JP2002271263A - Radio communication system and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system, which can set appropriate transmission power properly, by determining the quality of communication with a radio terminal of each noncontrol station, without a control station managing the control of transmission power, and a radio communication method. SOLUTION: The controller 18 of each radio terminal is equipped with a storage 1 circuit 19, which stores the quality A of communication between the control station and each radio terminal, and a storage 2 circuit 20, which stores the quality B of communication between the mutual radio terminals, and it decides the transmission power level of its own radio terminal, based on the quality A of communication and the quality B of communication, and switches the transmission power level of a transmission amplifier 12, so that is become the decided transmission power level, thereby performing the transmission power control.

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 radio communication method comprising a control station and a plurality of radio terminals, and more particularly, to a radio communication system for directly communicating between a plurality of radio terminals and a radio communication system. The present invention relates to a wireless communication method.

[0002]

2. Description of the Related Art In wireless communication, a positional relationship and a communication environment between wireless terminals dynamically change, and communication quality greatly changes. In order to perform stable communication in such an unstable situation, it is necessary to appropriately control settings related to transmission power (transmission power setting) and settings related to reception power (reception sensitivity setting) according to a change in communication environment. is there.

[0003] The communication quality is information that specifically indicates the quality of communication when communication is performed between wireless terminals. For example, there are the following. (1) Error rate Indicates the rate at which data packet transmission failed when data transmission was performed from one wireless terminal to the other wireless terminal. (2) Maximum received power This is the received power at the receiving wireless terminal when the transmitting wireless terminal performs transmission at the maximum transmitting power.

[0004] Japanese Patent Application Laid-Open No. 11-266256 discloses that each wireless terminal transmits a test signal in a frame head area, and other wireless terminals receive the test signal and measure the strength or error rate of the test signal. A method for knowing the communication quality with all wireless terminals is disclosed. Based on this, it is possible to perform high-speed but low-reliability data transmission between wireless terminals with high communication quality, and perform low-speed but high-reliability transmission with wireless terminals with low communication quality. In this way, the communication quality can be dynamically determined by using the periodically transmitted test signal, and the optimal modulation scheme can be determined according to the communication quality.

[0005]

However, the apparatus described in the above publication has the following problems. There are three types of information to be transmitted: control data, a temporally continuous data stream, and asynchronous data such as commands. Hereinafter, when simply described as data, it means asynchronous data. The procedure of data communication will be described.

FIG. 16 is a schematic diagram showing a flow of a data communication procedure. As shown in FIG. 16, the procedure of data communication can be divided into data transmission (request transmission) and data transmission confirmation (response transmission). In request transmission, request data is transmitted to the responding wireless terminal. In response transmission, the responding wireless terminal transmits response data to the requesting wireless terminal. By transmitting the request data, the requesting wireless terminal requests the responding wireless terminal to operate the content of the request data as request transmission. The responding wireless terminal
After receiving the request data, an operation is performed based on the content of the data, and response data is transmitted to the requesting wireless terminal using a result of the reception of the request data as a response transmission. The requesting wireless terminal knows that the request data has been received by receiving the response data, and the communication ends.

FIG. 17 is a schematic diagram of a request data packet.
FIG. 18 is a schematic diagram of a response data packet. As shown in these figures, the sequence number in the request data is
A number is assigned to each request data. The sequence number in the response data stores the sequence number of the request data to which the responding wireless terminal responds. The requesting wireless terminal
From the sequence number in the response data, it is determined which request data the response is related to.

[0008] When the requesting wireless terminal detects the sequence number in the response data, it determines that the request data transmission of the sequence number has succeeded. If the transmission times out after the transmission of the request data without confirming the success of the transmission, it is determined that the transmission of the request data has failed. When determining that the data transmission has failed, the requesting wireless terminal retransmits the request data.

When the responding wireless terminal receives the sequence number of the transmitted response data from the requesting wireless terminal again,
It is determined that transmission of the response data has failed. If the request data of the transmitted sequence number is not retransmitted before the transmission of the response data times out, it is determined that the transmission was successful. However, the time required to determine that the transmission was successful is much longer than the request transmission because it waits for a timeout.

In data transmission, there is a polling method for equally giving each wireless terminal a transmission opportunity. The polling method is used in a wireless communication system.
This is a method in which one wireless terminal transmits a polling packet to another wireless terminal in a wireless communication system to give the right to transmit data. The wireless terminal given the transmission right starts data transmission if there is data to be transmitted.

In the polling communication, one of the wireless terminals transmits a polling packet to give a data transmission right to a destination wireless terminal. Here, the control station transmits a polling packet to give the wireless terminal a data transmission right. After granting the wireless terminal data transmission right by transmitting a polling packet to the wireless terminal, the control station determines that the wireless terminal data transmission has been completed or has not been performed. To send data. Here, the device described in the above publication is to select an optimal modulation method as appropriate according to the transmission path, and does not consider power control in data transmission.

When performing data transmission in polling communication, not only the communication quality between the transmitting wireless terminal and the receiving wireless terminal but also the communication quality between the transmitting wireless terminal and the control station must be considered. No. The transmission power and the reception power must be appropriately controlled according to the communication quality. For example, even when the communication quality between the transmitting wireless terminal and the receiving wireless terminal is extremely good, if the communication quality between the control station and the transmitting wireless terminal is poor, the transmitting wireless terminal can output data at the maximum output. Without transmission, data transmission may not be successful.

Here, a case where the distance between the transmitting-side wireless terminal and the receiving-side wireless terminal is very short and the distance from the control station is very long will be considered with reference to FIGS. Figure 1
FIG. 9 is a schematic diagram illustrating an example of an arrangement of wireless terminals. FIG.
17 is a schematic diagram in the case of an example of wireless terminal arrangement (FIG. 16), which is the communication quality between the control station and each wireless terminal. Also,
FIG. 21 is a schematic diagram in the case of the example of the wireless terminal arrangement (FIG. 16) and shows the communication quality between the terminals.

[0014] Assuming that the transmitting wireless terminal transmits at a suitable intensity that the receiving wireless terminal can receive without attenuating the received radio wave, the radio wave does not reach the control station as shown in FIG. The control station determines that the transmitting wireless terminal has not performed data transmission, and starts transmitting a polling packet to give the next wireless terminal a transmission right. Collide. Conversely, assuming that the transmitting wireless terminal transmits at a strength at which the radio wave reaches the control station, as shown in FIG. 21, the receiving strength of the radio wave at the receiving wireless terminal becomes very strong, and the receiving wireless terminal Received radio waves are too strong to receive data.

As shown in this example, even if the communication environment between the transmitting wireless terminal and the receiving wireless terminal is extremely good, the transmitting wireless terminal can communicate normally without transmitting at the maximum transmission intensity. Sometimes you can't. Therefore, in order to perform normal communication between wireless terminals, it is necessary to determine the communication quality between the transmitting wireless terminal and the receiving wireless terminal and the communication quality between the transmitting wireless terminal and the control station, and to perform appropriate transmission. Power settings must be derived. As a transmission power control method, there is a method in which a control station performs transmission control by managing control of transmission power of all terminals in the system. However, this method increases communication overhead.

The present invention has been made in view of such a problem, and a radio terminal of a non-control station judges each communication quality without controlling the control of transmission power by a control station, and performs appropriate control. It is an object of the present invention to provide a wireless communication system and a wireless communication method capable of appropriately setting a transmission power setting.

[0017]

A wireless communication system according to the present invention includes a control station, and a plurality of wireless terminals wirelessly connected to the control station, wherein the wireless terminals can directly communicate with each other. In the system, the wireless terminal includes a switching unit for switching a transmission power level, a communication quality A with the control station, and n communication qualities b1, b2,..., Bn with each of the other wireless terminals. Storage means for storing the communication quality A and the communication qualities b1, b2,
, Bn, and a control unit that switches the switching unit so that the transmission power level is determined, and performs data transmission to another wireless terminal at the determined transmission power level. Transmission means.

The communication quality A or the communication quality b1,
b2,..., bn may include communication quality information based on a reception result when transmitting at a known transmission power, and the communication quality A or the communication qualities b1, b2,.
May include information indicating a margin value up to a lower limit of the receivable power of each wireless terminal calculated by the control station based on a reception result when transmitting at a known transmission power.

The communication quality A or the communication quality b1,
b2,..., bn may include communication quality information based on a reception result when each wireless terminal performs transmission power control, and a reception result when each wireless terminal performs transmission power control. May include sufficient / insufficient binary information.

More preferably, the margin value is included in the communication quality A, the binary information is included in the communication quality A and the communication qualities b1, b2,..., Bn. , B, b2,..., B when transmitting with transmission power larger than the transmission power indicated by the margin value.
When the transmission power is controlled by the binary information included in n and transmitted at a transmission power smaller than the transmission power indicated by the margin value, the communication quality A and the communication qualities b1, b2,
, Bn may be used to control the transmission power based on the binary information.

Further, a wireless communication method according to the present invention includes a control station and a plurality of wireless terminals wirelessly connected to the control station, wherein the wireless communication method enables direct communication between the wireless terminals. In the method, at each wireless terminal, a communication quality A between the control station and its own wireless terminal, and n communication qualities b between its own wireless terminal and each of the other wireless terminals.
, Bn, and performs transmission power control of its own wireless terminal based on the communication quality A and the communication qualities b1, b2,..., Bn.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a wireless communication system and a wireless communication method according to the present invention will be described below in detail with reference to the accompanying drawings. First, the basic concept of the present invention will be described. A wireless communication system to which the present invention is applied is divided into a region for transmitting a frame at a known transmission power (known transmission power region) and a transmission region for a variable transmission power (variable transmission power region).

Each wireless terminal has its own wireless terminal and control station,
The communication quality between the own wireless terminal and another wireless terminal is determined. According to the communication quality, the own wireless terminal determines a transmission power setting when transmitting to another wireless terminal in the variable transmission power region, and performs transmission to another wireless terminal with the determined transmission power setting. To

Each wireless terminal determines the communication quality regarding reception from the reception results in the known transmission power region and the variable transmission power region, and broadcasts the result to all the wireless terminals. Each wireless terminal stores the received communication quality, and determines the quality of communication between its own wireless terminal and the control station and between its own wireless terminal and another wireless terminal. Each wireless terminal stores a margin value up to the lower limit of the receivable power of the wireless terminal and binary information indicating whether the wireless terminal has sufficient or insufficient transmission power in the variable transmission power region.

When the wireless terminal transmits at a transmission power larger than the transmission power indicated by the margin between its own wireless terminal and the control station, the wireless terminal between the own wireless terminal and the receiving-side wireless terminal transmits the signal. The transmission power is controlled based on the binary information. When transmitting at a transmission power smaller than the transmission power indicated by the margin value between the own wireless terminal and the control station, the own wireless terminal and the control station, between the own wireless terminal and the receiving-side wireless terminal The transmission power is controlled based on the binary information. In this way, each wireless terminal determines the communication quality between its own wireless terminal and the control station, its own wireless terminal and another wireless terminal, and controls the transmission power of its own wireless terminal according to the communication quality. Do.

FIG. 1 is a block diagram showing a configuration of a transmission / reception unit of a radio terminal in a radio communication system according to an embodiment of the present invention based on the above basic concept. An example of the flow of transmission power control and reception power control Is shown. In the figure, thick arrows indicate control signals. In FIG. 1, a transmission / reception unit 10 of a wireless terminal includes an antenna 11, a transmission amplifier 12 (switching means), a modulation unit 13, an attenuator (attenuator) 14,
GC (Automatic Gain Control) circuit 1
5, a demodulation unit 16, a reception level indication circuit (RSSI circuit) 17, which detects a reception signal level from an intermediate frequency signal (IF signal), and performs logarithmic conversion to output an RSSI output signal; A controller 18 (control means) for controlling the transmission amplifier 12, the attenuator 14, and the AGC circuit 15 based on the input is provided.
Reference numeral 8 denotes a storage 1 circuit 19 (storage means) for storing the communication quality (communication quality A) between the control station and the own wireless terminal, and n storage circuits 19 between the own wireless terminal and each of the other wireless terminals. , And bn as communication quality B.

The antenna 11, the transmission amplifier 12, and the modulation section 13 constitute a transmission means for transmitting data to another wireless terminal at the determined transmission power level as a whole.
Hereinafter, the operation of the wireless communication system configured as described above will be described. First, the operation of the transmitting / receiving device 10 will be described.

When transmitting, the transmission signal is modulated by the modulator 13, the signal is amplified by the transmission amplifier 12, transmitted to the antenna 11 and transmitted. Transmission amplifier 12
Is controlled by the controller 18 to adjust the transmission power. When receiving, the signal is transmitted from the antenna 11 to the attenuator 14 and the received signal is attenuated. The attenuator 14
The attenuation rate is adjusted by the controller 18. When the controller 18 determines that the received signal is too strong when demodulating the received signal and becomes saturated during demodulation of the received radio wave, the controller 18 attenuates the received radio wave by the attenuator 14 so that the received radio wave is demodulated. Is adjusted so as not to saturate during demodulation. Information on whether or not the demodulation unit 16 is saturated is sent from the demodulation unit 16 to the controller 18.

The received signal passing through the attenuator 14 is AGC
It is sent to the circuit 15 and the RSSI circuit 17. The AGC circuit 15 performs variable gain control to amplify the IF signal to an appropriate input level for the demodulation unit 16. Next, the demodulation unit 16 demodulates the received signal to restore the baseband signal. The other IF signal is output by the RSSI circuit 17
After being converted into a DC signal, the input power is logarithmically converted by an internal current-voltage conversion amplifier, and the output is sent to the controller 18.

The wireless terminal including the transmitting / receiving device 10
Set transmission power and reception sensitivity according to transmission and reception. Specifically, the controller 18 controls the transmission amplifier 1
2. By adjusting the attenuator 14 and the AGC circuit 15, the transmission power setting and the reception sensitivity setting are set in accordance with the transmission and reception. The information on the received power is obtained from the output from the RSSI circuit 17 and the setting of the attenuator 14. The reception power at the end of the antenna 11 is obtained by correcting the reception result from the RSSI circuit 17 by the amount of attenuation in the attenuator 14.

Next, the process of setting the receiving sensitivity will be described. The received power is controlled by the attenuator 14 and the AGC circuit 15. The attenuator 14 performs an attenuating operation with the setting specified by the controller 18. Regarding the AGC circuit 15,
The controller 18 only sets an initial value in the setting of the AGC circuit 15, and the subsequent operation is performed by the AGC circuit 15 based on an input signal to the AGC circuit 15 without depending on the instruction of the controller 18.

The control value used for controlling the AGC circuit 15 can be read by the controller 18. The controller 18 changes the setting of the attenuator 14 based on the control value read from the AGC circuit 15 so as to control the power passing through the attenuator 14 to fall within the controllable range of the AGC circuit 15.

When setting the transmission power setting and the receiving sensitivity setting, the controller 18 determines the setting values based on the communication quality of the wireless communication system. The controller 18 includes a storage 1 circuit 19 and a storage 2 circuit 20, and the communication quality between the control station and each wireless terminal is stored in the storage 1 circuit 1
9, the communication quality between each wireless terminal is stored in two circuits 20.
To memorize. The controller 18 can extract the communication quality from the storage circuits 19 and 20 when the communication quality is required.

Next, the operation of the control station and each wireless terminal of the wireless communication system will be described with reference to FIGS. In the following description, the wireless terminal 0 is a control station,
The wireless terminals 1 to 3 are wireless terminals of the controlled station. FIG.
FIG. 7 is a table showing an example of storage of a reception result in a control station stored in each wireless terminal. FIG. 3 is a table showing a storage example of a data non-reception power flag stored in each wireless terminal.

The control station broadcasts reception results in the known transmission power region and the variable transmission power region in the known transmission power region for each frame (for example, one frame is 4 ms). The information shown in FIG. 2 is transmitted to all wireless terminals by the broadcast of the control station. The expected surplus received power is
This is information on a margin value from the reception power at the control station when each wireless terminal transmits in the known transmission power region to the lower limit of the reception power receivable by the control station, derived by the control station.

The control station data non-reception power flag is a reception result at the control station when each wireless terminal transmits to another wireless terminal in the variable transmission power region. If the received power is not sufficient, this flag is set and the received power is reported to be insufficient. In addition, each wireless terminal broadcasts a reception result when another wireless terminal transmitted to its own wireless terminal in the variable transmission power region in the past as a data unreceivable power flag in the known transmission power region for each frame. As a result of the broadcast of each wireless terminal, each terminal sends one column, so that the data reception impossible power flag of FIG. 3 is transmitted to all wireless terminals.

The data unreceivable power flag is a reception result at the other wireless terminal when the upper wireless terminal transmits in the variable transmission power region. If the received power is not sufficient, this flag is set and the received power is reported to be insufficient. Further, a lower limit transmission power setting is derived from the expected surplus reception power shown in FIG.

Each wireless terminal controls the transmission power using the data unreceivable power flag of FIG. 3 until the lower limit transmission power is set. When the control station performs transmission power control below the power guaranteed to be received, the transmission power is controlled by the control station data non-reception power flag shown in FIG. 2 and the data reception non-power flag shown in FIG. In this way, each wireless terminal determines the communication quality between its own wireless terminal and the control station, its own wireless terminal and another wireless terminal, and controls the transmission power of its own wireless terminal according to the communication quality. Do.

FIG. 4 is a schematic diagram showing a schematic configuration of the wireless communication system in the present embodiment. In FIG. 4, a portion surrounded by an ellipse indicates a cover area in which communication can be performed in each wireless terminal. The network configuration is configured as a star topology configuration centered on a control station having only one control station in one wireless communication system. Therefore, an active wireless terminal on the wireless communication system is always in a state capable of two-way communication with the control station. Also, wireless terminals directly communicate with each other if the communication environment between the wireless terminals is good. However, there is a case where communication cannot be performed between wireless terminals due to a distance between the wireless terminals or an obstacle, and in such a case, communication is performed by relaying another wireless terminal.

FIG. 5 is a schematic diagram showing the configuration of a radio frame used by the radio communication system. As shown in FIG. 5, the radio frame is divided into a known transmission power region and a variable transmission power region. The known transmission power region is a management region,
The variable transmission power area is a user data area.

The management area is an area for performing communication between the control station and the wireless terminals in order to maintain and manage the frames and check the communication quality between the wireless terminals. Communication in this management area uses a common modulation method and coding rate, and performs transmission power at the maximum output. Also, the polling packet uses a common modulation method and coding rate, and transmits at maximum output power so as to reach all terminals.

<Management Area> (1) Frame Start Area 21 In order to notify the start of a frame to all wireless terminals in the wireless communication network, the control station transmits the information to all wireless terminals. It is also used as an area for maintaining and managing the wireless communication system. (2) Operation state report area 22 This is an area in which each wireless terminal participating in the wireless communication system reports its own operation state as an operation state report packet. Position information at which the wireless terminal transmits an operation status report packet is indicated in a frame management area, and each wireless terminal transmits an operation status report packet based on the management information.

<User Data Area> (1) User Data Area 23 Data communication is appropriately performed without securing a band in advance. In one frame, data is sequentially transmitted in an empty area from the end of the management area to the start of the next frame. The control station transmits a polling packet including the identification value, and the wireless terminal having acquired the transmission right starts transmitting data.

<Frame Start Area> FIG. 6 is a schematic diagram showing the structure of the frame start area 21. (1) Frame management area 24 The control station transmits information for maintaining and managing the wireless communication system.

The position information when the wireless terminal transmits an operation state report packet in the operation state report area is also transmitted here. (2) Wireless terminal information area 25 This is an area for the control station to transmit information on wireless terminals. Information about each wireless terminal is stored as wireless terminal information. The broadcast of FIG. 2 is performed in this area.

<Wireless Terminal Information> FIG. 7 is a schematic diagram showing the structure of wireless terminal information. (1) Wireless terminal number 26 This is a number for recognizing a wireless terminal. The wireless terminal information is information relating to the wireless terminal identified by the wireless terminal number. (2) Radio terminal status 27 This status indicates the current status of the radio terminal. Indicates whether it is operating or is saving power. (3) Expected surplus received power information 28 In the control station, whether the operation status report packet transmitted by the wireless terminal of the non-control station was successfully or unsuccessfully stored, and if the reception was successful, the expected surplus power is stored. .

FIG. 8 is a diagram showing an example of information stored in the expected surplus received power information 28. In FIG. 8, from the reception failure class “0” to the class “1” where the reception is successful but the lower limit from the maximum reception power is 0 dB, and further to the classification “7” where the reception is successful and the lower limit is −60 dB. It is classified into 8 categories. The control station derives, from the maximum received power of the packet of the wireless terminal indicated by the wireless terminal number in the control station, the expected surplus received power of the wireless terminal.

Here, the expected surplus power is information indicating whether the control station can receive a packet of power from the maximum reception power at the control station to minus what power. This information is derived by the control station. From the expected surplus received power, the control station can receive packets up to (maximum received power) − (expected surplus received power), and the wireless terminal indicated by the wireless terminal number is (maximum transmission power) − (expected surplus power). It can be determined that the transmission power can be reduced to the power of (reception power).

(4) Control Station Data Reception Unavailable Power Flag 2
9 Returning to FIG. 7, the control station receives the data transmitted by the wireless terminal to another wireless terminal, and among the received powers of the received data, the reception power is too small in the control station and the reception failure occurs. When there is data that is determined to be output, it is determined that the received power is insufficient, and the control station data non-receivable power flag is set. FIG. 9 is a diagram showing an example of information stored in the control station data non-reception power flag 29.

<Operation Status Report Packet> The operation status report packet used in the operation status report area 22 is a packet for the radio terminal to report information on its own radio terminal and communication quality with other radio terminals. It is.

FIG. 10 is a schematic diagram showing the configuration of the operation status report packet. The operation status report packet includes the self terminal information 30 and each terminal information area 31. (1) Self-terminal information 30 This is used to report the state of the own radio terminal. (2) Each terminal information area 31 The broadcast for each column shown in FIG. 3 is performed here.

[0052] It is used to report the communication status between its own wireless terminal and each terminal. Information on all wireless terminals is stored in the operation status report packet, and the number of each terminal information is equal to the number of all wireless terminals. Each terminal information is stored in the order of the wireless terminal number in each terminal information area.

If all the information on the communication status of the wireless communication system is stored in each terminal information, each terminal can surely and accurately judge the communication quality. However, the packet length of the operation status report packet becomes longer,
It will squeeze the band. For this reason, the information stored in each terminal information is simplified. Among the pieces of terminal information, the one related to the transmission power control is only the unreceivable power flag, and has a one-bit configuration.

<Each Terminal Information> FIG. 11 is a schematic diagram of each terminal information. It comprises an operation state report packet reception result 32 and a data reception impossible power flag 33. (1) Operation status report packet reception result 32 Whether the reception of the operation status report packet has succeeded or failed,
Also, information on received power when reception is successful is stored. (2) Data Reception Unavailable Power Flag 33 When the wireless terminal determines that the reception power in the data area is too small and there is a possibility that a failure may occur in the reception, the reception power is determined to be insufficient and the data reception unreachable power is determined. The flag 33 is set. Conversely, if the data unreceivable power flag 33 is not set, it is determined that the received power is sufficiently large. FIG. 12 is a diagram illustrating an example of information stored in the data reception impossible power flag.

Next, the communication quality will be described. The communication quality between the wireless terminals is derived based on the reception result of the operation state report packet received by the own wireless terminal and the communication result in the user area. The communication quality refers to information indicating the quality of communication held in the wireless terminal, and is derived from past communication records. The communication quality is as follows.

(1) Maximum received power This is the received power at the receiving wireless terminal when the transmitting wireless terminal transmits at the maximum transmitting power. The operation status report packet is transmitted at the maximum power. The reception power of the operation state report packet is defined as the maximum reception power of the own wireless terminal from another wireless terminal. (2) Lower limit transmission power setting This is the lower limit of the transmission power setting at which the control station can receive data when its own wireless terminal transmits data to another wireless terminal. When transmitting to another wireless terminal with a transmission power setting higher than the lower limit transmission power setting, the own wireless terminal determines that the reception power at the control station is the power capable of receiving the packet. The lower limit transmission power setting is derived by (maximum transmission power) − (expected surplus reception power).
Here, the expected surplus received power is information indicating how much minus dB the packet can be received, which is stored in the expected surplus received power information.

Here, determination of success of data transmission will be described. The data communication procedure can be divided into data transmission (request transmission) and data transmission confirmation (response transmission) as shown in FIG. In request transmission, request data is transmitted to the responding wireless terminal. In response transmission, the responding wireless terminal transmits response data to the requesting wireless terminal. By transmitting the request data, the requesting wireless terminal requests the responding wireless terminal to operate the content of the request data as request transmission. After receiving the request data, the responding wireless terminal performs an operation based on the content of the data, and transmits the response data to the requesting wireless terminal as a response transmission of the request data reception result. The requesting wireless terminal
By receiving the response data, it is known that the request data has been received, and the communication ends.

FIG. 17 is a schematic diagram of a request data packet, and FIG. 18 is a schematic diagram of a response data packet. As shown in FIGS. 17 and 18, the sequence numbers in the request data are numbered for each request data.
The sequence number in the response data stores the sequence number of the request data to which the responding wireless terminal responds. The requesting wireless terminal determines from the sequence number in the response data
Judge which request data is the response.

Upon detecting the sequence number in the response data, the requesting wireless terminal determines that the request data transmission of the sequence number has been successful. If the transmission times out without confirming the success of the transmission after transmitting the request data, it is determined that the transmission of the request data has failed. When determining that the data transmission has failed, the requesting wireless terminal retransmits the requested data.

When the responding wireless terminal receives the sequence number of the transmitted response data from the requesting wireless terminal again,
It is determined that transmission of the response data has failed. If the request data of the transmitted sequence number is not retransmitted before the transmission of the response data times out, it is determined that the transmission was successful. However, the time required to determine that the transmission has been successful is much longer than that of the request academic communication because it waits for a timeout.

Next, processing in the transmission process will be described.
FIG. 13 is a flowchart showing the process of the transmission process, in which S indicates each step of the flow. The operation of the transmission process is performed according to the following procedure. First, an operation in the case of performing fine control of transmission power will be described. When slightly increasing the transmission power, an operation of increasing the transmission power setting by one step is performed. When the transmission power is slightly lowered, an operation of lowering the transmission power setting by one step is performed. When the transmission power setting is increased by one step, for example, an operation of increasing the transmission power by 0.5 dBm is performed. When lowering the transmission power setting, for example, an operation of lowering the transmission power by 0.5 dBm is performed.

(1) It is determined whether the transmission power is small (step S1). When the data unreceivable power flag of each terminal information in the operation status report packet is set, it is determined that the transmission power is small. Otherwise,
It is determined that the communication quality is stable. (2) If the transmission power is not low, it is determined that the communication quality is stable, the transmission power setting is derived in step S2, data transmission is performed in step S4, and the transmission process ends. (3) When the transmission power is low, it is determined that the communication quality is unstable, the transmission power setting is increased by one step (for example, 0.5 dBm) in step S3, and data transmission is performed in step S4 to perform transmission process processing. To end.

FIG. 14 is a flowchart showing the process of deriving the transmission power setting when the communication quality is stable.
This corresponds to the process of step S13 in FIG. First, in step S11, it is determined whether or not the transmission power setting is larger than the lower limit transmission power setting. If the transmission power setting is equal to or less than the lower limit transmission power setting, the control station data reception impossible power flag of the wireless terminal information is set in step S12. It is determined whether or not it has been performed. If the transmission power setting is larger than the lower limit transmission power setting in step S11, or if the control station data reception impossible power flag of the wireless terminal information is not set in step S12, the transmission power setting is changed in step S13. It is determined whether the data transmission is successful.

If the data transmission is successful after the transmission power setting is changed, the transmission power setting is lowered by one step in step S14, and this flow is terminated. After the transmission power setting is changed, the data transmission is not successful. In this case, step S15
Then, the transmission power setting is maintained as it is, and this flow ends. On the other hand, if the control station data non-reception power flag of the wireless terminal information is set in step S12, the transmission power setting is increased by one step in step S16, and this flow ends.

As described above, when the transmission power setting is larger than the lower limit transmission power setting for the control station of the own radio terminal,
If the data transmission is successful after changing the transmission power setting, the transmission power setting is lowered by one step, and if the data transmission is not successful after changing the transmission power setting, the transmission power setting is maintained.

When the transmission power setting is smaller than the lower limit transmission power setting for the control station of the own radio terminal, and when the control station data reception impossible power flag of the radio terminal information is set, the transmission power setting is set to one. If the transmission power setting has not been set, and the data transmission has succeeded after changing the transmission power setting, the transmission power setting is reduced by one step.
If data transmission is not successful after changing the transmission power setting, the transmission power setting is maintained as it is.

Next, the processing in the receiving process will be described.
FIG. 15 is a flowchart showing the processing in the receiving process. The operation of the receiving process is performed according to the following procedure. (1) Between the previous reception process and the current reception process,
It is determined whether the maximum received power has been updated (step S21). (2) When the maximum received power is updated, the attenuator 14
Is derived (step S22).

The wireless terminal, even when its own wireless terminal is receiving a low-power packet, suddenly starts transmitting at the maximum transmission power at the transmitting wireless terminal, the AGC circuit. The attenuator 14 is designed so that the reception power control can be performed only by the control of No. 15. The wireless terminal compares the maximum received power with the control range of the AGC circuit 15. When it is determined that the maximum received power is out of the control range of the AGC circuit 15, when the received power is the maximum received power, the AGC circuit 1
The setting of the attenuator 14 is derived so as to be within the control range of 5.

(3) AGC according to the setting of the attenuator 14
The setting of the circuit 15 is derived (step S23). The wireless terminal derives the setting of the AGC circuit 15 when the data of the previous reception power is received with the current setting of the attenuator 14.
When the setting of the attenuator 14 is changed, the wireless terminal corrects the setting of the AGC circuit 15 by the change amount of the setting of the attenuator 14.

(4) Automatic control by the AGC circuit 15 is performed (step S25). In step S24, it is determined whether or not data is being received. If data is not being received, the process in the receiving process is terminated.
The automatic control by the GC circuit 15 is repeated until no data is received. The wireless terminal controls the received power by the AGC circuit 15 automatically controlling the received power during data reception.

As described above, in each wireless terminal of the wireless communication system according to the present embodiment, the controller 18 includes the storage 1 circuit 19 for storing the communication quality A between the control station and each wireless terminal, and each wireless terminal. A storage circuit 20 for storing the communication quality B between the terminals is provided, the transmission power level of the own wireless terminal is determined based on the communication quality A and the communication quality B, and the transmission power level is determined to be the determined transmission power level. Since the transmission power is controlled by switching the transmission power level of the transmission amplifier 12, each wireless terminal can improve the communication quality between its own wireless terminal and the other wireless terminal, and between its own wireless terminal and the control station. Judgment can be made, and transmission can be performed such that radio waves reach both the control station and the transmitting-side wireless terminal according to the communication quality.

In other words, since the wireless terminal holds the communication quality up to the wireless terminal to be transmitted in advance, it can transmit at an appropriate transmission intensity without establishing a communication path, and the communication establishment time can be reduced. Significant shortening and power saving can be achieved. Further, since each wireless terminal independently performs the above-described transmission power control, it is possible to reduce the burden of the control station managing the control of the transmission power of all terminals in the system, and reduce communication overhead. .

As described above, when the communication environment fluctuates greatly as in the case of wireless communication, the radio waves reach both the control station and the transmitting wireless terminal so that communication between the wireless terminals is enabled. Transmission settings can be derived, and transmission power can be appropriately controlled. The above embodiment is an example applied to a wireless communication system including a control station and a wireless terminal wirelessly connected to the control station.
The present invention is applicable to any communication system such as the M (Orthogonal Frequency Division Multipex) system and the TDMA system.

In the above embodiment, the names of the control station and the radio terminal are used, but this is for convenience of explanation, and may be, for example, a base station, a mobile station, or the like. Further, it may be incorporated in a part of a communication device or the like, and may be a PDA (Personal Digital Assistant) having the above-mentioned wireless communication function.
t) and small notebook computers.

In this embodiment, the controller 1
8 is a storage 1 circuit 19 for storing a communication quality A between the control station and each wireless terminal, and a communication quality B between each wireless terminal.
, The type of storage means, storage method, and the like are not limited to the above-described embodiment. For example, the storage circuits 19 and 20 need only be functionally separated, and need not be divided into two hardware. Further, the controller may be provided outside the controller 18.

Further, the types and numbers of the attenuators, amplifiers, AGC circuits and the like constituting the receiving apparatus are not limited to those in the above-described embodiment. In this embodiment, the high-frequency band-pass filter (RFBPF), the intermediate frequency band-pass filter (IFBPF), and the like are not shown, but it is needless to say that these may be provided.

[0077]

As described above in detail, according to the present invention, the control station does not manage the control of the transmission power, and the radio terminals of the non-control stations judge the communication quality and determine the appropriate transmission power. The setting can be appropriately set, and each wireless terminal can perform appropriate transmission power control according to communication quality by its own judgment. Therefore, even when the communication environment fluctuates greatly as in the case of wireless communication, the transmission power is appropriately controlled, and communication between wireless terminals becomes possible.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a transmission / reception unit of a wireless terminal in a wireless communication system according to an embodiment of the present invention.

FIG. 2 is a table showing a storage example of reception results in a control station stored in each wireless terminal of the wireless communication system according to the present embodiment.

FIG. 3 is a table showing a storage example of a data reception impossible power flag stored in each wireless terminal of the wireless communication system according to the present embodiment.

FIG. 4 is a schematic diagram illustrating a schematic configuration of a wireless communication system according to the present embodiment.

FIG. 5 is a schematic diagram illustrating a configuration of a radio frame used by the radio communication system according to the present embodiment.

FIG. 6 is a schematic diagram illustrating a configuration of a frame start area of the wireless communication system according to the present embodiment.

FIG. 7 is a schematic diagram illustrating a configuration of wireless terminal information of the wireless communication system according to the present embodiment.

FIG. 8 is a diagram illustrating an example of information stored in expected surplus received power information of the wireless communication system according to the present embodiment.

FIG. 9 is a diagram showing an example of information stored in a control station data non-reception power flag of the wireless communication system according to the present embodiment.

FIG. 10 is a schematic diagram illustrating a configuration of an operation status report packet of the wireless communication system according to the present embodiment.

FIG. 11 is a schematic diagram of each terminal information of the wireless communication system according to the present embodiment.

FIG. 12 is a diagram illustrating an example of information stored in a data reception impossible power flag of the wireless communication system according to the present embodiment.

FIG. 13 is a flowchart illustrating processing in a transmission process of the wireless communication system according to the present embodiment.

FIG. 14 is a flowchart illustrating a process of deriving a transmission power setting when the communication quality of the wireless communication system according to the present embodiment is stable.

FIG. 15 is a flowchart showing processing in a receiving process of the wireless communication system according to the present embodiment.

FIG. 16 is a schematic diagram showing a flow of a data communication procedure of the wireless communication system.

FIG. 17 is a schematic diagram of a request data packet of the wireless communication system.

FIG. 18 is a schematic diagram of a response data packet of the wireless communication system.

FIG. 19 is a schematic diagram illustrating an example of an arrangement of wireless terminals in a wireless communication system.

FIG. 20 is a schematic diagram of an example of a wireless terminal arrangement in a wireless communication system.

FIG. 21 is a schematic diagram of an example of a wireless terminal arrangement in a wireless communication system.

[Explanation of symbols]

 Reference Signs List 10 transmitting / receiving section of wireless terminal 11 antenna 12 transmission amplifier (switching means) 13 modulation section 14 attenuator (attenuator) 15 AGC circuit 16 demodulation section 17 RSSI circuit 18 controller (control means) 19 storage 1 circuit (storage means) 20 storage 2 Circuit (storage means)

Claims (12)

[Claims] 1. A wireless communication system comprising: a control station; and a plurality of wireless terminals wirelessly connected to the control station. The wireless communication system enables direct communication between the wireless terminals. Switching means for switching, communication quality A between the control station, and n (n is an arbitrary natural number) communication qualities b1, b2,
, Bn, and communication quality A and communication quality b stored in the storage means
1, b2,..., Bn, a transmission power level is determined, and control means for switching the switching means to reach the determined transmission power level is transmitted to another wireless terminal at the determined transmission power level. A wireless communication system comprising: a transmission unit that performs data transmission. 2. The communication quality A or the communication qualities b1, b
2. The wireless communication system according to claim 1, wherein 2,..., Bn include communication quality information based on a reception result when transmitting at a known transmission power. 3. The communication quality A or the communication qualities b1, b
2,..., Bn include information indicating a margin value up to a lower limit of receivable power of each wireless terminal calculated by the control station based on a reception result when transmitting at a known transmission power. The wireless communication system according to claim 1. 4. The communication quality A or the communication qualities b1, b
4. The wireless communication system according to claim 1, wherein 2,..., Bn include communication quality information based on a reception result when each wireless terminal performs transmission power control. 5. The communication quality for a reception result when each of the wireless terminals performs transmission power control is sufficient / insufficient.
The wireless communication system according to claim 4, further comprising value information. 6. The communication quality A includes the margin value, and the binary information includes the communication quality A and the communication quality b.
, Bn,..., Bn, and when each wireless terminal transmits at a transmission power larger than the transmission power indicated by the margin value, the communication quality b1, b2,
, Bn, the transmission power is controlled by the binary information, and when transmission is performed at a transmission power smaller than the transmission power indicated by the margin value, the communication quality A and the communication qualities b1, b2,
The wireless communication system according to claim 3, wherein transmission power is controlled by the binary information included in ..., bn. 7. A wireless communication method for a wireless communication system comprising a control station and a plurality of wireless terminals wirelessly connected to the control station, wherein the wireless terminals can directly communicate with each other. The communication quality A between the control station and the own wireless terminal and the n communication qualities b1, b2,..., Bn between the own wireless terminal and each of the other wireless terminals are stored. A wireless communication method characterized by performing transmission power control of its own wireless terminal based on A and communication qualities b1, b2, ..., bn. 8. The communication quality A or the communication qualities b1, b
8. The wireless communication method according to claim 7, wherein 2,..., Bn include communication quality information based on a reception result when transmitting at a known transmission power. 9. The communication quality A or the communication qualities b1, b
, Bn include information indicating a margin value up to a lower limit of receivable power of each wireless terminal calculated by the control station based on a reception result when transmitting at a known transmission power. The wireless communication method according to claim 7. 10. The communication quality A or communication quality b1, b
The wireless communication method according to any one of claims 7 to 9, wherein 2, ..., bn include communication quality information based on a reception result when each wireless terminal performs transmission power control. 11. The wireless communication method according to claim 10, wherein the communication quality with respect to the reception result when each of said wireless terminals performs transmission power control includes binary information of sufficient / insufficient. 12. The communication quality A includes the margin value, and the binary information includes the communication quality A and the communication quality b.
, B2,..., Bn. When each wireless terminal transmits at a transmission power higher than the transmission power indicated by the margin value, the communication quality b1, b
When the transmission power is controlled by the binary information included in 2,..., Bn and the transmission power is smaller than the transmission power indicated by the margin value, the communication quality A and the communication qualities b1, b2,
The wireless communication method according to claim 9, wherein the transmission power is controlled based on the binary information included in..., Bn.