Fiber sensing system with self-detection mechanism

The present invention discloses a fiber sensing system with self-detection mechanism which utilizes a central office to control secondary ring architecture formed by fiber sensor, remote node and optical coupler primarily. The secondary ring architecture is connected serially to form a primary ring architecture. The central office has a tunable laser light source that can deliver the light source to the fiber sensor. Since the fiber sensor has reflective ability, all light source signal sent by the tunable laser light source will be detected and measured by the fiber sensor. Thus central office can detect all signals reflected by the fiber sensor and produce a spectrum for analyzing fault point locations. The present invention can greatly enhance survivability and sensing capacity of all fiber sensors, so that when a fault point caused by environmental change within the fiber, it will not effect the overall operation of the sensing mechanism. The application of fiber sensor can also reduce cost and complexity of the overall fiber network topology.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a fiber network system, particularly to a fiber sensing system with self-detection mechanism that is able to detect fiber network system and enhance overall transmission reliability of a network.

2. Description of the Related Art

In recent years, Fiber Bragg Grating (FBG) has become an important element in the field of optical sensing. Among the sensing system that using FBG primarily, the ability of providing diversified division multiplexing is one of most important characteristic for those sensing systems. FBG within the applications of division multiplexing includes wavelength-division multiplexing (WDM), space-division multiplexing (SDM), time-division multiplexing (TDM), code-division multiple access (CDMA), strength wavelength-division multiplexing and frequency-modulated continuous-wave (CW) multiplexing. Based on the existing division multiplexing technology and their ability to combine with each other, long range FBG sensing system can be easily manufactured. Therefore, how to enhance reliability and survivability of the FBG sensing system becomes an important issue recently. In general, network using architecture such as bus (in-line) topology, tree (star) topology and ring topology is unable to provide protection function to the sensing system. For instance, when a fault point appears on a fiber line with bus topology, the fiber sensor is no longer able to provide any sensing for any part of the fiber line after the fault point. In order to maintain the survivability of the FBG sensing system and operation of sensing mechanism to avoid the situation caused by environmental issue such as the fault point, it is essential to create a self-restored mechanism within the actual fiber sensing application.

In the paper “J. Lightwave Technol (2001), p 32” proposed by W. P. Lin, it mentioned a sensing architecture that combined the tree topology and the ring topology. Then in 2003, P. C. Peng added a self-restored mechanism to the sensing architecture mentioned above and the experiment result was proposed in the paper “IEEE Photon. Technol. Lett. vol. 15 (2003), p. 1270.” However, such self-restored mechanism for the sensing network requires an additional active component on every remote node (RN) of the network, making the topology of the whole fiber network more complex and also increases the manufacture cost of the network. If there is a simpler FBG multi-ring fiber sensing system that has an ability of self protection (restoration), it would be able to solve many problems when multi-ring architecture network encounters disconnection. Such self-restoration mechanism can be executed quickly and provide users with wider and higher range of reliability, thus decrease production and maintenance cost of the network.

To overcome the abovementioned problem, the present invention proposes a novel fiber sensing system with self-detection mechanism that is able to overcome the obstacles encountered by the prior arts.

SUMMARY OF THE INVENTION

The primary objective of the present invention is to provide a fiber sensing system with self-detection mechanism which uses tunable laser as source of light in order to provide better reliability for wide-range sensing system. When there is an error occurred within the network connection architecture, the self-detection mechanism will execute sensing and restoration mechanism immediately.

Another objective of the present invention is to provide a fiber sensing system with self-detection mechanism that can greatly enhance survivability and sensing capacity of all fiber sensors, so that when a fault point caused by environmental change within the fiber, it will not effect the overall operation of the sensing mechanism. The application of fiber sensor can also reduce cost and complexity of the overall fiber network topology.

In order to realize objectives mentioned above, the fiber sensing system with self-detection mechanism of the present invention comprises a primary ring architecture and a central office. The primary ring architecture is formed by multiple secondary ring architectures which are connected to each other serially to form a primary loop. The secondary ring architecture includes at least two fiber sensors which can receive and reflect light source signal and a remote node. The remote node has an optical coupler which allows the light source signal to pass the fiber sensor to form a secondary loop, additionally the remote node can connect to adjacent secondary ring architectures. The primary function of central office is to provide and monitor the light source signal. The central office also has an optical switch wherein the optical switch has two outputs that connect to the primary ring architecture, forming a first path and a second path respectively. The optical switch can switch the traveling of the light source signal between the first path and the second path. The central office also comprises a tunable laser light source and an optical circulator, where the tunable laser light source emits the light source signal to the optical switch through the optical circulator, the optical switch can then switch the path of the light source signal to either first path or second path. The central office further includes an optical spectrum analyzer which is connected to the optical circulator. The fiber sensor mentioned above is Fiber Bragg Grating (FBG). The tunable laser light source is first dispersed into multi-light source and delivered to each remote node, then to the fiber sensor through the optical coupler on the remote node. Since the fiber sensor has reflective ability, all light source signal sent by the tunable laser light source will be detected and measured by the fiber sensor. If there is no fault point on the primary ring architecture and the secondary ring architecture, central office can detect all signals reflected by the fiber sensor. The fiber sensing system with self-detection mechanism of the present invention utilizes central office to control the secondary ring architecture formed by the fiber sensor, the remote node and the optical coupler primarily, the secondary ring architecture is connected serially to form a primary ring architecture. The central office has a tunable laser light source, the tunable laser light source is first dispersed into multi-light source and delivered to each remote node, then to the fiber sensor through the optical coupler on the remote node. Since the fiber sensor has reflective ability, all light source signal sent by the tunable laser light source will be detected and measured by the fiber sensor. If there is no fault point on the primary ring architecture and the secondary ring architecture, central office can detect all signals reflected by the fiber sensor and produce a spectrum. Not only does the present invention provides wider-range and multi-point detection, it also greatly reduce the manufacture cost of the optical network.

Below, the embodiments are described in detail in cooperation with the attached drawings to make easily understood the objectives, technical contents, characteristics and accomplishments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1is a diagram schematically showing the system architecture of the present invention, as the figure shows, the present invention is a fiber sensing system with self-detection mechanism, primarily comprises a primary ring architecture10and a central office30. The primary ring architecture10is formed by multiple secondary ring architectures20which are connected to each other serially to form a primary loop. The secondary ring architecture20includes at least two fiber sensors22(the following will use S11, S12, S21, S22, S31. . . etc to denote each fiber sensor) which can receive and reflect light source signal and a remote node24. The remote node has an optical coupler26which allows the light source signal to pass the fiber sensor22to form a secondary loop, additionally the remote node24can connect to adjacent secondary ring architectures. Suppose the primary ring architecture10has m secondary ring architecture20and each secondary ring architecture20has n fiber sensor22. If every remote node24uses a 2×2 optical coupler26which makes the fiber sensor22to form a loop and connects to adjacent secondary ring architecture such as20′ and20″ through remote node24, the system will have m×n sensors. The primary function of central office30is to provide and monitor the light source signal. The central office30also has an optical switch32wherein the optical switch32has two outputs that connect to the primary ring architecture10, forming a first path34and a second path36respectively. The optical switch32can switch the traveling of the light source signal between the first path34and the second path36. The central office30also comprises a tunable laser light source38and an optical circulator40, where the tunable laser light source38emits the light source signal to the optical switch32through the optical circulator40, the optical switch32can then switch the path of the light source signal to either first path34or second path36. The central office30further includes an optical spectrum analyzer42which is connected to the optical circulator40. The fiber sensor22of the present invention mentioned above is Fiber Bragg Grating (FBG) and the tunable laser light source38of the present invention can be a tunable erbium-fiber laser or any kind of laser light source.

FIG. 2(a) is a diagram schematically showing system test of the present invention. In one of the embodiments, a simple experiment was set up to analyze the fiber sensing system with self-detection mechanism. Suppose m and n is 4 and 2 respectively, which means there are total of eight fiber sensor22installed in this architecture, in addition, each fiber sensor22is being used as a reflective component. All light signal with different wavelength emitted by the tunable laser light source38within the central office30will all be detected by the fiber sensor22. The Bragg wavelengths for those eight FBGs are 1526.63, 1528.87, 1532.64, 1536.57, 1538.24, 1541.88, 1545.83 and 1555.85 nm respectively. In addition, when there an external stress and temperature interferes with the Bragg wavelength of the fiber sensor22, the sensing system of the present invention can still measure the wavelength accurately. Under normal circumstances, optical switch32is connected to the first path34, so that all lasing wavelength from central office30will detect all fiber sensor22through the first path34. The arrow sign in the figure represents sensing path of the whole sensing system from the first path34when there is no fault point; If the fiber sensor22is being assigned relative numbers from fiber sensor S11to fiber sensor S42, the signal spectrum from tunable laser light source38which is being reflected from fiber sensor S11to fiber sensor S42can produce spectrum diagram likeFIG. 2(b).FIG. 2(b) is a diagram schematically showing spectrum result of the system test of the present invention which has no fault point, as the figure shows, when there is no fiber fault point in the system, the central office30can completely detect all reflected signals generated by the eight fiber sensors.

In the sensing system of the preferred embodiment, there are primary three places which fault point may occur within the fiber network, those places are connection fiber of primary ring architecture10, connection fiber of secondary ring architecture20or fiber sensor22itself, the following paragraph will analyze and discuss these three types of fault point and how the present invention can provide relative self protection mechanism when they occurs.

FIG. 3(a) is a diagram schematically showing system test of the present invention that has a fault point on the primary ring architecture, as the figure shows, a fault point44occurs between fiber sensor S22and fiber sensor S31on the primary ring architecture10. The original sensing signal sent out from first path34(denoted by solid arrow sign in the figure) will only sense fiber sensor S11, fiber sensor S12, fiber sensor S21and fiber sensor S22. In order to detect the rest fiber sensor22signals, optical switch32will automatically switch the sensing path to second path36(denoted by hollow arrow sign in the figure). The system will then use the second path36to proceed sensing to the fault point44and sense out the rest of signals. The location of fault point44can be more clearly seen from the spectrum asFIG. 3(b) shows.FIG. 3(b) is a diagram schematically showing spectrum result of the system test of the present invention which has fault point, wherein solid lines represent signals detected by the first path34and dotted lines represents signals detected by the second path36. Referred3(b) to3(a) at same time, since first path34(denoted by solid arrow sign in the figure) can not detect any signal beyond fiber sensor S22and second path36(denoted by hollow arrow sign in the figure) can not detect any signal before fiber sensor S31, from the information given above, the system can determine that the location of the fault point is between fiber sensor S22and fiber sensor S31. As a result, the fiber sensing system with self-detection mechanism mentioned above not only is able to protect the primary ring architecture10from problems caused by the broken fiber, it can also detect approximate fault point location.

BothFIGS. 4(a) and4(b) are diagrams schematically showing system test of the present invention that has a fault point on the secondary ring architecture. When sensing uses first path34(denoted by solid arrow sign in the figure) to proceed transmission, asFIG. 4(a) shows, if a fault point44occurs between fiber sensor S21and fiber sensor S22on the secondary ring architecture20′, the first path34will unable to detect signal of fiber sensor S21, which make central office30to switch to second path36(denoted by hollow arrow sign in the figure). AsFIG. 4(b) shows, central office30receives all reflected signals and produces sensing spectrum, in addition, central office30has already opened second path36. BothFIGS. 4(c) and4(d) both are diagrams schematically showing spectrum result of the system test of the present invention which has fault point. Compare the spectrum diagram produced from first path34onFIG. 4(c) with the spectrum diagram produced from second path36onFIG. 4(d), because first path34is unable to detect signal of fiber sensor S21and second path36can not detect signal of fiber sensor S22, the system is thus able to determine that the location of the fault point44is between fiber sensor S21and fiber sensor S22.

BothFIGS. 5(a) and5(b) are diagram schematically showing system test of the present invention that has a fault point on the fiber sensor. If stress or temperature around fiber sensor22changes due to environmental change or human error, it may shift the Bragg wavelength of the sensor. When those changes exceed the maximum limit which the fiber sensor22can tolerate; it will cause fiber sensor22to break. The sensing system of the present invention can also detect fault point in the situation like this. AsFIG. 5(a) shows, when sensing uses first path34(denoted by solid arrow sign in the figure) to proceed transmission, if fiber sensor S22itself is broken, it will produce a sensing spectrum likeFIG. 5(c). BothFIGS. 5(c) and5(d) are diagram schematically showing spectrum result of the system test of the present invention which has fault point. InFIG. 5(c), since fiber sensor S22within the first path34is broken, signals from fiber sensor S22and fiber sensor S21will be unable to be detected. Back toFIG. 5(a), in order to regain the two missing signals, central office30will automatically switch to second path36(denoted by hollow arrow sign in the figure) asFIG. 5(b) shows. Compare two paths fromFIGS. 5(c) and5(d) now, it can be seen that signal of fiber sensor S22is missing from the spectrum diagram of the second path, thus the system is able to determine that the fault point occurs on the fiber sensor S22itself. In addition, if fiber sensor S22and fiber sensor S32is broken at same time when using first path34to proceed transmission, the sensing spectrum will miss sensor signals of fiber sensor S21, fiber sensor S22, fiber sensor S31and fiber sensor S32. When the system switch to second path36to proceed sensing, it will still see that signal from fiber sensor S22and fiber sensor S32is still missing. Thus the sensing system of the present invention can also detect two or more broken sensors.

The fiber sensing system with self-detection mechanism of the present invention utilizes central office to control the secondary ring architecture formed by the fiber sensor, the remote node and the optical coupler primarily. The secondary ring architecture is connected serially to form a primary ring architecture. The central office has a tunable laser light source, the tunable laser light source is first dispersed into multi-light source and delivered to each remote node, then to the fiber sensor through the optical coupler on the remote node. Since the fiber sensor has reflective ability, all light source signal sent by the tunable laser light source will be detected and measured by the fiber sensor. If there is no fault point on the primary ring architecture and the secondary ring architecture, central office can detect all signals reflected by the fiber sensor and produce a spectrum for analyzing fault point locations. Not only does the present invention provides wider-range and multi-point detection, it also greatly reduce the manufacture cost of the optical network.

The embodiments described above are only to exemplify the present invention but not to limit the scope of the present invention. Therefore, any equivalent modification or variation according to the shapes, structures, characteristics and spirits discloses in the present invention is to be also included within the scope of the present invention.