KR100535312B1 - A Tunable Optical Encoder/Decoder using PN code and Chirped Fiber Bragg Grating and Tunale Optical CDMA Transmitter/Receiver with the Encoder/Decoder - Google Patents

Abstract

The present invention relates to a variable optical encoder / decoder capable of arranging reflected wavelengths of a chirped optical fiber diffraction grating in a PN code and adjusting another channel using one controller, and a variable optical CDMA transceiver employing the same. In the encoder of the present invention, the variable optical encoder according to the present invention forms a grating so as to correspond to the overlapping PN code at least two PN codes are repeatedly arranged, and the grating is formed at a portion corresponding to '0' of the redundant PN code. Without forming a lattice, a lattice is formed at a portion corresponding to '1' of the overlapping PN code so that the lattice is formed to reflect the wavelength of the optical signal, and at the portion where the lattice is not formed, the lattice is transmitted to transmit the lattice. One chirped optical fiber diffraction grating for encoding an optical signal with a PN code; Characteristic control means for controlling characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each PN code; And wavelength selection means for selecting a wavelength region of the optical signal encoded according to the PN code among the wavelength regions reflected or transmitted by the optical fiber diffraction grating. According to the present invention, it is possible to reduce the unit cost, service cost of the optical communication system, and increase communication traffic efficiency.

Description

Tunable Optical Encoder / Decoder using PN code and Chirped Fiber Bragg Grating and Tunale Optical CDMA Transmitter / Receiver with the Encoder / Decoder

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a variable optical encoder / decoder, and in particular, arranges the reflection or transmission wavelength of a chirped fiber Bragg grating (FBG) in a wavelength domain optical CDMA system into a PN code code. The present invention relates to a variable optical encoder / decoder using a PN code and a chirped optical fiber diffraction grating, and a variable optical CDMA transceiver using the same.

In general, in the CDMA data communication, when a transmission side multiplies an arbitrary PN code by data to be transmitted, the transmission data is transmitted using the same code as the PN code multiplied at the time of transmission to the data received at the reception side. It is a communication method to extract the same data as. At this time, the PN code has the same energy as the transmission data, but the bandwidth is considerably wider. The PN code has no relation with the transmission data and uses a signal such as noise that is difficult to estimate. Therefore, the receiving side should know the PN code used by the transmitting side, and the PN code has the same result as using another PN code according to its start time, so the receiving side must know the start time of the corresponding PN code correctly.

This PN code is the most used code in wireless CDMA. However, since the number of code values '1' and '-1' (or '0') constituting the PN code is not the same, interference between each channel of the CDMA appears. U.S. Patent No. 6,614,950 B2 (Fiber Bragg grating-based optical CDMA encoder / decoder) proposes an encoder / decoder of wavelength domain optical CDMA by arranging an optical fiber diffraction grating (FBG) as a PN code, and at the receiving end, two optical The system uses a detector to detect variance. Since the number of code values '1' and '-1' (or '0') constituting the PN code used in this method is not the same, detecting signals with a bipolar code has a problem that it is difficult to use because there is a lot of interference between channels. .

In order to compensate for this problem, stuff bits are added to arbitrary columns so that the number of '1' and '-1' are the same to eliminate interference and accordingly orthogonal code is added. A structure for transmitting a radio frequency (RF) signal in electrical CDMA using a modified PN code has been proposed (US Pat. No. 4,460,992: Orthogonal CDMA system utilizing direct sequence pseudo noise codes). ). However, this method is not applicable to optical CDMA because it proposes a method of electrically encrypting and reverse encrypting. That is, not only the encoder, the decoder, and the switch are all composed of electronic devices, but in the electrical method, the application of the PN code can be applied only to the time domain coding method.

Furthermore, U.S. Patent No. 6,504,969 B1 (Tunable optical encoder and decoder) proposes a variable optical encoder / decoder that optically encodes / decodes in the time domain using a 2x2 optical switch. This is a method of controlling the channel by electrically adjusting the optical switch. Since only a single optical switch can be used to manufacture a variable encoder / decoder, the structure is simple and the channel control is easy. However, it is expensive to implement such as using an optical amplifier to compensate for the loss due to the loss of the encoding pulse. In addition, since the code used is encoded in the time domain, there is a problem that the prime codes are limited by the transmission speed of data that can be transmitted.

Conventional variable wavelength optical CDMA encoders / decoders can adjust the channel by individually adjusting optical filters including an optical fiber diffraction grating (FBG). However, since a separate controller must be attached to each optical filter, manufacturing is difficult and channel control is difficult. In addition, most of the variable optical encoders / decoders have a complicated structure because several controllers are required to vary the encoder / decode channels used in the time domain optical CDMA and wavelength / time domain optical CDMA methods. There was a problem.

The present invention has been proposed to solve the conventional problems as described above, in the wavelength domain optical CDMA system to form a chirped optical fiber diffraction grating in accordance with the PN code and to change the characteristics of the optical fiber diffraction grating to the PN code and the It is an object of the present invention to provide an optical encoder / decoder using a PN code and a chirped optical fiber diffraction grating to be encoded and decoded with a complementary code of a PN code, and a variable optical CDMA transceiver using the same.

In the variable optical encoder according to the present invention for achieving the above object, at least two PN codes are formed to form a lattice corresponding to the duplicated PN code is listed repeatedly, the grid corresponding to '0' of the redundant PN code Without forming a lattice, a lattice is formed at a portion corresponding to '1' of the overlapping PN code so that the lattice is formed to reflect the wavelength of the optical signal, and at the portion where the lattice is not formed, the lattice is transmitted to transmit the lattice. One chirped optical fiber diffraction grating for encoding an optical signal with a PN code; Characteristic control means for controlling characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each PN code; And wavelength selection means for selecting a wavelength region of the optical signal encoded according to the PN code among the wavelength regions reflected or transmitted by the optical fiber diffraction grating.

In addition, the variable optical CDMA transmitter according to the present invention for achieving the above object, the light source means for transmitting the light having a multiple wavelength through the optical fiber; Data generating means for generating binary data of '1' and '0', having two output stages, if the generated data is '1' outputs the transmitted light to the first output stage and the '0' Optical modulation means for outputting the transmitted light to the second output terminal; At least two PN codes connected to the first output terminal may be formed to correspond to the duplicated PN codes repeatedly listed, and the overlapping PN codes may be formed without forming a grid at a portion corresponding to '0' of the redundant PN codes. A lattice is formed at a portion corresponding to '1', and the lattice is formed to reflect the wavelength of the optical signal, and at the portion where the lattice is not formed, the wavelength of the optical signal is transmitted to encode the optical signal with the redundant PN code. One chirped optical fiber diffraction grating; Characteristic control means for controlling characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each PN code; Wavelength selection means for selecting a wavelength region of the optical signal encoded according to the one PN code among the wavelength regions reflected or transmitted by the optical fiber diffraction grating; And the second output terminal and the chirped optical fiber diffraction grating, wherein the light transmitted from the second output terminal is transmitted to the chirped optical fiber diffraction grating, and light transmitted or reflected from the chirped optical fiber diffraction grating is transmitted to an external output terminal. It includes an optical circulator to output.

In addition, the variable optical decoder according to the present invention for achieving the above object is a chirped optical fiber to select a wavelength region of the optical signal encoded according to a specific PN code of the input optical signal and to describe the optical signal of the selected wavelength region described later Wavelength selecting means for outputting the diffraction grating; A grid is formed such that at least two specific PN codes repeatedly correspond to duplicate PN codes listed, but do not form a grid at a portion corresponding to '0' of the duplicate PN code, and correspond to '1' of the duplicate PN code. One chirp for decoding a light signal encoded with the specific PN code by forming a grating in the portion where the grating is formed to reflect the wavelength of the optical signal, and in the portion where the grating is not formed, transmits the wavelength of the optical signal. Optical fiber diffraction gratings; And characteristic control means for controlling the characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each specific PN code.

In addition, the variable optical CDMA receiver according to the present invention for achieving the above object, has two output stages, and transmits the optical signal input to the input terminal to the chirped optical fiber diffraction grating described below connected to the first output terminal and the chirped optical fiber An optical circulator for outputting an optical signal reflected from the diffraction grating to a second output terminal; A wavelength selecting means connected to the first output terminal and selecting a wavelength region of an optical signal encoded according to a specific PN code among the input optical signals and outputting the optical signal of the selected wavelength region to a chirped optical fiber diffraction grating described later; At least two grids connected to the first output terminal may be formed to correspond to duplicate PN codes repeatedly listed, and the grid may be formed without forming a grid at a portion corresponding to '0' of the redundant PN code. A lattice is formed at a portion corresponding to '1' of the PN code to reflect the wavelength of the optical signal at the portion where the lattice is formed, and transmits the wavelength of the optical signal at the portion where the lattice is not formed to be encoded into the specific PN code. One chirped optical fiber diffraction grating for decoding the optical signal; Characteristic control means for controlling a characteristic of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each specific PN code; And an optical signal of the reflected wavelength transmitted from the second output terminal and the second output terminal and the chirped optical fiber diffraction grating and of the transmitted wavelength transmitted from the chirped optical fiber diffraction grating. And a balance detector for detecting a difference in the optical signal and outputting the decoded optical signal.

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

Figure 1 shows a PN code according to an embodiment of the present invention, Figure 1 (a) shows a conventional PN code of length 7 according to an embodiment of the present invention, Figure 1 (b) is A modified PN code of length 8 according to one embodiment of the invention is shown. Referring to FIG. 1, the PN code 11 having a length of 7 is transformed into a PN code 12 having a length of 8. The length of the existing PN code 11 may be 2 ⁿ −1 (an integer of n ≧ 3), and thus the length of the modified PN code 12 may be 2 ⁿ . As shown in the example shown in the drawing, the difference in the number of '1' and '0' is always 1 in the existing length PN code 11. As described above, in the optical CDMA system that receives unipolar data using the existing PN code 11, the number of '1' and '0' is used when configuring the optical CDMA system that receives bipolar data. Due to this difference, interference occurs between different CDMA channels. As shown in FIG. 1, when the stuff bit 13 '0' is added to the existing PN code 11 so that the number of '1' and '0' is equal to an arbitrary position, the bipolar data is added. When configuring receiving optical CDMA, interference between different channels is eliminated. In this case, the added stuff bit 13 is irrelevant to the position and may be added to the same column in all channel codes. Therefore, the PN code having a length of 7 shown in FIG. 1 (a) is preferably applied in an optical CDMA system for transmitting and receiving unipolar data, and the modified PN code having a length of 8 shown in FIG. It would be desirable to apply to optical CDMA systems that transmit and receive unipolar or bipolar data.

FIG. 2 illustrates the characteristics of a chirped optical fiber diffraction grating encoded with a modified PN code of length 8 according to an embodiment of the present invention. FIG. 2 illustrates filtering characteristics of an encoder / decoder filter using a PN code of length 8. It is seen. FIG. 2 (a) shows the encoding type for each wavelength of a chirped fiber Bragg grating (chirped FBG) 21 according to an embodiment of the present invention, and FIG. 2 (b) shows FIG. 2 (c) shows the transmission characteristics with respect to FIG. 2 (a). Although the drawings show the reflection and transmission characteristics of a chirped optical fiber diffraction grating encoded with a modified PN code having a length of eight for convenience of description of the invention, in another embodiment of the invention the chirped optical fiber diffraction grating has a length Can also be encoded with a PN code of 7. Since the chirped optical fiber diffraction grating has the same encoding as the conventional PN code and the modified PN code, only the modified PN code having a length of 8 will be described below.

Referring to FIG. 2, in general, the starting wavelength of the diffraction grating in the chirped optical fiber diffraction grating 21 is And the end wavelength If is and Reflects light of all wavelengths in between. This is because a typical chirped optical fiber diffraction grating has a grating line 22. Therefore, when fabricating a chirped optical fiber diffraction grating such that no grating is formed at a specific portion, the wavelength corresponding to the specific portion is transmitted without being reflected.

As shown in Fig. 2 (a), when fabricating the chirped optical fiber diffraction grating 21 according to the invention, it corresponds to the modified PN code 12 according to the first channel shown in Fig. 1. , , And Corresponding to the portion 23, 25 to form a grating 22, , , And The parts 24 and 26 that correspond to the grating do not form as shown in FIG. 2 (b). , , And Light having a wavelength of is reflected, as shown in FIG. , , And Light having a wavelength of is transmitted. Therefore, using this method, the chirped optical fiber diffraction grating can be used as an encoder / decoder of wavelength domain optical CDMA.

3 is a structural diagram of a variable encoder / decode according to an embodiment of the present invention. Although the variable encoder is shown in FIG. 3, the variable decoder according to the present invention has the same structure as the encoder shown in the figure. Referring to FIG. 3, the variable encoder / decoder 30 according to an embodiment of the present invention includes a chirped optical fiber diffraction grating 31 in which a grating is formed in a specific portion according to the modified PN code of FIG. 1B. A wavelength selecting means for selecting and outputting a specific wavelength region among the characteristic control means 32 for controlling the characteristics of the chirped optical fiber diffraction grating 31 and the wavelength reflected or transmitted from the chirped optical fiber diffraction grating 31; 33). Although not shown in the drawing, the variable encoder / decoder according to the present invention includes a PN code generating means for generating a PN code applied to the present invention as shown in FIG. 1 and a PN modified by adding stuff bits to the generated PN code. It may further comprise a bit stuffing means for generating a code.

Referring to FIG. 3, the chirped optical fiber diffraction grating 31 is an example in which a grating is formed according to the sign of the first channel of the modified PN code 12 shown in FIG. That is, as shown in reference numeral 34, a lattice is formed at a portion corresponding to '1' in the modified PN code and no lattice is formed at a portion corresponding to '0'. In addition, in the chirped optical fiber diffraction grating 31 according to the present invention, as shown at 35, a portion corresponding to the remaining PN code is added once more except for the portion 36 corresponding to the stuff bit 13. Accordingly, reference numerals 34 and 35 have the same order and structure.

The characteristic control means 32 controls the characteristic by changing the physical value of the chirped optical fiber diffraction grating 31. For example, the property control means 32 may change the temperature or tension of the chirped optical fiber diffraction grating 31 or apply an electric field. Thus, the characteristic control means 32 may preferably comprise a temperature changing means, a tension changing means or an electric field applying means. When a change occurs in the chirped optical fiber diffraction grating 31, such as temperature change, tensile change, or armature application, light of a specific wavelength is shifted and output. That is, in the region that reflects or transmits light of a specific wavelength, light of another wavelength immediately before or immediately after the light is reflected or transmitted.

The wavelength selecting means 33 selects a specific wavelength region to cover the channel of the modified PN code among the wavelengths reflected or transmitted by the chirped optical fiber diffraction grating 31.

It should be noted that in FIG. 3, the chirped optical fiber diffraction grating 31 is illustrated as being encoded with a modified PN code having a length of 8 shown in FIG. 1B, but the present invention is not limited thereto. no. That is, the chirped optical fiber diffraction grating 31 according to the present invention may be encoded with an existing PN code having a length of 7 shown in FIG.

Hereinafter, for convenience of description, the operation of the variable encoder / decoder encoded with the modified PN code shown in FIG. 1B will be described in more detail with reference to FIG. 4.

4 is a view illustrating characteristics of a variable encoder filter according to an embodiment of the present invention. FIG. 4 (a) shows encoding types of wavelengths of the variable encoder, and FIG. 4 (b) shows reflection characteristics of the variable encoder. (c) shows the transmission characteristics of the variable encoder. In FIG. 4, the same reference numerals are used for the same components as in FIG. 3. When manufacturing the chirped optical fiber diffraction grating 31 with an encoder / decoder according to an embodiment of the present invention, the stuff bit 36 of the modified PN code 12 as shown in FIG. Add the rest of the bits except the previous bit with To ) Or the remaining portion except for the stuff bit 36 is added once more to form a grating line. Then, the wavelength is changed by the tension change, the temperature change, the electric field applied by the characteristic control means 32, and the like. Wavelengths in the area reflecting light To reflect the light. If we define this change as the first step, → , → , ..., → , → , ..., → , → : The index of the reflected wavelength decreases by one), and the reflected waveform of the chirped optical fiber diffraction grating 31 is changed to the waveform of the first stage in the initial stage of FIG. Similarly wavelength Wavelengths in the area reflecting light If it is defined as the nth step to change the light reflected by the reflected wave according to each step is changed as shown in Figure 4 (b).

At this time, the wavelength selecting means 33 selects a wavelength region encoded by the modified PN code among the waveforms reflected from the chirped optical fiber diffraction grating 31. As shown in FIG. 4 (b), when looking at the distribution of wavelengths existing in the specific selection wavelength region 41 selected by the wavelength selection means 33, the shape of the light reflected at each step is shown in FIG. Have the same shape as the modified PN code shown in Thus, it is possible to generate all channels by changing one chirped fiber diffraction grating encoded with a modified PN code. That is, it can be manufactured by a variable encoder / decoder.

In addition, Fig. 4 (c) shows the transmission characteristics of the variable encoder / decoder filter using the modified PN code in Fig. 4 (a). Similarly, if the characteristics of the chirped optical fiber diffraction grating 31 are changed by changing the tension, temperature, or applying an electric field by the specific control means 32, the wavelength is changed. Wavelength in the region of light transmission If you change it to transmit light, and define this process as the first stage, → , → , ..., → , → , ..., → , → The transmission waveform of the chirped diffraction grating is changed from the initial stage of FIG. 4 (c) to the waveform of the first 'stage. Similarly wavelength Wavelength in the region of light transmission If it is defined as the n 'step to transmit the light of the transmission waveform of each step is changed as shown in Figure 4 (c).

At this time, looking at the distribution of the wavelength present in the specific selection wavelength region 42 selected in the same way as the above reflection characteristics, the shape of the transmitted light in each step is the shape of the modified PN code shown in FIG. It has the same distribution as the complementary code. As such, all channels can be generated by changing one chirped fiber diffraction grating encoded with a modified PN code.

Although described above with reference to the variable encoder, the present invention also provides a variable decoder. Since the variable decoder according to the present invention has the same configuration and operation as the above-described variable encoder, redundant description is omitted. However, in the variable decoder according to the present invention, the light input and output directions are only opposite to the variable encoder.

5 is an exemplary view of an optical CDMA transmitter with a variable encoder in accordance with the present invention. Referring to FIG. 5, the variable optical CDMA transmitter according to the present invention includes a light source 51 for transmitting light having multiple wavelengths through an optical fiber, and data generating means 52 for generating binary data of '1' and '0'. And an optical modulator 53 for outputting the light to the rear stage according to the generated data, the variable encoder 30, and the light transmitted to the first output terminal to the encoder 30. The light transmitted from 30 includes an optical circulator 54 which outputs to another output stage. In this case, the variable encoder 30 is connected to the first output terminal and a stuff bit is added to the PN code in which the remaining PN codes except the stuff bits are repeatedly listed in the modified PN code. One chirped optical fiber diffraction grating 31 which encodes into the modified PN code by reflecting some wavelengths and transmitting the remaining wavelengths by forming a grating in a corresponding portion, and reflects or transmits the wavelength reflected or transmitted from the chirped optical fiber diffraction grating. Characteristic control means 32 for controlling the characteristics of the optical fiber diffraction grating so as to shift and output in a specific direction, and the wavelength region reflected from the chirped optical fiber diffraction grating is selected and transmitted so that it is encoded by the modified PN code. A wavelength selection number for selecting a corresponding region to be encoded by the complementary code of the modified PN code It includes 33.

Referring to FIG. 5, when the data generated by the data generating means 52 is '1', light is sent to the lower output end of the optical modulation means 53, and when the data is '0', light is sent to the upper output end. . Therefore, when the generated data is '1', the light at the lower output terminal passes through the optical circulator 54 and is input to the variable encoder 30, and then the light reflected by the variable encoder 30 is modified. Encrypted with a PN code, it is passed back to the optical circulator 54 and output to the output terminal 55. On the other hand, when the data is '0', light is output to the upper output terminal of the optical modulation means 53, and is output by being encoded by the complementary code of the modified PN code through the variable encoder 30, and the light is output. Passed through the circulator 54 is output to the output terminal (55). The reflection or transmission process of the variable encoder 30 is as described above, and description thereof will be omitted. At this time, in the case of such an optical CDMA transmitter, the position of the wavelength selecting means 33 may be located between the chirped optical fiber diffraction grating 31 and the optical circulator 54 or may be located at the optical output end 55. .

6 is an exemplary view of an optical CDMA receiver having a variable decoder according to the present invention. Referring to FIG. 6, an optical signal output from the variable optical CDMA transmitter is transmitted to the optical transmission path 55 and then input to the variable decoder 60 through the optical circulator 56. Light input to the variable decoder 60 is input to the optical fiber diffraction grating 62 in which only an optical signal having a desired wavelength is chirped through the wavelength selecting means 61. At this time, when fabricating the optical diffraction grating chirped in the same way as the optical CDMA transmitter described above, if the grating is not formed in a specific portion, the wavelength corresponding to the specific portion is transmitted without being reflected, and the grating is formed in the specific portion. In the light of the corresponding wavelength is reflected. The light transmitted from the chirped optical fiber diffraction grating 62 is incident on the first photodetector 64 and converted into an electrical signal, and the reflected light is incident on the second photodetector 65 through the optical fiber circulator 56. And converted into an electrical signal. In this case, the balanced detector 66 outputs a difference signal between the electrical signal output from the second photodetector 65 and the electrical signal output from the first photodetector 64. Thus, if the sign of the optical CDMA transmitter and the sign of the optical CDMA receiver are not the same, the magnitude of the optical signal input to the two photo detectors 64 and 65 is always the same and does not affect the balance detector output. If the codes of the optical CDMA transmitters and receivers are the same, the optical signal is incident only to the second photodetector 65 when the data value is '1', and when the data value is '0', the optical signal is the first photodetector 64. Can be incident only to receive a bipolar signal. The channel variation of the optical CDMA receiver is made by the characteristic control means 63, which is the same as the operation principle of the variable encoder / decoder described above. Furthermore, the channel variable principle of the optical CDMA receiver is the same as that of the variable optical CDMA transmitter described above.

The above description and contents of the drawings disclose an encoder / decoder and an optical CDMA transmitter according to an embodiment of the present invention, but the present invention is not limited thereto. Those skilled in the art to which the present invention pertains may make various changes and modifications within the scope of the present invention with reference to the detailed description and drawings disclosed in the present invention. Accordingly, the scope of the present invention should be determined by the appended claims rather than by the foregoing description and drawings.

According to the present invention, it is possible to operate the system more efficiently by increasing the efficiency of the communication traffic of the optical communication system, it is possible to reduce the unit cost, the service cost of the system.

In addition, the variable encoder / decoder according to the present invention has a very good characteristic in terms of cost and operation because each channel can be adjusted using one controller.

In addition, it is expected to be very useful in the overall optical communication as well as the optical communication network requiring security to be developed in the future.

1 (a) is a PN code having a length of 7 according to an embodiment of the present invention,

1B is a modified PN code of length 8 according to an embodiment of the present invention.

2 is a characteristic diagram of a chirped optical fiber diffraction grating encoded with a modified PN code of length 8 in accordance with an embodiment of the present invention.

3 is a structural diagram of a variable encoder / decoder filter according to an embodiment of the present invention.

4 is a characteristic diagram of a variable encoder filter according to an embodiment of the present invention.

5 is a structural diagram of an optical CDMA transmitter to which a variable encoder according to the present invention is applied.

6 is a structural diagram of an optical CDMA receiver to which a variable decoder according to the present invention is applied.

 Explanation of symbols on the main parts of the drawings

30: variable encoder / decoder 31; Chirped Fiber Optic Grating

32: characteristic control means 33; Wavelength selection means

51: light source 52: data generating means

53: optical modulation means 54: optical circulator

Claims (14)

A grid is formed such that at least two PN codes repeatedly correspond to duplicate PN codes listed, but a portion corresponding to '1' of the redundant PN code without forming a grid at a portion corresponding to '0' of the duplicate PN code A chirped optical fiber diffraction grating for encoding an optical signal with the overlapping PN code by forming a lattice to reflect the wavelength of the optical signal in the portion where the lattice is formed and transmitting the wavelength of the optical signal in the portion where the lattice is not formed ; Characteristic control means for controlling characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each PN code; And Wavelength selection means for selecting a wavelength region of the optical signal encoded according to the one PN code among the wavelength regions reflected or transmitted by the optical fiber diffraction grating; Variable optical encoder using a PN code and the chirped optical fiber diffraction grating, comprising a. The method of claim 1, wherein the PN code, A variable optical encoder using a PN code and a chirped optical fiber diffraction grating characterized in that the stuff bit of '0' is added to an arbitrary position and is modified to have the same number of '1' and '0' of the PN code. . The method of claim 1, wherein the characteristic control means, And a change means for changing an external environment including temperature, tension, and electric field of the chirped optical fiber diffraction grating. The method of claim 1, wherein the wavelength selection means, The wavelength region is selected to be encoded by the PN code among the wavelength regions reflected by the chirped optical fiber diffraction grating, and the corresponding wavelength region is encoded by the complementary code of the PN code among the wavelength regions transmitted by the chirped optical fiber diffraction grating. A variable optical encoder using a PN code and a chirped optical fiber diffraction grating characterized in that it is selected. Light source means for transmitting light having multiple wavelengths through the optical fiber; Data generating means for generating binary data of '1' and '0', An optical modulation means having two output stages and outputting the transmitted light to the first output stage when the generated data is '1' and outputting the transmitted light to the second output stage when the generated data is '0'; At least two PN codes connected to the first output terminal may be formed to correspond to the duplicated PN codes repeatedly listed, and the overlapping PN codes may be formed without forming a grid at a portion corresponding to '0' of the redundant PN codes. A lattice is formed at a portion corresponding to '1', and the lattice is formed to reflect the wavelength of the optical signal, and at the portion where the lattice is not formed, the wavelength of the optical signal is transmitted to encode the optical signal with the redundant PN code. One chirped optical fiber diffraction grating; Characteristic control means for controlling characteristics of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each PN code; Wavelength selection means for selecting a wavelength region of the optical signal encoded according to the one PN code among the wavelength regions reflected or transmitted by the optical fiber diffraction grating; And A light transmitted from the second output terminal to the chirped optical fiber diffraction grating, and light transmitted or reflected from the chirped optical fiber diffraction grating is output to an external output terminal. An optical circulator; Variable optical CDMA transmitter comprising a. The method of claim 5, wherein the PN code, A variable optical CDMA transmitter, characterized in that a stuff bit of '0' is added to an arbitrary position and modified so that the number of '1' and '0' of the PN code is the same. The method of claim 5, wherein the characteristic control means, And varying means for changing an external environment, including temperature, tension, and electric field application of the chirped optical fiber diffraction grating. Wavelength selection means for selecting a wavelength region of the optical signal encoded according to a specific PN code among the input optical signals and outputting the optical signal in the selected wavelength region to a chirped optical fiber diffraction grating described later; A grid is formed such that at least two specific PN codes repeatedly correspond to duplicate PN codes listed, but do not form a grid at a portion corresponding to '0' of the duplicate PN code, and correspond to '1' of the duplicate PN code. One chirp for decoding a light signal encoded with the specific PN code by forming a grating in the portion where the grating is formed to reflect the wavelength of the optical signal, and in the portion where the grating is not formed, transmits the wavelength of the optical signal. Optical fiber diffraction gratings; And Characteristic control means for controlling a characteristic of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each specific PN code; A variable optical decoder using a PN code and a chirped optical fiber diffraction grating comprising a. The method of claim 8, wherein the PN code, A variable optical decoder using a PN code and a chirped optical fiber diffraction grating, wherein a stuff bit of '0' is added to an arbitrary position and modified so that the number of '1' and '0' of the PN code is the same. . The method of claim 8, wherein the characteristic control means, And a means for changing the external environment including temperature, tension and electric field application of the chirped optical fiber diffraction grating. The method of claim 8, wherein the wavelength selection means, The wavelength region is selected to be decoded by the PN code among the wavelength regions reflected by the chirped optical fiber diffraction grating, and the corresponding wavelength region is decoded by the complementary code of the PN code among the wavelength regions transmitted by the chirped optical fiber diffraction grating. A variable optical decoder using a PN code and a chirped optical fiber diffraction grating characterized in that it is selected. An optical circulator having two output stages, which transmits an optical signal input to an input terminal to a chirped optical fiber diffraction grating connected to a first output terminal, and outputs an optical signal reflected from the chirped optical fiber diffraction grating to a second output terminal. ; A wavelength selecting means connected to the first output terminal and selecting a wavelength region of an optical signal encoded according to a specific PN code among the input optical signals and outputting the optical signal of the selected wavelength region to a chirped optical fiber diffraction grating described later; At least two grids connected to the first output terminal may be formed to correspond to duplicate PN codes repeatedly listed, and the grid may be formed without forming a grid at a portion corresponding to '0' of the redundant PN code. A lattice is formed at a portion corresponding to '1' of the PN code to reflect the wavelength of the optical signal at the portion where the lattice is formed, and transmits the wavelength of the optical signal at the portion where the lattice is not formed to be encoded into the specific PN code. One chirped optical fiber diffraction grating for decoding the optical signal; Characteristic control means for controlling a characteristic of the optical fiber diffraction grating to output the wavelength reflected or transmitted from the chirped optical fiber diffraction grating by one bit in a specific direction for each specific PN code; And A difference between an optical signal of the reflected wavelength transmitted from the second output terminal and the optical signal of the transmitted wavelength transmitted from the chirped optical fiber diffraction grating, coupled to the second output terminal and the chirped optical fiber diffraction grating A balance detector for outputting the decoded optical signal; Variable optical CDMA receiver comprising a. The method of claim 12, wherein the PN code, A variable optical CDMA receiver, characterized in that a stuff bit of '0' is added to an arbitrary position and modified so that the number of '1' and '0' of the PN code is the same. The method of claim 12, wherein the characteristic control means, And varying means for varying the external environment, including temperature, tension, and electric field application of the chirped optical fiber diffraction grating.