JP2827876B2 - Optical transmission method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical information transmission network.

[0002]

2. Description of the Related Art Conventionally, an optical multi-access system using a subcarrier multiplex transmission system has been studied as one of systems for transmitting information signals from a plurality of locations through an optical fiber network. According to this method, signal light intensity-modulated by a carrier having a different frequency is output from each of N terminals connected to the optical fiber network. However, this carrier is modulated by an information signal such as a video signal. This signal light is multiplexed in an optical fiber network, input to a receiving terminal, and converted into a high-frequency signal by an optical receiver. This high frequency signal is frequency-multiplexed with N carrier waves having different frequencies. Therefore, by taking out and demodulating an arbitrary carrier wave out of the N carrier waves by the tuner,
The receiving terminal can receive an information signal from any terminal. Regarding the optical multi-access scheme using such a subcarrier multiplex transmission scheme, for example, Shibuya et al., "Wide-area monitoring information transmission system-aiming at information transmission at an arbitrary point in a city," IEICE technical report OCS
92-25 (1992).

[0003]

In the conventional optical multi-access system using the subcarrier multiplex transmission system, a plurality of signal lights are multiplexed on an optical fiber network. If the wavelengths of these signal lights match or are very close to each other, noise due to interference between these signal lights, so-called beat noise, is generated at the receiving terminal, and in some cases, it becomes impossible to receive the transmission signal. . Therefore, it is necessary to control the wavelength of the optical transmitter in order to prevent the occurrence of the beat noise, which causes problems such as a complicated network, an increase in cost, and a limitation on the number of connectable terminals. The problem of the beat noise in the optical multi-access system using the subcarrier multiplex transmission system is described in, for example, Shibuya et al., "Wide-area surveillance information transmission system-aiming for information transmission at an arbitrary point in a city". Details are described in literatures such as the research report OCS92-25 (1992).

Further, in the conventional optical multi-access system using the subcarrier multiplex transmission system, a large problem is a loss of light generated when a plurality of signal lights are multiplexed on an optical fiber network. In particular, in a bus type optical fiber network in which an optical multiplexing section is inserted in series into an optical fiber network, the optical loss increases rapidly as the number of optical multiplexing sections increases, so that the number of connectable terminals is significantly limited.

Accordingly, an object of the present invention is to provide an optical transmission method in which no beat noise occurs and the number of terminals is not limited by optical multiplexing loss in an optical multi-access system using a subcarrier multiplexing system. It is in.

[0006]

An optical transmission method according to a first aspect of the present invention.
Means N (N is a natural number) optical terminals in the optical fiber transmission line
Each optical terminal has one or more information
Sources are connected and from the information source
The transmitted signal is input to each of the optical terminals, and the K-th (K is N or less)
(Natural number below), the K-1st optical terminal sends
The received signal light is received by the optical receiver,
A carrier signal from an information source connected to an optical terminal
High frequency signal output from receiver is multiplexed by multiplexer
The high-frequency signal output from the multiplexer is transmitted to the optical transmitter.
Applied from the Kth terminal to the (K + 1) th terminal
The signal light transmitted to the optical terminal is intensity modulated
And

[0007]

According to a second aspect of the present invention, in the optical transmission system according to the first aspect, the signal light transmitted through the optical fiber transmission line is intensity-modulated by a pilot signal. In the terminal, a pilot signal is extracted from the high-frequency signal obtained by receiving the signal light, the strength of the pilot signal is detected, and the strength of the high-frequency signal is adjusted by signal strength adjusting means so that the pilot signal strength becomes a predetermined value. It is characterized by increasing or decreasing.

In an optical transmission method according to a third aspect of the present invention, in the optical transmission system according to the first aspect, the signal light transmitted through the optical fiber transmission line is intensity-modulated by a pilot signal. In the terminal, a pilot signal is extracted from the high-frequency signal obtained by receiving the signal light, the strength of the pilot signal is detected, and the strength of the high-frequency signal is adjusted by signal strength adjusting means so that the pilot signal strength becomes a predetermined value. Increase / decrease, further, after the high frequency signal and the carrier signal from the information source are multiplexed by the multiplexer, the intensity of the high frequency signal output from the multiplexer is detected. After the intensity of the high-frequency signal is increased or decreased by the second signal strength adjusting means so as to obtain a value, the high-frequency signal is applied to the optical transmitter.

[0010]

In the first invention, each optical terminal converts an input optical signal into an electrical signal once, multiplexes the electrical signal with a carrier signal from an information source, converts the optical signal again into an optical signal, and outputs the optical signal from the optical terminal. . That is, each optical terminal performs analog reproduction relay and frequency multiplexing of the carrier signal. For this reason, since a plurality of signals are not combined on the optical fiber network, beat noise does not occur. Since signal multiplexing is performed in the electric stage, optical multiplexing loss does not occur as in the related art.

In the second invention, the signal light is intensity-modulated by the pilot signal, and the intensity of the pilot signal is detected at each optical terminal to perform automatic gain control. Instead, the optical modulation degree of the optical terminal output signal light is always kept constant.

In the third invention, automatic gain control using a pilot signal is performed in each optical terminal, and the carrier signal input to this optical terminal and the carrier signal from the preceding optical terminal are:
Multiplexing is always performed at a constant power ratio regardless of the intensity of the optical terminal input signal light. Further, after the second automatic gain control is performed so that the total intensity of these carriers becomes a predetermined value, the carrier is input to the optical transmitter. As a result, the optical modulation degree of the output signal light of each optical terminal is automatically set so as to reduce noise and distortion. According to the fourth aspect, even if the K-th and L-th (K and L are different natural numbers) optical terminals are exchanged, the setting of the carrier signal strength input to the optical terminal and the internal setting of the optical terminal are not performed. No need to change.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing a basic configuration of an optical transmission system according to the present invention. In FIG. 1, three optical terminals 10
0, 101, 102 and the center terminal 300 are connected in series by the optical fiber transmission line 10. Optical terminal 1
00, 101, and 102 are input with carrier signals 110, 111, and 112 having different frequencies, respectively. In the optical terminal 100, the carrier signal 110 is applied to the bias current of the optical transmitter 130, and the intensity of the signal light 140 output from the optical transmitter 130 is modulated by the carrier signal 110. In the optical terminal 101, the signal light 140 output from the optical terminal 100 is received by the optical receiver 151. The high-frequency signal 161 and the carrier signal 111 output from the optical receiver 151 are multiplexed by the multiplexer 171 and the optical transmitter 1
31 is input. As a result, the signal light 141 output from the optical terminal 101 is intensity-modulated by the carrier signals 110 and 111. Similarly, in the optical terminal 102, the signal light 1
41 is received by the optical receiver 152, and the obtained high-frequency signal 162 and carrier signal 112 are multiplexed by the multiplexer 172 and input to the optical transmitter 132. Optical terminal 10
The signal light 142 output from 2 is received by the optical receiver 350 of the center terminal 300. The high-frequency signal 360 output from the optical receiver 350 includes the carrier signals 110 and 11
1, 112 are frequency-multiplexed, and these carrier signals are tuned and demodulated, respectively.
Information from 0, 101, and 102 can be received.

FIG. 2 is a block diagram of the first embodiment of the present invention. The optical fiber transmission line 10 includes optical terminals 100, 10
1, 102 and the center terminal 300 are connected, and the fiber length between each optical terminal and the center terminal is 3 km.
Met. The optical terminal 100 receives carrier signals 110 and 111 from information sources 400 and 401. Similarly,
The optical terminals 101 and 102 have information sources 402 and 403
And carrier signals 112, 113 from 404, 405
And 114 and 115 are input. In the case of this embodiment,
The information sources 400 to 405 are monitoring camera terminals, and the carrier signals 110 to 115 are FM-modulated by video signals. Also, carrier signals 110, 111, 112, 11
The center frequencies of 3, 114 and 115 are 1049, respectively.
MHz, 1088MHz, 1126MHz, 1165M
Hz, 1203 MHz and 1241 MHz.

The optical terminal 100 has a pilot signal generator 410 for outputting a pilot signal 420 having a frequency of 1101 MHz. This pilot signal 420 and information source 4
The carrier signals 110 and 111 from 00 and 401 are multiplexed by the multiplexer 170 and input to the optical transmitter 130. In the present embodiment, a Fabry-Perot LD of 1.3 micron band is used as the optical transmitters 130, 131, and 132. Both the pilot signal 420 and the carrier signals 110 and 111 at the time of input to the optical transmitter 130 have an intensity of −21 dBm, whereby the signal light 140 is subjected to intensity modulation with an optical modulation factor per carrier of 5%.

In the optical terminal 101, the signal light 140 output from the optical terminal 100 is received by the optical receiver 151. The optical receivers 151, 152, and 350 of the present embodiment are 50
PIN-PD with ohm load resistance connected. The high-frequency signal 161 output from the optical receiver 151 is amplified by the variable gain amplifier 210,
Is partially branched, and the carrier signal 1 is further divided by the multiplexer 171.
The signals are multiplexed with the signals 12 and 113 and input to the optical transmitter 131.

The high-frequency signal partially branched by the splitter 211 is input to the automatic gain control circuit 231 after only the pilot signal 420 is separated by the band-pass filter 221. Automatic gain control circuit 231 detects the intensity of input pilot signal 420 and controls the gain of variable gain amplifier 201 such that the intensity of input pilot signal 420 becomes a predetermined value. By this so-called feedback control, the input level of the high-frequency signal 161 to the multiplexer 171 is always kept constant. In this embodiment, the duplexer 2
11, the demultiplexing ratio is 10 to 1, and the automatic gain control circuit 2
Reference numeral 31 controls the gain of the variable gain amplifier 201 so that the input pilot signal strength becomes -21 dBm. Thus, regardless of the reception intensity of the signal light 140, the multiplexer 171
Signal 420 and carrier signal 1 input to
The strength of 10,111 is kept at -11 dBm. The multiplexing loss of the multiplexer 171 is 10 dB, and the
Thirteen multiplexer input levels are set to -11 dBm. Therefore, the input intensities of the pilot signal 420 and the carrier signals 110 to 113 of the optical transmitter 131 were both -21 dBm. Therefore, the signal light 141 output from the optical transmitter 131 is intensity-modulated by the pilot signal 420 and the carrier signals 110 to 113 at an optical modulation factor of 5%.

The optical terminal 102 has the same configuration as the optical terminal 101, and the signal light 142 output from the optical terminal 102 is the pilot signal 42 transmitted from the optical terminals 100 and 101.
0, and modulated by carrier waves 114 and 115 input to the optical terminal 102 in addition to the carrier signals 110 to 113. Also, by the same automatic gain control as that of the optical terminal 101, the optical modulation degree per carrier of the signal light 142 is maintained at 5% regardless of the light receiving level.

The center terminal 300 receives the signal light 142 from the optical terminal 102 by the optical receiver 350, and obtains a high-frequency signal 360 in which the pilot signal 420 and the carrier signals 110 to 115 are frequency-multiplexed. Further tuner 370
, One of the carrier signals 110 to 115 is selected and demodulated, so that an arbitrary video signal from the information sources 400 to 405 can be obtained. In this embodiment, a BS tuner for receiving satellite broadcasting is used as the tuner 370.

In the first embodiment described above, three optical terminals are cascaded, and two carrier signals are multiplexed for each optical terminal. However, the number of optical terminals and the number of carrier signals of the present invention are However, the present invention is not limited to this. In the present invention, the number of connected optical terminals is limited by the accumulation of noise and distortion generated in each optical terminal, and the number of carrier signals is limited by bands of an optical transmitter, an optical receiver, a tuner, and the like. In this embodiment, up to ten optical receiving terminals can be connected. However, tuner 3
Since a BS tuner is used as 70, the number of carrier signals that can be transmitted simultaneously is limited to eight.

FIG. 3 is a block diagram of a second embodiment of the present invention. In the first embodiment, the optical modulation degree of the signal light output from each optical terminal is constant. However, in the present embodiment, automatic gain control capable of reducing deterioration due to accumulation of noise due to multiple connection of optical terminals. Is performed on each terminal. Further, optical terminals are connected by a loop-shaped optical fiber transmission line starting from the center terminal, so that a data signal for control can be transmitted from the center terminal to each optical terminal.

In center terminal 300 of FIG. 3, pilot signal 420 is converted to PSK by data signal 430 of 64 kbps input to pilot signal generator 410.
Modulated. The signal light 340 output from the center terminal 300 is modulated by the pilot signal 420 at a light modulation factor of 13.2%.

In the optical terminal 100, a part of the high-frequency signal 160 obtained by receiving the signal light 340 is split by the splitter 210, and the pilot signal 42 is output by the band-pass filter 220.
After only 0 is separated, the signal is further branched into two by the splitter 240, and the automatic gain control circuit 230 and the demodulator 25
Input to 0. Demodulator 250 demodulates PSK-modulated pilot signal 420 and extracts data signal 430. Further, the automatic gain control circuit 230 controls the gain of the variable gain amplifier 200 according to the input pilot signal intensity, and reduces the input intensity of the multiplexer 170 of the pilot signal 420 by-
Keep at 11 dBm. Further, the intensity of the multiplexer 170 is -1.
Carrier waves 110 and 111 set to 1 dBm are input.

High-frequency signal 1 output from multiplexer 170
After passing through the second variable gain amplifier 260, a part of the signal 60 is split by a splitter 270 having a splitting ratio of 10: 1, and is input to the optical transmitter 130. The high-frequency signal partially branched by the splitter 270 is input to the second automatic gain control circuit 280. The second automatic gain control circuit 280 controls the gain of the second variable gain amplifier 260 so that the input high-frequency signal level becomes -22.5 dBm. At this time, the input level of the high-frequency signal 160 to the optical transmitter 130 is -12.5.
dBm and the pilot signal 4 contained therein.
The input level of the optical transmitter 130 for 20 and the carrier waves 110 and 111 is about -17.3 dBm. In this case, the signal light 140 includes the pilot signal 420 and the carrier signal 11.
The intensity is modulated by 0,111 at a light modulation degree of 7.7%.

In the optical terminal 101, similarly to the optical terminal 100, the pilot signal 4 is output by the automatic gain control circuit 231.
The input intensity of the multiplexer 171 of the carrier 20 and the carriers 110 and 111 is kept at -11 dBm. Further, carrier waves 112 and 113 having an intensity of −11 dBm are input to the multiplexer 171. Further, the second automatic gain control circuit 281 controls the gain of the second variable gain amplifier 261 so that the input high-frequency signal level becomes -22.5 dBm.
The input level of the optical transmitter 131 is the same as that of the optical terminal 100-
It is kept at 12.5 dBm. However, in the optical terminal 101,
Pilot signal 420 and carrier signals 110-113
Are contained in the high-frequency signal 161, the input level of the optical transmitter 131 per carrier is -1.
9 dBm, and as a result, the optical modulation degree per carrier of the signal light 141 is 5.9%.

Further, in the optical terminal 102, the optical terminals 100, 1
01 is performed, and the high-frequency signal 162
Of the optical transmitter 132 is kept at -12.5 dBm. However, in the optical terminal 102, the pilot signal 420
Since a total of seven carriers of the carrier signals 110 to 115 are included in the high-frequency signal 162, the input level of the optical transmitter 132 per carrier is -21 dBm, and as a result, the optical modulation degree of the signal light 142 per carrier is obtained. Is 5%.

As described above, in this embodiment, the degree of optical modulation per carrier differs for each optical terminal in accordance with the number of carriers applied to the optical transmitter. This makes it possible to reduce noise in the entire system while keeping the intermodulation distortion generated during signal light modulation low. That is, the optical terminal 1
Even if the noise intensities generated at 00, 101 and 102 are the same, the degree of optical modulation per carrier wave is
101, 100, the relative level of noise received by the center terminal 300 is equal to the optical terminals 102, 101,
It becomes smaller in the order of 100. Therefore, the sum of noise can be reduced as compared with the case where the optical modulation degree of each optical terminal is constant.

Further, according to the automatic gain control system of the present embodiment, it is not necessary to change the internal settings of the optical terminal, regardless of where the optical terminal is inserted in the optical network. For example,
Even if the optical terminals 101 and 102 are interchanged in FIG. 3, it is necessary to change the settings of the automatic gain control circuits 231 and 232 and the second automatic gain control circuits 281 and 282 and the optical terminal input strength of the carrier signals 112 to 115. Absent.

[0030]

As described above, according to the present invention, it is possible to realize an optical multi-access network using a subcarrier multiplexing method without causing beat noise deterioration and optical multiplexing loss.

[Brief description of the drawings]

FIG. 1 is a diagram showing a basic configuration of an optical transmission system according to the present invention.

FIG. 2 is a diagram for explaining a configuration of a first exemplary embodiment of the present invention.

FIG. 3 is a diagram for explaining a second embodiment of the present invention.

[Description of Signs] 10 Optical fiber transmission line 100, 101, 102 Optical terminal 110, 111, 112, 113, 114, 115 Carrier signal 130, 131, 132, 330 Optical transmitter 140, 141, 142, 340 Signal light 150 , 151, 152, 350 Optical receiver 160, 161, 162, 360 High frequency signal 170, 171, 172 Multiplexer 200, 201, 202 Variable gain amplifier 210, 211, 212, 240, 241, 242, 2
70, 271, 272 Demultiplexer 220, 221, 222 Bandpass filter 230, 231, 232 Automatic gain control circuit 250, 251, 252 Demodulator 260, 261, 262 Second variable gain amplifier 280, 281, 282 Second Automatic gain control circuit 300 Center terminal 370 Tuner 400, 401, 402, 403, 404, 405 Information source 410 Pilot signal generator 420 Pilot signal 430 Data signal

──────────────────────────────────────────────────続 き Continuation of the front page (51) Int.Cl. ⁶ Identification symbol FI H04B 10/18 H04J 14/00 14/02 (56) References JP-A-3-104434 (JP, A) JP-A 64-64 10797 (JP, A) Osamu Hirota, "Introduction to Optical Communications-Basics of Optical Fiber Systems-", First Edition, Keigaku Shuppan Co., Ltd., June 20, 1982, p. 78-81 (58) Field surveyed (Int. Cl. ⁶ , DB name) H04B 10/00-10/28

Claims (3)

(57) [Claims] 1. N (N is a natural number) optical terminals are cascaded in an optical fiber transmission line, and one or a plurality of information sources are connected to each optical terminal. A different carrier signal is input to each of the optical terminals, and at the K-th (K is a natural number equal to or less than N) optical terminal, the signal light transmitted from the (K-1) -th optical terminal is received by the optical receiver, A carrier signal from an information source connected to the optical terminal and a high-frequency signal output from the optical receiver are multiplexed by a multiplexer, and the high-frequency signal output from the multiplexer is applied to an optical transmitter. From the K-th terminal
An optical transmission method, wherein the signal light transmitted to the (+1) th optical terminal is intensity-modulated. 2. The signal light transmitted through the optical fiber transmission line is intensity-modulated by a pilot signal. At each terminal, a pilot signal is extracted from a high-frequency signal obtained by receiving the signal light. intensity detecting the optical transmission method according to claim 1, wherein increasing or decreasing the intensity of the high frequency signal by the signal strength adjusting means such that the pilot signal strength has a predetermined value. 3. A signal light transmitted through the optical fiber transmission line is intensity-modulated by a pilot signal. Each terminal extracts a pilot signal from a high-frequency signal obtained by receiving the signal light and outputs the pilot signal. Detecting the strength, increasing or decreasing the strength of the high-frequency signal by signal strength adjusting means so that the pilot signal strength becomes a predetermined value, furthermore, the high-frequency signal and the carrier signal from the information source are combined by the multiplexer. After the multiplexing, the intensity of the high-frequency signal output from the multiplexer is detected, and the intensity of the high-frequency signal is increased or decreased by the second signal intensity adjusting means so that the high-frequency signal intensity becomes a predetermined value. the optical transmission method according to claim 1, wherein applying the RF signal to the optical transmitter.