KR20030050904A - Monitoring System of Environment by Detecting the Birefringence Changes of the Optical Fiber - Google Patents

Abstract

PURPOSE: An environment monitoring system is provided to detect a sudden environmental variation with a simple structure by using a variation of birefringence of optical fiber. CONSTITUTION: An environment monitoring system includes a beam transmitting section(80), an optical fiber section(20) and a beam receiving/signal processing section(81). The beam transmitting section(80) has a beam splitter(11) connected to a light source(10) and a polarizing light adjuster(12). The optical fiber section(20) transfers a signal of the beam transmitting section(80). The beam receiving/signal processing section(81) has a beam detector(40) connected to a polarizing device(30) in order to receive the signal transmitted from the beam transmitting section(80) and a signal processing section(50).

Description

Monitoring System of Environment by Detecting the Birefringence Changes of the Optical Fiber}

The present invention relates to an environmental monitoring system for detecting a sudden environmental change or an abnormal state in a section to be monitored, and more particularly, by detecting a change in the birefringence of the optical fiber and the polarization change of the light traveling in the optical fiber. The present invention relates to an environmental monitoring system that detects abnormal conditions of sudden environmental changes such as very rapid temperature changes due to severe winds or fires in a certain section.

US Patent No. 5,499,313 of the conventional environmental monitoring device that performs such a role is a technology that detects only the ambient temperature and informs it, another US Patent No. 5,636,021 is Sagnac composed of an optical fiber 508 as shown in FIG. Schematic of the strain sensor using a Michelson interferometer, where reference numeral 102 is a light source, reference numerals 136,502,504 are photodetectors, reference numerals 352,358,118 are reflectors, reference numeral 144 is four optical coupling separators, and reference numeral 520 is An electronic control unit is shown.

Such a conventional U.S. Patent No. 5,636,021 constitutes an interferometer with an optical fiber, and a part of the light interferes with the reference beam and the light reflecting the influence of the environmental change. Since the size of the conventional technology is very precisely measuring the distribution of temperature or strain, there is a problem that the structure is complicated and the cost is quite expensive.

Accordingly, the present invention has been invented to solve the conventional problems as described above, it is possible to detect and monitor when a sudden environmental change, such as a temperature change caused by a strong wind or fire in the section to be monitored It is an object of the present invention to provide an environmental monitoring system using a birefringent change of an optical fiber, which is relatively simple, and has a simple structure and simple economical effect.

1 (a), (b), (c) are graphs showing the output states of the photodetector according to the wind strength for explaining the present invention,

Figure 2 is a block diagram of the principle configuration of the environmental monitoring system using the birefringence change of the optical fiber according to the present invention,

3 is a configuration diagram showing an example of an environmental monitoring system using a birefringence change of the optical fiber according to the present invention,

Figure 4 is a block diagram showing an environmental monitoring system using a conventional optical fiber.

-Explanation of symbols for the main parts of the drawings-

10-light source 11-light separator

12-Polarization Controller 20-Fiber Optic

30-polarizer 40-photodetector

50-Signal Processing Unit 80-Optical Transmitter

81-light receiving / signal processing unit

The present invention for achieving the above object is an optical transmitter having an optical splitter and a polarization controller connected to a light source, an optical fiber for transmitting a signal of the optical transmitter, and connected to a polarizer to receive a signal of the optical transmitter It consists of a light receiving / signal processing unit having a photodetector and a signal processing unit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram showing an example of an environmental monitoring system using the birefringence change of the optical fiber according to the present invention.

First, the background of the present invention will be described with reference to FIGS. 1 and 2 before detailed description of the present invention.

The principle of the system according to the invention is that the linearly polarized light from the light source 10 travels along the optical fiber 20 and changes from the photodetector 40 to an electrical signal via the polarizer 30 as shown in FIG. 2. In this case, when the outside temperature of the optical fiber 20 is changed or shakes due to external wind or external force such as wind in the optical fiber 20, the intensity of light passing therethrough is changed, and thus the photodetector 40 is changed. The magnitude of the electrical signal generated at is changed.

This signal change is interpreted by the signal processing unit 50 so that the environmental state in the section where the optical fiber 20 is located can be monitored.

In other words, this is because a sudden change in various parameters such as temperature or vibration changes the birefringence inside the optical fiber, which in turn changes the polarization of the light passing through the inside of the optical fiber. Since there is no purpose to measure, the present invention can be achieved by using only the simple polarizing element 30 and the photodetector 40 for receiving light.

On the other hand, in order to confirm the applicability of the principle described above, using the optical fiber 20 of 2m length in the laboratory except for the signal processing unit 50, the configuration of the photodetector 40 was observed using an oscilloscope.

FIG. 1A is an output graph of the photodetector 40 when the optical fiber 20 is left for a long time without applying any external stimulus.

Figure 1 (b) is a graph of the output of this photodetector 40 after giving a certain intensity of wind to the optical fiber 20 by using a fan, Figure 1 (c) is a photo detector when the wind of the fan is very strong ( This is an output graph of 40).

As can be seen from these graphs, it can be seen that the high frequency component is gradually seen in the output waveform of the photodetector 40 when there is wind compared to when there is no wind.

This high frequency component shows the change in the internal birefringence as the optical fiber used in the experiment is shaken by the wind. If the length of the optical fiber is several hundred meters long, like the composite processing line installed between the transmission tower and the pylon, the polarization of the light is further increased. The output of the photodetector will vary even more than shown in the experimental graph as it will vary greatly.

On the other hand, the signal processing of the photodetector 40 can be used in a variety of ways depending on the situation, for example, when looking at the waveforms of Figures 1 (a) to (c) there is a distinctly different high-frequency waveform when the wind is simple The frequency analysis circuit can be used to detect changes in the environment. In addition, the output characteristics of the photodetectors will vary depending on the length of the optical fiber and the environmental variables to be monitored. Reveal in advance.

Next, an example of the present invention will be described in detail with reference to FIG. 3.

The present invention provides an optical transmitter (80) having an optical separator (11) and a polarization controller (12) connected to a light source (10), an optical fiber (20) for transmitting a signal of the optical transmitter (80), and the optical transmitter In order to receive the signal of 80, the light detector 40 is connected to the polarizing element 30 and the light receiving / signal processing unit 81 having a signal processing unit 50.

In the drawings, reference numerals 90 and 91 denote transmission towers.

That is, the present embodiment is an environmental monitoring system using the optical fiber 20 in the composite processing branch line installed between the transmission tower 90, 91, the light from the optical transmitter 80 for transmitting the light is the optical fiber 20 Is transmitted to the optical reception / signal processing unit 81 which receives and interprets the signal.

In the structure of the optical transmitter 80, the light source 10 serves to output the linearly flattened light as an output. In general, the light source 10 may be configured as a laser diode. none.

It is also possible to use a wavelength filter and a polarizer in combination with a light source that outputs unpolarized light having a broad spectrum, such as an LED.

Next, if a laser is used as the light source 10, an optical separator 11 is installed to prevent the light from being reflected back to the light source in the optical connector on the light propagation path.

This is because when the light exiting from the laser enters the laser again, the operation of the laser is often unstable, and thus has the above structure.

Next, to increase the response characteristics of the system is installed a polarization controller 12 that can adjust the polarization of the output light.

On the other hand, the light from the optical transmitter 80 is transmitted to the optical fiber 20 in the composite processing line along the optical fiber 20.

Therefore, when a sudden environmental change occurs between the transmission towers 90 and 91 where the optical fiber 20 is hypothesized, the polarization of the light traveling through this section is also greatly changed, and the light reaching the transmission tower 91 is the optical fiber 20. Then, the optical receiver / signal processor 81 detects light and interprets a signal.

The light receiving / signal processing unit 81 causes the light undergoing the polarization change to enter the polarizing element 30, and the polarizing element 30 filters only light of a certain polarization component and sends it to the photodetector 40. do.

Therefore, when the light undergoes many polarization changes, the power of the light going to the photodetector 40 is greatly changed. Since the light detector 40 is a device that converts the power of the light into an electrical signal, the output voltage of the photodetector is changed. This is detected by the signal processing unit 50 and finds that there is a sudden environmental change in the section.

Although not shown in the drawing, the light source 10, the photodetector 40, and the power supply for supplying power to the signal processing unit 50 are separately provided, and the signal processing unit 50 is provided with communication means, and is currently provided with a transmission tower. It is intended to inform remote monitors of environmental conditions in sections (90,91).

As described above, all of the conventional monitoring techniques using optical fibers as sensors can measure the distribution of temperature or strain very precisely, but require a very complicated system configuration to achieve this.

On the contrary, the monitoring system proposed in the present invention has an advantage of detecting a sudden change of the environment, such as a very rapid temperature change due to severe wind or fire, in a very simple configuration.

Therefore, not only the monitoring system can be configured at a low cost, but it can be easily installed even in a difficult place such as a mountainous area where monitoring is required, and the difficulty in maintenance / repair is greatly reduced.

On the other hand, the present invention is not limited only to the above embodiments, many modifications are possible by those skilled in the art within the technical idea of the present invention.

Claims (6)

An optical transmitter 80 having an optical separator 11 and a polarization controller 12 connected to the light source 10, an optical fiber 20 for transmitting a signal of the optical transmitter 80, and the optical transmitter 80 Environmental monitoring system using a polarization change of the optical fiber consisting of a light receiving / signal processing unit 81 having a photo detector 40 and a signal processing unit 50 connected to the polarizing element 30 to receive a signal of. The polarization change of the optical fiber according to claim 1, wherein the light source for outputting linearly polarized light is generated by a light source for outputting light that is not linearly polarized, such as an LED, and means for converting the light into linearly polarized light. Environmental monitoring system using. 2. The environmental monitoring system according to claim 1, further comprising an optical separator after the light source to prevent back light from being scattered in the light source and re-entering the light source. The environmental monitoring system using a polarization change of an optical fiber according to claim 1, further comprising a polarization controller for controlling a polarization state of light incident on the optical link after the light source. The environmental monitoring system according to claim 1, wherein the signal processing unit determines whether or not there is an environmental abnormality by performing frequency analysis on the output waveform of the photodetector. The environmental monitoring system according to claim 1, wherein the signal processing means further comprises a communication means for informing a remote monitor to inform the environment of the current optical fiber link in real time.