KR101377368B1 - Apparatus for time delay - Google Patents

Abstract

According to an aspect of the present invention, there is provided a time delay device comprising: an input terminal to which an optical signal is input and an output terminal to which an optical signal is output; And a variable band pass filter for selecting and transmitting the wavelength of the optical signal delayed in the optical line to the output end side, and a wavelength converter for converting the wavelength of the input optical signal located on the optical line.

Time delay, wavelength conversion, frequency

Description

Time delay device {APPARATUS FOR TIME DELAY}

The present invention relates to a variable time delay device, and more particularly to an optical delay time delay device.

Due to the development of high speed memory and electronic processors, the time delay of digital signals can be implemented relatively easily. However, the memory device is not suitable for the analog method, and deterioration due to the signal-to-noise ratio occurs greatly when the signal is stored and read out, so it is not suitable for use in a variable time delay device. In recent years, digital electrical or electronic systems are generally used. However, in the optical relay network used in the wireless communication system, analog input and output configuration may be required for the analog method.

The above-described optical relay network receives a radio signal transmitted from a base station, transmits data through an optical path established to a local base station (relay station) or an area adjacent to a subscriber side, and then converts it into a radio signal to a local base station or each subscriber. It means a network that transmits wireless signals wirelessly. That is, the optical relay network requires a time delay device for removing the time difference between the radio signal received from the central base station and the radio signal wirelessly transmitted to the local base station or subscriber side.

In particular, the analog optical relay network uses a digital time delay device due to the absence of the analog time delay device.

However, an optical relay network having a time delay device at the central base station has a problem in that the network configuration is limited. In addition, the analog type time delay device has a problem that loss is large and integration is not easy.

The present invention seeks to solve the above problems and to provide a time delay device capable of minimizing distortion and loss of a signal.

The time delay device according to the present invention,

An input terminal for receiving an optical signal and an output terminal for outputting an optical signal;

An optical line connected to each of the input terminal and the output terminal and outputting the optical signal inputted from the input terminal to the output terminal with a time delay;

A variable band transmission filter for selecting a wavelength of the optical signal delayed in the optical line and transmitting the wavelength to the output end;

And a wavelength converter positioned on the optical line and configured to convert wavelengths of the input optical signal.

The time delay device according to the present invention has the advantage that the loss can be implemented in a small volume.

In addition, in the ROF type optical relay network configuration, the present invention can configure a time delay apparatus on the local base station side, so that the network configuration is easier than that of the central base station with the time delay apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

1 is a diagram illustrating a time delay device according to a first embodiment of the present invention. Referring to FIG. 1, the time delay device 100 according to the present invention includes an input terminal 101 through which an optical signal is input and an output terminal 102 through which an optical signal is output, an optical line 120 having a ring shape, and a variable shape. An optical amplifier positioned between the bandable filter 140, the wavelength converter 130, the first and second optical couplers 111 and 112, and the first and second optical couplers 111 and 112. An optical amplifier 150.

The optical line 120 is in the form of a loop (or ring) connected to the input and output terminals 101 and 102 by the first and second optical couplers 111 and 112, and the input terminal 101 and the output terminal 102. It has a different length than the directly connected section. That is, the optical line 120 has a length longer than a partial section forming a closed loop and directly connecting the first and second optical couplers 111 and 112, and thus the optical line 120. The optical signal that circulates is time delayed.

FIG. 2 is a graph for describing an operation of the time delay device of FIG. 1. Referring to FIG. 2, an optical signal branched from the second optical coupler 112 to the optical line 120 is time delayed by the optical line 120, and the wavelength converter 130 is connected to the second optical line 120. The wavelength of the optical signal branched from the combiner 112 is converted and output to the first optical combiner 111. That is, the optical signal λ ₁ input to the input terminal 101 is branched from the second optical coupler 112 to the optical line 120, and then the first optical coupler 111 and the second optical coupler are separated. The optical path 120 is circulated by 112, and the wavelength converter 130 converts the wavelength into λ ₂ to λ _{M a} plurality of times.

That is, the wavelength converter 130 is positioned on the optical line 120, and the optical signal λ ₁ input to the input terminal 101 has a plurality of optical signals λ having different wavelengths (or frequencies). ₂ to λ _M ), and the variable band pass filter 140 converts an optical signal having a wavelength required by a user from among the first input optical signal λ ₁ or wavelength converted optical signals λ ₂ to λ _M. Can be selectively permeable. The optical signals λ ₁ to λ _M have the same data, and the degree of time delay may be determined according to the degree of wavelength conversion. That is, the wavelength converter 130 provides a function of counting a kind of time delay by converting an optical signal into a wavelength.

The first and second optical couplers 111 and 112 may be wavelength selective couplers or beam splitters, and the first and second optical couplers 111 and 112 may delay the optical line 120 with the time delay. Optical connection to the device. The first optical coupler 111 outputs the optical signals received from the input terminal 101 and the optical line 120 to the optical amplifier 150 side, and the second optical coupler 112 is the optical amplifier ( The optical signals received from the 150 are output to the optical line 120 and the variable band transmission filter 140.

The optical amplifier 150 is positioned between the first and second optical couplers 111 and 112, and amplifies optical signals received from the first optical coupler 111 to the second optical coupler 112. Output

The tunable band pass filter 140 is positioned between the second optical coupler 112 and the output terminal 102 and selects among the optical signals received from the second optical coupler 112. Only optical signals of wavelength can be selectively transmitted.

The wavelength converter 130 may be an acoustic wavelength converter, and the optical amplifier may be a semiconductor optical amplifier.

3 is a diagram illustrating a configuration of a time delay device according to a second embodiment of the present invention. Referring to FIG. 3, the time delay apparatus 200 according to the present embodiment includes an input terminal 201 through which an optical signal is input and an output terminal 202 for outputting a time delayed optical signal, an optical line 220, and variable band transmission. A filter 240, a circulator 231 and a reflection mirror 233, a wavelength converter 232 positioned between the circulator 231 and the reflection mirror 233, the input terminal 201, A first optical coupler 211 connecting the optical line 220, a second optical coupler 212 connecting the output terminal 202 and the optical line 220, and the first and second optical couplers Optical amplifier 250 positioned between 211,212.

The optical signal input to the input terminal 201 is input to the optical amplifier 250 through the first optical combiner 211, and the optical amplifier 250 amplifies the optical signal received from the input terminal 211. And output to the second optical coupler 212.

In addition, the second optical coupler 212 splits the optical signal received from the optical amplifier 250 and outputs the divided optical signals to the variable band pass filter 240 and the optical line 220, respectively.

The optical line 220 is a kind of loop connected to each of the input terminal 201 and the output terminal 202, and delays an optical signal input from the input terminal 201 to the output terminal. That is, the optical signal incident to the first optical coupler 211 is branched from the second optical coupler 212 to the optical line 220, and the optical line 220 is connected to the first and second optical couplers. Due to the length different from the directly connected section between the 211 and 212, the optical signals input to the optical line 220 are circulated and time delayed.

In addition, the circulator 231 includes first to third ports, and the wavelength converter connected to the second port receives an optical signal input to a first port connected to the second optical coupler 212. Output to (232). The wavelength converter 232 converts the optical signal received from the second port to the reflection mirror 233 by converting the wavelength and converts the optical signal reflected by the reflection mirror 233 to wavelength conversion again. To the second port of 231). The circulator 231 receives the optical signal, which has been wavelength-converted twice in the wavelength converter 232, into the second port, and receives the optical signal input to the second port from the first optical combiner 211. Output to the first optical coupler 211 through a third port connected to the.

That is, the first optical coupler 211 receives the optical signal input to the input terminal 201 and the optical signals, which are time-delayed and wavelength-converted from the optical line 220, and outputs the optical signal to the optical amplifier 250. The second optical coupler 212 outputs the optical signals amplified by the optical amplifier 250 to the variable band pass filter 240.

The variable band pass filter 240 may selectively transmit an optical signal having a wavelength satisfying a required delay time among the wavelength converted optical signals. That is, the optical line 220 may circulate the optical signal over a plurality of times, and determine the delayed time of the optical signal according to the degree of wavelength conversion compared to the wavelength of the optical signal input to the input terminal 201. . Thus, the required delay time can be satisfied by selecting the wavelength converted optical signal.

4 is a diagram illustrating a configuration of a time delay device according to a third embodiment of the present invention. Referring to FIG. 4, the time delay device 300 according to the present embodiment includes an input terminal 301 to which an optical signal is input and an output terminal 302 to output a time delayed optical signal, and each of the input terminal 301 and the output terminal 302. An optical line 320 for outputting the optical signal input from the input terminal 301 to the output terminal 302 as a ring connected to the optical line 320, and outputting the optical signal delayed in the optical line 320. To provide a sinusoidal wave to a variable band pass filter 340 for selecting a wavelength and transmitting it toward the output terminal 302, an external modulator 331 located on the optical line 320, and the external modulator 331. A sinusoidal wave generator 332, a first optical coupler 311 connecting the input terminal 301 and the optical line 320, and a second optical line connecting the output terminal 302 and the optical line 320. Between the coupler 312 and the first and second optical couplers 311 and 312. Mounted optical amplifier 350.

The variable band pass filter 340 is positioned between the second optical coupler 312 and the output terminal 302, and circulates through the optical line 320 to satisfy a delay time among wavelength and time delayed optical signals. An optical signal having a wavelength is selected and output to the output terminal 302 side.

The optical line 320 may use a polarization controller, and the external modulator 331 may use a phase modulator.

5 is a diagram illustrating a configuration of a time delay device according to a fourth embodiment of the present invention. Referring to FIG. 5, the time delay device 400 according to the present embodiment includes an input terminal 401 to which an optical signal is input and an output terminal 402 to output an optical signal that is time delayed, and each of the input terminal 401 and the output terminal 402. An optical line 420 for delaying an optical signal (frequency f ₁ ) input from the input terminal 401 as a loop connected to the output terminal 402, and the optical delayed time in the optical line 420. A variable band pass filter 440 for selecting and transmitting a signal to the output terminal side, an external modulator 431 located on the optical line 420, and a sine wave generator for providing a sine wave to the external modulator 431 432, a first optical coupler 411 connecting the input terminal 401 and the optical line 420, and a second optical coupler 412 connecting the output terminal 402 and the optical line 420. ) And between the first and second optical couplers 411 and 412 It includes an amplifier (450).

The variable band pass filter 440 is positioned between the second optical coupler 412 and the output terminal 402, and has a frequency-converted and time-delayed optical signal f ₁ to f _M that circulates through the optical line. An optical signal having a frequency satisfying a delay time is selected from the output signal and output to the output terminal 402.

The optical line 420 may use a polarization maintaining optical fiber (PMF), and the external modulator 431 may use a phase modulator. The first and second optical couplers 411 and 412 may use polarization mode combiners.

The sinusoidal wave generator 432 generates a sinusoidal wave and outputs it to the phase modulator, and the phase modulator 431 modulates a frequency of the optical signal to a sinusoidal wave and outputs it to the first optical combiner 411.

The optical line 420 according to the present embodiment maintains a polarization component in the optical line 420 by using a polarization maintaining optical fiber, thereby suppressing malfunction due to an unspecified polarization component during phase modulation.

6 is a diagram illustrating a configuration of a time delay apparatus according to a fifth embodiment of the present invention. In the time delay apparatus 500 according to the present embodiment, an input terminal 501 to which an optical signal is input and an output terminal to which a time delayed optical signal is output are shown. 502, an optical line 520 for delaying the optical signal input from the input terminal 501 and outputting the optical signal to the output terminal, and a wavelength of the optical signal delayed in the optical line 520 for the output terminal. A variable band pass filter 540 for transmitting to side 502, an external modulator 531 located on the optical line 520, and a sine wave generator 532 for providing a sine wave to the external modulator 531. ), A first optical coupler 511 connecting the input end 501 and the optical line 520, a second optical coupler 512 connecting the output end 502 and the optical line 520, and And optical enhancement positioned between the first and second optical couplers 511 and 512. And a group (550). The external modulator 531 may be a Mach-gender modulator. In the Mach-gender modulator described above, a bias may be located at the extinction point in order to maximize the frequency conversion efficiency. That is, by placing a bias at the extinction point, the wavelength of the optical signal input to the Mach-gender modulator is not output. Furthermore, the Mach-gender modulator, in which the bias is set at the extinction point, takes advantage of the nonlinearity of the response characteristic, thus allowing frequency conversion to twice the frequency of the applied clock signal.

The variable band pass filter 540 is positioned between the second optical coupler 512 and the output terminal 502, and circulates the optical line 520 to satisfy a delay time among frequency converted and time delayed optical signals. An optical signal of a frequency to be selected is selected and output to the output terminal 502 side.

7 is a diagram illustrating a configuration of a time delay device according to a sixth embodiment of the present invention. In the time delay device 600 according to the present embodiment, an input terminal 601 to which an optical signal is input and an output terminal to which a time delayed optical signal is output are shown. 602, an optical line 620 that is a loop connected to each of the input terminal 601 and the output terminal 602, and outputs the optical signal input from the input terminal 601 to the output terminal with a time delay, and the optical line ( A variable band pass filter 640 for selecting the time-delayed optical signal at 620 and transmitting it to the output terminal 602, an external modulator 631 positioned on the optical line 620, and the external modulator ( 631, a sinusoidal wave generator 632 for providing a sine wave, a first optical coupler 611 connecting the input terminal 601 and the optical line 620, the output terminal 602 and the optical line 620 ) A second optical coupler 612, and the first and the second Optical amplifier 650 positioned between two optical couplers 611,612.

The variable band pass filter 640 is positioned between the second optical coupler 612 and the output terminal 602, circulates through the optical line 620, and satisfies a delay time among the frequency converted and time delayed optical signals. An optical signal of a frequency to be selected is selected and output to the output terminal 602 side.

FIG. 8 is a diagram illustrating a configuration of the external modulator 631 illustrated in FIG. 7. The external modulator 631 may be a single sideband modulator. Referring to FIG. 8, a single-sided band modulator used as the external modulator is a kind of dual arm Mach-Zehnder modulator 631a and generated by the sinusoidal wave generator 632. And a phase holder 631b for fixing the branched portion of the sinusoidal phase by 90 °. That is, the above-described Mach-Zehnder modulator 631a modulates and outputs the data of the optical signal to a sinusoidal wave which is phase-locked at 90 ° with the sinusoidal wave of the normal phase by the sinusoidal wave generator 632.

9 is a diagram illustrating a time delay device according to a seventh embodiment of the present invention. Referring to FIG. 9, the time delay apparatus 700 according to the present embodiment includes an input terminal 701 for inputting an electrical signal and an output terminal 702 for outputting an optical signal, an input terminal 701 for inputting the electrical signal, and the The all-optical converter 703 located between the first optical coupler 711 and the electrical signal input from the input terminal 701 as a loop connected to each of the input terminal 701 and the output terminal 702. An optical line 720 for converting the optical signal converted into an optical signal and outputting the optical signal that has been totally optically converted to the output terminal 702, and selecting the optical signal that has been delayed in the optical line 720. Variable band transmission filter 740 for transmitting to the side 702, a wavelength converter 730 for converting the wavelength of the input optical signal located on the optical line 720, and the variable band transmission filter 740 Between the output terminal 702 and Connected photoelectric converter 704, the first optical coupler 711 connecting the input terminal 701 and the optical line 720, and the optical line 720 and the variable band transmission filter 740. A second optical coupler 712 and an optical amplifier 750 positioned between the first and second optical couplers 711 and 712.

The photoelectric converter 750 may convert an optical signal received from the variable band pass filter 740 into an electrical signal and output the electrical signal to the outside of the time delay device 700 through the output terminal 702.

1 is a diagram illustrating a time delay device according to a first embodiment of the present invention;

2 is a graph illustrating the operation of the time delay device of FIG. 1;

3 is a diagram illustrating a configuration of a time delay device according to a second embodiment of the present invention;

4 is a diagram illustrating a configuration of a time delay device according to a third embodiment of the present invention;

5 is a diagram illustrating a configuration of a time delay device according to a fourth embodiment of the present invention;

6 is a diagram illustrating a configuration of a time delay device according to a fifth embodiment of the present invention;

7 is a diagram illustrating a configuration of a time delay device according to a sixth embodiment of the present invention;

8 shows an example of the Mach-gender modulator shown in FIG. 7;

9 is a diagram illustrating a configuration of a time delay device according to a seventh embodiment of the present invention.

Claims (18)

In the time delay device, An input terminal for receiving an optical signal and an output terminal for outputting an optical signal; An optical line connected to each of the input terminal and the output terminal and outputting the optical signal inputted from the input terminal to the output terminal with a time delay; A variable band transmission filter for selecting a wavelength of the optical signal delayed in the optical line and transmitting the wavelength to the output end; A wavelength converter positioned on the optical path and configured to convert wavelengths of the input optical signal; A first optical coupler connecting the input terminal to the optical line, outputting an optical signal input from the input terminal to an optical amplifier, and outputting an optical signal converted from the wavelength converter to the optical amplifier; A second optical coupler connecting the optical line to the variable band pass filter and branching an optical signal amplified from the optical amplifier to the variable band pass filter and the wavelength converter; And the optical amplifier positioned between the first optical coupler and the second optical coupler to amplify the optical signal input from the first optical coupler and the optical signal converted from the wavelength converter. Delay device. delete delete The method according to claim 1, And the wavelength converter comprises an acoustic wavelength converter. In the time delay device, An input terminal for inputting an optical signal and an output terminal for outputting a time delayed optical signal; An optical line connected to each of the input terminal and the output terminal and outputting the optical signal inputted from the input terminal to the output terminal with a time delay; A variable band transmission filter for selecting a wavelength of the optical signal delayed in the optical line and transmitting the wavelength to the output end; A circulator located on the optical path; A wavelength converter connected to the circulator and a reflection mirror connected to the wavelength converter; A first optical coupler connecting the input terminal to the optical line, outputting an optical signal input from the input terminal to an optical amplifier, and outputting an optical signal input from the circulator to the optical amplifier; A second optical coupler connecting the optical line to the variable band pass filter and branching an optical signal amplified from the optical amplifier to the variable band pass filter and the circulator; A time amplifier positioned between the first optical coupler and the second optical coupler, the optical amplifier amplifying the optical signal input from the first optical coupler and the optical signal input from the circulator; Delay device. delete 6. The method of claim 5, And the wavelength converter comprises an acoustic wavelength converter. In the time delay device, An input terminal for inputting an optical signal and an output terminal for outputting a time delayed optical signal; An optical line connected to each of the input terminal and the output terminal and outputting the optical signal inputted from the input terminal to the output terminal with a time delay; A variable band transmission filter for selecting a wavelength of the optical signal delayed in the optical line and transmitting the wavelength to the output end; An external modulator located on the optical path; A sine wave generator for providing a sine wave to the external modulator; A first optical coupler connecting the input terminal to the optical line, outputting an optical signal input from the input terminal to an optical amplifier, and outputting an optical signal input from the external modulator to the optical amplifier; A second optical coupler connecting the optical line to the variable band pass filter and branching an optical signal amplified from the optical amplifier to the variable band pass filter and the external modulator; And an optical amplifier positioned between the first optical coupler and the second optical coupler to amplify the optical signal input from the first optical coupler and the optical signal converted from the external modulator. Time delay device. delete 9. The method of claim 8, And the optical path comprises a polarization controller. 9. The method of claim 8, The optical path comprises a polarization maintaining optical fiber. 9. The method of claim 8, And the first and second optical couplers comprise a polarization mode combiner. 9. The method of claim 8, And the external modulator comprises a phase modulator. 9. The method of claim 8, And said external modulator comprises a Mach-gender modulator. 9. The method of claim 8, And the external modulator comprises a single sideband modulator. In the time delay device, An input terminal for inputting an electrical signal and an output terminal for outputting the electrical signal; An all-optical converter for all-optical converting the electrical signal input from the input terminal into an optical signal; An optical line for delaying the optical signal, which is optically converted, as a loop connected to each of the input terminal and the output terminal and outputting the delayed optical signal to the output terminal; A variable band transmission filter for selecting a wavelength of the optical signal delayed in the optical line and transmitting the wavelength to the output end; A wavelength converter positioned on the optical path for converting wavelengths of the input optical signal; A photoelectric converter positioned between the variable band pass filter and the output terminal and configured to convert an optical signal input from the variable band pass filter into an electrical signal; A first optical coupler connecting the input terminal to the optical line, outputting an optical signal input from the input terminal to an optical amplifier, and outputting an optical signal converted from the wavelength converter to the optical amplifier; A second optical coupler connecting the optical line to the variable band pass filter and branching an optical signal amplified from the optical amplifier to the variable band pass filter and the wavelength converter; A time delay positioned between the first optical coupler and the second optical coupler and including an optical amplifier for amplifying the optical signal converted from the all-optical converter and the optical signal converted from the wavelength converter. Device. delete delete

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