KR101314844B1 - Apparatus for synchronization of digital signal in coherent optical receiver - Google Patents

Abstract

The present invention relates to a digital signal synchronization device of a coherent optical receiver. The digital signal synchronizing apparatus of the coherent optical receiver according to the present invention synchronizes the digitized signal of the optical signal generated by the interference between the optical signal input through the optical path and the laser optical signal output from the local oscillator, and processes the decoding using the optical signal. And a digital signal manager configured to monitor the digital signal processor and control information of the optical signal to be normally output according to the synchronized digital signal.

Coherent, Optical Receiver, Digital Synchronization, Optical Signal

Description

Apparatus for synchronization of digital signal in coherent optical receiver

TECHNICAL FIELD The present invention relates to optical transmission technology, and more particularly, to a digital synchronization device of a coherent optical receiver.

The present invention is derived from the research conducted as part of the IT source technology development project of the Ministry of Knowledge Economy and the Ministry of Information and Telecommunication Research and Development. [Task management number: 2008-F-017-01, Task name: 100Gbps Ethernet and optical transmission technology development] .

Coherent optical communication technology, developed in the 1980s, uses an optical phase-locked loop (PLL) or optically polarized light to control the phase and polarization of light in a coherent optical receiver. Although the technique such as an optical p0olarization cntroller has been attempted to be implemented in an optical domain, its utility and practicality are inferior.

In the early 1990s, research and commercialization of optical communication systems using optical amplifiers were actively carried out with the invention of Erbium doped fiber amplifiers (EDFAs), while coherent optical communication research was gradually reduced. However, recently, due to the development of integrated circuits and digital signal processing (DSP), interest in coherent optical communication research is increasing. Recent development of coherent optical communication technology using DSP has many similarities with RF / wireless communication technology. However, coherent optical communication technologies using DSPs have achieved remarkable results over the years by combining RF / wireless communication technologies developed over decades.

Coherent optical receivers digitally compensate for disturbances in optical paths such as chromatic dispersion and polarization mode dispersion. The coherent reception method of such a coherent optical receiver has a higher reception sensitivity than the conventional method and is more resistant to noise factors such as amplified spontaneous emission (ASE).

Meanwhile, conventional coherent optical receivers that control various polarizations or various phases are controlled by chromatic dispersion, polarization mode dispersion (PMD), etc. generated in the optical path using a digital adaptive equalizer. Obstacles were compensated for.

Another conventional coherent optical receiver uses a digital phase estimator or digital phase locked loop to compensate for the laser frequency difference between the laser of the local oscillator and the input optical signal. .

Meanwhile, a general coherent optical receiver reproduces a clock signal from a received signal for synchronizing an input optical signal, and reproduces a received signal by using the same. That is, the synchronization of the coherent optical receiver is clocked by analog or digital, and the sampler operates using the reproduced clock to reproduce the received signal.

As described above, the conventional coherent optical receiver has a very complicated configuration for synchronizing the received signal, and has a problem in that the actual implementation is very difficult because the limited symbol rate (GBaud) area is limited.

An object of the present invention is to improve the digital signal synchronization function of a coherent optical receiver, so that the synchronization can be performed well at a wider symbol rate.

The above-described technical problem is achieved by the characteristic aspects of the present invention described later. The digital signal synchronizing apparatus of the coherent optical receiver according to the present invention synchronizes the digitized signal of the optical signal generated by the interference between the optical signal input through the optical path and the laser optical signal output from the local oscillator, and processes the decoding using the optical signal. And a digital signal manager configured to monitor the digital signal processor and control information of the optical signal to be normally output according to the synchronized digital signal.

According to an aspect of the present invention, a digital signal processor includes: a frequency offset estimator for compensating and combining a frequency difference between an optical signal and a laser optical signal; a digital signal synchronizer for synchronizing a clock of a digital signal with a compensated frequency; And a decoder for decoding the digital signal with reference to the clock of the synchronized digital signal.

According to an additional aspect of the present invention, the digital signal processor checks whether or not a failure of an optical signal converted into a digital signal occurs according to a plurality of obstacles generated in an optical path, and thereby compensates for the failure of the optical signal converted into a digital signal. It characterized in that it further comprises a path failure compensation unit.

The digital signal manager according to an additional aspect of the present invention checks whether the synchronized digital signal is normally decoded by the decoder, and accordingly, the digital signal inspector that controls the operation of the decoder, and if the test result is abnormally determined, the digital signal And an initial condition setting unit for initializing the preset condition of the synchronization unit.

The digital signal manager according to an additional aspect of the present invention refers to a digital signal checker for determining whether to stabilize the synchronized digital signal with reference to the changed parameters of the synchronized digital signal from the digital signal synchronizer, and if it is determined that the test is unstable, the digital signal And an initial condition setting unit for initializing predetermined parameters of the synchronization unit.

According to this aspect of the present invention, the digital signal management unit checks whether the digital signal of the optical signal is normally decoded through the decoder or whether the digital signal of the optical signal is synchronized in a stable state, thereby ensuring stable digital synchronization even at a wide range of symbol rates. Can be implemented.

As described above, the digital synchronization apparatus of the coherent optical receiver according to the present invention has an effect that stable digital synchronization with respect to an input optical signal can be realized even at a symbol speed of a wider area than other synchronization schemes.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail so that those skilled in the art can easily understand and reproduce the present invention through these embodiments.

1 is a block diagram of a coherent optical receiver in accordance with an embodiment of the present invention.

As shown in FIG. 1, the coherent optical receiver according to the present invention includes a local oscillator 100, an optical hybrid 200, photo receivers 300 and 310, an analog-digital converter 400, and a digital signal control manager. 500.

The local oscillator 100 outputs an optical signal of a laser. The optical hybrid 200 receives an optical signal input through an optical path and a laser optical signal output from the local oscillator 100 and combines the two optical signals. Thereafter, the optical hybrid 200 outputs the combined optical signals with a phase difference of 90 °. The photo receivers 300 and 310 receive an optical signal output by a phase difference of 90 ° from the optical hybrid 200, convert the optical signal into an electrical signal, and output the converted optical signal.

When the optical signal is converted into an electrical signal through the photo receivers 300 and 310, the analog-digital converter 400 converts the optical signal converted into an electrical signal into a digital signal.

The digital signal control manager 500 combines the digital signals of the optical signal converted from the analog-digital converter 400 and synchronizes them so that the digital signal of the optical signal input through the optical path is normally decoded and output. That is, the digital signal control manager 500 normally outputs the information of the optical signal input through the optical path by using the digital signals of the synchronized optical signal. The digital signal control management unit 500 includes a digital synchronization device according to the present invention, which will be described later, and the digital synchronization device will be described in detail below. Meanwhile, the coherent optical receiver may be configured as shown in FIG. 2 to compensate for an impairment related to polarization such as polarization mode dispersion (PMD) or polarization dependent loss (PDL).

2 is a block diagram of a coherent optical receiver in accordance with another embodiment of the present invention.

As shown, the coherent optical receiver in accordance with the present invention comprises a local oscillator 100, a polarizing beam splitter 130, 150, optical hybrids 200, 210, photo receivers 300, 310, 320, 330, The analog to digital converter 400 and the digital signal control management unit 500 is included. The polarization beam splitter 130 divides the optical signal input through the optical path into two polarizations (x-polarized light, y-polarized light) and transmits them to the respective optical hybrids 200 and 210. In addition, when the laser beam signal output from the local oscillator 100 is input, the polarization beam splitter 150 divides the input laser beam signal into two polarizations (x-polarized light and y-polarized light), respectively. 210). Each of the optical hybrids 200 and 210 combines the polarized light (x-polarized light, y-polarized light) of the laser light signal with the optical signal input from the respective polarization beam splitters 130 and 150.

Then, each of the optical hybrids 200 and 210 outputs an optical signal coupled by interfering with a phase difference of 90 °. The photo receivers 300 and 310 connected to the optical hybrid 200 receive the x-polarized light of the optical signal output by the phase difference of 90 ° from the optical hybrid 200 and convert the x-polarized light into an electrical signal. The photo receivers 320 and 330 connected to the optical hybrid 210 receive the y-polarized light of the optical signal output by the phase difference of 90 ° from the optical hybrid 210 and convert the y-polarized light into an electrical signal.

Thereafter, the analog-digital converter 400 converts the optical signal converted from each photo receiver 300, 310, 320, 330 into an electrical signal into a digital signal. The digital signal control manager 500 combines the digital signals of the optical signal converted from the analog-digital converter 400 and synchronizes them so that the digital signals of the optical signal input through the optical path are normally decoded and output. That is, the digital signal control manager 500 outputs the information of the optical signal input through the optical path normally using the synchronized digital signal. As such, the coherent optical receiver does not need to match the polarization of the optical signal input through the optical path with the polarization of the laser optical signal output from the local oscillator 100, and does not have to be a polarization mode dispersion (PMD) or a PDL (PDL). Polarization-related disorders such as polarization dependent loss) can be compensated for. Hereinafter, the digital synchronization device in the digital signal control management unit 500 for synchronizing the digital signal in the coherent optical receiver will be described in detail.

3 is a block diagram illustrating a configuration of a digital synchronization device that determines whether to synchronize according to a state of a digital signal decoded in a coherent optical receiver according to an embodiment of the present invention.

As shown, the digital synchronization device according to the present invention includes a digital signal processor 515 and a digital signal manager 550. The digital signal processor 515 synchronizes the digitized signal of the optical signal generated by the interference between the optical signal input through the optical path and the laser optical signal output from the local oscillator 100, and processes the decoding using the digital signal. The digital signal processor 515 includes a frequency offset estimator 510, a digital signal synchronizer 520, an optical path failure compensator 530, and a decoder 540.

The frequency offset estimator 510 compensates for the frequency difference between the optical signal input through the optical path and the laser optical signal output from the local oscillator 100. That is, as the optical signal and the laser optical signal are converted into a digital signal by the analog-to-digital conversion unit 400, the original frequency is also converted. Accordingly, the frequency offset estimator 510 estimates the frequency difference between the optical signal and the laser optical signal and compensates using the estimated frequency difference. The digital signal synchronizer 520 synchronizes the frequency-compensated digital signal through the frequency offset estimator 510. The digital signal synchronization unit 520 may be configured as shown in FIG. 4.

4 is a block diagram showing a configuration of a digital signal synchronization unit according to an embodiment of the present invention.

As shown, the digital signal synchronizer 520 includes a timing divider 521, a timing error detector 522, a loop filter 523, and a timing processor 524.

The timing dividing circuit 521 calculates a value between sample values of the frequency-compensated digital signal through the frequency offset estimator 510. That is, the timing dividing circuit 521 creates a new digital signal sequence using the minimum error value fed back through the respective configurations to be described later. The digital signal sequence generated in this manner is equal to the value sampled at the center of the symbol of the transmission signal.

The timing error detector 522 calculates an error value corresponding to a timing error generated by calculating sample values of the digital signal through the timing division circuit 521. For example, in the case of a phase shift keying (PSK) signal, the timing error detector 522 calculates an error value through the following equation using the characteristics of the PSK signal.

e (m _k ) = Re {y (m _k T _s + μ _k T _s ) y (m _k T _s + μ _k T _s )} = Re {(m _k T _s + μ _k T _s ) [y ( (m _k + 1) T _s + μ _k T _s )-y ((m _k -1) T _s + μ _k T _s )]}

As described above, the timing error detector 522 calculates an error value for the timing error through Equation 1 in the case of the PSK signal. The loop filter 523 designed to have a proportional integral structure calculates an output value using the error value calculated through Equation 1 of the timing error detector 522. Thereafter, the timing processor 524 feeds back the timing division circuit 521 such that the error value becomes the minimum value from the output value of the loop filter 523. Accordingly, the timing division circuit 521 creates a new digital signal sequence such that the feedback error value is minimized, and the generated digital signal sequence is equal to the sampled value at the center of the symbol. The signal is synchronized.

The optical path failure compensator 530 checks whether or not a failure of the optical signal converted into the digital signal occurs according to a plurality of obstacles generated in the optical path, and compensates for the failure of the optical signal converted into the digital signal. That is, as the optical signal is transmitted through the optical path, obstacles such as chromatic dispersion or polarization mode dispersion occur. Accordingly, when the digital signal is synchronized through the digital signal synchronization unit 520, the optical path failure compensator 530 compensates for the failure occurring in the optical signal input through the optical path. The optical path failure compensator 530 may compensate for the failure of the optical signal before the clock of the digital signal is synchronized through the digital signal synchronizer 520 as shown in FIG. 5.

FIG. 5 is a block diagram illustrating a configuration of a digital synchronization device that determines whether to synchronize according to a state of a digital signal decoded in a coherent optical receiver according to another embodiment of the present invention.

As shown, when the frequency of the optical signal and the laser optical signal converted into a digital signal by the frequency offset estimator 510 is compensated, the optical path failure compensator 530 is a failure of the optical signal input through the optical path To compensate. As described above, as the optical signal is transmitted through the optical path, obstacles such as color dispersion and polarization mode dispersion occur. Accordingly, the optical path failure compensator 530 compensates for the failure generated in the optical signal, and the digital signal synchronization part 520 synchronizes the clock of the digital signal in which the failure is compensated.

As such, when the digital signal is synchronized through the digital signal synchronization unit 520 and the digital signal is synchronized through the digital signal synchronization unit 520 after the failure of the optical signal is compensated or after the failure of the optical signal is compensated, the decoder 540 decodes the digital signal of the optical signal input through the optical path using the synchronized digital signal.

The digital signal manager 550 controls the information of the optical signal input through the optical path to be normally output according to the synchronized digital signal. The digital signal manager 550 may be achieved through the digital signal inspector 551 and the initial condition setter 553. The digital signal checker 551 checks whether the synchronized digital signal is normally decoded by the decoder 540, and controls the operation of the decoder 540 accordingly. That is, the digital signal inspecting unit 551 checks whether the digital signal synchronized in the decoder 540 is normally decoded, and if it is determined that the digital signal is abnormally decoded, the digital signal inspecting unit 551 stops the operation of the existing decoder 540. . Thereafter, when the initial condition setting unit 553 is abnormally determined as a result of the test, the initial condition setting unit 553 initializes the initial condition preset in the digital signal synchronization unit 520.

Accordingly, the digital signal synchronization unit 520 may re-synchronize the digital signal, so that the digital signal is normally decoded by the decoder 540 so that the information of the optical signal may be normally output. Meanwhile, according to an additional aspect of the present invention, the digital signal manager 550 checks the digital signal synchronizer 520 as shown in FIG. 6 or 7.

6 is a block diagram illustrating a digital synchronization device for determining whether to synchronize according to a stabilized state of a digital signal synchronized in a coherent optical receiver according to an embodiment of the present invention. FIG. 7 is a block diagram illustrating a digital synchronization device for determining whether to synchronize according to a stabilization state of a digital signal synchronized in a coherent optical receiver according to another embodiment of the present invention.

As illustrated in FIG. 6, the digital signal inspecting unit 551 of the digital signal managing unit 550 determines whether to stabilize the synchronized digital signal with reference to the changed parameters of the digital signal synchronized from the digital signal synchronizing unit 520. . If it is determined that the test result is unstable through the digital signal inspecting unit 551, the initial condition setting unit 553 initializes the parameters preset in the digital signal synchronizing unit 520. As such, the digital signal synchronizer 520 re-performs the stabilized synchronization of the digital signal using the initialized parameter information. The digital signal synchronizing unit 520 in which parameter information is initialized through the initial condition setting unit 553 is re-executed so that the digital signal is stabilized to be synchronized. Accordingly, when the synchronization of the digital signal is performed again, the optical path failure compensator 530 compensates for the failure of the optical signal converted into the digital signal. Thereafter, the decoder 540 normally decodes the synchronized digital signal through which the obstacle is compensated through the optical path failure compensator 530, so that the information of the optical signal may be normally output.

Meanwhile, as illustrated in FIG. 7, the digital signal inspecting unit 551 synchronizes the digital signal synchronized from the digital signal synchronizing unit 520 for synchronizing the digital signal in which the optical signal is compensated for through the optical path failure compensator 530. The changed parameter may be referred to to determine whether to stabilize the synchronized digital signal. If it is determined that the test result is unstable through the digital signal inspecting unit 551, the initial condition setting unit 553 initializes the parameters preset in the digital signal synchronizing unit 520. Accordingly, the digital signal synchronizer 520 performs the stabilized synchronization of the digital signal using the initialized parameter information. Accordingly, the optical signal input through the optical path can be stabilized digital synchronization even in the symbol speed of a wide area as shown in FIG.

8 is a graph illustrating bit error rate results of optical signals using a digital synchronization device according to an embodiment of the present invention.

As shown, the optical signal input through the optical path was modulated by a quaternary phase shift keying (QPSK) scheme, and the symbol rate was set to a value near 10 Gbaud. As a result, even though the symbol rate of QPSK varies greatly from 9.0 to 10.7 Gbaud, it can be seen that a similar bit error rate can be obtained. That is, by using the digital synchronization device of the present invention, the input optical signal can be stabilized digital synchronization at a wide range of symbol rates.

So far I looked at the center of the preferred embodiment for the present invention.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

1 is a block diagram of a coherent optical receiver in accordance with one embodiment of the present invention;

2 is a block diagram of a coherent optical receiver in accordance with another embodiment of the present invention;

3 is a block diagram illustrating a configuration of a digital synchronization device that determines whether to synchronize according to a state of a digital signal decoded in a coherent optical receiver according to an embodiment of the present invention;

4 is a block diagram showing the configuration of a digital signal synchronization unit according to an embodiment of the present invention;

FIG. 5 is a block diagram illustrating a configuration of a digital synchronization device that determines whether to synchronize according to a state of a digital signal decoded in a coherent optical receiver according to another embodiment of the present invention; FIG.

6 is a block diagram illustrating a digital synchronization device for determining whether to synchronize according to a stabilization state of a digital signal synchronized in a coherent optical receiver according to an embodiment of the present invention;

7 is a block diagram illustrating a digital synchronization device for determining whether to synchronize according to a stabilized state of a digital signal synchronized in a coherent optical receiver according to another embodiment of the present invention;

8 is a graph showing the bit error rate results of the optical signal using the digital synchronization device according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: local oscillator 130, 150: polarized beam splitter

200, 210: optical hybrid 300, 310, 320, 330: photo receiver

400: analog to digital conversion unit 500: digital signal control management unit

510: frequency offset estimator 515: digital signal processor

520: digital signal synchronization unit 530: optical path failure compensation unit

540: decoder 550: digital signal management unit

551: digital signal inspection unit 553: initial condition setting unit

Claims (14)

A digital signal processor for digitizing the optical signal input through the optical path and the laser optical signal output from the local oscillator, synchronizing the digitized optical signal between clocks, and decoding the input optical signal using the synchronized digital signal; Monitor the digital signal processor to check whether the digital signal processor normally processes the synchronized digital signal so that the information of the input optical signal is normally output according to the synchronized digital signal. A digital signal manager for initializing a condition; Digital signal synchronization device comprising a. The method of claim 1, wherein the digital signal processing unit: A frequency offset estimator for compensating and combining the frequency difference between the digital signal of the optical signal and the laser optical signal; A digital signal synchronizing unit configured to synchronize the combined digital signal by compensating the frequency difference; A decoder for decoding an input optical signal with reference to the synchronized digital signal; Digital signal synchronization device comprising a. The digital signal processor of claim 2, wherein the digital signal processor comprises: An optical fiber path failure compensator configured to check whether an optical signal converted into the digital signal occurs according to a plurality of obstacles generated in the optical path, and thereby compensate for the failure of the optical signal converted into the digital signal; Digital synchronizing device further comprises. 4. The optical path failure compensation unit of claim 3, wherein: And a digital signal synchronized with the digital signal synchronizer to compensate for the failure of the optical signal. 4. The optical path failure compensation unit of claim 3, wherein: And a digital signal whose frequency difference is compensated for by the frequency difference compensator to compensate for the failure of the optical signal. The digital signal manager of claim 2, wherein the digital signal manager comprises: A digital signal inspection unit which checks whether the synchronized digital signal is normally decoded by the decoder, and controls the operation of the decoder accordingly; An initial condition setting unit which initializes a predetermined condition of the digital signal synchronization unit when it is determined that the test result is abnormal; Digital synchronization device comprising a. The digital signal manager of claim 2, wherein the digital signal manager comprises: A digital signal inspecting unit determining whether the synchronized digital signal is stabilized by referring to a changed parameter of the digital signal synchronized from the digital signal synchronizing unit; An initial condition setting unit which initializes predetermined parameters of the digital signal synchronization unit when it is determined that the test result is unstable; Digital synchronization device comprising a. An optical hybrid for outputting the optical signal and the laser optical signal at different phase differences when the optical signal transmitted through the optical line and the laser optical signal output from the local oscillator are input; A photo receiver for converting optical signals and laser optical signals output at different phase differences through the optical hybrid into electrical signals, respectively; An analog-digital converter for converting the optical signal and the laser optical signal converted into the electrical signal into a digital signal; Combine the converted digital signals of the optical signal and the laser optical signal to synchronize between clocks, decode the input optical signal using the synchronized digital signal, and output information of the input optical signal normally according to the synchronized digital signal. A digital signal control management unit which checks whether the synchronized digital signal is normally processed and initializes a preset condition for synchronizing the digital signal if the inspection result is abnormal; Coherent light receiving device comprising a. The optical hybrid of claim 8, wherein the optical hybrid is: And outputting the optical signal and the laser optical signal at a 90 [deg.] Phase difference. The method of claim 8, wherein the digital signal control management unit: A frequency offset estimator for compensating and combining the frequency difference between the digital signal of the optical signal and the laser optical signal; A digital signal synchronizing unit for synchronizing the combined digital signal with the compensated frequency; A decoder which decodes an input optical signal using the synchronized digital signal; A digital signal manager which controls information of an input optical signal to be normally output according to the synchronized digital signal; Coherent light receiving device comprising a. The method of claim 10, wherein the digital signal control management unit: An optical path failure compensator configured to check whether a failure of the optical signal converted into the digital signal occurs according to a plurality of obstacles generated in the optical path, and thereby compensate for the failure of the optical signal converted into the digital signal; Coherent light receiving device further comprises. The method of claim 11, wherein the disability compensation unit: And a coherent optical receiving device compensating for the failure of the optical signal after the digital signal is synchronized through the digital signal synchronization unit or before the synchronization is performed. The method of claim 10, wherein the digital signal management unit: A digital signal inspection unit which checks whether the synchronized digital signal is normally decoded by the decoder, and controls the operation of the decoder accordingly; An initial condition setting unit for initializing a predetermined condition of the digital signal synchronization unit if it is determined that the test result is abnormal; Coherent light receiving device comprising a. The method of claim 10, wherein the digital signal management unit: A digital signal inspecting unit determining whether the synchronized digital signal is stabilized by referring to a changed parameter of the digital signal synchronized from the digital signal synchronizing unit; An initial condition setting unit which initializes predetermined parameters of the digital signal synchronization unit when it is determined that the test result is unstable; Coherent light receiving device comprising a.

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