KR100225450B1 - Wavelength demultiplexing apparatus - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a narrowband transmission filter and a wavelength division demultiplexer using the filter.

2. The technical problem to be solved by the invention

The present invention provides a narrow band transmission filter for converting an operating wavelength using a wavelength variable that can connect Bragg diffraction gratings having slightly different center wavelengths in series and convert the center wavelength of each Bragg diffraction grating, and the wavelength division using the same. To provide a multiplexer.

3. Summary of Solution to Invention

According to the present invention, when two Bragg diffraction gratings having a slightly different center wavelength reflected by a slightly different lattice period and an effective refractive index are connected in series, the BFA diffraction grating reflects a shorter wavelength and a longer wavelength of the Bragg diffraction grating which reflects a shorter wavelength. A transmission band is formed at the portion where the transmission bands of the Bragg diffraction gratings overlap each other, and the difference between the center wavelengths of the two Bragg diffraction gratings is adjusted to a value slightly larger than the sum of half of the bandwidths of each Bragg diffraction grating. Therefore, the bandwidth of the transmission band can be narrowed, and the operating wavelength can be converted by varying the center wavelength reflected using a wavelength variable that can convert the grid period and effective refractive index of each Bragg diffraction grating. Narrowband transmission filters can be connected in series or in parallel for use on the receiver side of a WDM system. The signal of the desired wavelength can be separated.

4. Important uses of the invention

The present invention is used on the receiving side of a wavelength division multiplex (WDM) system.

Description

Narrow-band transmission filter using serially connected Bragg diffraction grating and wavelength division demultiplexer using the filter

The present invention provides a narrowband transmission filter used in a wavelength division multiplexing (WDM) method in which different information is loaded on different wavelengths of light, multiplexed, transmitted through the same optical fiber, and a signal of a desired wavelength is separated at a receiving end. The present invention relates to a wavelength division demultiplexer using the wavelength division demultiplexer. In particular, a wavelength modulator capable of connecting a Bragg diffraction grating having a slightly different center wavelength in series to form a narrow band transmission band and converting the center wavelength of each Bragg diffraction grating is used. The present invention relates to a narrowband transmission filter for converting an operating wavelength and a wavelength division demultiplexer for separating signals of a desired wavelength by connecting narrowband transmission filters in series or in parallel for use on a receiving side of a wavelength division multiplexing system.

Optical communication has a wider bandwidth and a higher transmission speed than conventional communication methods, and thus can transmit a large amount of data. The development of a light source having a narrow line width makes it possible to efficiently use a wide frequency band, but the transmission amount is still insufficient to transmit a large amount of information such as voice or moving images in real time. As a solution to this, wavelength division multiplexing (WDM) is used, in which different information is loaded on different wavelengths of light, multiplexed and transmitted through one strand of optical fiber, and then a signal of a desired wavelength is separated and used at a receiving end.

In other words, the WDM method is a method for effectively transmitting a large amount of information such as a voice or a moving picture. The WDM method is a method in which different information is loaded on different wavelengths and multiplexed through a single optical fiber. It refers to a communication method that obtains desired information by selecting a signal of a desired wavelength at a receiving side. In order to realize the wavelength division multiplexing (WDM) method, an optical filter element capable of separating a signal having a desired wavelength from signals of various wavelengths received by a receiver is essential.

Such a conventional optical filter element may be a device using a Bragg diffraction grating, which is largely classified into an optical fiber form and a slab waveguide form. The Bragg diffraction grating in the form of an optical fiber is made by periodically converting the refractive index of a portion of the optical fiber core. Germanium (Ge) or the like added optical fiber (photosensitivity) has a characteristic of, and when exposed to the UV (Ultra Violet) beam, the refractive index of the exposed portion increases. When the interference pattern having a certain period is formed by the UV beam, and the optical fiber is exposed to it, the refractive index changes in the shape of the interference pattern in the portion exposed by photosensitivity, thereby forming a grating. On the other hand, the Bragg diffraction grating in the form of a planar waveguide forms a lattice by etching the waveguide at regular intervals and causing a change in its effective refractive index, or forming a lattice by exposing the waveguide to a UV beam and converting the refractive index as described above. do. When light is incident on the Bragg diffraction grating thus made, the light in some bands is reflected and the remaining light passes through it, centering on a specific wavelength satisfying a certain condition. In this case, the reflected center wavelength is proportional to the lattice period and the effective refractive index of the grating generated by the change of the refractive index, and is expressed as Equation 1 below.

[Equation 1]

: 반사되는 중심파장here,

: Reflected center wavelength

n _eff : effective refractive index of the lattice

: 격자주기

: Grid cycle

m: integer

In the conventional optical filter element using the Bragg diffraction grating having such a property, light having a plurality of wavelengths is incident on the Bragg diffraction grating to reflect light of a specific wavelength, and then the reflected light of the specific wavelength is circulated again. By receiving (extracting) by using a circulator or a coupler, a signal having a desired wavelength could be obtained.

However, a conventional optical filter element using one Bragg diffraction grating having a characteristic of reflecting some wavelength regions and passing light of other wavelengths centered on a specific wavelength satisfying a predetermined condition according to the lattice period among incident lights , Additional cost is required because a separate element such as a circulator or coupler is required, and a loss occurs when inserting a separate element such as a circulator or a coupler. Since the center wavelength reflected by the Bragg diffraction grating is fixed constantly, there is a problem that the operating wavelength cannot be changed.

On the other hand, when the demultiplexer of the wavelength division multiplexing (WDM) system is implemented using such a conventional optical filter element, the system is lost due to the loss generated when inserting a separate element such as a circulator or a coupler. When the performance of the device decreases and the center wavelength reflected by the Bragg diffraction grating is fixed, there is a problem that the component itself needs to be replaced when the operating wavelength is changed.

An object of the present invention devised to solve the above problems is that the Bragg diffraction grating reflects short wavelengths by connecting two Bragg diffraction gratings having a slightly different center wavelength reflected in series with a slightly different lattice period and effective refractive index. The transmission band is formed at the overlapping part of the long-wavelength transmission band and the short-wavelength transmission band of the Bragg diffraction grating reflecting the long wavelength.The difference between the center wavelengths of the two Bragg diffraction gratings is half the bandwidth of each Bragg diffraction grating. By appropriately adjusting the value slightly larger than the sum of, the bandwidth of the transmission band can be narrowed and the center wavelength reflected by using the wavelength variable which can convert the lattice period and effective refractive index of each Bragg diffraction grating The present invention provides a narrowband transmission filter capable of converting an operating wavelength by varying the wavelength.

Another object of the present invention is to provide a wavelength division demultiplexer for separating signals of a desired wavelength by connecting narrowband transmission filters in series or in parallel for use on the receiving side of the wavelength division multiplexing system.

1 is a representative structural diagram of Bragg diffraction grating used in the present invention,

2 is a configuration diagram of a first embodiment of a narrowband transmission filter according to the present invention;

3 is a configuration diagram of a second embodiment of a narrowband transmission filter according to the present invention;

4 is a configuration diagram of a third embodiment of a narrowband transmission filter according to the present invention;

5 is a configuration diagram of a fourth embodiment of a narrowband transmission filter according to the present invention;

6 is an output characteristic waveform diagram of a fourth embodiment of a narrowband transmission filter according to the present invention;

7 is a configuration diagram of an embodiment of a wavelength division demultiplexer according to the present invention;

8 is a block diagram of another embodiment of a wavelength division demultiplexer according to the present invention;

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

12: optical splitter

14-1,14-2,... , 14-m: narrow band pass filter

16: light splitter

20: receiver

22: optical waveguide

32-1,32-1 ', 32-2,... , 32-k: Bragg diffraction grating

46: wavelength variable

52-1,52-2,... , 52- (m-1): signal reflected from (m-1) narrowband transmission filters

52-1 ', 52-2',... , 52- (m-1 '): 52-1,52-2,... , 52- (m-1) signal transmitted through optical splitter

82: signal of multiple wavelengths

82-1,, 82-2,... , 82-m: signal passing through each narrowband transmission filter

92,93,94,95: Signal transmitted through narrowband transmission filter

An apparatus of the present invention for achieving the above object, the first optical transmission path for transmitting a multi-wavelength signal from the outside; A first Bragg diffraction grating for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength; Connected in series with the first Bragg diffraction grating and receiving an optical signal transmitted through the first Bragg diffraction grating, the center wavelength at which the first Bragg diffraction grating reflects is centered on a specific wavelength spaced at a predetermined interval. A second Bragg diffraction grating for reflecting the optical signal of the second predetermined band; And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the second Bragg diffraction grating to the outside.

Another apparatus of the present invention for achieving the above object, the first optical transmission path for transmitting a multi-wavelength signal from the outside; Wavelength varying means for converting the center wavelength of the reflected optical signal; A region for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength, and being spaced apart from the specific wavelength by a wavelength varying means at a predetermined interval; One Bragg diffraction grating including an area for reflecting an optical signal of a second predetermined band around the wavelength; And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the Bragg diffraction grating to the outside.

An apparatus of the present invention for achieving the above another object, the first optical transmission path for transmitting a multi-wavelength signal from the outside; Optical distribution means for receiving a multi-wavelength signal through the first optical transmission path and distributing it into at least one optical signal; At least one second optical transmission path for receiving and transmitting one optical signal among at least one optical signal distributed by the optical distribution means; At least one filtering means for receiving and filtering an optical signal of at least one optical signal transmitted through the at least one second optical transmission path to transmit an optical signal corresponding to its transmission band; At least one third optical transmission path for receiving and transmitting one optical signal among at least one optical signal output from the at least one filtering means; And at least one receiving means for receiving one of the at least one optical signal transmitted through the at least one third transmission path.

Another apparatus of the present invention for achieving the above another object, the first optical transmission path for transmitting a multi-wavelength signal from the outside; First optical transmission means for receiving and transmitting a multi-wavelength signal from the first optical transmission path and receiving the reflected optical signal and transmitting the received optical signal to a next stage; A second optical transmission path for receiving and transmitting a multi-wavelength signal from the first optical transmission means and transferring the reflected optical signal to the first optical transmission means; First filtering means for receiving a signal having multiple wavelengths transmitted through the second optical transmission path, reflecting a predetermined band, transmitting the reflected signal to the second optical transmission path, and transmitting an optical signal corresponding to its transmission band; A third optical transmission path for receiving and transmitting the optical signal output from the first filtering means; First receiving means for receiving an optical signal transmitted through the third optical transmission path; an n1th optical transmission path for transferring the reflected optical signal from the (n-1) th optical transmission means of the (n-1) th stage (n is a natural number); Nth light transmitting means for receiving and transmitting the reflected optical signal from the nth optical transmission path and receiving the reflected optical signal to the (n + 1) th stage; An n2th optical transmission path for receiving and transmitting an optical signal from the nth optical transmission means and transmitting a reflected optical signal to the nth optical transmission means; N-th filtering means for receiving an optical signal transmitted through the n-th optical path and reflecting a predetermined band to be transmitted to the n-th optical path and transmitting an optical signal corresponding to its transmission band; An n3th optical transmission path for receiving and transmitting the optical signal output from the nth filtering means; N-th receiving means for receiving an optical signal transmitted through said n-th optical path; a k1th optical transmission path for transmitting the reflected optical signal from the (k-1) th optical transmission means of the (k-1) th stage (k is a natural number greater than n); K-th filtering means for receiving the reflected optical signal transmitted through the k-th optical transmission path and transmitting the optical signal corresponding to its transmission band; A k2th optical transmission path for receiving and transmitting the optical signal output from the kth filtering means; And kth receiving means for receiving the optical signal transmitted through the k2th optical transmission path.

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

1 is a representative structural diagram of Bragg diffraction grating used in the present invention, the refractive index of the waveguide is formed in a form that periodically changes to different values of n ₁ , n ₂ with respect to the direction of light travel. As such, the Bragg diffraction grating is formed by periodically converting a refractive index of a portion of the waveguide. When light is incident thereon, a specific wavelength of the incident light is reflected and the remaining light is transmitted. At this time, the reflected central wavelength is determined by the lattice period and effective refractive index of the Bragg diffraction grating.

2 is a configuration diagram of a first embodiment of a narrowband transmission filter according to the present invention, in which 22 is an optical waveguide, 32-1 and 32-2 are Bragg diffraction gratings, 82 is a multi-wavelength signal, and 92 is narrow Signals passing through the band pass filter are shown respectively.

First, the configuration of a first embodiment of a narrowband transmission filter according to the present invention will be described.

The narrow band pass filter includes an optical waveguide 22 which transmits a multi-wavelength signal 82 having a plurality of wavelengths, and a first Bragg diffraction grating 32-1 which reflects light of a predetermined band around a specific wavelength. ), The second Bragg diffraction grating (32-2) reflecting a certain band of light around a specific wavelength slightly different from the center wavelength reflected by the first Bragg diffraction grating, and transmitted through the two Bragg diffraction gratings And an optical waveguide 22 for guiding the signal 92 having a predetermined wavelength.

Next, operation of the first embodiment of the narrowband transmission filter according to the present invention will be described.

The multi-wavelength signal 82 of various wavelengths is transmitted to the first Bragg diffraction grating 32-1 through the optical waveguide 22. The first Bragg diffraction grating 32-1 reflects a certain band of light around a specific wavelength and transmits the rest. In this case, the reflected center wavelength is determined as a value proportional to the lattice period and the effective refractive index of the Bragg diffraction grating. That is, the shorter the lattice period and the smaller the effective refractive index of the Bragg diffraction grating, the shorter the central wavelength reflected, and the longer the lattice period and the larger the effective refractive index, the longer the reflected central wavelength. If the reflected center wavelength is connected in series with the first Bragg diffraction grating 32-2, which is slightly different from the first Bragg diffraction grating 32-1, the short wavelength is reflected. A transmission band is formed at a portion where the long-wavelength transmission band of the Bragg diffraction grating and the short-wavelength transmission band of the Bragg diffraction grating reflecting the long wavelength overlap. In this case, the difference in the center wavelength reflected by the two Bragg diffraction gratings 32-1 and 32-2 is appropriately adjusted to a value slightly larger than half of the sum of the reflection bandwidths formed by the respective Bragg diffraction gratings. It can make the band narrow.

When the multi-wavelength signal 82 enters the two Bragg diffraction gratings 32-1 and 32-2, only the signal 92 having a predetermined wavelength transmits through the narrow band transmission band formed by the above-described principle. And signals of the remaining wavelengths are reflected. At this time, in order for the signals of the remaining wavelengths to be reflected, these signals must belong to a reflection band reflected by each Bragg diffraction grating. A signal having multiple wavelengths can transmit more information as the number of wavelengths increases. For this purpose, the reflection band reflected by each Bragg diffraction grating must be wide enough. The reflection band of the Bragg diffraction grating becomes wider as the refractive index difference of the grating portion of the Bragg diffraction grating becomes larger, but the larger the refractive index difference can be obtained as the material having high photosensitivity becomes wider.

On the other hand, when the bandwidth is widened by increasing the difference in refractive index, sidelobes appearing at both ends of the reflection bandwidth increase and become larger. These sidelobes cause ripple in the transmission band formed at the portion where the transmission bands of each Bragg diffraction grating overlap, which adversely affects the performance of the narrow band transmission filter. Therefore, by converting the refractive index difference of the grating portion into the form of a specific function with respect to the length of the Bragg diffraction grating, it is possible to eliminate sidelobes appearing in the Bragg diffraction grating. It is called an apodized Bragg diffraction grating.

However, the slope of the boundary portion of the reflection band is reduced during the sidelobe removal process. When the narrow band transmission filter is configured with the Bragg diffraction grating, the transmission band is widened and the performance of the narrow band transmission filter is improved. Will be degraded. To compensate for this, the length of the Bragg diffraction grating should be increased to increase the slope of the boundary of the reflection band.

The narrowband transmission filter configured in this manner may be used to construct a demultiplexer of a wavelength division multiplexing system to be described later, and may serve to guide a signal having a predetermined wavelength.

3 is a configuration diagram of a second embodiment of a narrowband transmission filter according to the present invention, in which FIG. 22 is an optical waveguide, 32-1, 32-1 'is Bragg diffraction grating, 46 is a wavelength variable, and 82 is a multiple wavelength. 93 denotes a signal transmitted through the narrow band transmission filter.

First, the configuration of a second embodiment of a narrowband transmission filter according to the present invention will be described.

The narrow-band transmission filter includes an optical waveguide 22 for transmitting a multi-wavelength signal 82 having a plurality of wavelengths, a portion 32-1 of the Bragg diffraction grating reflecting a specific wavelength, and a Bragg diffraction grating. A wavelength converter 46 for converting the center wavelength reflected from the remaining portion 32-1 'of the Bragg, and a Bragg reflecting a predetermined band around a specific wavelength different from the portion 32-1 of the Bragg diffraction grating A portion 32-1 'of the diffraction grating and an optical waveguide 22 for guiding the signal 93 having a predetermined wavelength therethrough.

Next, the operation of the second embodiment of the narrowband transmission filter according to the present invention will be described.

The center wavelength reflected by the Bragg diffraction grating has a value approximately proportional to the lattice period and the effective refractive index of the Bragg diffraction grating. When the wavelength variable 46 converts the lattice period and the effective refractive index of the Bragg diffraction grating, The reflected center wavelength is changed to behave like other Bragg diffraction gratings. The wavelength converter 46 is a material in which a strain is generated by an external signal, a material in which the refractive index or the refractive index and the length are changed at the same time by ultrasonic or pressure, a material in which the refractive index or the refractive index and the length are changed by the heat, and the intensity of the light. According to the present invention, the Bragg diffraction grating is formed using a material whose refractive index changes according to the intensity of the electric field, a material whose refractive index changes according to the strength of the electric field, and a material whose refractive index changes according to the strength of the magnetic field. .

If the lattice period and effective refractive index of the Bragg grating element part 32-1 'are converted using the wavelength converter 46, the center wavelength reflected by the part and the center wavelength reflected by the other part are different from each other. Part of it will act as another Bragg grating element. Therefore, by adjusting the wavelength variable that is changed by the wavelength converter 46 to adjust the difference between the two reflected central wavelengths, a narrow band transmission band is formed. Using this method, a single Bragg diffraction grating can form a narrow band transmission band. When a signal 82 having several wavelengths is incident on a narrow band transmission filter composed of one diffraction grating 32-1, 32-1 ′ and a wavelength converter 46 through the optical waveguide 22, the signal having a predetermined wavelength is input. Only 93 is transmitted. In addition, by adjusting the wavelength variable that is changed by the wavelength variable 46, it is possible to make the signal of any wavelength is not transmitted by eliminating the transmission band.

The narrowband transmission filter configured in this manner may be used to construct a demultiplexer of a wavelength division multiplexing system to be described below, and may serve to guide a signal of a predetermined wavelength or not to guide a signal of any wavelength.

4 is a configuration diagram of a third embodiment of a narrowband transmission filter according to the present invention, in which 22 is an optical waveguide, 32-1 and 32-2 are Bragg diffraction gratings, 46 is a wavelength variable transformer, and 82 is a multiple wavelength A signal 94 represents a signal transmitted through the narrow band transmission filter, respectively.

First, the configuration of a third embodiment of a narrowband transmission filter according to the present invention will be described.

The central wavelength variable narrow band transmission filter includes an optical waveguide 22 which transmits a multi-wavelength signal 82 having a plurality of wavelengths, and a first Bragg diffraction grating (32-) reflecting a predetermined band around a specific wavelength. 1), a first wavelength converter 46 for converting the center wavelength reflected from the first Bragg diffraction grating, and a second Bragg for reflecting a predetermined band around a specific wavelength different from the first Bragg diffraction grating A diffraction grating 32-2, a second wavelength variabler 46 for converting the center wavelength reflected by the second Bragg diffraction grating, and a variable constant wavelength signal transmitted through the center wavelength variable narrowband transmission filter ( And an optical waveguide 22 for guiding 94.

Next, the operation of the third embodiment of the narrowband transmission filter according to the present invention will be described.

By connecting two Bragg diffraction gratings 32-1 and 32-2 in series in the same manner as described above in FIG. 2, a narrow band transmission band can be formed. When the lattice periods and effective refractive indices of the Bragg diffraction gratings 32-1 and 32-2 are converted by using the first and second wavelength variable transformers 46, the center wavelengths reflected by the Bragg diffraction gratings are reflected. Will change. In this way, if the wavelength variable is converted while maintaining the transmission band of the narrow band constant, the operating wavelength itself of the narrow band transmission band can be converted. In addition, proper adjustment of the wavelength variability may cause the transmission band of this narrow band to disappear. When the multi-wavelength signal 82 is incident on the central wavelength variable narrowband transmission filter through the optical waveguide 22, only the signal 94 having a certain wavelength variable according to the wavelength variability changed by the wavelength variable converter 46 is used. It is transmitted and guided to the optical waveguide 22. At this time, it is possible to make the signal of any wavelength not transmitted by adjusting the wavelength variable that is changed by the wavelength converter 46.

The narrowband transmission filter configured in this manner may be used to construct a demultiplexer of a wavelength division multiplexing system to be described later. The narrowband transmission filter may serve to guide a signal having a specific wavelength of a specific wavelength or do not guide a signal of any wavelength.

5 is a configuration diagram of a fourth embodiment of a narrowband transmission filter according to the present invention, in which 22 is an optical waveguide, 32-1, 32-2,... 32-k denotes a Bragg diffraction grating, 46 denotes a wavelength variable analyzer, 82 denotes a multi-wavelength signal, and 95 denotes a signal transmitted through a narrowband transmission filter.

First, the configuration of a fourth embodiment of a narrowband transmission filter according to the present invention will be described.

The center wavelength variable multi-wavelength narrow band transmission filter includes an optical waveguide 22 which transmits a multi-wavelength signal 82 having a plurality of wavelengths, and a first Bragg diffraction grating which reflects a predetermined band around a specific wavelength. 32-1), the second Bragg diffraction grating 32-2 reflecting a predetermined band around a specific wavelength different from the first Bragg diffraction grating, and the (k-1) Bragg diffraction in the same manner. K-th Bragg diffraction grating 32-k (k is a natural number) that reflects a predetermined band around a specific wavelength different from the grating, and each Bragg diffraction grating 32-1, 32-2, ..., 32 k waveguides 46 for converting the center wavelengths reflected at the < RTI ID = 0.0 > k) < / RTI > and an optical waveguide for guiding the signals 95 of a plurality of variable wavelengths transmitted through the center wavelength variable multiwavelength narrowband transmission filter thus configured ( 22).

Next, operation of the fourth embodiment of the narrowband transmission filter according to the present invention will be described.

By connecting two Bragg diffraction gratings 32-1 and 32-2 in series in the same manner as described above in FIG. 2, a narrow band transmission band can be formed. Similarly, the third Bragg diffraction grating 32-3, which works with the second Bragg diffraction grating 32-2 to form a narrow band transmission band, is formed by the two Bragg diffraction gratings 32-1 and 32-. When connected in series with 2), it is possible to form a narrow band transmission band having a different operating wavelength than the operating waveform formed by the first and second Bragg diffraction gratings 32-1.32-2. If the k-th Bragg diffraction grating 32-k is connected in series in the same manner, it is possible to form transmission bands of k-1 narrow bands. Each Bragg diffraction grating using a wavelength converter 46 for converting the center wavelength reflected from each Bragg diffraction grating 32-1, 32-2, ..., 32-k in the same manner as described above in FIG. By converting the lattice period and effective refractive index of (32-1,32-2, ..., 32-k), the center wavelength reflected by each Bragg diffraction grating (32-1, 32-2, ..., 32-k) Will change. The narrow band transmission band formed by the first Bragg diffraction grating 32-1 and the second Bragg diffraction grating 32-2 converts the operating wavelength by adjusting the wavelength variability of the two Bragg diffraction gratings. You can do it and make it disappear. In the same way, the transmission band of each narrow band can convert the operating wavelength and make it disappear by adjusting the wavelength variation of the two Bragg diffraction gratings forming the transmission band of this narrow band. When the multiple-wavelength signal 82 is incident on the central wavelength variable multi-wavelength narrow band transmission filter configured as described above through the optical waveguide 22, a plurality of wavelengths varying according to the wavelength variability changed by each wavelength variable 46. Only signal 95 is transmitted and guided to the optical waveguide 22. At this time, the number of wavelengths transmitted can be adjusted by adjusting the wavelength variable that is changed by the wavelength variable 46, and the signal of any wavelength may not be transmitted.

The narrowband transmission filter configured in this way may be used to construct a demultiplexer of a wavelength division multiplexing system to be described later, and may serve to guide a variable multiple wavelength signal or do not guide a signal of any wavelength.

6 is an output characteristic waveform diagram of a fourth embodiment of a narrowband transmission filter according to the present invention.

The center wavelength tunable multiwavelength narrowband transmission filter composed of k wavelength transducers converting the center wavelengths reflected by k Bragg diffraction gratings and the center wavelength reflected by each Bragg diffraction grating has k-1 narrow bands. Form a transmission band. By adjusting the wavelength variable of each Bragg diffraction grating changed by each wavelength variable, the center wavelength reflected by each Bragg diffraction grating changes. That is, by appropriately adjusting the wavelength variability, the center wavelength of the transmission band of each narrow band may be varied or the transmission band may disappear.

In this case, the first narrow band transmission band is varied according to the wavelength variability changed by the wavelength variable acting on the first Bragg diffraction grating and the second Bragg diffraction grating. The second narrow band transmission band is varied according to the wavelength variability changed by the wavelength variable acting on the second Bragg diffraction grating and the third Bragg diffraction grating. Similarly, the k-1 th narrow band transmission band is varied according to the wavelength variability changed by the wavelength variable acting on the k-1 th Bragg diffraction grating and the k th Bragg diffraction grating. In this way, the number of wavelengths transmitted can be adjusted by adjusting the wavelength variable that is changed by the wavelength variable, the operating wavelength can be varied, and the signal of any wavelength can be made not transmitted.

Meanwhile, a multi-wavelength narrow band transmission filter may be implemented by connecting a plurality of Bragg diffraction gratings in series by the method described above in the first or second embodiment of the narrow band transmission filter according to the present invention.

7 is a configuration diagram of an embodiment of a wavelength division demultiplexer according to the present invention, in which 12 is an optical splitter, 14-1,14-2,... 14-m is a narrowband transmission filter, 20 is a receiver, 22 is an optical waveguide, 82 is a multi-wavelength signal, 82-1, 82-2,... Denotes a signal transmitted through each narrowband transmission filter.

First, the configuration of an embodiment of the wavelength division demultiplexer according to the present invention will be described.

The wavelength division demultiplexer includes an optical waveguide 22 capable of transmitting a multi-wavelength signal 82 having a plurality of wavelengths, and an optical splitter that divides the multi-wavelength signal into the following multiple optical waveguides 22 ( 12), the first narrowband transmission filter 14-1 that transmits the first wavelength of the multi-wavelength signal, and the signal 82-1 transmitted by the first narrowband transmission filter 14-1 can be delivered. An optical waveguide 22, a receiver 20 for receiving a signal passing through the optical waveguide 22, a second narrowband transmission filter 14-2 for transmitting light of a second wavelength of the multi-wavelength signal, and An optical waveguide 22 capable of transmitting the signal 82-2 transmitted by the second narrowband transmission filter 14-2, a receiver 20 receiving a signal passing through the optical waveguide 22, The m-th narrowband transmission filter (14-m) and m-th which are configured in parallel in the same manner and transmit the m-th wavelength of the multi-wavelength signal, An optical waveguide 22 capable of transmitting the signal 82-m transmitted by the narrowband transmission filter 14-m, and an mth receiver 20 receiving a signal passing through the optical waveguide 22; .

Next, the operation of one embodiment of the wavelength division demultiplexer according to the present invention will be described.

,

,

,

,

의 파장의 신호(82)는 광도파로(22)를 통해서 도파된다. 다시 이 신호는 광분배기(12)에 의해서 일정한 출력으로 m개의 광도파로(22)로 분배되어 도파된다. 첫 번째 광도파로(22)를 통해 전송된 다파장의 신호(82)는

의 파장의 신호를 투과시키는 특성을 가지는 첫 번째 협대역 투과 필터(14-1)를 거치면서

의 파장의 신호(82-1)만이 투과된다. 이 신호는 다시 광도파로(22)를 통해 첫 번째 수신단(20)에서 검출된다. 두 번째 광도파로(22)를 통해 전송된 다파장의 신호(82)는

의 파장의 신호를 투과시키는 특성을 가지는 두 번째 협대역 투과 필터(14-2)를 거치면서

의 파장의 신호만이 투과된다. 이 신호는 다시 광도파로를 통해 두 번째 수신단(20)에서 검출된다. 같은 방법으로 m번째의 광도파로(22)를 통해 전송된 다파장의 신호(82)는

의 파장의 신호를 투과시키는 특성을 가지는 m번째 협대역 투과 필터(14-m)를 거치면서

의 파장의 신호(82-m)만이 투과된다. 이 신호는 광도파로(22)를 거쳐 수신단(20)에서 검출된다.From devices that generate signals of multiple wavelengths

,

,

,

,

The signal 82 of wavelength is guided through the optical waveguide 22. This signal is again distributed and guided to the m optical waveguides 22 at constant output by the optical splitter 12. The multi-wavelength signal 82 transmitted through the first optical waveguide 22 is

While passing through the first narrowband transmission filter (14-1) having the property of transmitting a signal having a wavelength of

Only the signal 82-1 of wavelength is transmitted. This signal is again detected at the first receiving end 20 via the optical waveguide 22. The multi-wavelength signal 82 transmitted through the second optical waveguide 22 is

While passing through a second narrowband transmission filter 14-2 having a characteristic of transmitting a signal having a wavelength of

Only the signal of wavelength is transmitted. This signal is again detected at the second receiving end 20 via the optical waveguide. In the same way, the multi-wavelength signal 82 transmitted through the m-th optical waveguide 22 is

While passing through the m-th narrowband transmission filter (14-m) having a characteristic of transmitting a signal having a wavelength of

Only the signal 82-m of the wavelength of is transmitted. This signal is detected at the receiving end 20 via the optical waveguide 22.

When the above m narrowband transmission filters are implemented as a center wavelength variable narrowband transmission filter, any single wavelength as well as any number of other wavelengths can be arbitrarily selected and transmitted. The toilet can easily be changed and may not transmit any wavelength. Therefore, when the wavelength division demultiplexer is used at a receiving end of a wavelength division multiplexing (WDM) system, a signal having a plurality of wavelengths can be divided into a specific wavelength or a signal having specific wavelengths.

8 is a configuration diagram of another embodiment of the wavelength division demultiplexer according to the present invention. 14-m is a narrowband transmission filter, 16 is an optical splitter, 20 is a receiver, 22 is an optical waveguide, 52-1,52-2,. , 52- (m-1) is a signal reflected from (m-1) narrowband transmission filters, 52-1 ', 52-2',... , 52- (m-1 ') is 52-1,52-2,... , 52- (m-1) signal transmitted through optical splitter, 82 is multi-wavelength signal, 82-1, 82-2,... Denotes a signal transmitted through each narrowband transmission filter.

First, the configuration of another embodiment of the wavelength division demultiplexer according to the present invention will be described.

The wavelength division demultiplexer includes an optical waveguide 22 capable of transmitting a multi-wavelength signal 82 composed of multiple wavelengths, and a signal 82-1 of the first wavelength signal from the multi-wavelength signal emitted through the optical splitter 16. First narrowband transmission filter 14-1 for transmitting the optical waveguide 22, and an optical waveguide 22 for transmitting the signal 82-1 transmitted from the first narrowband transmission filter 14-1, Receiving unit 20 for receiving a signal passing through the waveguide 22 and the remaining signal 52-1, which is not transmitted and reflected among the signals input to the first narrowband transmission filter 14-1, receives the next stage of light An optical splitter 16 which sends to the waveguide 22, an optical waveguide 22 which can transmit a signal 52-1 'from the optical splitter 16, and a first narrowband transmission filter 14-. A second narrowband transmission filter 14-2 which receives the remaining unreflected signal transmitted from 1) and transmits the signal 82-2 having the second wavelength, and An optical waveguide 22 capable of transmitting the signal 82-2 transmitted from the first narrowband transmission filter 14-2, a receiver 20 receiving a signal passing through the optical waveguide, and a second narrowband transmission The optical splitter 16 receives the remaining signals 52-2 that are not transmitted and reflected among the signals input to the filter 14-2, and sends them to the optical waveguide 22 of the next stage, and through the optical splitter 16. The optical waveguide 22 capable of transmitting the emitted signal 52-2 ', and the rest reflected and not transmitted through the signal input to the m-second narrowband transmission filter 14-m-2 configured in the above manner M-1 th narrowband transmission filter (14-m-1) and m-1 th narrowband transmission filter (14-m) receiving the signal 52-m-2 'and transmitting a signal of m-1th wavelength An optical waveguide 22 capable of transmitting the signal 82-m-1 transmitted in -1), a receiver 20 receiving a signal passing through the optical waveguide 22, and an m-1 th narrowband transmission Transmission of the signal input to the filter 14-m-1 The optical splitter 16 receives the remaining reflected signal 52-m-1 and sends it to the optical waveguide 22 of the next stage, and the signal 52-m-1 'outputted through the optical splitter 16. ) Receives an optical waveguide 22 capable of transmitting a second wave, and the remaining signal 52-m-1 ′ that is not transmitted and is reflected among the signals input to the m−1 th narrowband transmission filter 14-m−1. m-th narrowband transmission filter 14-m for transmitting the m-th wavelength signal, and optical waveguide 22 for transmitting the signal 82-m transmitted in the m-th narrowband transmission filter 14-m And a receiver 20 for receiving a signal passing through the optical waveguide 22.

Next, the operation of another embodiment of the wavelength division demultiplexer according to the present invention will be described.

,

,

,

,

의 파장의 신호(82)는 이러한 다파장의 신호중

의 파장의 신호를 투과시키는 첫 번째 협대역 투과 필터(14-1)를 거치면서

의 파장의 신호(82-1)만이 투과된다. 이 신호는 광도파로(22)를 통해 첫 번째 수신부(20)에서 검출된다. 한편, 첫 번째 협대역 투과 필터(14-1)에 입력된 신호중 투과되지 않고 반사된 나머지 신호(52-1)는 이 신호를 전달받아 다음 단의 광도파로(22)로 보내주는 광분할기(16)로 들어간다. 광분할기(16)를 통해 다음 단의 광도파로(22)로 보내진 신호(52-1')는

의 파장의 신호(82-2)를 투과시키는 두 번째 협대역 투과 필터(14-2)를 거치면서

의 파장의 신호(82-2)만이 투과된다. 이 신호는 다시 광도파로(22)를 통해 두 번째 수신부(20)에서 검출된다. 한편, 두 번째 협대역 투과 필터(14-2)에 입력된 신호중 투과되지 않고 반사된 나머지 신호(52-2)는 반사되어 들어온 신호를 다음 단의 광도파로(22)로 보내주는 광분할기(16)로 들어가고 광분할기(16)를 통해 다음 단의 광도파로(22)로 신호(52-2')가 보내진다. 위와 같은 방법으로 광도파로(22)를 통해 m-1번째 협대역 투과 필터(14-m-1)로 들어간 신호(52-m-2')는

의 파장의 신호(82-m-1)만이 투과된다. 이 신호는 다시 광도파로(22)를 통해 m-1번째 수신부(20)에서 검출된다. 한편, m-1번째 협대역 투과 필터(14-m-1)에 입력된 신호중 투과되지 않고 반사된 나머지 신호(52-m-1)는 반사되어 들어온 신호를 다음 단의 광도파로(22)로 보내주는 광분할기(16)로 들어가고 광분할기(16)를 통해 다음 단의 광도파로(22)로 신호(52-m-1')가 보내진다. 이 신호는 m번째 협대역 투과 필터(14-m)로 들어가게 되고

의 파장의 신호(82-m)만이 투과된다. 이 신호는 다시 광도파로(22)를 통해 m번째 수신부(20)에서 검출된다.Transmitted through the optical waveguide 22

,

,

,

,

The wavelength of the signal 82 is one of these multi-wavelength signals

While passing through a first narrowband transmission filter (14-1) that transmits a signal having a wavelength of

Only the signal 82-1 of wavelength is transmitted. This signal is detected at the first receiver 20 via the optical waveguide 22. On the other hand, the remaining signal 52-1 which is not transmitted and reflected among the signals input to the first narrowband transmission filter 14-1 receives the signal and sends it to the optical waveguide 22 of the next stage. Enter). The signal 52-1 'sent to the optical waveguide 22 of the next stage through the optical splitter 16 is

While passing through a second narrowband transmission filter 14-2 that transmits a signal 82-2 having a wavelength of

Only the signal 82-2 of wavelength is transmitted. This signal is again detected by the second receiver 20 via the optical waveguide 22. On the other hand, the remaining signal 52-2 which is not transmitted and reflected among the signals input to the second narrowband transmission filter 14-2 transmits the reflected signal to the optical waveguide 22 of the next stage. ) And a signal 52-2 'is sent to the optical waveguide 22 of the next stage through the optical splitter 16. In the same manner as described above, the signal 52-m-2 'that enters the m-1 th narrowband transmission filter 14-m-1 through the optical waveguide 22 is

Only the signal 82-m-1 of wavelength is transmitted. This signal is again detected by the m-1 th receiver 20 through the optical waveguide 22. On the other hand, the remaining signal 52-m-1, which is not transmitted and reflected among the signals input to the m-1 th narrowband transmission filter 14-m-1, passes the reflected signal to the optical waveguide 22 of the next stage. The optical splitter 16 is sent to the optical splitter 16, and the signal 52-m-1 'is transmitted to the optical waveguide 22 of the next stage through the optical splitter 16. This signal enters the mth narrowband transmission filter (14-m)

Only the signal 82-m of the wavelength of is transmitted. This signal is again detected by the m-th receiver 20 via the optical waveguide 22.

When the m narrowband transmission filters 14-1, 14-2, ..., 14-m described above are implemented as a center wavelength variable narrowband transmission filter, any arbitrary single wavelength as well as a plurality of other wavelengths may be arbitrarily selected. One or more wavelengths that can be transmitted and transmitted can be easily varied using a wavelength variable, and may not transmit any wavelength. Therefore, when the wavelength division demultiplexer is used at the receiving end of the wavelength division multiplexing (WDM) system, a signal composed of several wavelengths can be divided into a specific wavelength or a signal composed of specific wavelengths.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains, and the above-described embodiments and accompanying It is not limited to the drawing.

As described above, the present invention can be easily configured with a plurality of wavelength variable which can change the lattice period and the effective refractive index of a plurality of Bragg diffraction gratings and each Bragg diffraction grating connected in series. Circulator or coupler, which is a disadvantage of the method of separating the signal of a certain wavelength using a single Bragg diffraction grating, can be easily separated from the signal of the system. The additional cost can be reduced by preventing the use of separate devices, and the loss of the signal due to the use of such separate devices can be reduced, and the lattice period and effective refractive index of each Bragg diffraction grating can be reduced by using a wavelength converter. By changing the operating wavelength to change the operating wavelength, it is possible to avoid parts replacement due to the change of the operating wavelength.

Claims (37)

A first optical transmission path for transmitting a multi-wavelength signal from the outside; A first Bragg diffraction grating for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength; Connected in series with the first Bragg diffraction grating and receiving an optical signal transmitted through the first Bragg diffraction grating, the center wavelength at which the first Bragg diffraction grating reflects is centered on a specific wavelength spaced at a predetermined interval. A second Bragg diffraction grating for reflecting the optical signal of the second predetermined band; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the second Bragg diffraction grating to the outside. The method of claim 1, First wavelength varying means for converting the central wavelength of the optical signal reflected from the first Bragg diffraction grating; And And a second wavelength varying means for converting the central wavelength of the optical signal reflected from the second Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material in which strain is generated by an external signal to convert the effective refractive index or lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by an externally applied ultrasonic wave to convert the effective refractive index or lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by an externally applied pressure to convert the effective refractive index or the lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by heat applied from the outside to convert the effective refractive index or the lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material whose refractive index changes by an intensity of light applied from the outside in order to convert the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material whose refractive index is changed by an intensity of an electric field applied from the outside in order to convert the effective refractive index of the Bragg diffraction grating. The method of claim 2, The wavelength variable means, And a material whose refractive index is changed by an intensity of a magnetic field applied externally to convert the effective refractive index of the Bragg diffraction grating. The method according to any one of claims 3 to 9, A material for forming the wavelength variable means, And a Bragg diffraction grating used as a material to form the integrally configured to perform a variable wavelength function in the Bragg diffraction grating. The method according to any one of claims 3 to 9, A material for forming the wavelength variable means, A permeable filter, which is formed by adhering to the Bragg diffraction grating. The method according to any one of claims 3 to 9, A material for forming the wavelength variable means, A transmission filter comprising the coating on the Bragg diffraction grating. The method according to any one of claims 1 to 9, The predetermined spacing interval, The Bragg diffraction grating reflects the long-wavelength transmission band and the long wavelength of the Bragg diffraction grating that reflects the short wavelength by adjusting a greater than half of the sum of the reflection bandwidths formed by the first and second Bragg diffraction gratings. A transmission filter comprising a narrow band transmission band at a portion where the short wavelength transmission band overlaps. The method of claim 13, The Bragg diffraction grating, A transmission filter comprising a material having high photosensitivity in order to increase a reflection band by increasing a refractive index difference. The method of claim 14, The Bragg diffraction grating, Affixed by converting the difference in refractive index of the grating portion into a function of the length of the Bragg diffraction grating in order to remove sidelobes that appear at both ends of the reflection bandwidth causing ripple in the transmission band. (apodized) A transmission filter comprising a Bragg diffraction grating. The method of claim 15, The Bragg diffraction grating, The transmission filter, characterized in that for increasing the length of the Bragg diffraction grating to form a narrow transmission band. The method according to any one of claims 1 to 9, and (k is a natural number) the plaque diffraction gratings connected in series to form a transmission band of (k-1) or less narrow bands. A first optical transmission path for transmitting a multi-wavelength signal from the outside; Wavelength varying means for converting the center wavelength of the reflected optical signal; A region for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength, and being spaced apart from the specific wavelength by a wavelength varying means at a predetermined interval; One Bragg diffraction grating including an area for reflecting an optical signal of a second predetermined band around the wavelength; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the Bragg diffraction grating to the outside. The method of claim 18, The transmission band is, A transmission filter, characterized in that to form a narrow band by controlling the difference between the two reflected central wavelengths by adjusting the wavelength variable changes by the wavelength variable means. The method of claim 18 or 19, The wavelength variable means, And a material in which strain is generated by an external signal to convert the effective refractive index or lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by an externally applied ultrasonic wave to convert the effective refractive index or lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by an externally applied pressure to convert the effective refractive index or the lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material of which the refractive index or the refractive index and the length thereof are simultaneously changed by heat applied from the outside to convert the effective refractive index or the lattice period and the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material whose refractive index changes by an intensity of light applied from the outside in order to convert the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material whose refractive index is changed by an intensity of an electric field applied from the outside in order to convert the effective refractive index of the Bragg diffraction grating. The method of claim 18 or 19, The wavelength variable means, And a material whose refractive index is changed by an intensity of a magnetic field applied externally to convert the effective refractive index of the Bragg diffraction grating. The method according to any one of claims 20 to 26, A material for forming the wavelength variable means, And the Bragg diffraction grating is integrally configured to perform a variable wavelength function in the Bragg diffraction grating using a material forming a region for reflecting the optical signal of the second predetermined band. The method according to any one of claims 20 to 26, A material for forming the wavelength variable means, And the Bragg diffraction grating is bonded to an area for reflecting the optical signal of the second predetermined band. The method according to any one of claims 20 to 26, A material for forming the wavelength variable means, The Bragg diffraction grating is formed by coating an area for reflecting the optical signal of the second predetermined band. A first optical transmission path for transmitting a multi-wavelength signal from the outside; Optical distribution means for receiving a multi-wavelength signal through the first optical transmission path and distributing it into at least one optical signal; At least one second optical transmission path for receiving and transmitting one optical signal among at least one optical signal distributed by the optical distribution means; At least one filtering means for receiving and filtering an optical signal of at least one optical signal transmitted through the at least one second optical transmission path to transmit an optical signal corresponding to its transmission band; At least one third optical transmission path for receiving and transmitting one optical signal among at least one optical signal output from the at least one filtering means; And And at least one receiving means for receiving one of the at least one optical signal transmitted through the at least one third transmission path. The method of claim 30, The filtering means, A first optical transmission path for transmitting a multi-wavelength signal from the outside; A first Bragg diffraction grating for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength; Connected in series with the first Bragg diffraction grating and receiving an optical signal transmitted through the first Bragg diffraction grating, the center wavelength at which the first Bragg diffraction grating reflects is centered on a specific wavelength spaced at a predetermined interval. A second Bragg diffraction grating for reflecting the optical signal of the second predetermined band; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the second Bragg diffraction grating to the outside. The method of claim 31, wherein First wavelength varying means for converting the central wavelength of the optical signal reflected from the first Bragg diffraction grating; And And a second wavelength varying means for converting the central wavelength of the optical signal reflected from the second Bragg diffraction grating. The method of claim 30, The filtering means, A first optical transmission path for transmitting a multi-wavelength signal from the outside; Wavelength varying means for converting the center wavelength of the reflected optical signal; A region for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength, and being spaced apart from the specific wavelength by a wavelength varying means at a predetermined interval; One Bragg diffraction grating including an area for reflecting an optical signal of a second predetermined band around the wavelength; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the Bragg diffraction grating to the outside. A first optical transmission path for transmitting a multi-wavelength signal from the outside; First optical transmission means for receiving and transmitting a multi-wavelength signal from the first optical transmission path and receiving the reflected optical signal and transmitting the received optical signal to a next stage; A second optical transmission path for receiving and transmitting a multi-wavelength signal from the first optical transmission means and transferring the reflected optical signal to the first optical transmission means; First filtering means for receiving a signal having multiple wavelengths transmitted through the second optical transmission path, reflecting a predetermined band, transmitting the reflected signal to the second optical transmission path, and transmitting an optical signal corresponding to its transmission band; A third optical transmission path for receiving and transmitting the optical signal output from the first filtering means; First receiving means for receiving an optical signal transmitted through the third optical transmission path; an n1th optical transmission path for transferring the reflected optical signal from the (n-1) th optical transmission means of the (n-1) th stage (n is a natural number); Nth light transmitting means for receiving and transmitting the reflected optical signal from the nth optical transmission path and receiving the reflected optical signal to the (n + 1) th stage; An n2th optical transmission path for receiving and transmitting an optical signal from the nth optical transmission means and transmitting a reflected optical signal to the nth optical transmission means; N-th filtering means for receiving an optical signal transmitted through the n-th optical path and reflecting a predetermined band to be transmitted to the n-th optical path and transmitting an optical signal corresponding to its transmission band; An n3th optical transmission path for receiving and transmitting the optical signal output from the nth filtering means; N-th receiving means for receiving an optical signal transmitted through said n-th optical path; a k1th optical transmission path for transmitting the reflected optical signal from the (k-1) th optical transmission means of the (k-1) th stage (k is a natural number greater than n); K-th filtering means for receiving the reflected optical signal transmitted through the k-th optical transmission path and transmitting the optical signal corresponding to its transmission band; A k2th optical transmission path for receiving and transmitting the optical signal output from the kth filtering means; And And a k-th receiving means for receiving an optical signal transmitted through the k-th optical transmission path. The method of claim 34, wherein The filtering means, A first optical transmission path for transmitting a multi-wavelength signal from the outside; A first Bragg diffraction grating for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength; Connected in series with the first Bragg diffraction grating and receiving an optical signal transmitted through the first Bragg diffraction grating, the center wavelength at which the first Bragg diffraction grating reflects is centered on a specific wavelength spaced at a predetermined interval. A second Bragg diffraction grating for reflecting the optical signal of the second predetermined band; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the second Bragg diffraction grating to the outside. 36. The method of claim 35 wherein First wavelength varying means for converting the central wavelength of the optical signal reflected from the first Bragg diffraction grating; And And a second wavelength varying means for converting the central wavelength of the optical signal reflected from the second Bragg diffraction grating. The method of claim 34, wherein The filtering means, A first optical transmission path for transmitting a multi-wavelength signal from the outside; Wavelength varying means for converting the center wavelength of the reflected optical signal; A region for receiving a multi-wavelength signal through the first optical transmission path and reflecting an optical signal of a first predetermined band around a specific wavelength, and being spaced apart from the specific wavelength by a wavelength varying means at a predetermined interval; One Bragg diffraction grating including an area for reflecting an optical signal of a second predetermined band around the wavelength; And And a second optical transmission path for transmitting a signal having a predetermined wavelength transmitted through the Bragg diffraction grating to the outside.

Images