KR20120025317A - Device and method for generating the millimeter-wave based radio over fiber system - Google Patents

Abstract

PURPOSE: A WDM(Wavelength Division Multiplexing) based millimeter generating device and a method thereof are provided to generate a single sideband sub carrier millimeter wave by wavelength locked modulation, thereby reducing the effect of chromatic dispersion. CONSTITUTION: A first modulation unit(303) includes one or more sub carriers in a first light source. A light wavelength distributing unit(305) distributes a first modulation signal of the first modulation unit to a plurality of second light sources. A second modulation unit(307) includes data stream in at least one or more sub carriers. A millimeter wave generating unit(309) generates a millimeter wave by the interaction of at least one of optically amplified sub carriers and a main carrier, or at least one of optically amplified sub carriers and the other sub carriers.

Description

An apparatus and method for generating a millimeter wave based on wavelength division multiplexing. {DEVICE AND METHOD FOR GENERATING THE MILLIMETER-WAVE BASED RADIO OVER FIBER SYSTEM}

The present invention relates to a millimeter wave generator based on wavelength division multiplexing, and more particularly, to a millimeter wave generator capable of generating a millimeter wave in the form of a single sideband carrier to reduce the influence of color dispersion and obtain high optical gain. .

Researched and developed for the implementation of economical broadband wired / wireless integrated network, the Radio Over Fiber (RoF) technology transmits optical radio signals containing ultra-high frequency or millimeter-wave carriers through ultra-wideband, low-loss optical fibers. It is based on doing. This technology is being actively researched and developed around the world as an important alternative for establishing an economical wired / wireless integrated subscriber network by combining the advantages of optical fiber based optical communication technology and wireless communication technology most efficiently.

At present, the conventionally disclosed method for generating millimeter waves and transmitting them on an optical link is based on bilateral band-suppressed broadcast waves using a semiconductor optical amplifier Mach-Zehnder interferometer (SOI-MZI) as shown in FIG. There is a method of copying a band signal.

The method requires one SOI-MZI module for each channel, which is inefficient in terms of cost and maintenance in implementing the system. In addition, since cross-phase modulation (XPM) is used to generate the millimeter wave, when the millimeter wave in the form of a single sideband carrier is generated, the effect of color dispersion is small but the efficiency of copying the signal is reduced. When generating the millimeter wave of the shape, there is a problem in that the effect of color dispersion is increased, there is a disadvantage that only the two side band suppression carrier should be used.

Since millimeter waves have severe attenuation of signals in the air, many base stations are required to overcome them. To this end, WDM (wavelength division multiplexed) is used to transmit multiple signals using multiple wavelengths.

2 is a method of utilizing a wavelength conversion technology using the cross-absorption modulation phenomenon of the field absorption modulator to implement the WDM. In order to implement the WDM method, a multi-wavelength light source is used, and each wavelength has a millimeter wave of both sideband suppressor carriers by the first modulator. The WDM method also has a problem in that the baseband signal is not effectively copied to the millimeter wave when the millimeter wave in the single-side band carrier type is used. In the case of the millimeter wave in the double-side band carrier type, color dispersion is greatly affected. There is a limitation that the same data is carried for each wavelength.

In order to solve the problems of the prior art as described above, the present invention provides a millimeter wave generating apparatus that can generate a millimeter wave in the form of a single sideband carrier to reduce the influence of color dispersion and obtain a high optical gain.

In addition, the present invention provides a millimeter wave generator capable of simultaneously providing a wired signal and a wireless millimeter wave signal.

According to an exemplary embodiment of the present invention, a first modulation is performed by including at least one subcarrier having a wavelength adjacent to each of the main carriers in a first light source including main carriers having different wavelengths. A first modulator for modulating the signal; An optical wavelength distribution unit for distributing the first modulated signal to a plurality of second light sources including one primary carrier and at least one subcarrier based on a distance between the distribution channels; A second modulator for generating a second modulated signal by optically amplifying a data stream in at least one subcarrier of the one or more subcarriers for each of the plurality of second light sources; And a millimeter wave generator for generating a millimeter wave by interacting the at least one subcarrier with the optical amplification and the main carrier or by interacting the at least one subcarrier with the remaining subcarrier. The first modulated signal has any one of a form of a double side band carrier, a single side band carrier, and a double side band suppressed carrier, and the second modulated signal has a form of a single side band carrier. It provides a millimeter wave generator of.

Further comprising a light source generation unit for generating a first light source including a main carrier of different wavelengths,

The light source generator may include a plurality of distributed feedback (DFB) laser diodes or at least one Fabry-Perot laser diode, and each of the DFB laser diodes or the at least one Fabry-Perot laser diode has a different wavelength. A light source including a main carrier is generated.

Here, when the interval of the distribution channel is greater than or equal to the interval between the main carrier and the sub-carrier of any one of the plurality of second light source, the optical wavelength distribution unit is the main channel to any one of the optical wavelength distribution unit Distributing wavelengths so that the carrier and the subcarrier or the subcarriers on both sides are distributed together, wherein the interval of the distribution channel is the interval between the main carrier and the subcarrier of the light source of any one of the plurality of second light sources. If less than, the optical wavelength distribution unit is configured to distribute the wavelength so that the main carrier and the sub-carrier are separated and distributed respectively using the two distribution channels.

In addition, when the form of the first modulated signal is a bilateral band carrier including subcarriers on both sides of the main carrier, the millimeter wave interacts with the main carrier and optically amplified subcarriers among the subcarriers on both sides. And a frequency band of the millimeter wave is determined by an interval between the main carrier and the optically amplified subcarrier, wherein the second modulator is configured for a wired signal to the subcarrier not used for millimeter wave generation. It comprises a data stream to optically amplify to generate a modulated signal.

Here, when the first modulated signal has a form of a both side band carriers or both side band suppression carriers, the sub-carriers optically amplified by the second modulator of the sub-carriers on both sides will have amplified optical power, the optical The non-amplified subcarrier passes through the second modulator and the optical power is reduced due to the optical loss, so that the second modulated signal has the same form as a single sideband carrier.

In addition, according to another embodiment of the present invention, the method comprises the steps of: (a) generating a first light source including main carriers having different wavelengths; (B) including at least one subcarrier having a wavelength adjacent to each of the primary carriers in the first light source and modulating the first modulated signal; (C) distributing the first modulated signal to a plurality of second light sources including the one main carrier and at least one subcarrier based on an interval of a distribution channel to transmit different data streams for each wavelength; (D) generating a second modulated signal by optically amplifying a data stream in at least one subcarrier of the one or more subcarriers for each of the plurality of second light sources; (E) generating a millimeter wave by interacting the optically amplified at least one subcarrier with the primary carrier or by interacting the optically amplified at least one subcarrier with the remaining subcarriers, The first modulated signal is a bilateral band carrier type including subcarriers on both sides of the main carrier, a single sideband carrier type including subcarriers on one side of the main carrier, or the main carrier is suppressed and the suppressed main carrier A millimeter wave based on wavelength division multiplexing having any one of a form of a double sideband suppression carrier including a subcarrier on both sides of the second modulated signal, wherein the second modulated signal has a form of a single side wave carrier by the optical amplification. Provides a creation method.

Here, in the generating of the millimeter wave (d), when the first modulated signal has a bilateral band carrier type, one subcarrier optically amplified among the main carrier and the subcarriers on both sides of the bilateral band carriers may be used. And generating a millimeter wave by using the subcarrier, which is not used for millimeter wave generation, by including a data stream for a wired signal and optically amplifying the modulated signal.

According to the present invention, a single external modulator can freely modulate a plurality of light sources having different wavelengths in the form of a double sideband carrier, a single sideband carrier, and a sideband suppression carrier, and use a single sideband carrier type through wavelength locked modulation. By generating millimeter waves, the effects of chromatic dispersion can be reduced and high optical gain can be obtained to improve the signal quality.

In addition, it can generate a wireless millimeter signal and a wired signal together has the advantage that can be applied to the existing WDM-PON system.

FIG. 1 is a diagram of a related art for generating a millimeter wave by copying a baseband signal to a bilateral band-suppressing broadcast wave using a Mahzander modulator.
FIG. 2 is a diagram of a conventional technique for generating millimeter waves using a wavelength conversion technique using a cross-absorption modulation phenomenon of the field absorption modulator to implement WDM.
3 is a block diagram showing the structure of a millimeter wave generating apparatus according to an embodiment of the present invention.
4 is a diagram illustrating an example of a process of modulating a first light source into a bilateral band carrier, a bilateral band suppressor carrier, and a single band carrier by a first modulator according to an embodiment of the present invention.
5 is a diagram illustrating an example of a process of modulating a first modulated signal modulated by a first modulator in a second modulator according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating a process in which a first modulated signal modulated by the first modulator passes through an optical wavelength distributor according to an embodiment of the present invention and is distributed for each distribution channel.
7 illustrates an example of a method of using a primary carrier and a subcarrier to modulate a millimeter wave wireless signal and a wired signal together according to an embodiment of the present invention.
8 is a diagram illustrating an example of generating and transmitting a wired or wireless millimeter wave heterogeneous signal according to an embodiment of the present invention.
9 is a diagram of an optical spectrum after modulating a wired or wireless millimeter wave heterogeneous signal in a second modulator according to an embodiment of the present invention.
10 is an optical spectrum of a signal in which wired and wireless millimeter wave heterogeneous signals are added and transmitted by an optical wavelength distribution unit according to an embodiment of the present invention.
FIG. 11 is a diagram of an optical spectrum after modulated wired and wireless millimeter wave heterogeneous signals are distributed to a receiving end by an optical wavelength distribution unit according to an embodiment of the present invention.
12 is a diagram of an RF spectrum of a signal restored in a wired network receiver and a wireless network receiver according to an embodiment of the present invention.
13 is a view showing the overall flow of the millimeter wave generation method according to an embodiment of the present invention.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals are used for like elements in describing each drawing. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing the structure of a millimeter wave generating apparatus according to an embodiment of the present invention.

Referring to FIG. 3, the millimeter wave generator 300 includes a light source generator 301, a first modulator 303, an optical wavelength distributor 305, a second modulator 307, and a millimeter wave generator ( 309).

The light source generator 301 generates a light source including main carriers having different wavelengths. The light source generator 301 may include a plurality of distributed feedback (DFB) laser diodes or at least one or more Fabry Ferret laser diodes, and each of the plurality of DFB laser diodes or at least one or more Fabry Ferret laser diodes may have a wavelength. A first light source including another main carrier is generated.

The DFB laser diode can generate a light source having one wavelength and thus uses a plurality of DFB laser diodes to generate a main carrier having a plurality of wavelengths different from each other.

When generating a light source through a Fabry-Perot laser diode, a plurality of main carriers having a constant wavelength interval may be generated in a multi-mode, so that the light source generator 301 may include at least one Fabry-Perot laser diode.

The first modulator 303 further includes at least one subcarrier having a wavelength adjacent to each primary carrier in a first light source including primary carriers having different wavelengths generated by the light source generator 301. The modulated signal is modulated, and when the first light source is modulated by the first modulator 303, the frequency state conversion is performed such that the main carrier has a higher frequency band than the frequency band used.

Since the millimeter wave used in the optical communication is a region having a high carrier frequency (30 GHz to 300 GHz) rather than a frequency region in which existing data is used, frequency upconversion is performed through the first modulator 303.

The first modulator 303 may include a Mahzander modulator (MZM). When the light source is up-converted to the all-optical frequency through the Mahzander modulator, there is an advantage in that the modulation characteristics according to the polarization of the light source are small, have a high conversion gain, and have a wide frequency bandwidth that can be up-modulated. However, the Mahchender modulator is an expensive device and a cost problem occurs in a system having a Mahchender modulator for each light source.

In the present invention, the first light source including the main carriers having different wavelengths generated by the light source generator 301 is simultaneously frequency-modulated through the first modulator 303. Therefore, there is an advantage that the first modulator 303 need not be provided for each light source having a different wavelength.

Since the first modulator 303 does not directly modulate the data stream, the first modulated signal modulated by the first modulator 303 may be a double sideband carrier type, a single sideband carrier type, or both sideband suppression. It can be freely generated in any one of the carrier forms, which is effective in designing the system.

Hereinafter, a signal including a subcarrier and frequency up-converted through the first modulator 303 will be described with reference to FIG. 4.

4 is a diagram illustrating an example of a process of modulating a first light source into a bilateral band carrier, a bilateral band suppressor carrier, or a single band carrier by a first modulator according to an embodiment of the present invention.

Referring to FIG. 4, a first light source including main carriers having different wavelengths generated by the light source generator 301 is input to the first modulator 303 and passes through the first modulator 303. Includes subcarriers for each primary carrier and is converted into various forms.

Both sideband carriers have a form including subcarriers on both sides of the main carrier, the single sideband carrier has a form including a subcarrier on one side of the main carrier. Both side band suppression carriers have a form in which the main carrier becomes suppressed and subcarriers are included on both sides of the suppressed main carrier.

Again, the millimeter wave generating apparatus will be described with reference to FIG. 3.

The optical wavelength distributor 305 converts the first modulated signal modulated by the first modulator 303 into a plurality of second light sources including one main carrier and at least one subcarrier based on a distance between the distribution channels. To distribute.

The second modulator 307 includes a data stream in at least one subcarrier of the one or more subcarriers for each of the plurality of second light sources distributed by the optical wavelength distribution unit 305 to optically amplify the second modulated signal. Create

The millimeter wave generator 309 generates the millimeter wave by interacting the at least one optically amplified subcarrier with the primary carrier or by interacting the at least one subcarrier with the optical amplification and the remaining subcarriers.

The wavelength distribution unit 305 distributes light sources for each wavelength, and the second modulator 307 modulates the distributed light sources to include different data streams, thereby transmitting several signals using multiple wavelengths. multiplexed) can be implemented.

The second modulator 307 may include a Fabry-Perot laser diode or a reflective optical amplifier.

When modulating using a Fabry-Perot laser diode, wavelength-locked modulation may be performed to select and modulate only a subcarrier from among signals included in the second light source distributed by the optical wavelength distribution unit 305. When the modulation is performed using the amplifier, both the subcarrier and the main carrier included in the second light source distributed by the optical wavelength distribution unit 305 are modulated, and in this case, a larger millimeter wave signal is obtained. have.

If the light source generator 301 generates a light source including main carriers having different wavelengths through the Fabry ferret diode, the second modulator 307 may modulate the reflective optical amplifier. This is because when the light source is generated through the Fabry ferret diode, mode partition noise in which the size of the main carrier included in the light source is shaken is generated. Therefore, modulation is performed through the reflective optical amplifier to correct mode partition noise.

Hereinafter, a process of modulating the second light source distributed by the optical wavelength distribution unit 305 into the second modulated signal by the second modulator 307 will be described in detail with reference to FIG. 5.

5 is a diagram illustrating an example of a process of modulating a first modulated signal modulated by a first modulator in a second modulator according to an embodiment of the present invention.

Referring to FIG. 5, it is assumed that a signal modulated by the first modulated signal through the first modulator 303 is a double sideband carrier wave, and the second modulator 307 is formed of a Fabry-Perot laser diode.

The first light distribution signal 501, the second light distribution signal 503, and the third light distribution signal 505 are distributed for each wavelength through the light wavelength distribution unit 305, and the first light distribution signal 501 is formed by The second modulator A 511 and the second light splitting signal 503 are modulated by the second modulator B 513 and the third light splitting signal 505 through the second modulator C 515, respectively.

Subcarriers are modulated by the respective second modulators 511, 513, and 515, and may be optically modulated to include different data streams for each wavelength during wavelength locked modulation.

Each of the wavelength-locked modulated light distribution signals 501, 503, and 505 is re-input to the optical wavelength distribution unit 305, re-summing according to the wavelength, and output.

Referring to FIG. 5, when the signal modulated by the first modulating signal in the first modulator 303 is a bilateral band carrier, only the subcarrier is wavelength-locked modulated by a Fabry-Perot laser diode, or the main carrier and the subcarrier are reflected. The second modulated signal has a form of a single sideband carrier because the optical power is modulated by the fluorescent amplifier and has a high optical power and the optical power is reduced due to the optical loss in the second modulator 309.

In this case, the millimeter wave is generated by the interaction between the main carrier and the subcarrier of the light source, and the frequency band in which the millimeter is generated is determined by the interval between the main carrier and the subcarrier of the second light source.

When the signal modulated by the first modulation signal in the first modulation unit 303 is a double sideband suppression carrier, both the primary carrier and the subcarriers on both sides are distributed together by the optical wavelength distribution unit 305, and the Fabry-Perot laser diode The subcarriers of one of the subcarriers are wavelength-locked modulated by the subcarriers or the subcarriers on both sides are modulated together by a reflective optical amplifier so that the main carrier is suppressed with high optical power. Has

At this time, since the generation of the millimeter wave is generated by the interaction between the subcarriers, the frequency band of the millimeter wave is determined by the interval of the subcarriers. For example, in the first modulator 303, when the carriers are frequency up-converted to have a 30 GHz interval, the interval between subcarriers is 60 GHz and the millimeter wave is generated in the 60 GHz band.

Therefore, it is possible to generate a millimeter wave that is twice the frequency interval converted by the first modulator 303, which will be useful for making a millimeter wave of high frequency at a low frequency.

When the plurality of second light sources are remodulated by the second modulator 307 in the form of a single sideband carrier wave, the influence of color dispersion may be reduced during light transmission, and the modulated carrier wave may have a higher optical gain of 20 dB or more. Large optical signal-to-noise ratios can be achieved, resulting in better reception sensitivity and signal quality than previously proposed methods.

In this manner, the second modulator 307 can modulate the single sideband carrier in the form of a double sideband carrier, a single sideband carrier, or a sideband suppressor carrier in the first modulator 303. Effective in designing

In addition, by generating the millimeter wave through the second modulator 307 rather than an external modulator, the system can be easily implemented at the transmitter by using a cheap optical device having a relatively low quality. It will be easier to build an optical subscriber network for low-millimeter-wave transmission than that.

Hereinafter, the process of distributing the light source according to the wavelength in the light wavelength distribution unit 305 will be described in more detail.

An optical wavelength distribution unit 305 (arrayed waveguide (AWG)) distributes or distributes light sources according to wavelengths, and distributes light sources according to the spacing of distribution channels. The spacing of the distribution channels is a preset value in the wavelength division multiplex passive optical subscriber network.

Therefore, when the distribution channel interval of the optical wavelength distribution unit 305 is equal to or greater than the interval between the main carrier and the sub carrier of any one of the plurality of second light sources, the optical wavelength distribution unit 305 is the optical wavelength distribution unit 305. When a primary carrier and a subcarrier or subcarriers of both sides are distributed together in any one of the distribution channels of), and the distribution channel spacing of the optical wavelength distribution unit 305 is less than the interval between the main carrier and the subcarrier of the second light source. In the optical wavelength distribution unit 305, the main carrier and the subcarrier are separated and distributed by using two distribution channels.

Hereinafter, a process of passing the first modulated signal modulated by the first modulator 303 to the optical wavelength distributor 305 will be described with reference to FIG. 6.

FIG. 6 is a diagram illustrating a process in which a first modulated signal modulated by the first modulator passes through an optical wavelength distributor according to an embodiment of the present invention and is distributed for each distribution channel.

Referring to FIG. 6, when the distribution channel spacing of the optical wavelength distribution unit 305 is greater than or equal to the interval between the main carrier and the subcarrier, the optical wavelength distribution unit 305 may have a main carrier and a subcarrier in the case of a double sideband carrier or a single sideband carrier. In case of both side band suppressed carriers, the suppressed main carrier and both subcarriers are distributed together.

When the distribution channel spacing of the optical wavelength distribution unit 305 is less than the interval between the main carrier and the subcarrier, the optical wavelength distribution unit 305 is divided into the main carrier and the subcarrier in the case of a bilateral band carrier or a single sideband carrier. In the case of both sideband suppression carriers, subcarriers on both sides are separated and distributed.

At this time, since the carrier is divided into two distribution channels, the second modulator 307 includes the same data stream in two carriers for optical amplification or only one carrier includes the data stream for optical amplification. Can only achieve optical gain using a Fabry-Perot laser diode or a reflective optical amplifier.

Hereinafter, an example of a method of simultaneously modulating a millimeter wave of a wired signal and a wireless signal when the first modulated signal is a bilateral band carrier is described with reference to FIGS. 7 and 8.

7 illustrates an example of a method of using a primary carrier and a subcarrier to modulate a millimeter wave wireless signal and a wired signal together according to an embodiment of the present invention.

Referring to FIG. 7, when the shape of the first modulated signal is a double sideband carrier, the millimeter wave of the radio signal may interact with the main carrier and the subcarriers optically amplified by the second modulator 307 among the subcarriers on both sides. Is generated by

In this case, the second modulator 307 includes a data stream for the wired signal in a subcarrier that is not used when generating the millimeter wave, and optically amplifies the modulated signal for the wired signal.

8 is a diagram illustrating an example of generating and transmitting a wired or wireless millimeter wave heterogeneous signal according to an embodiment of the present invention.

Referring to FIG. 8, the light source generator 301 generates a first light source including main carriers having different wavelengths, and the first modulator 303 uses a first light source to form a first carrier having a bilateral band carrier. Modulate with modulated signal.

The first modulated signal in the form of both side band carriers is distributed through the optical wavelength distribution unit 305 into a subcarrier of a main carrier and a subcarrier wired signal of a radio signal.

In this case, in order to generate a heterogeneous signal of wired and wireless, the spacing of the distribution channel of the optical wavelength distribution unit 305 should have an interval of about twice the spacing between the main carrier and the subcarrier. This is to divide the subcarrier of the wired signal from the main carrier and the subcarrier of the radio signal separately.

The subcarrier of the wired signal includes the data stream of the wired signal through the wired signal modulator 801 and is optically amplified and modulated. The subcarrier of the wireless signal includes the data stream of the wireless signal through the wireless signal modulator 803. Optical amplification is modulated.

The reason for modulating using the subcarrier is because of the characteristics of the optical wavelength distribution unit 305. Due to the wide spacing of the distribution channels of the optical wavelength distribution unit 305, only the subcarriers of the wired signals cannot be completely distributed. Therefore, the subcarriers of the distributed wired signals include some main carriers. If the data stream of the signal is caught, the data stream of the radio signal is affected when the wired signal is modulated.

Therefore, the wired / wireless signal is modulated on the subcarrier, and the distance between the wired signal and the wireless signal can be widened and the interference can be minimized.

As such, the wired signal can be additionally modulated and transmitted, and since there is no influence of interference between the two signals, the millimeter wave can be transmitted by interworking with the existing WDM-PON (wavelength division multiplexing-passive optical network) network capable of transmitting wired signals. Has an advantage. It is economical to construct infrastructure because it can service wired signal and millimeter wave wireless signal with one system without constructing wired transmission network and millimeter wave transmission network separately.

Hereinafter, a process of modulating both sideband carriers having a 30 GHz interval into a wired signal of 1.25 Gbps and a wireless signal of 622 Mbps in order to verify the present invention will be described with reference to FIGS. 9 through 12.

9 is a diagram of an optical spectrum after modulating a wired or wireless millimeter wave heterogeneous signal in a second modulator according to an embodiment of the present invention.

Referring to FIG. 9, FIG. 9A illustrates an optical spectrum after the second modulator 307 modulates a subcarrier of a wired signal. Looking at Figure 9 (a) it can be seen that a part of the main carrier is included. However, since the main carrier does not include the data stream of the radio signal, it is not affected by the radio signal. FIG. 9B is an optical spectrum after the second modulator 307 modulates a subcarrier of a radio signal.

10 is an optical spectrum of a signal in which wired and wireless millimeter wave heterogeneous signals are added and transmitted by an optical wavelength distribution unit according to an embodiment of the present invention.

FIG. 11 is a diagram of an optical spectrum after modulated wired and wireless millimeter wave heterogeneous signals are distributed to a receiving end by an optical wavelength distribution unit according to an embodiment of the present invention.

FIG. 11 (a) shows the optical spectrum after the wired signal is distributed at the receiving end by the optical wavelength distribution unit 305, and FIG. 11 (b) shows the radio signal at the receiving end by the optical wavelength distribution unit 305. It is the light spectrum after it.

Even if the main carrier is not completely removed from the distribution signal of the wired signal due to the distribution characteristic of the optical wavelength distribution unit 305, since no signal is modulated, interference between the wired and wireless millimeter wave signals does not occur.

12 is a diagram of an RF spectrum of a signal restored in a wired network receiver and a wireless network receiver according to an embodiment of the present invention.

12 (a) is an RF spectrum showing a wired signal of 1.25 Gbps restored through all-optical change in the wired network receiving end 811, and FIG. 12 (b) is restored in all-optical change in the millimeter wave wireless network receiving end 813. RF spectrum showing a 622 Mbps wireless millimeter wave signal in a 30 GHz band. The signal in the band near 29.25 GHz is a virtual signal that is independent of the original signal as a result of using an external mixer to measure the RF spectrum in the high frequency millimeter band.

13 is a view showing the overall flow of the millimeter wave generation method according to an embodiment of the present invention. Hereinafter, a process performed at each step will be described with reference to FIG. 13.

First, in step S1300, the light source generating unit 301 generates a first light source including main carriers of different wavelengths.

In operation S1310, the first external modulator 303 may include one or more subcarriers having wavelengths adjacent to each main carrier in a first light source including main carriers having different wavelengths generated by the light source generator 301. It is further included to modulate the first modulated signal.

In this case, the form of the first modulated signal may have any one of a double sideband carrier, a single sideband carrier and a double sideband suppression carrier. It can be chosen freely according to system design and needs.

In operation S1320, the optical wavelength distribution unit 305 includes the one primary carrier and the at least one subcarrier based on the interval of the distribution channel in order to transmit the different data streams for each wavelength. It can distribute to a some 2nd light source.

In other words, when the first modulated signal is a double sideband carrier and a single sideband carrier, the optical wavelength distribution unit 305 may distribute the first modulated signal to include a main carrier and one subcarrier, and the first modulated signal is In the case of both sideband suppression carriers, the optical wavelength distribution unit 305 may distribute the first modulated signal to include both the suppressed main carrier and both subcarriers.

In operation S1330, the second modulator 307 generates a second modulated signal by optically amplifying a subcarrier by including a data stream for each of the plurality of second light sources distributed by the optical wavelength distributor 205.

When the first modulated signal is a bilateral band carrier or a bilateral band suppressed carrier, the second modulator 307 selects one subcarrier from both subcarriers and optically amplifies the second modulated signal.

In operation S1340, the millimeter wave generator 309 interacts the at least one optically amplified subcarrier with the primary carrier or the at least one optically amplified subcarrier with the remaining subcarrier to millimeter wave. Create

For example, when the first modulated signal is a bilateral band carrier or a single sideband carrier, the millimeter wave generator 309 generates the millimeter wave by the interaction between the primary carrier and the optically amplified subcarrier, and the first modulated signal. When is a bilateral band suppressed carrier form, the millimeter wave generator 309 generates a millimeter wave by the interaction between the optically amplified subcarrier and the remaining subcarriers.

As described above, the present invention has been described by specific embodiments such as specific components and the like. For those skilled in the art to which the present invention pertains, various modifications and variations are possible. Therefore, the spirit of the present invention should not be limited to the described embodiments, and all of the equivalents or equivalents of the claims as well as the claims to be described later will belong to the scope of the present invention. .

300: millimeter wave generator 301: light source generation unit
303: first modulator 305: optical wavelength distributor
307: second modulator
501: First light distribution signal 503: Second light distribution signal
505: Third light distribution signal 511: Second modulator A
513: second modulator B 515: second modulator C
801: wired signal modulator 803: wireless signal modulator
811 wired network receiver 813 wireless network receiver

Claims (15)

A first modulator including one or more subcarriers having a wavelength adjacent to each of the main carriers and modulating the first modulated signal into a first light source including main carriers having different wavelengths;
An optical wavelength distribution unit for distributing the first modulated signal to a plurality of second light sources including one primary carrier and at least one subcarrier based on a distance between the distribution channels;
A second modulator for generating a second modulated signal by optically amplifying a data stream in at least one subcarrier of the one or more subcarriers for each of the plurality of second light sources; And
A millimeter wave generator for generating the millimeter wave by interacting the at least one subcarrier with the optical amplification and the main carrier or by interacting the at least one subcarrier with the remaining subcarrier
Including,
The first modulated signal has any one of a form of a double side band carrier, a single side band carrier, and a double side band suppressed carrier, and the second modulated signal has a form of a single side band carrier. Based millimeter wave generator. The method of claim 1,
Further comprising a light source generation unit for generating a first light source including a main carrier of different wavelengths,
The light source generator may include a plurality of distributed feedback (DFB) laser diodes or at least one Fabry-Perot laser diode, and each of the DFB laser diodes or the at least one Fabry-Perot laser diode has a different wavelength. Millimeter wave generation apparatus based on wavelength division multiplexing, characterized in that for generating a light source including a main carrier. The method of claim 1,
When the interval of the distribution channel is equal to or greater than an interval between the main carrier and the subcarrier of any one of the plurality of second light sources, the optical wavelength distribution unit may be connected to the main carrier on one of the distribution channels of the optical wavelength distribution unit. And a wavelength division multiplexing-based millimeter wave generator, wherein the wavelength is divided so that the subcarriers or the subcarriers on both sides are distributed together. The method of claim 1,
When the interval of the distribution channel is less than the interval between the main carrier and the sub-carrier of any one of the plurality of light sources,
And the optical wavelength distribution unit distributes the wavelengths so that the main carrier and the subcarrier are separately divided and distributed by using the two distribution channels. The method of claim 1,
When the form of the first modulated signal is a two-side band carrier including subcarriers on both sides of the main carrier,
The millimeter wave is generated by the interaction between the main carrier and the optically amplified subcarrier of the subcarriers on both sides, and the frequency band of the millimeter wave is determined at an interval between the main carrier and the optically amplified subcarrier. Millimeter wave generator based on wavelength division multiplexing, characterized in that. The method of claim 3,
When the form of the first modulated signal is a single sideband carrier including a subcarrier on one side of the main carrier,
The millimeter wave is generated by the interaction between the main carrier and the optically amplified subcarrier, the frequency band of the millimeter wave is determined by the interval between the main carrier and the subcarrier based on wavelength division multiplexing Millimeter wave generator. The method of claim 1,
When the form of the first modulated signal is the main carrier is suppressed, and both sides of the suppressed carrier including subcarriers on both sides of the suppressed main carrier,
And the millimeter wave is generated by the interaction between the subcarriers on both sides, and the frequency band of the millimeter wave is determined by the interval between the subcarriers on both sides. The method of claim 5,
And the second modulator generates a modulated signal by optically amplifying the subcarrier, which is not used for generating the millimeter wave, by optically amplifying a data stream for a wired signal. The method of claim 8, wherein
When the interval of the distribution channel is equal to or greater than the interval between the main carrier and the sub-carrier of any one of the plurality of light sources,
The optical wavelength distribution unit distributes wavelengths such that the primary carrier and the subcarrier for generating millimeter waves in one of the distribution channels of the optical wavelength distribution unit are distributed so that the subcarriers for the wired signal are distributed in the distribution channel adjacent thereto. Wavelength division multiplexing based millimeter wave generator. The method of claim 1,
When the first modulated signal has the form of a both side band carrier or both side band suppression carrier,
The subcarriers optically amplified by the second modulator among the subcarriers on both sides have the amplified optical power, and the non-amplified subcarriers pass through the second modulator and reduce the optical power due to optical loss. And the second modulated signal has the same shape as a single sideband carrier wave. The method of claim 1,
The second modulator,
And a data stream included in the primary carrier or the remaining subcarriers in addition to the at least one subcarrier to optically amplify a second modulated signal to generate a second modulated signal. The method of claim 1,
And the first modulator performs frequency up-modulation such that the primary carrier has a higher frequency band than the frequency band in which the main carrier is used when modulating the first light source. (A) generating a first light source including main carriers having different wavelengths;
(B) including at least one subcarrier having a wavelength adjacent to each of the primary carriers in the first light source and modulating the first modulated signal;
(C) distributing the first modulated signal to a plurality of second light sources including the one main carrier and at least one subcarrier based on an interval of a distribution channel to transmit different data streams for each wavelength;
(D) generating a second modulated signal by optically amplifying a data stream in at least one subcarrier of the one or more subcarriers for each of the plurality of second light sources; And
(E) generating a millimeter wave by interacting the optically amplified at least one subcarrier with the primary carrier or by interacting the at least one optically amplified subcarrier with the remaining subcarriers (e)
Including,
The first modulated signal is a bilateral band carrier type including subcarriers on both sides of the main carrier, a single sideband carrier type including subcarriers on one side of the main carrier, or the main carrier is suppressed and the suppressed main carrier It has any one of the form of the both side band suppression carrier including the sub-carrier on both sides of,
And the second modulated signal has a form of a single side wave carrier by the optical amplification. The method of claim 13,
The step (d) of generating the millimeter wave,
When the first modulated signal has a bilateral band carrier form,
A millimeter wave is generated using a primary carrier among the two sideband carriers and one subcarrier optically amplified among the subcarriers on both sides,
And generating a modulated signal by optically amplifying a data stream of a wired signal in the subcarrier not used for generating the millimeter wave, thereby generating a modulated signal. The method of claim 13,
When the first modulated signal has the form of a both side band carrier or both side band suppression carrier,
The subcarriers optically amplified by the second modulator among the subcarriers on both sides have the amplified optical power, and the non-amplified subcarriers pass through the second modulator and reduce the optical power due to optical loss. And the second modulated signal has the same form as a single sideband carrier wave.

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