JP2003348641A - Wireless communication system and terminal station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily recognize a frequency channel used by its own wireless communication system and efficiently use a time region and a plurality of frequency channels in a wireless communication system adopting the distribution control method. <P>SOLUTION: When a first terminal station 11 is going to transmit data to a second terminal station 12, the first terminal station 11 selects the number of frequency channels used for communication on the basis of the information denoting a free frequency channel and a communication capacity, and transmits a transmission request signal including the information associated with the number of frequency channels to the second terminal station 12. The second terminal station 12 transmits a data transmission permission signal including the information of the frequency channel and the signal frequency bandwidth decided by the information included in the received transmission request signal and the information denoting the number of frequency channels for simultaneous communication by its own terminal. The first terminal station 11 transmits a data signal to the second terminal station 12 on the basis of the information included in the data transmission permission signal, and when the second terminal station 12 normally receives the data signal, the second terminal station 12 transmits a data signal reception completion signal. <P>COPYRIGHT: (C)2004,JPO

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio communication system and a terminal station constituting the radio communication system, and more particularly to a distributed control radio communication system.

[0002]

2. Description of the Related Art In recent years, a plurality of low-power wireless communication systems using a 5-GHz band and requiring no license have been proposed and standardized, and have actually been used in IEEE 802.11a and ARIB (American Radio Industry Association).
Wireless communication systems using the Hi-SWAN standard or the like have been developed.

[0003]

However, the 5.15 GHz band already approved for low-power wireless communication systems is used.
In the 5.25 GHz band, the frequency band is 20 MHz.
(Occupied signal frequency band is 18 MHz) There are only four frequency channels, and if a large number of wireless communication terminals or a plurality of wireless communication systems exist in the same area, there is a possibility that a decrease in throughput due to radio wave interference may occur. is there. Also, originally, the wireless communication system,
This system assumes that communication is performed using only one channel.

[0004] Recently, there has been a movement to release frequencies in a higher frequency band, and a low power radio communication system using a quasi-millimeter wave band of 25 GHz band or 27 GHz band has been permitted under the Radio Law and standardization has been promoted. I have. Conventionally, a frequency band limited to other uses is released by imposing a limit on electric power.

According to the frequency allocation plan updated by the Ministry of Internal Affairs and Communications on February 28, 2002, for example, a system in a personal area assuming outdoor Internet access at a hot spot such as a station or a coffee shop is 24.77.
Using a 460 MHz frequency band from GHz to 25.23 GH (excluding upper and lower 20 MHz guard bands), 23 radio channels can be arranged at a frequency interval of 20 MHz (the occupied signal frequency band per channel is 18 MHz), Simultaneous transmission of up to three consecutive channels is possible. Furthermore, from 27.02 GHz to 27.4
Up to 6 GHz (excluding upper and lower 20 MHz guard bands)
In a community area where a wireless LAN or a wireless home link is assumed at home or in a factory, the frequency 20
22 wireless channels can be arranged at MHz intervals, and simultaneous transmission of up to six consecutive channels is possible.

The above-mentioned Hi-SWAN standard is a standard in a centralized control system in which a base station manages another terminal station. Since the base station adjusts the communication timing of the terminal station, it is necessary to increase the communication efficiency. It is possible and suitable for communication in an environment where many terminal stations exist (for example, outdoor Internet connection at a hot spot).

On the other hand, the distributed control system represented by the IEEE 802.11a system is a system in which terminal stations make communication requests with each other, and individually adjust timing between the terminal stations. This method enables direct communication between terminal stations (mobile stations) without providing a base station, and enables a wireless communication system to be constructed more easily than a centralized control method. Suitable for wireless communication systems such as systems.

FIG. 5 is a diagram showing an example of a data structure in a wireless communication system using a distributed control system. In the case where the first terminal station transmits data to the second terminal station, the first terminal station performs the following operations in the time domain 131:
RTS (Request T) which is a data transmission request signal
o Send) signal to the second terminal station.
When the RTS signal is normally received in the time domain 135, the second terminal station transmits a CTS (Clear To Send) signal informing the completion of preparation for data reception in the time domain 136. The first terminal station performs CT in the time domain 132.
When the S signal is received normally, the time domain 133
A ta signal is transmitted to the second terminal station. When the Data signal is normally received in the time domain 137, the second terminal station transmits an ACK (Acknowledge) signal notifying that the data signal has been normally received in the time domain 138 and the first ACK signal in the domain 138. Transmit to the terminal station. If the first terminal station can normally receive the ACK signal in the time domain 134, a series of communication operations between the first terminal station and the second terminal station ends.

However, the above wireless communication system
A wireless communication system for performing communication using one frequency channel prepared in advance and capable of simultaneously using a plurality of frequency channels for data communication, such as the above 25 GHz band or 27 GHz band. Is not assumed.

An object of the present invention is to provide a radio communication system of a distributed control system capable of simultaneously using a plurality of frequency channels and a terminal station constituting the radio communication system.

[0011]

According to one aspect of the present invention, there is provided a wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels, wherein the first terminal transmits a signal. A wireless communication system is provided, wherein the station transmits first information regarding the number of frequency channels used by the station. The frequency bandwidth may be transmitted instead of or in addition to the number of frequency channels.

According to the wireless communication system, the first terminal station transmitting a signal can notify other terminal stations of first information on the number of frequency channels used by the first terminal station.

A wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels, wherein a first terminal station transmitting a data signal has a first terminal station related to the number of frequency channels used by the first terminal station. A second terminal transmitting the first information and receiving the data signal receives the first information, and based on the first information and a frequency channel available to the second terminal. , Determining a frequency channel used for transmitting a data signal from the first terminal station;
A wireless communication system is provided, wherein second information about the determined frequency channel is sent to the first terminal station.

According to another aspect of the present invention, a first terminal for transmitting a data signal is suitable for use in a wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels. A first station transmitting first information on the number of frequency channels used by the station;
Are provided.

According to another aspect of the present invention, it is suitable for use in a wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels. Transmits information on the number of frequency channels used by the receiving terminal to the receiving terminal, and obtains information on the number of frequency channels used by the transmitting terminal from the transmitting terminal transmitting the data signal when receiving the data signal And, based on the information and the frequency channels available to itself, determine a frequency channel used for data reception,
A terminal station is provided, which transmits information on the determined frequency channel to the transmitting terminal station.

Using the above terminal station, in a radio communication system capable of communicating using a plurality of frequency channels, it is possible to determine which frequency channel to use when transmitting and receiving, and to transmit and receive data and the like based on the determination. it can.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION In this specification, a terminal station (mobile station) on the transmitting side is referred to as a first terminal station, and a terminal station (mobile station) on the receiving side is referred to as a second terminal station. In practice, it is assumed that the terminal station has both a transmission function and a reception function.
The transmission function and the reception function are properly used according to the communication status.

The number of frequency channels and the frequency bandwidth have substantially the same meaning. That is, assuming that the frequency bandwidth of one frequency channel is actually the same and that continuous frequency channels are used, the number of frequency channels and the frequency bandwidth correspond one-to-one.

Before describing the embodiments of the present invention, considerations made by the inventors will be described below. For example, in a wireless communication system of a distributed control system configured by a plurality of terminal stations and capable of simultaneously using a plurality of frequency channels, the first terminal station to transmit is configured to transmit the transmission capacity and frequency of communication data. By accurately grasping the channel availability and selecting a frequency channel based thereon, and notifying the second terminal station on the receiving side of information on the frequency channel or frequency bandwidth used for transmission, the efficiency is improved. It was thought that it would be possible to perform communication in an efficient manner. Note that, as described above, the transmission side and the reception side are switched as appropriate.

In addition, the second terminal station on the receiving side searches for a frequency channel used by the terminal station on the transmitting side from, for example, 20 or more frequency channels, and determines a frequency channel or a frequency bandwidth used for transmission. Technology that recognizes information becomes important.

Therefore, when the first terminal station intends to transmit to the second terminal station, the first terminal station uses the information on the available frequency channel and the communication capacity for communication. The number of frequency channels or the frequency bandwidth is selected, and a data transmission request signal including first information on the number of frequency channels or the frequency bandwidth is transmitted to the second terminal station.

The second terminal station is a signal determined from the first information included in the received data transmission request signal and information on the number of frequency channels with which the (second) terminal station can simultaneously communicate. Then, the second terminal station transmits a data transmission permission signal including the second information on the number of frequency channels or the frequency bandwidth of the signal desired to be transmitted to the first terminal station. The first terminal station transmits a data signal to the second terminal station based on the second information included in the data transmission permission signal. If the data signal is successfully received, the second
Transmits a data signal reception completion signal.

Through the above steps, efficient communication in a wireless communication system including a plurality of terminal stations and using a plurality of frequency channels becomes possible.

Based on the above considerations, embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example of a wireless communication system according to the present invention. The wireless communication system 1 according to the embodiment of the present invention includes a first terminal station 11, a second terminal station 12, a third terminal station 13,
Is a wireless communication system of a TDMA (Time Division Multiple Access System) distributed control method configured to include:

The wireless communication system 1 has the above-mentioned 24.7.
This is a wireless communication system that uses frequencies from 7 GHz to 25.23 GHz, uses 23 radio frequency channels at a frequency interval of 20 MHz, and can simultaneously transmit up to three consecutive frequency channels. The first terminal station 11 and the second terminal station 12 are terminals that can simultaneously transmit and receive up to three frequency channels, and the third terminal station 13 has only a transmitting and receiving function of only one frequency channel. An example in which this is not the case will be described.

It should be noted that the above configuration relating to the maximum number of frequency channels that can be used is merely an example for convenience of description, and is not to be construed as limiting.

FIG. 2 is a block diagram showing a configuration example of the terminal stations (11, 12, 13) constituting the radio communication system 1 according to the embodiment of the present invention. However, there are cases where the specifications of the functional blocks partially differ depending on the terminal station due to the difference in the maximum number of transmission / reception channels described above.

As shown in FIG. 2, the terminal station 11, 12, or 13 includes a transmitting / receiving antenna 21 and an antenna duplexer 22.
, An RF / IF receiver 23, an A / D converter 24, a demodulator 25, a bus control unit 27, an information detector 26, a modulator 28, a D / A converter 29, an RF / IF IF transmitter 3
0 and a system control unit 31.

The received signal input from the transmitting / receiving antenna 21 has its receiving side route selected by the antenna duplexer 22.
The RF / IF receiver 23 performs amplification of the received signal and frequency conversion to an intermediate frequency (IF) band. The received signal converted to an intermediate frequency (for example, a center frequency of 20 MHz) is converted from an analog signal to a digital signal by an A / D converter 24, and the received signal is usually demodulated by a demodulator 25, and an interface with the outside is performed. Via a bus control unit 27 having such functions as described above, the data is taken into an information processing apparatus such as a personal computer (PC) as data (Data).

A preamble signal including information such as frame synchronization and a frequency channel is disclosed in, for example, JP-A-2001-2001.
Using the technique disclosed in JP-A-313623, it is possible for the information detector 26 to determine the frame synchronization and the frequency channel used by the own system from the preamble periodic pattern and the like.

The method described in Japanese Patent Application Laid-Open No. 2001-313623 performs a process of adding information on a frequency channel or the like used by itself to a preamble signal. The process of adding to the preamble signal corresponds to a process of changing the period Tw of the preamble signal according to the frequency band (the number of channels) used by the own system. For example, if the number of channels used by the own wireless communication system is 1
If so, the cycle of the preamble signal is set to Tw, if the number of channels is 2, the cycle is set to Tw / 2, and if the number of channels is 3, the cycle is set to Tw / 4. Then, depending on whether or not the period of the preamble signal matches the preamble pattern stored in the terminal station in advance,
The number of channels can be detected without demodulating the preamble signal. Of course, it is also possible to know the frequency channel number by demodulating the preamble signal without discriminating only by the preamble pattern.

The data (Data) signal output from the personal computer PC or the like is transmitted via the bus control unit 27 to control information addition and conversion to a transmission signal format (packet format or the like) used for wireless communication. This is performed in the modulator 28. The transmission signal is converted from a digital format into an analog format signal by a D / A converter 29, and is converted into an RF / IF signal.
In the transmitter 30, amplification of a transmission signal and high frequency (RF)
Frequency conversion into a signal is performed, and the signal is transmitted from the transmitting / receiving antenna 21 to the antenna via the antenna duplexer 22.

The system control unit 31 has a function of controlling the system of the entire terminal station, and also has a function of storing and determining frequency channel selection and the like and a function of controlling power supply to each unit.

FIG. 3 is a flowchart showing an operation example of a terminal station constituting the radio communication system according to the embodiment of the present invention. The flow of the operation from the stage before the negotiation (adjustment) between the terminal stations attempting to perform communication will be described.

First, in step S11, when the terminal station intends to perform a transmission operation, a carrier sense process is performed as shown in step S12. If the terminal station does not require a transmission operation, the process proceeds to step S15, and processing relating to a signal received from another terminal station is performed. An empty frequency channel is searched for by carrier sense processing.

In step S12, when the terminal station performs a carrier sense process and searches for a vacant frequency channel and there is no vacant frequency channel, the carrier sense process is performed again after a predetermined time has elapsed. Do. If a free frequency channel has been found, in step S13, the terminal station selects a frequency channel to be transmitted from the vacant frequency channels according to the type of signal to be transmitted (eg, RTS signal) and the transmission capacity. (For example, 1 channel and 2 channels) are selected.

In step S14, the terminal station performs signal transmission processing using the actually selected frequency channel, and proceeds to the reception operation in step S15 and thereafter.

If the terminal station requires a receiving operation in step S15, a search is made for a frequency channel in which the received signal exists in step S16. If no receiving operation is required, the process proceeds to step S18.

When a receiving operation is required, in the next step S16, a frequency channel in which the signal to be received exists is searched, and in step S17, the signal is actually received and signal processing such as demodulation is performed. .

In the next step S18, it is determined whether or not to end the communication.
Returning to step S11, it is determined whether to perform the transmission operation again.

Once the terminal stations communicate with each other, and negotiation (adjustment) is performed and communication is established, the process of searching for an empty frequency channel by carrier sense in step S12 is performed for the frequency channel to be actually transmitted. Since it is sufficient to replace only with a process of checking whether or not another wireless communication system is using the communication system, the processing time can be reduced.

Processing in step S13 after negotiation is performed (transmission frequency channel selection processing)
Selects a frequency channel in consideration of information requested from a communication partner terminal station and information on the number of frequency channels used for communication of the communication partner terminal station.

Further, after the negotiation is established,
If you disconnect the communication for a predetermined period and then perform the same communication,
For example, if information such as the content of the negotiation, especially the information about the frequency channel used for communication is stored in a memory or the like, the process of searching for the reception frequency channel in step S16 is automatically adjusted to the frequency channel used by the communication partner. Can be replaced with only processing, and the processing is simplified. With the above communication procedure, communication between terminal stations can be established.

FIG. 4 is a diagram showing an example of a communication data structure of the wireless communication system of the present invention. Hereinafter, a specific example of data communication in the wireless communication system according to the present embodiment will be described with reference to FIGS. 1 to 3 as appropriate.

First, in a state in which the first terminal station 11 is about to start data transmission to the second terminal station 12, the first terminal station 11 and the second terminal station 12 In, it is also assumed that no negotiation (adjustment) is performed.

First, the first terminal station 11 is the transmitting side,
The case where the second terminal station is on the receiving side will be described. The first terminal station 11 uses the channel 1 (CH), which has been confirmed as an empty frequency channel by the carrier sense process.
1), channel 2 (CH2) and channel 3 (CH
3) That is, the first data transmission request signal (RTS1) is added to all available frequency channels with first information on the number of frequency channels or the frequency bandwidth that the user wants to use. Send individually. Second terminal station 1 that is a communication partner of first terminal station 11
2 can extract the first information from the first data transmission request signal as long as the signal can be received in at least one of the three frequency channels.

By transmitting the first information on all available frequency channels, the first information is transmitted to the second terminal station 12 of the other party regardless of the available frequency channels of the other party. be able to.

The second terminal station 12 sequentially searches the frequency channels transmitted by the first terminal station 11 for a signal to be received by itself for each frequency channel.

In the radio communication system according to the present embodiment, first, second terminal station 12 receives first data transmission request signal (RTS1) in area 63, and thus receives first data transmission request signal (RTS1). ), The first information relating to the number of frequency channels or the frequency bandwidth of the signal that the first terminal station 11 wants to use is extracted. Based on this first information and the information on the number of frequency channels that can be transmitted and received by itself (the second terminal station 12) at the same time, the first terminal station 12 makes the first terminal station 11 Station 1
The frequency channel (including the number of channels) to be used when transmitting a data signal to 2 is determined. In other words, this is a case where the first terminal station 11 on the transmitting side notifies the second terminal station 12 on the receiving side that it wants to use the frequency bandwidth for three channels. Is not capable of simultaneously transmitting and receiving only the frequency bandwidth of two channels, the second terminal station 12 on the receiving side transmits the first signal on the transmitting side to transmit the data signal in the frequency bandwidth of two channels. Terminal station 1
Request 1

In the radio communication system according to the present embodiment, first terminal station 11 transmits first information indicating that it is desired to use three frequency channels from CH1 to CH3 for a data signal to a first data transmission request signal. To the second terminal station 12. Since the number of frequency channels that the second terminal station 12 can simultaneously transmit and receive is three, the second terminal station 12 performs transmission and reception as requested by the first terminal station.
The frequency channel used for communication can be determined. Based on this determination, the second terminal station 12 adds second information including information on the frequency channel for which use has been granted to the first data transmission grant signal (CTS1), To the terminal station 11.

The first terminal station 11 receives the first data transmission permission signal (CTS1) in the area 53, extracts the second information on the frequency channel used for transmission / reception, and based on the licensed frequency channel. In the area 54, the first data signal (Data1) is transmitted to the second terminal station 1
2 is transmitted. In the wireless communication system according to the present embodiment, the first data signal is transmitted using the licensed three frequency channels from CH1 to CH3.

On the other hand, the second terminal station 12 receives the first data signal in the area 65. At this time, when the reception of the first data signal ends normally, a first data signal reception completion signal (ACK1) is sent to the first terminal station 11 in an area 66. The first terminal station 11 receives the first data signal reception completion signal (ACK1) in the area 55 and recognizes that the communication of the first data signal has been normally completed. With the above processing, communication from the first terminal station 11 to the second terminal station 12 is completed.

Next, a case where the third terminal station is on the transmitting side and the first terminal station is on the receiving side will be described. The third terminal station 13 transmits to the first terminal station 11 in the area 70 new first information relating to the frequency channel or frequency bandwidth that the third terminal station 13 wants to use in the second data transmission request signal (RTS).
Send in addition to 2). The first terminal station 11 is located in the area 5
6, the second data request signal (RTS2) is received, and the frequency channel requested by the third terminal station 13 is recognized. The frequency channel requested by the third terminal station 13 is 2CH (the number of frequency channels is 1).
Terminal station 11 can simultaneously transmit and receive up to three frequency channels, so that it is possible to use 2CH. Therefore,
The first terminal station 11 determines a frequency channel to be used for transmission and reception in accordance with a request from the third terminal station 13 and
7, a second data transmission permission signal (CTS2) includes a new second
Is transmitted to the third terminal station 13. The third terminal station 13 receives the second data transmission permission signal in the area 71, extracts the second information on the frequency channel used for transmission and reception, and based on the licensed frequency channel, Data signal (Data
2) is transmitted to the first terminal station 11.

In the radio communication system according to the present embodiment, the second data signal (Data2) is transmitted using the licensed one frequency channel of CH2.

On the other hand, the first terminal station 11 receives the second data signal (Data 2) in the area 58. When the reception of the second data signal (Data2) ends normally,
In the area 59, the second data signal reception completion signal (AC
K2) to the third terminal station 13. The third terminal station 13 transmits the second data signal reception completion signal (A
CK2) is received and the communication from the third terminal station 13 to the first terminal station 11 is completed by recognizing that the communication of the second data signal (Data2) has been normally completed.

According to the wireless communication system of the present embodiment, in a wireless communication system capable of simultaneously using a plurality of frequency channels, the frequency channel used by the own communication system can be easily detected. Further, by setting a frequency channel to be used for wireless communication according to the communication data capacity and the availability of the frequency channel, a plurality of frequency channels can be used effectively without wasting radio wave resources.

In addition, in the wireless communication system according to the present embodiment, for example, the system control unit 3
1 may be provided with a power supply control means 31a.

The power supply control means 31a stops or reduces the power supply to the circuits related to the transmission or reception of the terminal station in an area not used for transmission / reception in the example of use of the time domain shown in FIG. Let it. For example, FIG.
Region 67 in the second terminal station shown in (B), FIG. 4 (C)
By stopping or reducing the power supply to the transmitting means or the receiving means in the area 69 in the third terminal station shown in (3), power saving of the terminal station becomes possible.

Further, the number of frequency channels to be used can be increased or decreased according to the required capacity for data communication. For example, various types of data such as text data, audio data, and moving image data, which increase in the required data transmission speed in this order, can be transmitted and received efficiently by increasing and decreasing the frequency channels. Also, by increasing or decreasing the number of frequency channels used for communication according to the required data transmission rate, it is possible to improve the power consumption efficiency of the terminal station.

Although the present invention has been described with reference to the embodiments, the present invention is not limited to these embodiments. It will be apparent to those skilled in the art that various other modifications, improvements, and combinations are possible.

[0061]

According to the wireless communication system of the present invention, smooth communication of a wireless communication system including a plurality of terminal stations and capable of simultaneously using a plurality of frequency channels is ensured, and radio resources can be effectively used. . Further, by increasing or decreasing the number of frequency channels to be used, there is an effect that the power consumption of the terminal station can be made more efficient.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration example of a wireless communication system according to an embodiment of the present invention.

FIG. 2 is a functional block diagram showing a configuration example of a terminal station in the wireless communication system according to one embodiment of the present invention.

FIG. 3 is a flowchart showing an operation flow of a terminal station in the wireless communication system according to one embodiment of the present invention.

FIG. 4 is a diagram illustrating an example of a data structure of a wireless communication system according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating an example of a data structure in a general distributed control wireless communication system.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Wireless communication system, 11 ... 1st terminal station, 12 ... 2nd
Terminal station, 13: third terminal station, 21: transmitting / receiving antenna,
22: antenna duplexer, 23: RF / IF receiver, 24
... A / D converter, 25 ... demodulator, 26 ... information detector, 2
7 bus controller, 28 modulator, 29 D / A converter,
30 RF / IF transmitter, 31 System control unit, 5
0, 51, 52, 63: first data transmission request signal area; 53, 64: first data transmission permission signal area;
4, 65... First data signal area, 55, 66.
Area of the data signal reception completion signal, 56, 70... Area of the second data transmission request signal, 57, 71... Area of the second data transmission permission signal, 58, 72... Area of the second data signal, 59 , 73... A second data signal reception completion signal area, 67, 69... A blank area.

Claims (16)

[Claims] 1. A wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels, wherein a first terminal station transmitting a signal has a first number of frequency channels used by the first terminal station. A wireless communication system for transmitting the information of: 2. A wireless communication system including a plurality of terminal stations and capable of performing communication using a plurality of frequency channels, wherein a first terminal station transmitting a data signal has a first terminal station related to the number of frequency channels used by the first terminal station. 1 information, and a second terminal station that receives the data signal receives the first information, and based on the first information and a frequency channel that can be used by the second terminal station. Determining a frequency channel to be used for transmitting a data signal from the first terminal station, and transmitting second information on the determined frequency channel to the first terminal station. 3. A wireless communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels, wherein a first terminal station transmitting a data signal uses a frequency used by the first terminal station. A first terminal station for transmitting first information on the number of channels. 4. The first terminal station according to claim 3, wherein the first terminal station transmits the first information on all frequency channels used by the first terminal station. 5. The first information is transmitted to a second terminal station that receives a data signal by adding the first information to a data transmission request signal for notifying that the first terminal station transmits a data signal. The first device according to claim 3 or 4, wherein
Terminal station. 6. The second terminal station receives the data transmission request signal, obtains the first information from the data transmission request signal, and obtains the first information and the second terminal station. The second terminal station according to claim 5, wherein a frequency channel used for transmitting a data signal from the first terminal station is determined based on a frequency channel that can be used. 7. The second terminal station adds the second information on the determined frequency channel to a data transmission permission signal for notifying the completion of preparation for receiving a data signal, and transmits the second information to the first terminal station. The second terminal station according to claim 6, wherein the second terminal station transmits. 8. The method according to claim 1, wherein the number of frequency channels that the first terminal station wants to use is equal to or less than the number of channels that the second terminal station can simultaneously transmit or receive. The number of frequency channels that the second terminal station wants to use and the number of frequency channels that the second terminal station wants to use if the number of channels exceeds the number of channels that can be simultaneously transmitted or received by the second terminal station. 8. The second terminal station according to 6 or 7. 9. The first terminal station transmits data transmitted from the second terminal station, the second terminal station including second information relating to a number of frequency channels determined to transmit a data signal. The first terminal station according to claim 8, wherein the first terminal station receives a license signal. 10. The first terminal according to claim 9, wherein the first terminal station transmits the data signal to the second terminal station based on the second information. Bureau. 11. The second terminal according to claim 10, wherein the second terminal receives a data signal transmitted from the first terminal based on the second information.
Terminal station. 12. The data signal for notifying the first terminal station of the completion of the reception of the data signal after the completion of the reception of the data signal transmitted from the first terminal station, the second terminal station comprising: The second terminal station according to claim 11, wherein the second terminal station transmits a reception completion signal. 13. The apparatus according to claim 12, wherein the first terminal station detects completion of data transmission to the second terminal station by receiving the data signal reception completion signal. First terminal station. 14. The terminal station according to claim 1, wherein the terminal station sends the first or second information on a frequency channel or the like used by the terminal station. A terminal station, which is a process for adding to a signal, wherein the terminal station is included by a process of changing a period of a preamble signal according to the number of frequency channels used by its own system. 15. The terminal station according to claim 1, further comprising: a power supply to a data signal transmission / reception unit in a time domain which is not used for transmission or reception by the terminal station. A terminal station comprising power supply control means for stopping or reducing supply. 16. A radio communication system including a plurality of terminal stations and capable of communicating using a plurality of frequency channels, wherein information on the number of frequency channels used by itself when transmitting a data signal is provided. To the receiving terminal station, and when receiving the data signal, obtain information on the number of frequency channels used by the transmitting terminal station from the transmitting terminal station transmitting the data signal, and use the information and the self A terminal station that determines a frequency channel to be used for data reception based on available frequency channels, and transmits information on the determined frequency channel to the transmitting terminal station.