JPS6411177B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an optical data multiplex transmission device using a spread spectrum method.

An example of an optical multiplex transmission device using a conventional spread spectrum method is shown in FIG. In the figure, 1 is an information source, 2 is a modulator for encoding or modulating information from the information source 1, 3 is a code generator that generates a different code for each information source, and 4 is a code generator for generating a code from the code generator 3. A spreading circuit that spreads the spectrum of information using codes; 5 is an electrical
an optical transmitter for performing optical conversion; 6 is a first data transmission terminal comprising a first information source 1; 7, 8 are second and third data transmission terminals having second and third information sources, respectively;
data transmission terminal, 9a is a photosynthesizer, 10
are the first, second and third data transmission terminals 6,
7, 8 and an optical combiner 9a, a spread spectrum data transmission station that converts the data to be transmitted into an optical signal, multiplexes it, and sends it out;
11a is an optical transmission line, 12a is an optical splitter, 13 is an optical receiver that performs optical-to-electrical conversion, 14 is a code generator, 15 is a despreading circuit, 16 is a demodulator, 17 is an information sink, and 18 is an optical receiver a first data receiving terminal which receives an optical signal and reproduces data; 19 is a fourth data transmitting terminal which includes a fourth information source; 9b
20 is an optical combiner, 20 is an optical splitter 12a, a data receiving terminal 18, and a fourth data transmitting terminal 1.
9. A data transmitting/receiving device consisting of an optical combiner 9b, which receives the optical signal transmitted through the optical transmission line 11a, reproduces the data, and sends the received optical signal and its own transmission data as optical output to the optical transmission line 11b. Terminal 12b is an optical branching device, 21, 22, and 23 are second, third, and fourth data receiving terminals having the same configuration as the first data receiving terminal 18, and 24 is an optical branching device 12b and three data receiving terminals. This is a data receiving station consisting of data receiving terminals 21, 22, and 23.

Next, the operation will be explained.

The signal from the information source 1 is subjected to conventional encoding or modulation by a modulator 2, and then spectrum spread by a spreading circuit 4 using a high speed code from a code generator 3, which is different for each information source.
This spectrum-spread signal is converted into an optical signal by an optical transmitter 5, and second and third optical signals from other data transmission terminals 7, 8 are spread spectrum-spread with different codes by a similar process. The signals are added together in the optical combiner 9a and sent from the data transmission station 10 to the optical transmission line 11a. The optical signal sent to the data transmission/reception station 20 is
A part of the optical power is guided to the data receiving terminal 18 in the optical branching device 12a, and is transmitted to the optical receiver 13.
is converted into an electrical signal by the despreading circuit 1 by the code from the code generator 14 that generates a code corresponding to the desired information, that is, the information of the first information source.
5, the spectrum is despread. By despreading, the desired signal is compressed and reproduced within the original band, but when signals from other information sources are despread, the original modulated wave is not reproduced and is spread over a wide band. They are only superimposed as interference noise, and by demodulating them through a narrow band filter in the demodulator 16, it is possible to separate and extract only the desired information.

The data transmission/reception station 20 includes a fourth data transmission terminal 1 having a fourth information source.
The spread spectrum optical signal from 9 is sent to the optical combiner 9b.
As a result, it is combined with the optical signal transmitted from the data transmission station 10, and sent out to the optical transmission line 11b.

The optical signal transmitted through the optical transmission path 11b is branched by the optical branching device 12b, and is split into the second, third, and fourth data receiving terminals 21, 22, and 23, respectively, in the same way as above. Information from the fourth information source is reproduced.

Although FIG. 1 shows the case where there is only one data transmitting/receiving station 20 between the data transmitting station 10 and the data receiving station 24, this means that a plurality of data transmitting/receiving stations 20 are connected vertically via an optical transmission line. It can be connected and provided.

In this way, by changing the code for each information source, it becomes possible to multiplex and transmit a plurality of pieces of information through a single optical transmission path.

The reception SN ratio in this method can be expressed as (S/N) _R = G _P + (D/U) ₀ [dB] (1). However, G _P [dB] is the band expansion rate by the spreading code, which is a gain called process gain. Further, (D/U) ₀ [dB] is the DU ratio at the optical receiver output. For example, G _P =
27 dB (500 times) and the required SN ratio (S/N) _R = 10 dB, then (D/U) ₀ = -17 dB. Therefore, if the levels reached by each signal are equal, it is 17 dB (50 dB).
times) becomes the permissible signal multiplicity, which makes it possible to multiplex 50 different pieces of information. Since G _P is proportional to the bit rate of the spreading code, increasing the multiplicity can be achieved by increasing the bit rate. Changing the multiplicity can be easily handled by changing the number of codes, and even if the multiplicity exceeds the limit, the reception SN ratio will only deteriorate slightly, providing high flexibility in system configuration.

However, when a large number of data stations are cascaded to a trunk optical fiber using the conventional configuration, there are the following drawbacks. That is, the optical power components of each signal in the optical combiner after the second data station following the data transmission station are unbalanced because the signals from the data transmission terminal located further away have greater attenuation. At the output of the optical receiver of each data station, the level of the interference signal superimposed on the desired signal is proportional to the optical power of that component, so if the optical power of the interference signal is large, the DU ratio will naturally deteriorate and the required reception SN There will be cases where the ratio cannot be guaranteed.

This invention was made in order to eliminate the drawbacks of the conventional ones as described above, and includes a device for monitoring the optical receiver output at each data receiving terminal.
An optical data multiplex transmission device that controls the transmitted optical power at the data transmitting terminal of the data station using this monitor output, so that the required DU ratio can be obtained at any data receiving terminal following the data station. is intended to provide.

An embodiment of the present invention will be described below with reference to the drawings. In Figure 2, 1 and 31 are information sources;
2 and 32 are modulators for encoding or modulating information from information sources 1 and 31, respectively;
33 is a code generator that generates a different code for each information source, and 4 and 34 are code generators 3 and 3, respectively.
3, a spreading circuit for spectrally spreading the information according to codes from 3; 5, 35 are optical transmitters that perform electrical-to-optical conversion; 6, a first data transmission terminal containing a first information source 1; 7, 8, a first data transmission terminal; second and third data transmission terminals each having a second and third information source; 9a an optical combiner for combining optical signals from each data transmission terminal; 10 the three data transmission terminals 6, 7, 8; a data transmitting station, 11a, comprising: a data transmitting station having only a transmitting state;
12a is an optical transmission line, 12a is an optical branching device, 13 is an optical receiver that performs optical-to-electrical conversion, 14 is a code generator that generates a code corresponding to desired information, and 15 is a code that generates information from the code generator 14. 16 is a demodulator for reproducing information from the signal compressed to the original band by the despreading circuit 15; 17 is the information reproduced by the demodulator 16; 41 is a reception monitor that monitors the output of the optical receiver 13; 42 is a transmission optical power controller that controls the transmission optical power of the optical transmitter 5 in response to the outputs of the reception monitor 41 and the diffusion circuit 34; 51; 52 is a data transmitting terminal with a controller having a transmitting optical power control function; 9b is an optical combiner; 53 is an optical branching device 12a; 51 is a data receiving terminal with a monitor;
This is a data transmitting/receiving station consisting of a data transmitting terminal 52 with a controller and a light combiner 9b. Further, 11b is an optical transmission line, 12b is an optical branching device,
21, 22, and 23 are second, third, and fourth data receiving terminals, and 24 is a data receiving station consisting of an optical branching device 12b and three data receiving terminals 21, 22, and 23.

Next, the operation will be explained. The process of sending information from the data transmitting station 10 is exactly the same as the conventional method shown in FIG. .
In the conventional system, since the optical transmission power from the second data transmission/reception station 20 was not particularly controlled, the optical power level of the passing optical signal from the first data transmission station 10 at the optical combiner 9b and the newly combined data Transmission terminal 1
The balance with the optical power level from 9 is lost,
Each signal at the third and subsequent data stations
There may be cases where the required reception S/N cannot be secured due to the deterioration of the DU ratio. In the present invention, the reception output of the spread spectrum optical signal is monitored by the reception monitor 41,
By controlling the newly combined optical transmission power so that the DU ratio with the signal from the spreading circuit 34 has a predetermined value, all the signals arriving at the third and subsequent data stations ensure a predetermined DU ratio. I'm trying to make it possible. By controlling the DU ratio at the time of transmission using the same operation at the data transmission terminals of the third and subsequent data stations, it is possible to ensure the necessary reception SN ratio at any data reception terminal for all signals. become.

That is, the optical output of the optical transmitter 35 of the data receiving terminal 52 of the data transmitting/receiving station 53 is controlled so that the combined optical power in the optical combiner 9b is equal to the optical power of each signal sent there. It is. And for that,
Now, the optical receiver 1 located at the data receiving terminal 51
Let the output of 3 be Pr, the output of the diffusion circuit 34 be Ps,
If α is the transmission light power control coefficient of the optical transmitter 35, then α should be controlled so that 10log(αKsPs/KrPr) = (S/N) _R − G _P +10log(M−M′) …(2) Bye. Here, Kr is the optical splitter 12a in the photosynthesizer 9b.
There is a relationship between the optical power Er and Er=KrPr,
Ks is a coefficient having a relationship with the optical power Es from the optical transmitter 35 in the optical combiner 9b such that Es=KsPs when α=1. Also, M is the total number of signals that may be multiplexed, M′ is the total number of signals that may have already been multiplexed before the optical transmitter under consideration, (S/N) _R , Similar to equation (1), G _P is the required reception SN ratio and process gain.

However, Pr≒0, that is, there is no signal sent,
If the output of the optical receiver 13 is only a random noise output, the data from the data transmission terminal 52 becomes the first transmitted data, so regardless of the magnitude of the output of the diffusion circuit 34, the output from the optical transmitter 35 is acceptable. It is sufficient to transmit at the maximum optical output that can be used.

Note that in the system shown in FIG. 2, there is only one data transmitting/receiving station 53 between the data transmitting station 10 and the data receiving station 24, but in this case, a plurality of data transmitting/receiving stations 53 are connected via an optical transmission line. They can be provided in cascade connection.

Although the above embodiment describes a method of assigning a different code to each information source, the same effect can be obtained by applying a method of assigning a different code to each information transmission destination. Further, in the above embodiment, a configuration was described in which each data receiving terminal monitors the output of the optical receiver, but if a certain relationship exists between the optical receiver output and the average received light power, the optical power can be directly monitored, The transmitted light output may be controlled by the monitor output, and the same effect as in the above embodiment can be achieved.

As described above, according to the present invention, in an optical data multiplex transmission apparatus using a spread spectrum method,
By monitoring the optical receiver output of the data receiving terminal and controlling the optical transmission power of newly merged data using this monitor output, the required DU ratio can be achieved at all data receiving terminals after the data station. This has the effect of increasing the reliability of the system.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an example of a conventional spread spectrum optical data multiplex transmission apparatus, and FIG. 2 is a block diagram of a spread spectrum optical data multiplex transmission apparatus according to an embodiment of the present invention. 6, 7, 8...data transmission terminal, 10...
...Data transmission station, 11a, 11b...
Optical transmission line, 51...Data receiving station, 1
9...Data transmission terminal, 41...Reception monitor (monitoring means), 42...Transmission light power controller (transmission light power control means), 53...Data transmission/reception station, 21, 22, 23...Data reception terminal, 24...Data receiving station. In the figures, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Claims] 1 It has a spread spectrum data transmission station that converts data to be transmitted into an optical signal and transmits it, an optical transmission line that transmits the optical signal from this data transmission station, and a monitor means that monitors the optical reception output. A spread spectrum data receiving terminal that receives the optical signal transmitted through the optical transmission line and reproduces the data, an optical receiving monitor output from this data receiving terminal, and a transmitting signal monitor output of the own station. A spread spectrum data transmission terminal having an optical transmission power control means for controlling transmission power, and regenerating and relaying data from other stations and transmitting own station's data 1
A plurality of data transmitting/receiving stations connected in cascade via an optical transmission line, an optical transmission line for transmitting the optical signal from the data transmitting/receiving station, and a data transmission line for receiving the optical signal transmitted by the optical transmission line. What is claimed is: 1. An optical data multiplex transmission device comprising: a data receiving station for reproducing the data;