JPS6159575B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an optical fiber multiple access communication device, and more particularly to an optical fiber multiple access communication device using a single closed optical fiber as a common transmission path.

FIG. 1 is a block diagram showing a conventional optical fiber multiple access communication device. In FIG. 1, the trunk optical fiber 1 is installed in a closed path. The center station 2 connects the trunk optical fiber 1 to the trunk optical fiber 1 via an optical branching coupler 3 inserted into the closed circuit of the trunk optical fiber 1.
is combined with Data station 201~
204 is coupled to the trunk optical fiber 1 via optical branching couplers 301 to 304 inserted into the closed circuit of the trunk optical fiber 1, and performs mutual communication under the control of the center station 2.

Next, this operation will be explained. Under the control of the center station 2, the data stations 201 to 204 share the transmission path of one closed trunk optical fiber 1 and perform N-to-N mutual communication. Now, the optical signal transmitted from the data station 201 is coupled to the trunk optical fiber 1 by the optical branching/coupling device 301, in one direction along the transmission path of the trunk optical fiber 1, that is, in the direction of arrow A shown in FIG. It spreads to. A portion of the optical power propagating through the trunk optical fiber 1 is branched at the optical branching couplers 302 to 304 and sent to each data station 20.
2 to 204. In this case, each data station 202-204 extracts and receives only the signal addressed to itself. In general, such N-to-N multiple access communication devices employ, for example, burst mode communication based on time division multiple access (hereinafter referred to as TDMA).

Since the conventional optical fiber multiplex communication device is configured as described above, the data station 201
~ data station 2 from any one of 204
The transmission loss to the others 01 to 204 changes depending on the number of optical branching couplers 301 to 304 passing through. Therefore, if multiple access technology such as TDMA is applied, for example, the data station 204
The optical signal level from the data stations 201 to 203 arriving at the data station 201
It changes greatly every 203 to 203. For this reason, it becomes extremely difficult to configure the optical receivers of each data station 201 to 204, such as receiving gain control.
There was a drawback that the quality of the transmitted signal deteriorated. In addition, the light that has passed around the closed trunk optical fiber 1 multiple times is also included in each data station 201 to 201.
204, the signal-to-noise ratio deteriorates.

This invention has been made in order to eliminate the drawbacks of the above-mentioned conventional ones. An embodiment of the present invention will be described below with reference to the drawings.

FIG. 2 is a block diagram showing an embodiment of an optical fiber multiple access communication device according to the present invention. 1st in the diagram
The same parts as those in the figure are given the same reference numerals. In FIG. 2, the center station 2 and data stations 201 to 204 each have a wavelength λ ₂
is configured to receive an optical signal of wavelength λ 1 and transmit an optical signal of wavelength λ ₁ . The optical repeater 4 is connected to the trunk optical fiber 1 so as to constitute a part of the closed circuit of the trunk optical fiber 1, and receives an optical signal with a wavelength λ ₁ and transmits an optical signal with a wavelength λ ₂ .
And when an optical signal of wavelength λ ₂ is received, this wavelength λ ₂
This prevents the propagation of optical signals.

Next, this operation will be explained. Wavelength λ ₁ transmitted from each data station 201 to 204
The optical signals are sent to optical branching couplers 301 to 30
4 to the trunk optical fiber 1. now,
An optical signal of wavelength λ ₁ from data station 204 propagating in the direction of arrow A through trunk optical fiber 1 is
It is received by the optical repeater 4. This received optical signal is relayed and amplified by the optical repeater 4, and the wavelength λ
₂ and is coupled to the trunk optical fiber 1. Wavelength λ ₂ propagating through trunk optical fiber 1
A part of the optical power of the optical signal is branched to the data station 201 at the optical branch/coupler 301, and the remaining optical power propagates through the trunk optical fiber 1 as it is, and is sequentially transmitted to each optical branch/coupler 302 to 303. It branches to data stations 202-203.

At this time, each data station 201 to 20
For example, the transmission optical power loss of each optical branching coupler 3, 301 to 304 is controlled by 1.
Then, each data station 201 to 204
If the transmitted optical power is 5 to 2, the received optical power at the optical repeater 4 is 1 for any optical signal from any of the data stations 201 to 204, and the received optical level at the optical repeater 4 is set to 5 to 2. It can be kept constant regardless of the In addition, by keeping the transmitting optical power of each data station 201 to 204 constant and optimizing the optical branching and coupling ratio of each optical branching coupler 301 to 304, the level of received light at the optical repeater 4 can be adjusted to the transmitting station. It can be kept constant regardless of the Therefore, data stations 201 to 20
The reception gain control mechanism of the optical receiver No. 4 is simplified.

FIG. 3 is a block diagram showing an optical branching coupler. In FIG. 3, the first beam splitter 5 is installed in the optical branching couplers 3, 301 to 304, and splits a part of the optical signal of wavelength λ ₂ propagating through the trunk optical fiber 1 at a predetermined ratio. The light is divided into transmitted light and reflected light. The light receiving element 6 is installed in the center station 2 and the data stations 201 to 204, and receives the reflected light of wavelength λ ₂ from the first beam splitter 5. The light emitting element 7 is installed in the center station 2 and the data stations 201 to 204, and generates an optical signal of wavelength _λ1 . The second beam splitter 8 is installed in the optical branching couplers 3, 301 to 304, and couples the optical signal of wavelength λ ₁ from the light emitting element 7 to the trunk optical fiber 1.

That is, data stations 201 to 204
The optical signal of wavelength λ ₁ emitted from the light emitting element 7 of
The trunk optical fiber 1 is connected to the main optical fiber 1 by the beam splitter 8 of
is coupled to and propagated. On the other hand, trunk optical fiber 1
An optical signal with a wavelength λ ₂ transmitted from the optical repeater 4 is split into transmitted light and reflected light at a predetermined ratio by the first beam splitter 5, and the reflected light is sent to the data station. 201-204
The light is received by the light receiving element 6.

Figure 4 shows the first and second beam splitters 5 and 8.
In this transmission characteristic diagram, the horizontal axis represents the wavelength λ and the vertical axis represents the transmittance T. In FIG. 4, a characteristic curve a is the transmission characteristic of the first beam splitter 5, and a characteristic curve b is the transmission characteristic of the second beam splitter 8. That is, by changing the transmission and reflection characteristics of the first and second beam splitters 5 and 8,
The branching/coupling ratio can be optimized depending on the device.

Furthermore, any method such as time division multiple access (TDMA), frequency division multiple access (FDMA), spread frequency multiple access (SSMA), etc. can be applied to multiple access of signals.

For example, considering the application of the TDMA system, each data station 201 to 204 sends its own signal in a burst format based on the reference signal of the frame transmitted by the center station 2 so that the transmission timings of each station do not overlap. will be sent to. In the optical repeater 4, each data station 20
The optical burst signal train of wavelength λ ₁ sent from 1 to 204 is received, and this is relayed and amplified to transmit the optical burst signal train of wavelength λ _2.
each data station 2 as an optical burst signal.
Send from 01 to 204. Each data station 201-204 extracts and receives only the signal addressed to itself from the sent burst signal. The signal transmitted from the optical repeater 4 does not necessarily have to be burst mode transmission, but may be continuous mode time division multiplex transmission.

In addition, in the above embodiment, the optical branching coupler 3, 301
_{~ 304} , we have explained the case of a wavelength-selective optical branching/coupling device that can select wavelengths by itself. It can also be a vessel. Further, there may be a plurality of optical repeaters 4, and the number of optical wavelengths used may be increased according to the number of optical repeaters 4. In addition, although the center station 2 is shown as an independent station in FIG.
It is also possible to have any one of 4.

The present invention is configured as described above, and enables mutual communication between a plurality of data stations 201 to 204.
Since this is done via the optical repeater 4 that converts the optical wavelength, each data station 201
The level of the optical signal arriving at the data station 204 can be made constant regardless of the transmitting station, and the reception level does not change for each transmitting station.
1 to 204 is not required, the device can be manufactured at low cost, and highly reliable signal transmission is possible.

As described above, according to the present invention, it is not necessary to control the reception gain of the data station, and the apparatus has various effects such as being inexpensive and having high reliability.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a conventional optical fiber multiple access communication device, FIG. 2 is a block diagram showing an embodiment of the optical fiber multiple access communication device according to the present invention, and FIG.
This figure is a block diagram showing the optical branching coupler, and FIG. 4 is a diagram showing the transmission characteristics of the beam splitter. In the figure, 1 is a trunk optical fiber, 2 is a center station, 201 to 204 are data stations, 3, 301 to 304 are optical branching couplers, and 4
is an optical repeater. In addition, the same parts in each figure are given the same reference numerals.

Claims (1)

[Scope of Claims] 1. A trunk optical fiber installed in a closed circuit, each connected to the trunk optical fiber via an optical branching coupler, each receiving an optical signal of a first wavelength and receiving an optical signal of a second wavelength. a plurality of data stations transmitting signals, and at least one data station connected to the trunk optical fiber so as to form part of a closed circuit of the trunk optical fiber, and receiving the optical signal of the second wavelength; 1. An optical fiber multiple access communication device comprising an optical repeater that transmits optical signals of different wavelengths. 2. The optical branching/coupling ratio of the optical branching/coupling device corresponding to each of the plurality of data stations is set so that the level of received light at the optical repeater is constant regardless of the originating station. The optical fiber multiple access communication device as described in . 3. Optical fiber multiple access communication according to claim 1, wherein the optical transmission power of each of the plurality of data stations is set so that the received optical level at the optical repeater is constant regardless of the originating station. Device.