station 6 by means of an inexpensive and simple transmission means 8, for example, a telephone line or a wireless line because the band used is not wide.

FIG. 2 shows that the downstream optical signal Ld emitted from the center terminal 1 is directly transmitted to each subscriber terminal 5 via an optical transmission medium.
FIG. 6 is a diagram showing a state transmitted to the user. After passing through the optical fiber transmission line 2, the downstream optical signal Ld having n signal contents is equally divided by the star coupler 3, and each of the subscriber terminals is connected via the branch optical fiber transmission lines 4 _1. 5 _1.
..Sent to 5n. Each of the subscriber terminals 5 ₁ ... 5n receives only the signal addressed to the corresponding subscriber from the transmitted signals.

FIG. 3 shows that after transmitting the electric signals S ₁ ... Sn output from the respective subscriber terminals 5 _1. And
FIG. 3 is a diagram illustrating a state where the signal is transmitted to a center terminal station 1 via an optical transmission medium. According to this method, the upstream optical signal Lu having n signal contents is transmitted only from the branch optical fiber transmission line 4a connected to the terminal terminal station 6, and transmitted through the relay optical fiber transmission line 2 to the center terminal station 1. Sent to Therefore, signals emitted from the plurality of subscriber terminals 5 ₁ ... 5n can be sent to the center terminal 1 without collision. The center terminal station 1 classifies each signal into a predetermined destination and sends it again to the final subscriber terminal via the optical transmission medium.

FIG. 4 is a diagram showing a configuration of a second optical transmission system according to the present embodiment, in which the terminal terminal 6a has an optical transmitting device 61 and an optical receiving device 63, and the other components are the same. This is the same as the configuration of FIG. The downstream optical signal Ld transmitted from the center terminal station 1 is equally divided by the star coupler 3, and one of the divided downstream optical signals Ld is transmitted to the optical receiving device of the terminal terminal station 6a via the branch optical fiber transmission line 4a. 6
3 is received. The second optical transmission system is an optical receiver 63
5n receive the downstream optical signal Ld (the subscriber terminals 5 ₁ ... 5n also receive the downstream optical signal Ld during this time), the transmission function of the optical transmitter 61 is stopped, and the optical receiver During the time period when light is received by 63, the upstream optical signal Lu cannot be transmitted.

Therefore, the light receiving device 63 only needs to be able to receive the downstream optical signal Ld and determine the strength thereof, so that a simple photodiode is used. The signal received by the optical receiver 63 is supplied to the
2 acting on a buffer having a multiplexing function and forming the electrical signals S ₁ ... Sent from the subscriber terminals 5 _1.
Sn is stopped, and the transmission function of the optical transmitter 61 is stopped.

The subscriber terminals 5 ₁ ... 5n receive the downstream optical signal L.
When the upstream optical signal Lu is transmitted from the terminating terminal station 6a during the time period during which d is being received, when the reflection occurs from the star coupler 3 or the relay optical fiber transmission line 2, the upstream optical signal Lu due to the reflection is transmitted to each subscriber terminal. And may interfere with the downstream optical signal. In a time period during which the downstream optical signal Ld is not received, the upstream optical signal Lu is reflected and each subscriber terminal 5 ₁ is reflected.
... Even if the light reaches 5n, the upstream optical signal Lu
Of the downstream optical signal L
The quality of the optical transmission system can be improved without being mistaken for d.

FIG. 5 is a diagram showing the relationship between the time zone for receiving the downstream optical signal Ld and the time zone for transmitting the upstream optical signal Lu at the terminal station 6a. During the time period from t ₂ to t ₃ and t _{4 to} t ₅ during which the downstream optical signal Ld is received, the optical transmitter 7
1 is stopped, and the optical transmitter 71 is provided only in the time period from t _{1 to} t ₂ and t _{3 to} t ₄ in which the downstream optical signal Ld is not received.
Is able to make outgoing calls.

FIG. 6 is a diagram showing a configuration of a third optical transmission system according to the present embodiment. The wavelength λ _u of the upstream optical signal Lu is different from the wavelength λ _d of the downstream optical signal Ld. The rest is the same as the configuration shown in FIG. As shown in FIG.
If is different from the wavelength lambda _d wavelength lambda _u and the downstream optical signal Ld of the upstream optical signal Lu, and at the same time each subscriber terminal 5 ₁ · · · 5n receives a downstream optical signal Ld, the reflected light of the upstream optical signals Lu Is sent to each of the subscriber terminals 5 ₁ ... 5n, by taking measures such as receiving light through a band-pass filter passing only the wavelength λ _d of the downstream optical signal Ld.
Only the downstream optical signal Ld can be received, excluding the reflected upstream optical signal Lu. Therefore, there is no time limit for transmitting the upstream optical signal, so that the effective transmission capacity can be increased.

FIG. 7 is a diagram showing a configuration of a fourth optical transmission system according to the present embodiment, in which a curb 8 and a second subscriber terminal 9 are added to the configuration shown in FIG. Things. In FIG. 7, the curb 8 has an optical receiving device 81 connected to the branch optical fiber transmission line 4b, an input terminal connected to the optical receiving device 81, and an output terminal having one or more second subscriber terminals 9 _1. .. 9n are connected to the second subscriber terminals 9 ₁ ... 9n through the receiving means 92 connected to the distributing apparatus 82 and the terminal station 6 via the transmitting means 7. And transmitting means 91 connected thereto.

The curb 8 receives the downstream optical signal Ld sent through the branch optical fiber transmission line 4b, and the received electric signal S is distributed by the distributor 82 to the second subscriber terminals 9 _1.
9n, the number of subscriber terminals accommodated can be increased at low cost. Other parts are shown in Fig. 1.
Is the same as the method shown in FIG.

[0028]

According to the optical transmission system of the present invention, after the signal output from each subscriber terminal is once sent to the terminal station,
The optical signal is converted to an optical signal, transmitted to the branch optical fiber transmission line connected to the terminal terminal, and transmitted to the center terminal via the relay optical fiber transmission line. Therefore, optical signals do not collide with each other during transmission.

The signal transmitted from each subscriber terminal to the terminating terminal is a voice, image or data transmitted from each subscriber terminal, and therefore can be transmitted through a telephone line or a wireless line, and is low in cost.

When a method of transmitting an upstream optical signal during a time period in which the optical receiving device of the terminal station does not receive the downstream optical signal is employed, the upstream optical signal reflected from the star coupler or the relay optical fiber transmission line or the like is transmitted. Even if the signal is mixed in the subscriber terminal, the destination of the signal can be confirmed, so that the signal is not erroneously received. When the wavelengths of the downstream optical signal and the upstream optical signal are different, both can be transmitted simultaneously, and the transmission capacity can be increased.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration of an optical transmission system according to an embodiment.

FIG. 2 is a diagram illustrating a propagation state of a downstream optical signal according to the present embodiment.

FIG. 3 is a diagram illustrating a propagation state of an upstream optical signal according to the present embodiment.

FIG. 4 is a diagram showing a configuration of a second optical transmission system according to the embodiment.

FIG. 5 is a diagram illustrating a time relationship in which an optical signal propagates in the second optical transmission system.

FIG. 6 is a diagram illustrating a configuration of a third optical transmission system according to the present embodiment.

FIG. 7 is a diagram illustrating a configuration of a fourth optical transmission system according to the present embodiment.

FIG. 8 is a diagram illustrating a configuration of a conventional optical transmission system.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Center terminal station, 11 ... Optical transmitter, 12 ... Optical receiver, 13 ... Optical demultiplexer, 2 ... Relay optical fiber transmission line, 3 ... Star coupler , 4 ... branch optical fiber transmission line, 5 ... subscriber terminal, 51 ... optical receiving device, 52 ... transmitting means, 6 ... terminal terminal, 61 ... optical transmitting device , 62 ...
Supply device, 63: optical receiving device, 64: optical multiplexer / demultiplexer, 7
· Transmission means, 8 ··· Curb, 81 · · · Optical receiver, 82 · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ·
Second subscriber terminal, 91 ... transmitting means, 92 ... receiving means,
Ld ··· downstream optical signal, Lu ··· upstream optical signal, the oscillation signal from the S ··· subscriber, the wavelength of λ _d ··· downstream optical signal, wavelength of λ _u ··· upstream optical signal

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Nobuo Ayumoto 1F Tayacho, Sakae-ku, Yokohama-shi, Kanagawa F-term in Sumitomo Electric Industries, Ltd. Yokohama Works 5K002 AA05 DA03 DA04 EA03 FA01

Claims (5)

[Claims] 1. A system for bidirectionally transmitting an optical signal between a center terminal having an optical transmitter and an optical receiver and a plurality of subscriber terminals via an optical transmission medium, wherein the optical transmission medium comprises: One relay optical fiber transmission line having one end connected to the center terminal station, and a plurality of branch optical fiber transmission lines connected so as to branch off from the other end of the relay optical fiber transmission line. Wherein the subscriber terminal has an optical receiving device connected to the branch optical fiber transmission line, and an electric signal transmitting means coupled to one end of a transmitting means for transmitting an electric signal; There is further provided a terminal terminal having an optical transmission device connected to an optical fiber transmission line and having an input terminal coupled to the other end of the transmission means, and a downstream optical signal emitted from the center terminal is connected to the optical transmission line. Said subscription via the medium While being transmitted to the terminal,
The optical signal emitted from the subscriber terminal is transmitted to the terminal terminal, converted into an upstream optical signal, and transmitted to the center terminal via the optical transmission medium. Transmission system. 2. The terminal station further includes an optical receiver connected to the branch optical fiber transmission line, and the terminal station receives the upstream optical signal during a time period when the terminal station does not receive the downstream optical signal. The optical transmission system according to claim 1, wherein the optical transmission system transmits a signal. 3. The wavelength of the downstream optical signal emitted from the center terminal station is different from the wavelength of the upstream optical signal emitted from the terminal station station.
An optical transmission system according to item 1. 4. An optical receiving device connected to the branch optical fiber transmission line, and a distribution device having an input terminal connected to the optical receiving device and an output terminal connected to one or more second subscriber terminals. Wherein the second subscriber terminal has receiving means connected to the distribution device, and transmitting means coupled to the terminating terminal via the transmitting means. The optical transmission system according to claim 1. 5. The optical transmission system according to claim 1, wherein the transmission unit is a telephone line or a wireless line.