WIRELESS COMMUNICATION METHOD AND WIRELESS COMMUNICATION SYSTEM

Abstract

A wireless communication method in a wireless communication system including an exchange device and a base station device configured to perform beamforming according to the control of the exchange device, in which: the exchange device performs beamforming control of the base station device by transmitting an optically modulated signal to the base station device via an optical transmission line, the optically modulated signal being generated by modulating an intensity of an optical signal on a basis of a transmission signal to be transmitted by controlling any combination of an optical wavelength, a frequency, and an optical polarization or controlling the frequency; and the base station device inputs an electrical signal based on the optically modulated signal to a beamforming circuit having an input port corresponding to the number of combinations of the optical wavelength, the frequency, and the optical polarization or the number of frequencies to perform beamforming in a direction corresponding to the input port to which the electrical signal has been input.

Description

TECHNICAL FIELD

The present invention relates to a wireless communication method and a wireless communication system.

BACKGROUND ART

Conventionally, wireless communication using a millimeter-wave band that allows high-speed transmission has attracted attention. However, in a case where the millimeter-wave band is used, there is a problem that a propagation loss is large and long-distance transmission is difficult. A radio over fiber (RoF) system enables long-distance transmission of a radio frequency signal (RF signal) in the millimeter-wave band, but a coverage area of an antenna unit is a problem. One solution to the problem is beamforming using an array antenna. Techniques disclosed in Patent Literature 1 and Non Patent Literature 1 are proposed as a beamforming technology using the RoF system or an optical technology.

CITATION LIST

Patent Literature

• • Patent Literature 1: JP 4246724 B2

Non Patent Literature

• • Non Patent Literature 1: Dennis T. K. Tong, Ming C. Wu. “A Novel Multiwavelength Optically Controlled Phased Array Antenna with a Programmable Dispersion Matrix”, IEEE Photonics Technology Letters. June 1996, VOL. 8, NO. 6, p. 812-814.

SUMMARY OF INVENTION

Technical Problem

FIG. 19 is an explanatory diagram of an overview of a wireless communication system 100 in Patent Literature 1. The wireless communication system 100 includes an exchange device 200 and a base station device 300. The exchange device 200 and the base station device 300 are connected via an optical fiber 400. The exchange device 200 modulates a plurality of optical signals having a specific wavelength interval output from a multi-wavelength variable light source 201 by using an optical modulator 202 and transmits the modulated optical signals to the base station device 300. At this time, when the optical fiber 400 transmits the optically modulated signals having a plurality of wavelengths, a delay difference different for each wavelength occurs due to an influence of chromatic dispersion.

The base station device 300 demultiplexes the optically modulated signals transmitted from the exchange device 200 for each wavelength by using an optical demultiplexer 301 and converts the optically modulated signals into electrical signals by using O/Es 302-1 to 302-p (p is an integer of 1 or more). The electrical signals are fed to antennas 303-1 to 303-p, but a delay difference also occurs between the electrical signals due to the delay difference caused by the chromatic dispersion generated when the optical fiber 400 has transmitted the signals. Thus, directivity is formed when the electrical signals are radiated as radio waves. Therefore, it is possible to control beam directions by controlling wavelengths of the optical signals output by the multi-wavelength variable light source 201.

However, a wavelength interval of the optical signals needs to be extremely large or small depending on the beam direction, a length of the optical fiber, and a frequency of an RF signal. In the former case, a wavelength band to be used is widened, which may reduce wavelength utilization efficiency. Meanwhile, in the latter case, it is difficult to control the multi-wavelength variable light source 201.

Further, in the technique in Patent Literature 1, in order to dynamically control an optical wavelength to dynamically control the beam direction, it is also necessary to dynamically control a demultiplexing mechanism of the optical demultiplexer 201 included in the base station device 300. Therefore, it is necessary to control the base station device 300, and thus simplification of the base station device 300 is limited. Further, in the technique in Patent Literature 1, distance information of the optical fiber is required for wavelength adjustment for adjusting a delay difference between optical signals. The length of the optical fiber 400 between the exchange device 200 and the base station device 300 is not generally known, or, even if an approximate length thereof is known, an accurate length is not commonly known. Therefore, it is considered that an applicable range of the technique in Patent Literature 1 is limited.

FIG. 20 is an explanatory diagram of the technique disclosed in Non Patent Literature 1. A device in FIG. 20 includes a multi-wavelength variable light source 501, an optical modulator 502, a programmable dispersion matrix (PDM) 503, an optical demultiplexer 504, O/Es 505-1 to 505-p, and antennas 506-1 to 506-p. FIG. 21 illustrates a configuration example of a conventional PDM 503. As illustrated in FIG. 21, the PDM 503 includes a plurality of optical switches 511-1 to 511-q (q is an integer of 2 or more) and a plurality of delay units 512-1 to 512-q. Unlike the technique in Patent Literature 1, the antennas fixedly correspond to different optical wavelengths, respectively, in the technique disclosed in Non Patent Literature 1. Further, the PDM 503 controls a dispersion value, controls a delay difference for each optical wavelength, and controls a beam direction.

Because the optical wavelengths are fixed in the technique disclosed in Non Patent Literature 1, the wavelength utilization efficiency is better than that in Patent Literature 1. Further, optical demultiplexing is also fixed, and thus there is no need to control the optical demultiplexer. However, it is considered that the PDM for controlling dispersion needs to be designed and manufactured with high accuracy, which may increase the size and cost of the device.

Further, there is no reference to application to the RoF in the technique disclosed in Non Patent Literature 1. In order to apply the RoF to the technique disclosed in Non Patent Literature 1 to perform long-distance optical fiber transmission, it is necessary to consider not only dispersion control using the PDM but also an influence of chromatic dispersion during the optical fiber transmission. Further, both the techniques of Patent Literature 1 and Non Patent Literature 1 make reference to beamforming of a transmission antenna, but do not make reference to beamforming of a receiving antenna.

In view of the above circumstances, an object of the present invention is to provide a technique capable of performing beamforming control of a transmission/receiving antenna, without controlling a base station device or using distance information of an optical fiber, while suppressing a decrease in wavelength utilization efficiency and an increase in cost.

Solution to Problem

One aspect of the present invention is a wireless communication method in a wireless communication system including an exchange device and a base station device configured to perform beamforming according to the control of the exchange device, in which: the exchange device performs beamforming control of the base station device by transmitting an optically modulated signal to the base station device via an optical transmission line, the optically modulated signal being generated by modulating an intensity of an optical signal on a basis of a transmission signal to be transmitted by controlling any combination of an optical wavelength, a frequency, and an optical polarization or controlling the frequency; and the base station device inputs an electrical signal based on the optically modulated signal to a beamforming circuit having an input port corresponding to the number of combinations of the optical wavelength, the frequency, and the optical polarization or the number of frequencies to perform beamforming in a direction corresponding to the input port to which the electrical signal has been input.

One aspect of the present invention is a wireless communication system including an exchange device and a base station device configured to perform beamforming according to the control of the exchange device, in which: the exchange device includes a control unit configured to control any combination of an optical wavelength, a frequency, and an optical polarization or controls the frequency, and an optical modulator configured to transmit an optically modulated signal to the base station device via an optical transmission line, the optically modulated signal being generated by modulating an intensity of an optical signal on a basis of a transmission signal to be transmitted on a basis of the any combination of the optical wavelength, the frequency, and the optical polarization or the frequency switched by the control unit; the base station device includes a beamforming circuit having an input port corresponding to the number of combinations of the optical wavelength, the frequency, and the optical polarization or the number of frequencies; and the beamforming circuit performs beamforming in a direction corresponding to the input port to which the electrical signal based on the optically modulated signal has been input.

Advantageous Effects of Invention

According to the present invention, it is possible to perform beamforming control of a transmission/receiving antenna, without controlling a base station device or using distance information of an optical fiber, while suppressing a decrease in wavelength utilization efficiency and an increase in cost.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates a configuration example of a wireless communication system according to a first embodiment.

FIG. 2 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the first embodiment.

FIG. 3 illustrates a configuration example of a wireless communication system according to a second embodiment.

FIG. 4 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the second embodiment.

FIG. 5 illustrates a configuration example of a wireless communication system according to a third embodiment.

FIG. 6 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the third embodiment.

FIG. 7 illustrates a configuration example of a wireless communication system according to a fourth embodiment.

FIG. 8 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the fourth embodiment.

FIG. 9 illustrates a configuration example of a wireless communication system according to a modification example of the fourth embodiment.

FIG. 10 illustrates a configuration example of a wireless communication system according to a fifth embodiment.

FIG. 11 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the fifth embodiment.

FIG. 12 illustrates a configuration example of a wireless communication system according to a sixth embodiment.

FIG. 13 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the sixth embodiment.

FIG. 14 illustrates a configuration example of a wireless communication system according to a seventh embodiment.

FIG. 15 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the seventh embodiment.

FIG. 16 illustrates a configuration example of a wireless communication system according to an eighth embodiment.

FIG. 17 is a sequence diagram illustrating a flow of processing of the wireless communication system according to the eighth embodiment.

FIG. 18 illustrates a configuration example of a wireless communication system according to a modification example of the eighth embodiment.

FIG. 19 is an explanatory diagram of an overview of a wireless communication system in Patent Literature 1.

FIG. 20 is an explanatory diagram of a technique disclosed in Non Patent Literature 1.

FIG. 21 illustrates a configuration example of a conventional PDM.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the present invention will be described with reference to drawings.

First Embodiment

FIG. 1 illustrates a configuration example of a wireless communication system 1 according to a first embodiment. The wireless communication system 1 includes an exchange device 10 and a base station device 20. The exchange device 10 and the base station device 20 are connected via an optical transmission line 30. The optical transmission line 30 is, for example, an optical fiber. The optical transmission line 30 may be one or more single-core fibers or a multi-core fiber having one or more cores. In the following description, a direction from the exchange device 10 toward the base station device 20 will be referred to as a downstream direction, and a direction from the base station device 20 toward the exchange device 10 will be referred to as an upstream direction.

FIG. 1 illustrates a case of one base station device 20, but the wireless communication system 1 may include a plurality of base station devices 20. In this case, the exchange device 10 and the plurality of base station devices 20 may be connected by a passive optical network (PON). In a case where the exchange device 10 and the plurality of base station devices 20 are connected by the PON, an optical splitter (splitting unit) is provided between the exchange device 10 and the plurality of base station devices 20. The optical splitter splits an optical signal output from the exchange device 10 and outputs the split optical signals to the base station devices 20. The passive optical network is, for example, a wavelength division multiplexing passive optical network (WDM-PON) or a time-division multiplexing passive optical network (TDM-PON).

The exchange device 10 remotely controls a beam of the base station device 20 by switching a frequency of a transmission signal. The exchange device 10 remotely controls the beam of the base station device 20 by using an analog RoF technology. Note that the transmission signal may be a base band (BB) signal, an intermediate frequency (IF) signal, or a radio frequency (RF) signal.

The base station device 20 wirelessly radiates a signal transmitted from the exchange device 10.

Next, specific configurations of the exchange device 10 and the base station device 20 will be described.

The exchange device 10 includes a control unit 11, a frequency conversion unit 12, and an optical modulation unit 13.

The control unit 11 selects a frequency according to a direction in which a beam is to be formed in the base station device 20. For example, the control unit 11 selects one or more of m (m is an integer of 1 or more) frequencies f_T1, . . . , and f_Tm.

The frequency conversion unit 12 converts a frequency of an input transmission signal into a frequency f_Ti designated by the control unit 11. Note that i is an integer of 1 or more and m or less.

The optical modulation unit 13 modulates an intensity of an optical signal having a certain wavelength by using the signal having the frequency f_Ti. Thus, the optical modulation unit 13 generates an optically modulated signal. The optical modulation unit 13 transmits the generated optically modulated signal to the base station device 20 via the optical transmission line 30.

The base station device 20 includes an O/E 21, a demultiplexer 22, a plurality of frequency conversion units 23-1 to 23-m, a beamforming circuit 24, and a plurality of antennas 25-1 to 25-N.

The O/E 21 is a photoelectric conversion unit that converts the optically modulated signal received via the optical transmission line 30 into an electrical signal. Therefore, the O/E 21 extracts the electrical signal having the frequency f_Ti.

The demultiplexer 22 demultiplexes the electrical signal extracted by the O/E 21 according to the frequency.

The frequency conversion units 23-1 to 23-m convert frequencies of input electrical signals into frequencies in an RF band.

The beamforming circuit 24 has m input ports and N (N is an integer of 1 or more) output ports. The input ports of the beamforming circuit 24 are connected to the frequency conversion units 23-1 to 23-m. The output ports of the beamforming circuit 24 are connected to the antennas 25-1 to 25-N. The m frequencies f_T1, . . . , and f_Tm have one-to-one correspondence with the m input ports of the beamforming circuit 24 and in transmission beams. Thus, transmission beam directions can be switched by switching the frequency of the transmission signal of the exchange device 10.

When a signal is input to a certain input port, the beamforming circuit 24 outputs signals having the same amplitude and linearly inclined phases from the N output ports. In the beamforming circuit 24, the inclination of the phase varies depending on the input port. The beamforming circuit 24 can form a beam in a direction corresponding to the input port.

The beamforming circuit 24 has input/output reversibility, and, when a signal arrives from a direction of a beam corresponding to a certain input port, the signal is output only from the input port. Examples of the beamforming circuit 24 include a Butler matrix, a Blas matrix, a Nolen matrix, and a Rotman lens (see, for example, Reference literature 1).

(Reference Literature 1: Wei Hong, Zhi Hao Jiang. Chao Yu. Jianyi Zhou, Peng Chen, Zhiqiang Yu, Hui Zhang, Binqi Yang, Xingdong Pang, Mei Jiang, Yujian Cheng. Mustafa K. Taher Al-Nuaimi, Yan Zhang, Jixin Chen, and Shiwen He, “Multibeam antenna technologies for 5G wireless communications”. IEEE Transactions on Antennas and Propagation.” 65(12), 6231-6249 (2017).)

The antennas 25-1 to 25-N wirelessly radiate electrical signals output from the beamforming circuit 24.

FIG. 2 is a sequence diagram illustrating a flow of processing of the wireless communication system 1 according to the first embodiment.

The control unit 11 selects a frequency according to a direction in which a beam is to be formed in the base station device 20 (step S101). For example, the control unit 11 selects one frequency f_Ti from the m frequencies f_T1, . . . , and f_Tm. The control unit 11 controls the frequency conversion unit 12 so as to convert a frequency into the selected frequency f_Ti.

The frequency conversion unit 12 converts a frequency of an input transmission signal into the frequency f_Ti designated by the control unit 11 (step S102). The frequency conversion unit 12 outputs the transmission signal having the frequency f_Ti to the optical modulation unit 13. The optical modulation unit 13 modulates an intensity of an optical signal having a certain wavelength by using the transmission signal having the frequency f_Ti output from the frequency conversion unit 12 (step S103). Thus, the optical modulation unit 13 generates an optically modulated signal. The optical modulation unit 13 transmits the generated optically modulated signal to the optical transmission line 30 (step S104).

The optically modulated signal transmitted to the optical transmission line 30 is input to the base station device 20. The O/E 21 of the base station device 20 converts the input optically modulated signal into an electrical signal (step S105). By this processing, the optically modulated signal is converted into an electrical signal having the frequency f_Ti. The O/E 21 outputs the electrical signal having the frequency f_Ti to the demultiplexer 22. The electrical signal having the frequency f_Ti output to the demultiplexer 22 is demultiplexed according to the frequency (step S106).

Output ports of the demultiplexer 22 are connected to the plurality of frequency conversion units 23-1 to 23-m. For example, the output port of the demultiplexer 22 corresponding to the frequency f_T1 is connected to the frequency conversion unit 23-1, the output port of the demultiplexer 22 corresponding to the frequency fi is connected to the frequency conversion unit 23-i, and the output port of the demultiplexer 22 corresponding to the frequency f_Tm is connected to the frequency conversion unit 23-m. Therefore, the electrical signal demultiplexed for each frequency by the demultiplexer 22 is output to the frequency conversion unit 23 connected to the output port corresponding to the frequency. In FIG. 2, the electrical signal having the frequency f_Ti is demultiplexed by the demultiplexer 22 and is input to the frequency conversion unit 23-i.

The frequency conversion unit 23-i converts the frequency of the input electrical signal into a frequency in the RF band (step S107). The frequency conversion unit 23-i outputs the electrical signal in the RF band to the beamforming circuit 24. The beamforming circuit 24 forms a beam in a direction corresponding to the input port to which the electrical signal has been input. Therefore, a wireless signal is emitted from the antenna 25 connected to an output port corresponding to the input port to which the electrical signal has been input. The antenna 25 connected to the output port corresponding to the input port to which the electrical signal has been input radiates a wireless signal corresponding to the input electrical signal (step S108).

According to the wireless communication system 1 configured as described above, the number of input ports corresponding to frequencies is provided in the beamforming circuit 24 included in the base station device 20. Therefore, it is possible to remotely switch a direction of a transmission beam by switching a frequency of a transmission signal in the exchange device 10. Such a configuration does not use a wavelength for beamforming control. Therefore, it is possible to perform beamforming control of the antennas while suppressing a decrease in wavelength utilization efficiency.

Further, in the wireless communication system 1, control of the base station device 20 and optical fiber distance information are not required by allocating a frequency to the beamforming circuit 24. This makes it possible to simplify the base station device 20.

Modification Example of First Embodiment

The exchange device 10 may form multiple beams in the base station device 20 by simultaneously using a plurality of frequencies to perform subcarrier multiplexing (SCM).

Second Embodiment

A second embodiment is different from the first embodiment in that an exchange device controls an optical wavelength and a frequency to remotely control beamforming in a base station device. In the second embodiment, differences from the first embodiment will be mainly described.

FIG. 3 illustrates a configuration example of a wireless communication system 1a according to the second embodiment. The wireless communication system 1a includes an exchange device 10a and a base station device 20a. The exchange device 10a and the base station device 20a are connected via an optical transmission line 30.

The exchange device 10a includes a control unit 11a, a frequency conversion unit 12, and an optical modulation unit 13a.

The control unit 11a selects a frequency and an optical wavelength according to a direction in which a beam is to be formed in the base station device 20a. For example, the control unit 11a selects one or more of applicable optical wavelengths λ_T1, . . . , and λ_Tn as the optical wavelength to be used by the optical modulation unit 13a. For example, the control unit 11a selects one or more of frequencies f^j_T1, . . . , and f^j_Tmj applicable to an optical wavelength λ_Tj. Here, j is an integer of 1 or more.

The frequency conversion unit 12a converts a frequency of an input transmission signal into a frequency f^j_T1 designated by the control unit 11a.

The optical modulation unit 13a modulates an intensity of an optical signal having the certain wavelength λ_Tj designated by the control unit 11a by using the signal having the frequency f^j_Ti. Thus, the optical modulation unit 13a generates an optically modulated signal having the wavelength λ_Tj. The optical modulation unit 13a transmits the generated optically modulated signal to the base station device 20a via the optical transmission line 30.

The base station device 20a includes an optical demultiplexer 26, a plurality of O/Es 21, a plurality of demultiplexers 22, a plurality of frequency conversion units 23, a beamforming circuit 24, and a plurality of antennas 25-1 to 25-N. Although not illustrated in FIG. 3 for simplification of description, the O/Es 21 and the demultiplexers 22 need to be provided for the number n of optical wavelengths λ_T, and the frequency conversion units 23 need to be provided for the number m_j of frequencies used by the optical wavelength λ_Tj. Therefore, the number of input ports of the beamforming circuit 24 is Σⁿ_j=1m_j.

The optical demultiplexer 26 demultiplexes the optically modulated signal received via the optical transmission line 30 according to the wavelength. For example, the optical demultiplexer 26 is an arrayed waveguide grating (AWG). The optically modulated signal demultiplexer by the optical demultiplexer 26 is input to the O/E 21.

The beamforming circuit 24 has Σⁿ_j=1m_j input ports and N output ports. The input ports of the beamforming circuit 24 are connected to the Σⁿ_j=1m_j frequency conversion units 23. The output ports of the beamforming circuit 24 are connected to the antennas 25-1 to 25-N. Here, Σⁿ_j=1m_j combinations of the optical wavelength λ_Tj and the frequency f^j_Ti have one-to-one correspondence with the Σⁿ_j=1m_j input ports of the beamforming circuit 24 and Σⁿ_j=1m_j transmission beams. Thus, transmission beam directions can be switched by switching the optical wavelength and frequency of the transmission signal of the exchange device 10a.

FIG. 4 is a sequence diagram illustrating a flow of processing of the wireless communication system 1a according to the second embodiment.

The control unit 11a selects a frequency and an optical wavelength according to a direction in which a beam is to be formed in the base station device 20a (step S201). For example, the control unit 11a selects one frequency fin from the frequencies f^j_T1, . . . , and f^j_Tmj. Further, the control unit 11a selects one optical wavelength h, from the optical wavelengths λ_T1, . . . , and λ_Tn. The control unit 11a controls the frequency conversion unit 12a so as to convert a frequency into the selected frequency f^j_Ti. Further, the control unit 11a controls the optical modulation unit 13a so as to modulate a light intensity by using the selected optical wavelength λ_Tj.

The frequency conversion unit 12a converts a frequency of an input transmission signal into the frequency f^j_T1 designated by the control unit 11a (step S202). The frequency conversion unit 12a outputs the transmission signal having the frequency f^j_Ti to the optical modulation unit 13a. The optical modulation unit 13a modulates an intensity with respect to the optical wavelength λ_Tj designated by the control unit 11a by using the transmission signal having the frequency f^j_Ti output from the frequency conversion unit 12a (step S203). Thus, the optical modulation unit 13a generates an optically modulated signal having the optical wavelength λ_Tj. The optical modulation unit 13a transmits the generated optically modulated signal to the optical transmission line 30 (step S204).

The optically modulated signal transmitted to the optical transmission line 30 is input to the base station device 20a. The optical demultiplexer 26 of the base station device 20a demultiplexes the input optically modulated signal having the optical wavelength λ_Tj (step S205). The O/Es 21 are connected to output ports of the optical demultiplexer 26 according to the number of optical wavelengths. Therefore, the optically modulated signal demultiplexed for each wavelength by the optical demultiplexer 26 is output to the O/F 21 connected to the output port corresponding to the wavelength. In FIG. 4, the optically modulated signal having the optical wavelength λ_Tj is demultiplexed by the optical demultiplexer 26 and is input to the O/E 21.

The O/E 21 converts the input optically modulated signal into an electrical signal (step S206). By this processing, the optically modulated signal is converted into an electrical signal having the frequency f^j_Ti. Therefore, the O/E 21 outputs the electrical signal having the frequency f^j_Ti to the demultiplexer 22. The electrical signal having the frequency f^j_Ti output to the demultiplexer 22 is demultiplexed according to the frequency (step S207). The electrical signal demultiplexed by the demultiplexer 22 is input to the frequency conversion unit 23.

The frequency conversion unit 23 converts the frequency of the input electrical signal into a frequency in the RF band (step S208). The frequency conversion unit 23 outputs the electrical signal in the RF band to the beamforming circuit 24. The beamforming circuit 24 forms a beam in a direction corresponding to the input port to which the electrical signal has been input. Therefore, a wireless signal is emitted from the antenna 25 connected to an output port corresponding to the input port to which the electrical signal has been input. The antenna 25 connected to the output port corresponding to the input port to which the electrical signal has been input radiates a wireless signal corresponding to the input electrical signal (step S209).

According to the wireless communication system 1a configured as described above, the number of input ports corresponding to combinations of the frequency and the optical wavelength is provided in the beamforming circuit 24 included in the base station device 20a. Therefore, it is possible to remotely switch a direction of a transmission beam by switching a frequency and optical wavelength of a transmission signal in the exchange device 10a. Such a configuration does not use a wavelength for beamforming control. Therefore, it is possible to perform beamforming control of the antennas while suppressing a decrease in wavelength utilization efficiency.

Modification Example of Second Embodiment

The exchange device 10a may form multiple beams in the base station device 20a by simultaneously using a plurality of optical wavelengths and a plurality of frequencies to perform subcarrier multiplexing and wavelength division multiplexing (WDM).

Third Embodiment

A third embodiment is different from the first embodiment in that an exchange device controls an optical polarization and frequency of a transmission signal to remotely control beamforming in a base station device. In the second embodiment, differences from the first embodiment will be mainly described.

FIG. 5 illustrates a configuration example of a wireless communication system 1b according to the third embodiment. The wireless communication system 1b includes an exchange device 10b and a base station device 20b. The exchange device 10b and the base station device 20b are connected via an optical transmission line 30.

The exchange device 10b includes a control unit 11b, a frequency conversion unit 12b, and an optical modulation unit 13b.

The control unit 11b selects a frequency and an optical polarization according to a direction in which a beam is to be formed in the base station device 20b. For example, the control unit 11b selects one or more of applicable optical polarizations X and Y as the optical polarization to be used by the optical modulation unit 13b. Here, X and Y represent horizontal polarization and vertical polarization, respectively. For example, the control unit 11b selects one or more of frequencies f^k_T1, . . . , and f^k_Tmk applicable to an optical polarization k (k is X or Y).

The frequency conversion unit 12b converts a frequency of an input transmission signal into a frequency f^k_Ti designated by the control unit 11b.

The optical modulation unit 13b modulates an intensity of an optical signal having the certain optical polarization k designated by the control unit 11b by using the signal having the frequency f^k_Ti. Thus, the optical modulation unit 13b generates an optically modulated signal having the optical polarization k. The optical modulation unit 13b transmits the generated optically modulated signal to the base station device 20b via the optical transmission line 30.

The base station device 20b includes a polarization separation unit 27, a plurality of O/Es 21-X and 21-Y, a plurality of demultiplexers 22, a plurality of frequency conversion units 23, a beamforming circuit 24, and a plurality of antennas 25-1 to 25-N. Although not illustrated in FIG. 5 for simplification of description, the demultiplexers 22 need to be provided for the number of (e.g. two) optical polarizations, and the frequency conversion units 23 need to be provided for the total number (m_X+m_Y) of the number m_X of frequencies used by the optical polarization X and the number m_Y of frequencies used by the optical polarization Y. Therefore, the number of input ports of the beamforming circuit 24 is m_X+m_Y.

The polarization separation unit 27 separates an optical polarization k component of the optically modulated signal received via the optical transmission line 30.

The beamforming circuit 24 has (m_X+m_Y) input ports and N output ports. The input ports of the beamforming circuit 24 are connected to the (m_X+m_Y) frequency conversion units 23. The output ports of the beamforming circuit 24 are connected to the antennas 25-1 to 25-N. Here, (m_X+m_Y) combinations of the optical polarization k and the frequency f^k_Ti have one-to-one correspondence with the (m_X+m_Y) input ports of the beamforming circuit 24 and (m_X+m_Y) transmission beams. Thus, transmission beam directions can be switched by switching the optical polarization and frequency of the transmission signal of the exchange device 10b.

FIG. 6 is a sequence diagram illustrating a flow of processing of the wireless communication system 1b according to the third embodiment.

The control unit 11b selects a frequency and an optical polarization according to a direction in which a beam is to be formed in the base station device 20b (step S301). For example, the control unit 11b selects one frequency f^X_Ti from frequencies f^X_T1, . . . , and f^X_Tmj. Further, the control unit 11b selects one optical polarization X from the optical polarizations k. The control unit 11b controls the frequency conversion unit 12b so as to convert a frequency into the selected frequency f^X_Ti. Further, the control unit 11b controls the optical modulation unit 13b so as to modulate a light intensity of an optical signal having the selected optical polarization X.

The frequency conversion unit 12b converts a frequency of an input transmission signal into the frequency f^X_Ti designated by the control unit 11b (step S302). The frequency conversion unit 12b outputs the transmission signal having the frequency f^X_Ti to the optical modulation unit 13b. The optical modulation unit 13b modulates an intensity of the optical signal having the optical polarization X designated by the control unit 11b by using the transmission signal having the frequency f^X_Ti output from the frequency conversion unit 12b (step S303). Thus, the optical modulation unit 13b generates an optically modulated signal having the optical polarization X. The optical modulation unit 13a transmits the generated optically modulated signal to the optical transmission line 30 (step S304).

The optically modulated signal transmitted to the optical transmission line 30 is input to the base station device 20b. The polarization separation unit 27 of the base station device 20b separates an optical polarization k component of the optically modulated signal having the input optical polarization X (step S305). The O/Es 21-X and 21-Y are connected to output ports of the polarization separation unit 27 according to the number of polarizations. Therefore, the optically modulated signal separated by the polarization separation unit 27 is output to the O/E 21-X or 21-Y connected to the output port corresponding to the optical polarization component. In FIG. 6, the optically modulated signal having the optical polarization X is separated by the polarization separation unit 27 and is input to the O/E 21-X.

The O/E 21-X converts the input optically modulated signal into an electrical signal (step S306). By this processing, the optically modulated signal is converted into an electrical signal having the frequency f^X_Ti. Therefore, the O/E 21-X outputs the electrical signal having the frequency f^X_Ti to the demultiplexer 22. The electrical signal having the frequency f^X_Ti output to the demultiplexer 22 is demultiplexed according to the frequency (step S307). The electrical signal demultiplexed by the demultiplexer 22 is input to the frequency conversion unit 23.

The frequency conversion unit 23 converts the frequency of the input electrical signal into a frequency in the RF band (step S308). The frequency conversion unit 23 outputs the electrical signal in the RF band to the beamforming circuit 24. The beamforming circuit 24 forms a beam in a direction corresponding to the input port to which the electrical signal has been input. Therefore, a wireless signal is emitted from the antenna 25 connected to an output port corresponding to the input port to which the electrical signal has been input. The antenna 25 connected to the output port corresponding to the input port to which the electrical signal has been input radiates a wireless signal corresponding to the input electrical signal (step S309).

According to the wireless communication system 1b configured as described above, the number of input ports corresponding to combinations of the frequency and the optical polarization is provided in the beamforming circuit 24 included in the base station device 20b. Therefore, it is possible to remotely switch a direction of a transmission beam by switching a frequency and optical polarization of a transmission signal in the exchange device 10b. Such a configuration does not use a wavelength for beamforming control. Therefore, it is possible to perform beamforming control of the antennas while suppressing a decrease in wavelength utilization efficiency.

Modification Example of Third Embodiment

The exchange device 10b may form multiple beams in the base station device 20b by simultaneously using a plurality of optical polarizations and a plurality of frequencies to perform subcarrier multiplexing and polarization division multiplexing (PDM).

Fourth Embodiment

A fourth embodiment is different from the first embodiment in that an exchange device controls an optical wavelength and optical polarization of a transmission signal to remotely control beamforming in a base station device. In the fourth embodiment, differences from the first embodiment will be mainly described.

FIG. 7 illustrates a configuration example of a wireless communication system 1e according to the fourth embodiment. The wireless communication system 1c includes an exchange device 10c and a base station device 20c. The exchange device 10c and the base station device 20c are connected via an optical transmission line 30.

The exchange device 10c includes a control unit 11c and an optical modulation unit 13c.

The control unit 11c selects a frequency and an optical polarization according to a direction in which a beam is to be formed in the base station device 20c. For example, the control unit 11c selects one or more of applicable optical polarizations X and Y as the optical polarization to be used by the optical modulation unit 13b. For example, the control unit 11c selects one or more of applicable optical wavelengths λ_T1, . . . , and λ_Tn as the optical wavelength to be used by the optical modulation unit 13c.

The optical modulation unit 13c modulates an intensity of a transmission signal in the RF band by using an optical signal having an optical polarization k having a certain optical wavelength λ_Tj. Thus, the optical modulation unit 13c generates an optically modulated signal having the optical polarization k having the optical wavelength λ_Tj. The optical modulation unit 13c transmits the generated optically modulated signal to the base station device 20c via the optical transmission line 30.

The base station device 20c includes an optical demultiplexer 26, a plurality of polarization separation units 27, a plurality of O/Es 21, a beamforming circuit 24, and a plurality of antennas 25-1 to 25-N. Although not illustrated in FIG. 7 for simplification of description, the polarization separation units 27 need to be provided for the number n of optical wavelengths λ_T, and the O/Es 21 need to be provided for the number of (e.g. two) optical polarizations used by the optical wavelength λ_Tj. Therefore, the number of input ports of the beamforming circuit 24 is 2n.

The optical demultiplexer 26 demultiplexes the optically modulated signal received via the optical transmission line 30 according to the wavelength. For example, the optical demultiplexer 26 is an AWG. The optically modulated signal demultiplexed by the optical demultiplexer 26 is input to the polarization separation unit 27.

The polarization separation unit 27 separates an optical polarization k component of the optically modulated signal output from the optical demultiplexer 26.

The beamforming circuit 24 has 2n input ports and N output ports. The input ports of the beamforming circuit 24 are connected to the 2n O/Es 21. The output ports of the beamforming circuit 24 are connected to the antennas 25-1 to 25-N. Here, 2n combinations of the optical wavelength λ_Tj and the optical polarization k have one-to-one correspondence with the 2n input ports of the beamforming circuit 24 and 2n transmission beams. Thus, transmission beam directions can be switched by switching the optical polarization and optical wavelength of the transmission signal of the exchange device 10c.

FIG. 8 is a sequence diagram illustrating a flow of processing of the wireless communication system 1c according to the fourth embodiment.

The control unit 11c selects an optical polarization and an optical wavelength according to a direction in which a beam is to be formed in the base station device 20c (step S401). For example, the control unit 11c selects one optical wavelength λ_Tj from the optical wavelengths λ_T1, . . . , and λ_Tn. Further, the control unit 11c selects one optical polarization X from the optical polarizations k. The control unit 11c controls the optical modulation unit 13c so as to modulate a light intensity of an optical signal having the optical polarization X having the selected optical wavelength λ_Tj.

The optical modulation unit 13c modulates an intensity of a transmission signal by using an optical signal having the optical polarization X having the optical wavelength λ_Tj designated by the control unit 11c (step S402). Thus, the optical modulation unit 13c generates an optically modulated signal having the optical polarization X having the optical wavelength λ_Tj. The optical modulation unit 13c transmits the generated optically modulated signal to the optical transmission line 30 (step S403).

The optically modulated signal transmitted to the optical transmission line 30 is input to the base station device 20c. The optical demultiplexer 26 of the base station device 20c demultiplexes the input optically modulated signal according to the wavelength (step S404). The polarization separation units 27 are connected to output ports of the optical demultiplexer 26 according to the number of wavelengths. Therefore, the optically modulated signal demultiplexed by the optical demultiplexer 26 is output to the polarization separation unit 27 connected to the output port corresponding to the wavelength. In FIG. 8, the optically modulated signal having the optical wavelength λ_Tj is demultiplexed by the optical demultiplexer 26 and is input to the polarization separation unit 27 connected to the output port corresponding to the optical wavelength λ_Tj.

The polarization separation unit 27 separates an optical polarization k component of the optically modulated signal having the optical polarization X (step S405). The O/Es 21 are connected to output ports of the polarization separation units 27 according to the number of optical polarizations. Therefore, the optically modulated signal separated by the polarization separation unit 27 is output to the O/E 21 connected to the output port corresponding to the optical polarization component. In FIG. 8, the optically modulated signal having the optical polarization X is separated by the polarization separation unit 27 and is input to the O/E 21 connected to the output port of the optical polarization X.

The O/E 21 converts the input optically modulated signal into an electrical signal (step S406). By this processing, the optically modulated signal is converted into an electrical signal. The O/E 21 outputs the converted electrical signal to the beamforming circuit 24. The beamforming circuit 24 forms a beam in a direction corresponding to the input port to which the electrical signal has been input. Therefore, a wireless signal is emitted from the antenna 25 connected to an output port corresponding to the input port to which the electrical signal has been input. The antenna 25 connected to the output port corresponding to the input port to which the electrical signal has been input radiates a wireless signal corresponding to the input electrical signal (step S407).

According to the wireless communication system 1c configured as described above, the number of input ports corresponding to combinations of the optical polarization and the optical wavelength is provided in the beamforming circuit 24 included in the base station device 20c. Therefore, it is possible to remotely switch a direction of a transmission beam by switching an optical polarization and optical wavelength of a transmission signal in the exchange device 10c. Such a configuration does not use a wavelength for beamforming control. Therefore, it is possible to perform beamforming control of the antennas while suppressing a decrease in wavelength utilization efficiency.

Modification Example of Fourth Embodiment

The exchange device 10c may form multiple beams in the base station device 20c by simultaneously using a plurality of optical polarizations and a plurality of optical wavelengths to perform wavelength division multiplexing and polarization division multiplexing.

In the configuration of the base station device 20c in FIG. 7, the order of the optical demultiplexer 26 and the polarization separation unit 27 may be switched as illustrated in FIG. 9. FIG. 9 illustrates a configuration example of a wireless communication system 1d according to a modification example of the fourth embodiment. The wireless communication system 1d includes the exchange device 10c and a base station device 20d. The exchange device 10c and the base station device 20d are connected via the optical transmission line 30. The wireless communication system 1d in FIG. 9 is different from the wireless communication system 1c in FIG. 7 in a configuration of the base station device 20d. Other configurations of the wireless communication system 1d are similar to those of the wireless communication system 1c.

The base station device 20d includes the polarization separation unit 27, the optical demultiplexer 26, the plurality of O/Es 21, the beamforming circuit 24, and the plurality of antennas 25-1 to 25-N. Although not illustrated in FIG. 9 for simplification of description, the optical demultiplexers 26 need to be provided for the number of (e.g. two) optical polarizations, and the O/Es 21 need to be provided for the total number (m_X+m_Y) of the number of frequencies m_X used by the optical polarization X and the number of frequencies m_Y used by the optical polarization Y. Therefore, the number of input ports of the beamforming circuit 24 is m_X+m_Y.

The beamforming circuit 24 has (m_X+m_Y) input ports and N output ports. The input ports of the beamforming circuit 24 are connected to the (m_X+m_Y) O/Es 21. The output ports of the beamforming circuit 24 are connected to the antennas 25-1 to 25-N. Here. (m_X+m_Y) combinations of the optical polarization k and the optical wavelength λ_Tj have one-to-one correspondence with the (m_X+m_Y) input ports of the beamforming circuit 24 and (m_X+m_Y) transmission beams. Thus, transmission beam directions can be switched by switching the optical polarization and optical wavelength of the transmission signal of the exchange device loc.

The base station device 20c in FIG. 7 demultiplexes the optically modulated signal received via the optical transmission line 30 and then separates the optical polarization k component, whereas the base station device 20d separates the optical polarization k component of the optically modulated signal received via the optical transmission line 30 and then demultiplexes the optically modulated signal.

Fifth Embodiment

In the first to fourth embodiments, the configurations of signal transmission in the downstream direction have been described. In a fifth embodiment, a configuration of signal transmission in the upstream direction will be described. In the fifth embodiment, a configuration in which a base station device performs subcarrier multiplexing and transmits a signal to an exchange device will be described.

FIG. 10 illustrates a configuration example of a wireless communication system 1e according to the fifth embodiment. The wireless communication system 1e includes an exchange device 10e and a base station device 20e. The exchange device 10e and the base station device 20e are connected via an optical transmission line 30.

The base station device 20e includes a plurality of antennas 31-1 to 31-N, a beamforming circuit 32, a plurality of frequency conversion units 33-1 to 33-m, a multiplexer 34, and an optical modulation unit 35.

The antennas 31-1 to 31-N receive wireless signals transmitted from an external device. The external device is, for example, a wireless device with which the base station device 20e performs communication. The antennas 31-1 to 31-N convert the received wireless signals into electrical signals and output the electrical signals to the beamforming circuit 32.

The beamforming circuit 32, as well as the beamforming circuit 24 in the first embodiment, has m input ports and N output ports. The input ports of the beamforming circuit 32 are connected to the frequency conversion units 33-1 to 33-m. The output ports of the beamforming circuit 32 are connected to the antennas 31-1 to 31-N. The m frequencies f_T1, . . . , and f_Tm have one-to-one correspondence with the m input ports of the beamforming circuit 24 and m received beams. The beamforming circuit 32 receives the electrical signals output from the antennas 31-1 to 31-N via the output ports and outputs the electrical signals to the frequency conversion units 33-1 to 33-m connected to the input ports.

The frequency conversion units 33-1 to 33-m convert frequencies of the input electrical signals. Therefore, the electrical signals input to the frequency conversion units 33-1 to 33-m are converted into signals having a frequency f_Ri.

The multiplexer 34 multiplexes the electrical signals output from the frequency conversion units 33-1 to 33-m.

The optical modulation unit 35 performs subcarrier multiplexing by modulating an intensity of an optical signal having a certain wavelength by using the electrical signal multiplexed by the multiplexer 34. Thus, the optical modulation unit 35 generates a multiplexed signal. The optical modulation unit 35 transmits the generated multiplexed signal to the exchange device 10e via the optical transmission line 30.

The exchange device 10e includes an O/E 14, a demultiplexer 15, and an output unit 16.

The O/E 14 is a photoelectric conversion unit that converts the multiplexed signal received via the optical transmission line 30 into an electrical signal.

The demultiplexer 15 demultiplexes the electrical signal output by the O/H 14 according to the frequency. For example, the demultiplexer 15 demultiplexes the electrical signal into electrical signals having frequencies f_R1, . . . , and f_Rm.

The output unit 16 demodulates the input electrical signals having the frequencies f_R1, . . . , and f_Rm. For example, the output unit 16 may select and demodulate one of the input electrical signals having the frequencies f_R1, . . . , and f_Rm. This is equivalent to selecting one beam from the m received beams. The output unit 16 can also form multiple beams by selecting and simultaneously using a plurality of frequencies. The output unit 16 may perform multiple input multiple output (MIMO) signal processing after demodulating more than one of the input electrical signals having the frequencies f_R1, . . . , and f_Rm.

FIG. 11 is a sequence diagram illustrating a flow of processing of the wireless communication system 1e according to the fifth embodiment.

The antenna 31 receives a wireless signal transmitted from an external device (step S501). The antenna 31 converts the received wireless signal into an electrical signal and outputs the electrical signal to the beamforming circuit 32. The beamforming circuit 32 outputs the electrical signal to the frequency conversion unit 33 connected to the input port corresponding to the output port to which the electrical signal has been input. In FIG. 11, for example, the electrical signal is output from an input port i of the beamforming circuit 32.

The frequency conversion unit 33 connected to the input port i of the beamforming circuit 32 converts a frequency of the electrical signal output from the beamforming circuit 32 (step S502). Therefore, the frequency of the electrical signal is converted into the frequency f_Ri. The frequency conversion unit 33 outputs the electrical signal having the frequency f_Ri to the multiplexer 34. The multiplexer 34 multiplexes the electrical signal output from each frequency conversion unit 33 (step S503). The electrical signal multiplexed by the multiplexer 34 is output to the optical modulation unit 35.

The optical modulation unit 35 performs subcarrier multiplexing by modulating an intensity of an optical signal having a certain wavelength by using the electrical signal multiplexed by the multiplexer 34 (step S504). Thus, the optical modulation unit 35 generates a multiplexed signal. The optical modulation unit 35 transmits the generated multiplexed signal to the exchange device 10e via the optical transmission line 30 (step S505).

The multiplexed signal transmitted to the optical transmission line 30 is input to the exchange device 10e. The O/E 14 of the exchange device 10e converts the input multiplexed signal into an electrical signal (step S506). By this processing, the multiplexed signal is converted into an electrical signal having the frequency f_Ri. The O/E 14 outputs the electrical signal having the frequency f_Ri to the demultiplexer 15. The electrical signal having the frequency f_Ri output to the demultiplexer 15 is demultiplexed according to the frequency (step S507). The electrical signal having the frequency f_Ri demultiplexed by the demultiplexer 15 is input to the output unit 16. The output unit 16 demodulates the input electrical signal having the frequency f_Ri (step S508).

According to the wireless communication system 1e configured as described above, effects similar to those of the first embodiment can be obtained also in the upstream direction.

Sixth Embodiment

A sixth embodiment is different from the fifth embodiment in that a base station device performs subcarrier multiplexing and wavelength division multiplexing and transmits a signal to an exchange device. In the sixth embodiment, differences from the fifth embodiment will be mainly described.

FIG. 12 illustrates a configuration example of a wireless communication system 1f according to the sixth embodiment. The wireless communication system 1f includes an exchange device 10f and a base station device 20f. The exchange device 10f and the base station device 20f are connected via an optical transmission line 30.

The base station device 20f includes a plurality of antennas 31-1 to 31-N, a beamforming circuit 32, a plurality of frequency conversion units 33, a plurality of multiplexers 34, a plurality of optical modulation units 35, and an optical multiplexer 36. Although not illustrated in FIG. 12 for simplification of description, the multiplexers 34 and the optical modulation units 35 need to be provided for the number n of optical wavelengths 4, and the frequency conversion units 33 need to be provided for the number m_j of frequencies used by an optical wavelength λ_Rj. Therefore, the number of input ports of the beamforming circuit 32 is Σⁿ_j=1m_j.

The optical multiplexer 36 multiplexes signals subjected to subcarrier multiplexing by the optical modulation units 35 and performs wavelength division multiplexing. Thus, the optical multiplexer 36 generates a wavelength-division multiplexed signal. The optical multiplexer 36 transmits the generated wavelength-division multiplexed signal to the exchange device 10f via the optical transmission line 30.

The beamforming circuit 32, as well as the beamforming circuit 24 in the second embodiment, has Σⁿ_j=1m_j input ports and N output ports. The input ports of the beamforming circuit 32 are connected to the Σⁿ_j=1m_j frequency conversion units 33. The output ports of the beamforming circuit 32 are connected to the antennas 31-1 to 31-N. Here. Σⁿ_j=1m_j combinations of the optical wavelength λ_Rj and a frequency f^j_Ri have one-to-one correspondence with the Σⁿ_j=1m_j input ports of the beamforming circuit 32 and Σⁿ_j=1m_j received beams. The beamforming circuit 32 receives electrical signals output from the antennas 31-1 to 31-N via the output ports and outputs the electrical signals to the frequency conversion units 33 connected to the input ports.

The exchange device 10f includes an optical demultiplexer 17, a plurality of O/Es 14, a plurality of demultiplexers 15, and an output unit 16. Although not illustrated in FIG. 3 for simplification of description, the O/Es 14 and the demultiplexers 15 need to be provided for the number n of optical wavelengths λ_R.

The optical demultiplexer 17 demultiplexes the wavelength-division multiplexed signal received via the optical transmission line 30 according to the wavelength. For example, the optical demultiplexer 17 is an AWG. The multiplexed signal demultiplexed by the optical demultiplexer 17 is input to the O/E 14.

FIG. 13 is a sequence diagram illustrating a flow of processing of the wireless communication system 1f according to the sixth embodiment.

The antenna 31 receives a wireless signal transmitted from an external device (step S601). The antenna 31 converts the received wireless signal into an electrical signal and outputs the electrical signal to the beamforming circuit 32. The beamforming circuit 32 outputs the electrical signal to the frequency conversion unit 33 connected to the input port corresponding to the output port to which the electrical signal has been input.

Each frequency conversion unit 33 converts a frequency of the electrical signal output from the input port into the frequency f^j_Ri corresponding to the optical wavelength λ_Rj (step S602). The frequency conversion unit 33 outputs the electrical signal having the frequency f^j_Ri to the multiplexer 34. The multiplexer 34 multiplexes the electrical signal output from each frequency conversion unit 33 (step S603). The electrical signal multiplexed by the multiplexer 34 is output to the optical modulation unit 35.

The optical modulation unit 35 performs subcarrier multiplexing by modulating an intensity of an optical signal having a certain wavelength by using the electrical signal multiplexed by the multiplexer 34 (step S604). Thus, the optical modulation unit 35 generates a multiplexed signal. The optical modulation unit 35 outputs the generated multiplexed signal to the optical multiplexer 36. The optical multiplexer 36 multiplexes the multiplexed signal generated by each optical modulation unit 35 and performs wavelength division multiplexing (step S605). Thus, the optical multiplexer 36 generates a wavelength-division multiplexed signal. The optical multiplexer 36 transmits the generated wavelength-division multiplexed signal to the exchange device 10f via the optical transmission line 30 (step S606).

The wavelength-division multiplexed signal transmitted to the optical transmission line 30 is input to the exchange device 10f. The optical demultiplexer 17 of the exchange device 10f demultiplexes the input wavelength-division multiplexed signal according to the wavelength (step S607). Thus, the wavelength-division multiplexed signal becomes an optically modulated signal having the optical wavelength λ_Rj and is output to the corresponding O/E 14. The O/Es 14 are connected to the optical demultiplexer 17 according to the number of wavelengths. The O/E 14 converts the optically modulated signal having the optical wavelength λ_Rj demultiplexed by the optical demultiplexer 17 into an electrical signal (step S608). By this processing, the optically modulated signal having the optical wavelength λ_Rj is converted into an electrical signal having the frequency f^j_Ri. The O/F 14 outputs the electrical signal having the frequency f^j_Ri to the demultiplexer 15.

The electrical signal having the frequency f^j_Ri output to the demultiplexer 15 is demultiplexed according to the frequency (step S609). The electrical signal having the frequency fi demultiplexed by the demultiplexer 15 is input to the output unit 16. The output unit 16 demodulates the input electrical signal having the frequency f^j_Ri (step S610). For example, the output unit 16 may select and demodulate one of the Σⁿ_j=1m_j combinations of the optical wavelength λ_Rj and the frequency f^j_Ri. This is equivalent to selecting one beam from the Σⁿ_j=1m_j received beams. The output unit 16 can also form multiple beams by selecting and simultaneously using a plurality of frequencies and a plurality of optical wavelengths. The output unit 16 may perform MIMO signal processing after demodulating more than one of the input electrical signals having the frequencies f^j_R1, . . . , and f^j_Rm.

According to the wireless communication system 1f configured as described above, effects similar to those of the second embodiment can be obtained also in the upstream direction.

Seventh Embodiment

A seventh embodiment is different from the fifth embodiment in that a base station device performs subcarrier multiplexing and polarization division multiplexing and transmits a signal to an exchange device. In the seventh embodiment, differences from the fifth embodiment will be mainly described.

FIG. 14 illustrates a configuration example of a wireless communication system 1g according to the seventh embodiment. The wireless communication system 1g includes an exchange device 10g and a base station device 20g. The exchange device 10g and the base station device 20g are connected via an optical transmission line 30.

The base station device 20g includes a plurality of antennas 31-1 to 31-N, a beamforming circuit 32, a plurality of frequency conversion units 33, a plurality of multiplexers 34, a plurality of optical modulation units 35, and a polarization multiplexer 37. Although not illustrated in FIG. 14 for simplification of description, the optical modulation units 35 and the multiplexers 34 need to be provided for the number of (e.g. two) optical polarizations, and the frequency conversion units 33 need to be provided for the total number (m_X+m_Y) of the number of frequencies m_X used by the optical polarization X and the number of frequencies m_Y used by the optical polarization Y. Therefore, the number of input ports of the beamforming circuit 32 is m_X+m_Y.

The polarization multiplexer 37 multiplexes signals subjected to subcarrier multiplexing by the plurality of optical modulation units 35 and performs polarization division multiplexing. Thus, the polarization multiplexer 37 generates a polarization-division multiplexed signal. The polarization multiplexer 37 transmits the generated polarization-division multiplexed signal to the exchange device 10g via the optical transmission line 30.

The beamforming circuit 32, as well as the beamforming circuit 24 in the third embodiment, has (m_X+m_Y) input ports and N output ports. The input ports of the beamforming circuit 32 are connected to the (m_X+m_Y) frequency conversion units 33. The output ports of the beamforming circuit 32 are connected to the antennas 31-1 to 31-N. Here, (m_X+m_Y) combinations of an optical polarization k and a frequency f^k_Ri have one-to-one correspondence with the (m_X+m_Y) input ports of the beamforming circuit 32 and (m_X+m_Y) received beams. The beamforming circuit 32 receives electrical signals output from the antennas 31-i to 31-N via the output ports and outputs the electrical signals to the frequency conversion units 33 connected to the input ports.

The exchange device 10g includes a polarization separation unit 18, a plurality of O/Es 14-X and 14-Y, a plurality of demultiplexers 15, and an output unit 16. Although not illustrated in FIG. 14 for simplification of description, the O/Es 14 and the demultiplexers 15 need to be provided for the number of (e.g. two) optical polarizations.

The polarization separation unit 18 separates an optical polarization k component of the polarization-division multiplexed signal received via the optical transmission line 30.

FIG. 15 is a sequence diagram illustrating a flow of processing of the wireless communication system 1g according to the seventh embodiment.

The antenna 31 receives a wireless signal transmitted from an external device (step S701). The antenna 31 converts the received wireless signal into an electrical signal and outputs the electrical signal to the beamforming circuit 32. The beamforming circuit 32 outputs the electrical signal to the frequency conversion unit 33 connected to the input port corresponding to the output port to which the electrical signal has been input.

Each frequency conversion unit 33 converts a frequency of the electrical signal output from the input port into the frequency f^k_Ri corresponding to the optical polarization k (step S702). The frequency conversion unit 33 outputs the electrical signal having the frequency f Ki to the multiplexer 34. The multiplexer 34 multiplexes the electrical signal output from each frequency conversion unit 33 (step S703). The electrical signal multiplexed by the multiplexer 34 is output to the optical modulation unit 35.

The optical modulation unit 35 performs subcarrier multiplexing by modulating an intensity of an optical signal having the optical polarization k by using the electrical signal multiplexed by the multiplexer 34 (step S704). Thus, the optical modulation unit 35 generates a multiplexed signal. The optical modulation unit 35 outputs the generated multiplexed signal to the polarization multiplexer 37. The polarization multiplexer 37 multiplexes the multiplexed signal generated by each optical modulation unit 35 and performs polarization division multiplexing (step S705). Thus, the polarization multiplexer 37 generates a polarization-division multiplexed signal. The polarization multiplexer 37 transmits the generated polarization-division multiplexed signal to the exchange device 10g via the optical transmission line 30 (step S706).

The polarization-division multiplexed signal transmitted to the optical transmission line 30 is input to the exchange device 10g. The polarization separation unit 18 of the exchange device 10g separates the optical polarization k of the input polarization-division multiplexed signal (step S707). Thus, the polarization-division multiplexed signal becomes an optically modulated signal having the optical polarization k and is output to the corresponding O/E 14. The O/E 14 converts the optically modulated signal having the optical polarization k separated by the polarization separation unit 18 into an electrical signal (step S708). By this processing, the optically modulated signal having the optical polarization k is converted into an electrical signal having the frequency f^k_Ri. The O/E 14 outputs the electrical signal having the frequency f^k_Ri to the demultiplexer 15.

The electrical signal having the frequency f^k_Ri output to the demultiplexer 15 is demultiplexed according to the frequency (step S709). The electrical signal having the frequency f^k_Ri demultiplexed by the demultiplexer 15 is input to the output unit 16. The output unit 16 demodulates the input electrical signal having the frequency f^k_Ri (step S710). For example, the output unit 16 may select and demodulate one of the (m_X+m_Y) combinations of the optical polarization k and the frequency f^k_Ri. This is equivalent to selecting one beam from the (m_X+m_Y) received beams. The output unit 16 can also form multiple beams by selecting and simultaneously using a plurality of frequencies and a plurality of optical polarizations. The output unit 16 may perform MIMO signal processing after demodulating more than one of the input electrical signals having the frequencies f^k_R1, . . . , and f^k_Rm.

According to the wireless communication system 1g configured as described above, effects similar to those of the third embodiment can be obtained also in the upstream direction.

Eighth Embodiment

An eighth embodiment is different from the fifth embodiment in that a base station device performs wavelength division multiplexing and polarization division multiplexing and transmits a signal to an exchange device. In the eighth embodiment, differences front the fifth embodiment will be mainly described.

FIG. 16 illustrates a configuration example of a wireless communication system 1h according to the eighth embodiment. The wireless communication system 1h includes an exchange device 10h and a base station device 20h. The exchange device 10h and the base station device 20h are connected via an optical transmission line 30.

The base station device 20h includes a plurality of antennas 31-1 to 31-N, a beamforming circuit 32, a plurality of optical modulation units 35, a plurality of polarization multiplexers 37, and an optical multiplexer 36. Although not illustrated in FIG. 16 for simplification of description, the polarization multiplexers 37 need to be provided for the number n of optical wavelengths λ_R, and the optical modulation units 35 need to be provided for the number of (e.g. two) polarizations used by an optical wavelength λ_Rj. Therefore, the number of input ports of the beamforming circuit 32 is 2n.

The polarization multiplexer 37 multiplexes signals subjected to subcarrier multiplexing by the plurality of optical modulation units 35 and performs polarization division multiplexing. Thus, the polarization multiplexer 37 generates a polarization-division multiplexed signal.

The optical multiplexer 36 multiplexes signals subjected to polarization division multiplexing by the polarization multiplexer 37 and performs wavelength division multiplexing. Thus, the optical multiplexer 36 generates a wavelength-division multiplexed signal. The optical multiplexer 36 transmits the generated wavelength-division multiplexed signal to the base station device 20b via the optical transmission line 30.

The beamforming circuit 32, as well as the beamforming circuit 24 in the fourth embodiment, has 2n input ports and N output ports. The input ports of the beamforming circuit 32 are connected to the 2n optical modulation units 35. The output ports of the beamforming circuit 32 are connected to the antennas 31-1 to 31-N. Here, 2n combinations of the optical wavelength λ_Rj and an optical polarization k have one-to-one correspondence with the 2n input ports of the beamforming circuit 32 and 2n received beams. The beamforming circuit 32 receives electrical signals output from the antennas 31-1 to 31-N via the output ports and outputs the electrical signals to the optical modulation units 35 connected to the input ports.

The exchange device 10h includes an optical demultiplexer 17, a plurality of polarization separation units 18, a plurality of O/Es 14, and an output unit 16. Although not illustrated in FIG. 16 for simplification of description, the polarization separation units 18 need to be provided for the number n of optical wavelengths 4, and the O/Es 14 need to be provided for the number of (e.g. two) optical polarizations used by the optical wavelength λ_Rj.

The optical demultiplexer 17 demultiplexes the wavelength-division multiplexed signal received via the optical transmission line 30.

The polarization separation unit 18 separates an optical polarization k component of the optically modulated signal demultiplexed by the optical demultiplexer 17.

FIG. 17 is a sequence diagram illustrating a flow of processing of the wireless communication system 1h according to the eighth embodiment. In FIG. 17, the same processing steps as those in FIG. 11 will be denoted by the same reference signs as those used in FIG. 11, and description thereof will be omitted.

The antenna 31 receives a wireless signal transmitted from an external device (step S801). The antenna 31 converts the received wireless signal into an electrical signal and outputs the electrical signal to the beamforming circuit 32. The beamforming circuit 32 outputs the electrical signal to the optical modulation unit 35 connected to the input port corresponding to the output port to which the electrical signal has been input.

Each optical modulation unit 35 modulates an intensity of an optical signal having the optical wavelength λ_Rj and the optical polarization k by using the electrical signal output from the input port (step S802). The optical modulation unit 35 outputs the generated optically modulated signal having the optical polarization k to the polarization multiplexer 37.

The polarization multiplexer 37 multiplexes the optically modulated signal generated by each optical modulation unit 35 and performs polarization division multiplexing (step S803). Thus, the polarization multiplexer 37 generates a polarization-division multiplexed signal. The polarization multiplexer 37 outputs the generated polarization-division multiplexed signal to the optical multiplexer 36. The optical multiplexer 36 multiplexes the polarization-division multiplexed signal generated by each polarization multiplexer 37 and performs wavelength division multiplexing (step S804). Thus, the optical multiplexer 36 generates a wavelength-division multiplexed signal. The optical multiplexer 36 transmits the generated wavelength-division multiplexed signal to the exchange device 10g via the optical transmission line 30 (step S805).

The wavelength-division multiplexed signal transmitted to the optical transmission line 30 is input to the exchange device 10h. The optical demultiplexer 17 of the exchange device 10h demultiplexes the input wavelength-division multiplexed signal according to the wavelength (step S806). Thus, the wavelength-division multiplexed signal becomes an optically modulated signal having the optical wavelength λ_Rj and is output to the corresponding polarization separation unit 18. The polarization separation unit 18 separates the optical polarization k of the input optically modulated signal having the optical wavelength λ_Rj (step S807). Thus, the optically modulated signal having the optical wavelength λ_Rj becomes an optically modulated signal having the optical polarization k and is output to the corresponding O/E 14. The O/E 14 converts the optically modulated signal having the optical polarization k separated by the polarization separation unit 18 into an electrical signal (step S808). By this processing, the optically modulated signal having the optical polarization k is converted into an electrical signal. The O/E 14 outputs the electrical signal to the output unit 16.

The output unit 16 demodulates the input electrical signal (step S809). For example, the output unit 16 may select and demodulate one of the 2n combinations of the optical wavelength λ_Rj and the optical polarization k. This is equivalent to selecting one beam from the 2n received beams. The output unit 16 can also form multiple beams by selecting and simultaneously using a plurality of optical wavelengths and a plurality of optical polarizations. The output unit 16 may perform MIMO signal processing after demodulating more than one of the input electrical signals.

According to the wireless communication system if configured as described above, effects similar to those of the fourth embodiment can be obtained also in the upstream direction.

Modification Example of Eighth Embodiment

The exchange device 10h and the base station device 20h in FIG. 16 may be configured as illustrated in FIG. 18. FIG. 18 illustrates a configuration example of a wireless communication system 1i according to a modification example of the eighth embodiment. The wireless communication system 1i includes an exchange device 10i and a base station device 20i. The exchange device 10i and the base station device 20i are connected via the optical transmission line 30.

The base station device 20i includes the plurality of antennas 31-1 to 31-N, the beamforming circuit 32, the plurality of optical modulation units 35, the plurality of optical multiplexers 36, and the polarization multiplexer 37. Although not illustrated in FIG. 18 for simplification of description, the optical multiplexers 36 need to be provided for the number of (e.g. two) polarizations, and the optical modulation units 35 need to be provided for the total number (m_X+m_Y) of the number of frequencies m_X used by the optical polarization X and the number of frequencies m_Y used by the optical polarization Y. Therefore, the number of input ports of the beamforming circuit 24 is m_X+m_Y.

The beamforming circuit 32 has (m_X+m_Y) input ports and N output ports. The input ports of the beamforming circuit 32 are connected to the (m_X+m_Y) optical modulation units 35. The output ports of the beamforming circuit 32 are connected to the antennas 31-1 to 31-N. Here, (m_X+m_Y) combinations of the optical polarization k and the optical wavelength λ_Tj have one-to-one correspondence with the (m_X+m_Y) input ports of the beamforming circuit 32 and (m_X+m_Y) received beams.

The exchange device 10i includes the polarization separation unit 18, the plurality of optical demultiplexers 17, the plurality of O/Es 14, and the output unit 16. Although not illustrated in FIG. 18 for simplification of description, the optical demultiplexers 17 need to be provided for the number n of optical wavelengths λ_R, and the O/Es 14 need to be provided for the number of (e.g. two) optical polarizations used by the optical wavelength λ_Rj.

In the base station device 20h in FIG. 16, the wavelength division multiplexing is performed after the polarization division multiplexing, whereas, in the base station device 20i, the polarization division multiplexing is performed after the wavelength division multiplexing. In the exchange device 10i, the polarization separation unit 18 separates the optical polarization k component of the polarization-division multiplexed signal received via the optical transmission line 30, and then the optical demultiplexer 17 demultiplexes the signal according to the wavelength.

Modification Examples of First to Eighth Embodiments

The configurations in the first to fourth embodiments and the configurations in the fifth to eighth embodiments may be combined. For example, the first embodiment and the fifth embodiment may be combined. In this case, the exchange device 10 and the exchange device 10e are combined as the exchange device, and the base station device 20 and the base station device 20e are combined as the base station device. For example, the second embodiment and the sixth embodiment may be combined. For example, the third embodiment and the seventh embodiment may be combined. For example, the fourth embodiment and the eighth embodiment may be combined.

The first to eighth embodiments show the configurations of controlling only the frequency, controlling the frequency and the optical wavelength, controlling the frequency and the optical polarization, and controlling the optical polarization and the optical wavelength. In the first to eighth embodiments, all of the optical polarization, the optical wavelength, and the frequency may be controlled. In such a configuration, in a case of transmission in the downstream direction, it is only necessary to combine the configuration in the first embodiment and the configuration in the fourth embodiment so as to control all of the optical polarization, the optical wavelength, and the frequency. In a case of transmission in the upstream direction, it is only necessary to combine the configuration in the fifth embodiment and the configuration in the eighth embodiment so as to control all of the optical polarization, the optical wavelength, and the frequency.

Some functional units of the exchange devices 10, 10a, 10b, 10c, 10d, 10e, 10f, 10g, 10h, and 10i and the base station devices 20, 20a, 20b, 20c, 20d, 20e, 20f, 20g, 20h, and 20i in the above embodiments may be implemented by a computer. In that case, a program for implementing those functions may be recorded in a computer-readable recording medium, and the program recorded in the recording medium may be read and executed by a computer system to implement the functions. The “computer system” herein includes an OS and hardware such as a peripheral device.

The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disc, a ROM, or a CD-ROM or a storage device such as a hard disk included in the computer system. Further, the “computer-readable recording medium” may include a medium that dynamically holds the program for a short time, such as a communication line used to transmit the program via a network such as the Internet or a communication line such as a telephone line, and a medium that holds the program for a certain period of time, such as a volatile memory inside the computer system serving as a server or a client in that case. Further, the above program may be for implementing some of the above functions, may implement the above functions in combination with a program already recorded in the computer system, or may be implemented by using a programmable logic device such as an FPGA.

Hereinabove, the embodiments of the present invention have been described in detail with reference to the drawings, but specific configurations are not limited to those embodiments and include designs and the like within the spirit of the present invention.

INDUSTRIAL APPLICABILITY

The present invention is applicable to a wireless communication system that performs analog RoF transmission.

REFERENCE SIGNS LIST

• • 10, 10a, 10b, 10c, 10d, 10e, 10f, 10g, 10h, 10i Exchange device
  • 11, 11a, 11b Control unit
  • 12, 12a, 12b Frequency conversion unit
  • 13, 13a, 13b Optical modulation unit
  • 14 O/E
  • 15 Demultiplexer
  • 16 Output unit
  • 20, 20a, 20b, 20c, 20d, 20e, 20f, 20g, 20h, 20i Base station device
  • 21 O/E
  • 22 Demultiplexer
  • 23-1 to 23-m, 33 Frequency conversion unit
  • 24 Beamforming circuit
  • 25-1 to 25-N. 31-1 to 31-N Antenna
  • 26 Optical demultiplexer
  • 27 Polarization separation unit
  • 34 Multiplexer
  • 36 Optical multiplexer
  • 37 Polarization multiplexer

Claims

1. A wireless communication method in a wireless communication system including an exchange device and a base station device configured to perform beamforming according to control of the exchange device, wherein: the exchange device performs beamforming control of the base station device by transmitting an optically modulated signal to the base station device via an optical transmission line, the optically modulated signal being generated by modulating an intensity of an optical signal on a basis of a transmission signal to be transmitted by controlling any combination of an optical wavelength, a frequency, and an optical polarization or controlling the frequency; andthe base station device inputs an electrical signal based on the optically modulated signal to a beamforming circuit having an input port corresponding to the number of combinations of the optical wavelength, the frequency, and the optical polarization or the number of frequencies to perform beamforming in a direction corresponding to the input port to which the electrical signal has been input.

2. The wireless communication method according to claim 1, wherein: the exchange device performs the beamforming control of the base station device by transmitting the optically modulated signal to the base station device, the optically modulated signal being generated by controlling the frequency to convert a frequency of the transmission signal and modulating the intensity of the optical signal on the basis of the transmission signal having the converted frequency; andthe base station device converts the optically modulated signal into the electrical signal, then demultiplexes the electrical signal according to the frequency, and inputs the electrical signal to the beamforming circuit to perform beamforming.

3. The wireless communication method according to claim 1, wherein: the exchange device performs the beamforming control of the base station device by transmitting the optically modulated signal to the base station device, the optically modulated signal being generated by controlling the combination of the optical wavelength and the frequency to convert a frequency of the transmission signal and modulating the intensity of the optical signal having the controlled optical wavelength on the basis of the transmission signal having the converted frequency; andthe base station device demultiplexes the optically modulated signal according to the wavelength, converts the optically modulated signal demultiplexed for each wavelength into an electrical signal, demultiplexes the electrical signal according to the frequency, and inputs the electrical signal to the beamforming circuit to perform beamforming.

4. The wireless communication method according to claim 1, wherein: the exchange device performs the beamforming control of the base station device by transmitting the optically modulated signal to the base station device, the optically modulated signal being generated by controlling the combination of the optical polarization and the frequency to convert a frequency of the transmission signal and modulating the intensity of the optical signal having the controlled optical polarization on the basis of the transmission signal having the converted frequency; andthe base station device separates an optical polarization component of the optically modulated signal, converts the optically modulated signal separated for each optical polarization component into an electrical signal, demultiplexes the electrical signal according to the frequency, and inputs the electrical signal to the beamforming circuit to perform beamforming.

5. The wireless communication method according to claim 1, wherein: the exchange device performs the beamforming control of the base station device by transmitting the optically modulated signal to the base station device, the optically modulated signal being generated by controlling the combination of the optical polarization and the optical wavelength to modulate the intensity of the optical signal having the optical polarization having the controlled optical wavelength by using the transmission signal; andthe base station device demultiplexes the optically modulated signal according to the wavelength and then separates an optical polarization component of the optically modulated signal demultiplexed for each wavelength or separates the optical polarization component of the optically modulated signal and then demultiplexes the optically modulated signal separated for each optical polarization component according to the wavelength, converts the optically modulated signal into an electrical signal, and inputs the electrical signal to the beamforming circuit to perform beamforming.

6. The wireless communication method according to claim 1, wherein: the exchange device performs the beamforming control of the base station device by transmitting the optically modulated signal to the base station device, the optically modulated signal being generated by controlling the combination of the optical polarization, the frequency, and the optical wavelength to convert a frequency of the transmission signal and modulating the intensity of the optical signal having the optical polarization having the controlled optical wavelength on the basis of the transmission signal having the converted frequency; andthe base station device inputs the electrical signal obtained on the basis of the optically modulated signal to the beamforming circuit to perform beamforming.

7. The wireless communication method according to claim 1, wherein: the base station device converts a wireless signal transmitted from an external device into an electrical signal, inputs the electrical signal to an output port of the beamforming circuit, outputs the electrical signal from the input port of the beamforming circuit corresponding to the output port, and transmits, to the exchange device, an optical signal whose intensity has been modulated by using the electrical signal; andthe exchange device demodulates the optical signal transmitted from the base station device.

8. A wireless communication system including an exchange device and a base station device configured to perform beamforming according to the control of the exchange device, wherein: the exchange device includesa controller configured to control any combination of an optical wavelength, a frequency, and an optical polarization or controls the frequency, andan optical modulator configured to transmit an optically modulated signal to the base station device via an optical transmission line, the optically modulated signal being generated by modulating an intensity of an optical signal on a basis of a transmission signal to be transmitted on a basis of the any combination of the optical wavelength, the frequency, and the optical polarization or the frequency switched by the controller;the base station device includesa beamforming circuit having an input port corresponding to the number of combinations of the optical wavelength, the frequency, and the optical polarization or the number of frequencies; andthe beamforming circuit performs beamforming in a direction corresponding to the input port to which the electrical signal based on the optically modulated signal has been input.