WO2013190671A1 - Station sans fil, système de communication sans fil, et procédé - Google Patents

Station sans fil, système de communication sans fil, et procédé Download PDF

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Publication number: WO2013190671A1
Authority: WO; WIPO (PCT)
Prior art keywords: wireless; unit; station; communication; transmission method
Prior art date: 2012-06-20
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Ceased

Application number

PCT/JP2012/065789

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English (en)

Japanese (ja)

Inventor

玉木　諭

雄介正村

栄里子武田

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Hitachi Ltd

Original Assignee

Hitachi Ltd

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

2012-06-20

Filing date

2012-06-20

Publication date

2013-12-27

2012-06-20 Application filed by Hitachi Ltd filed Critical Hitachi Ltd

2012-06-20 Priority to PCT/JP2012/065789 priority Critical patent/WO2013190671A1/fr

2012-06-20 Priority to JP2014521159A priority patent/JP5820069B2/ja

2013-12-27 Publication of WO2013190671A1 publication Critical patent/WO2013190671A1/fr

2014-12-20 Anticipated expiration legal-status Critical

Status Ceased legal-status Critical Current

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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/16—Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
- H04W28/18—Negotiating wireless communication parameters

Definitions

the present invention relates to a radio station, a radio communication system, and a method, and more particularly, to a radio communication technique for performing communication by controlling a communication method such as a modulation method according to a communication situation.
wireless data communication is used for various purposes.
wireless communication is characterized in that the propagation environment is more likely to vary than wired communication, and that the amount of data that can be communicated per time is likely to vary with changes in the propagation environment.
the modulation method, error correction method, etc. are adaptively changed following such fluctuations to control the transmission data rate.
Patent Document 1 discloses a technique for selecting a modulation method based on a bit error rate detected by error correction processing.
Patent Document 2 discloses a technique for detecting a movement situation using GPS or the like and switching a polling cycle of a base station group as a connection destination candidate so as to increase the frequency during movement, for example, according to the movement situation.
Patent Document 3 discloses a technique for selecting and switching a wireless communication method such as a modulation method according to the speed and acceleration of a moving body.
an object of the present invention is to provide a radio station, a radio communication system, and a method capable of achieving a stable data communication speed even when a propagation environment changes due to movement of the radio station. Is to provide.
a radio station in a radio communication system that performs communication between a plurality of radio stations, a transmission method determining unit that changes a data communication speed according to communication quality, and a radio A mobile state detector that detects the mobile state of the station, and when the mobile state detector detects that the wireless station is moving, the transmission method determination unit reduces the communication speed when the signal communication quality decreases.
a radio station configured to suppress the above.
a wireless communication system that performs communication between a plurality of wireless stations, wherein the wireless station changes a data communication speed according to communication quality.
at least one wireless station includes a movement state detection unit that detects a movement state of the wireless station, and when the movement state detection unit detects that the wireless station is moving, the transmission method determination unit Provided is a wireless communication system configured to suppress a decrease in communication speed when signal communication quality is deteriorated.
a wireless communication method for performing communication between a plurality of wireless stations, wherein the wireless station changes the data communication speed according to the communication quality.
the wireless station changes the data communication speed according to the communication quality.
the present invention it is possible to provide a radio station, a radio communication system, and a method capable of achieving a stable data communication speed even when a propagation environment changes due to movement of the radio station or the like. To do.
FIG. 3 is a diagram illustrating an example of a functional configuration of a mobile station that communicates with the mobile station according to the first embodiment. It is a figure for demonstrating an example of the production method of the movement state used for the transmission system determination in the movement state determination part based on Example 1.
FIG. 1 is a figure which shows an example of the flow of the transmission system determination process of the transmission system determination part based on Example 1.
FIG. 1 is a first example of a functional configuration diagram of a fixed station that communicates with a mobile station according to the first embodiment.
FIG. 3 is a diagram illustrating an example of a functional configuration of a mobile station that communicates with a fixed station according to the first embodiment.
FIG. 6 is a diagram illustrating another example of a functional configuration of a mobile station that communicates with the mobile station according to the first embodiment.
FIG. 6 is a diagram illustrating another example of a functional configuration of a fixed station that communicates with a mobile station according to the first embodiment.
FIG. 6 is a diagram illustrating another example of a functional configuration of a mobile station that communicates with a fixed station according to the first embodiment.
1 is a diagram illustrating an example of a hardware configuration of a radio station according to Embodiment 1.
FIG. It is a figure which shows the 1st example of the transmission signal output from a transmission part based on Example 1.
FIG. It is a figure which shows the 2nd example of the transmission signal output from the transmission part based on Example 1.
FIG. 1 is a diagram illustrating an example of a wireless communication system according to the first embodiment and its peripheral configuration.
the present embodiment is a wireless communication system that performs communication between a plurality of wireless stations, the wireless station includes a transmission method determining unit that changes a data communication speed according to communication quality, and at least one wireless station includes: Provided with a movement state detection unit that detects the movement state of the wireless station, when the movement state detection unit detects that the wireless station is moving, the transmission method determination unit reduces the communication speed when the signal communication quality decreases.
a movement state detection unit that detects the movement state of the wireless station, when the movement state detection unit detects that the wireless station is moving, the transmission method determination unit reduces the communication speed when the signal communication quality decreases.
the wireless communication system 100 includes a plurality of wireless stations 101 to 105.
Each wireless station has a wireless communication function, and communicates wirelessly with one or more wireless stations.
the wireless station 101, the wireless station 103, the wireless station 104, and the wireless station 102 and the wireless station 105 are performing wireless communication.
Each of the wireless stations 101 to 105 also has an interface function, and is connected to the network 110 or the devices 120 to 122 via the interface function.
the devices 120 to 122 communicate with the center 111 via the wireless communication system 100 and the network 110, for example, the measurement results obtained by each device are aggregated in the center 111, or according to instructions from the center 111, Operation is controlled.
the devices 120 to 122 may directly communicate with each other via the wireless communication system 100.
the radio station and the device are described separately, but it is not necessary that the functions of the radio station and the device are physically different. For example, the functions are implemented on the same hardware. May be.
radio stations that is, radio stations corresponding to the radio stations 103 to 105 in the example of FIG. 1, each have a moving state detection function inside, and are used for radio communication control.
a radio station that has a movement state detection function and is used for control of radio communication is referred to as a mobile station.
a wireless station that does not have a movement state detection function and a wireless station that does not use its own movement state detection function for wireless communication control are called fixed stations.
FIG. 2 is a diagram illustrating a first example of a functional configuration of a mobile station that communicates with the mobile station according to the present embodiment.
the mobile stations that communicate with the mobile station of this example are a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a mobile information signal extraction unit 214, a transmission unit 220, respectively. It has a transmission method determination unit 221, a movement state determination unit 230, a movement state detection unit 231 that realizes the above-described movement state detection function, and a movement information signal generation unit 232.
control lines, signal lines, and the like between the radio station controller 200 and other component blocks are omitted.
the wireless station control unit 200 transmits and receives messages between wireless stations, controls the operation of the entire wireless station, and holds information related to the operation of the entire wireless station. For example, the radio station control unit 200 notifies the transmission unit 220 of the parameters related to signal transmission, such as the presence / absence of signal transmission, the signal transmission time, and the transmission power, and the presence / absence of signal reception and the signal to the reception unit 210. Notifies parameters related to signal reception such as reception time. Also, the reception quality determination unit 211 is notified of parameters for obtaining reception quality information such as an averaging method.
the radio transmission / reception unit 201 converts the frequency of the transmission signal input from the transmission unit 220, converts the frequency into a radio frequency transmission signal, and transmits the signal via the antenna.
the radio transmission / reception unit 201 also converts the frequency of the radio frequency reception signal received via the antenna, generates a reception signal, and outputs the reception signal to the reception unit 210.
the interface unit 202 connects the wireless station with other networks and devices.
the interface unit 202 When the reception information is received from the reception unit 210, the interface unit 202 outputs the reception information to a connected device or network according to an accompanying destination.
the interface unit 202 When receiving transmission information from a device or network outside the wireless station, the interface unit 202 outputs the transmission information to the transmission unit 220.
the receiving unit 210 performs processing such as demodulation and decoding on the reception signal input from the wireless transmission / reception unit 201 according to the control signal included in the reception signal and the parameter notified from the wireless station control unit 200, and the result is obtained.
the received information is output to the interface unit 202, the movement information signal is output to the movement information signal extraction unit 214, and the control information is notified to the radio station control unit 200.
the receiving unit 210 also outputs information about the presence or absence of errors in received information obtained as a result of processing such as demodulation and decoding, and information such as received signal power, interference power, and noise power to the received quality determining unit 211.
the reception quality determination unit 211 determines the reception quality based on the information input from the reception unit 210, and outputs the reception quality determination information to the transmission method determination unit 221.
the movement information signal extraction unit 214 decodes the movement information signal input from the reception unit 210, extracts the movement state of the opposite station indicating the presence / absence of movement of the opposite station, and outputs it to the movement state determination unit 230.
the transmission unit 220 receives the transmission information input from the interface unit 202, the movement information input from the movement information signal generation unit 232, the control information input from the wireless station control unit 200, and the like from the wireless station control unit 200. Processing such as encoding and modulation is performed according to the notified parameters and the transmission method information input from the transmission method determination unit 221, a control signal necessary for performing wireless communication is added, a transmission signal is created, and wireless transmission / reception is performed. Output to the unit 201. A specific example of this transmission signal will be described later.
the transmission scheme determination unit 221 determines a transmission scheme including a modulation scheme and an encoding scheme in advance based on the reception quality determination information input from the reception quality determination unit 211 and the movement state determination information input from the movement state determination unit 230. From the prepared method list, a transmission method having a higher data rate is selected and determined as the overall reception quality is higher, and transmission method information is output to the transmission unit 220.
a transmission method with a high data rate means, for example, a modulation method with a high number of bits per symbol or a coding method with a high coding rate
a transmission method with a low data rate means, for example, a modulation method with a low number of bits per symbol, It means a coding method with a low coding rate.
QPSK has a higher data rate than BPSK, and 16QAM, 64QAM, and 256QAM are higher than QPSK.
the coding method for example, when the error correction coding is not performed, the data rate is the highest, the coding rate is 5/6, the coding rate is 3/4, the coding rate is 1/2, and the coding rate is 1/3. The lower the coding rate, the lower the data rate.
the movement state determination unit 230 determines a movement state used for transmission method determination. Information is created and output to the transmission method determination unit 221.
the movement state detection unit 231 that implements the movement state detection function detects the movement state of the local station using a sensor or the like, and outputs it to the movement state determination unit 230 and the movement information signal generation unit 232.
the moving state of the own station is information indicating that the wireless station is stopped or moving, and is information indicating the degree or the like if the wireless station is moving. For example, if the movement state is quantized in four ways, there is no information indicating that the movement state cannot be acquired due to sensor data acquisition failure or the like, the stop indicating that the wireless station is stopped, the wireless station is moving, but the movement It is expressed as small movement indicating that the degree of is small and large movement indicating that the radio station is moving and large.
a position measuring means such as GPS (Global Positioning System), an acceleration sensor, or the like is used.
the position measuring means in the moving state detection unit 231 for example, the measured position information is differentiated in the time direction to acquire the position fluctuation per unit time, and after this position fluctuation is directly or time averaged If it is stopped or moving by comparing with the threshold value, or if it is moving, it is judged to that extent.
prior information regarding the movement of the radio station may be used. For example, if there is prior information that the movement range of the radio station does not exceed a preset range, if a position outside the range is detected, the position information measured as a false detection is discarded, and the movement state is information Outputs none.
speed information is acquired by integrating in the time direction after removing fixed components such as gravitational acceleration from the output of the acceleration sensor, and this speed information is directly obtained. Or, after averaging the time, it is compared with the threshold value to determine whether it is stopped or moving, or if it is moving. Also, for example, if acceleration is used as it is without integration and it is determined that it is stopped or moving by comparing it with the threshold value directly or after averaging the acceleration, it is determined whether it is moving or It may be determined whether or not it is determined that the movement is a degree.
the vehicle may be moving for a certain time after detecting an acceleration equal to or greater than a threshold and is stopped after a certain time has elapsed.
prior information regarding the movement of the radio station may be used for these determinations. For example, if there is prior information that the radio station is stopped in a specific time zone, the moving state is output as being stopped regardless of the measurement result of the acceleration sensor, and the integral value of the held acceleration is set to zero.
the movement information signal generation unit 232 encodes the movement state of the own station input from the movement state detection unit 231 and outputs it to the transmission unit 220 as a movement information signal.
FIG. 3 is a diagram illustrating an example of a table showing a moving state creation method used for determining a transmission method in the moving state determination unit 230.
the movement state used for determining the transmission method is represented by three types of 0, 1, and 2.
the movement state of the opposite station input from the movement information extraction unit 214 and the own station input from the movement state detection unit 231 are displayed. From the moving state, select 2 if one or both moving states are large, select 1 if both moving states are not large and one or both are small, otherwise select 0. is doing.
the output value is selected based on a selection policy that matches the movement state on the side where the movement of the own station and the opposite station is intense, but other selection policies may be used.
the selection policy which selects a value according to the average of the movement state of an own station and an opposite station.
the movement state used for determining the transmission method is ternary. However, for example, it may be represented by only two values of 0 indicating that the vehicle is stopped and 1 indicating that the vehicle is moving, or may be expressed by multiple values. Also good.
the reception quality output by the reception quality determination unit 211 the number of errors within a certain range is used.
the reception quality judgment unit 211 uses the error presence / absence information input from the reception unit 210 and occurs within a certain time range or while receiving a certain number of data.
the number of errors is output to the transmission method determination unit 221.
the number of errors may be the number of bits in which an error has occurred, or may be the number of error detection codes such as CRC that detected an error.
the reciprocal of the elapsed period from the previous error occurrence may be used.
the transmission method determination unit 221 changes the transmission method so that the data rate is increased if the number of errors is small, and the data rate is decreased if the number of errors is large. Change the transmission method to. However, correction is performed so that the determination of lowering the data speed is less likely to occur when the degree of movement is large due to the movement state input from the movement state determination unit 230.
FIG. 4 is a diagram illustrating an example of the flow of the transmission method determination process of the transmission method determination unit 221.
the transmission method determination unit 221 performs control so as to suppress a decrease in communication speed when a signal communication quality decreases when a wireless station performing communication is moving.
a speed increase threshold Tu and a speed decrease threshold Td are set for the number of errors.
the speed increase threshold Tu is a value for determining that the current communication is sufficiently stable
the speed decrease threshold Td is a value for determining that the current communication is unstable.
Td ⁇ Tu is satisfied.
the signal reception speed decrease threshold Td set in the process 401 is set in order to suppress a decrease in the communication speed when the signal reception quality detected based on the number of errors is reduced according to the movement state of the wireless station.
the movement state notified from the movement state determination unit 230 is three values of 0, 1, and 2, and the degree of movement is larger as the value is larger, the value Td0 selected as Td when the movement state is 0, the movement state Between the value Td selected as Td when 1 is 1 and the value Td2 selected as Td when the movement state is 2, a relationship of Td0 ⁇ Td1 ⁇ Td2 is established.
the number of errors input from the reception quality determination unit 211 is compared with the speed decrease threshold Td set according to the movement state. If the number of errors is equal to or greater than the speed decrease threshold Td, the process 403 is performed. In other cases, the process branches to processing 404.
the transmission scheme is updated so that the data rate is lower than the transmission scheme in use.
the transmission method determination unit 21 according to the present embodiment can suppress the decrease in the communication speed when the signal reception quality decreases in accordance with the movement state of the wireless station that performs communication. Become. It should be noted that the transmission method is not updated when the data rate is the lowest among the transmission methods that can be selected. Also, in the process 403, random numbers may be used, and the transmission method may be updated so that the data rate is lower than the transmission method in use with a certain probability. In other cases, the transmission method may not be updated. .
the process 404 the number of errors input from the reception quality judgment unit 211 is compared with the speed increase threshold Tu, and if the number of errors is greater than or equal to the speed increase threshold Tu, the process branches to process 406, and otherwise the process branches to process 405.
the transmission scheme is updated so that the data rate is higher than the transmission scheme in use. Note that the transmission method is not updated when the data rate is the highest among the transmission methods that can be selected.
random numbers may be used to update the transmission method so that the data rate is higher than the transmission method being used with a certain probability, and in other cases, the transmission method may not be updated. .
the transmission method when the transmission method is updated, the updated transmission method is output to the transmission unit 220, and when the update is not performed, the transmission method determination process is terminated.
a channel quality value is used.
the reception quality determination unit 211 uses the power information input from the reception unit 210, for example, the channel quality value is obtained by averaging or quantizing the received signal power value. Is output to the transmission method determination unit 221.
the result of averaging or quantization performed on the ratio between the received signal power value and the noise power value is output to the transmission power determining unit 221 as a channel quality value.
the result of averaging or quantization performed on the ratio of the sum of the noise power value and the interference power value and the received power value is output to the transmission power determining unit 221 as a channel quality value.
the transmission method determination unit 221 selects a higher data rate as the channel quality value is higher and a lower data rate as the channel quality value is lower.
the transmission method determination unit 221 selects a higher data rate as the channel quality value is higher and a lower data rate as the channel quality value is lower.
FIG. 5 is a functional block diagram showing another example of the flow of the transmission method determination process of the transmission method determination unit 221 of the present embodiment, and shows an example in which a channel quality value is used as the reception quality.
the channel quality value input as the reception quality from the reception quality determination unit 211 is stored in the channel quality storage unit 501.
the movement state input from the movement state determination unit 230 is stored in the movement state storage unit 502.
the weighted average unit 503 extracts channel quality values for a certain period from the channel quality accumulation unit 501, retrieves the movement state for the corresponding period from the movement state accumulation unit, and uses the weight coefficient determined by the movement state to use the channel quality value To obtain an average channel quality value.
the weighting factor is a value selected so as to decrease as the degree of movement in the movement state increases.
the weighting factor w0 is 1 when the movement state is 0 and the movement state is 1.
a relationship of w0 ⁇ w1 ⁇ w2 holds between the weighting factor w1 at the time and the weighting factor w2 when the movement state is 2.
a weighting factor that decreases the weight as the channel quality value becomes older may be added.
the method selection unit 504 selects a transmission method in which the higher the average channel quality value, the higher the data rate, and the lower the average channel quality value, the lower the data rate.
the method change comparison unit 505 compares the transmission method selected by the method selection unit 504 with the transmission method recorded in the selection method recording unit 506. As a result of the comparison, when the data rate of the transmission method selected by the method selection unit 504 is lower and the latest movement state acquired from the movement state storage unit 502 indicates that it is moving, the data is recorded in the selection method recording unit 506
the transmission method selected is output from the transmission method determination unit 221, and the transmission method selected by the method selection unit 504 is recorded in the selection method recording unit 506. If the above conditions are not satisfied, the transmission method selected by the method selection unit 504 is output as the transmission method determination unit 221, and the transmission method selected by the method selection unit 504 is recorded in the selection method recording unit 506.
the method change comparison unit 505 may be omitted and the output of the method selection unit 504 may be used as the output of the transmission method determination unit 221 as it is.
FIG. 6 is a diagram illustrating a first example of a functional configuration of a fixed station that communicates with a mobile station according to the present embodiment.
the fixed station that communicates with the mobile station of the present embodiment includes a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a movement information signal extraction unit 214, a transmission unit 220, A transmission method determination unit 221 and a movement state determination unit 230 are included.
the functions and operations are the same as the functions and operations of the parts having the same names and symbols in the mobile station communicating with the mobile station shown in FIG.
the transmission unit 220 in the fixed station that communicates with the mobile station receives the parameter notified from the wireless station control unit 200 with respect to the transmission information input from the interface unit 202, the control information input from the wireless station control unit 200, and the like. And processing such as encoding and modulation according to the transmission method information input from the transmission method determining unit 221, creating a transmission signal by adding a control signal necessary for performing wireless communication, Output.
the movement state determination unit 230 in the fixed station that communicates with the mobile station creates a movement state used for transmission scheme determination based on the movement information of the opposite mobile station input from the movement information signal extraction unit 214, and transmits The data is output to the method determination unit 221.
the movement state used for determining the transmission method for example, the table of FIG.
FIG. 7 is a diagram illustrating a first example of a functional configuration of a mobile station that communicates with a fixed station according to the present embodiment.
the mobile station that communicates with the fixed station of this embodiment includes a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a transmission unit 220, a transmission method determination unit 221, and a mobile unit.
a state determination unit 230, a movement state detection unit 231, and a movement information signal generation unit 232 are included.
the functions and operations of the information signal generator 232 are the same as the functions and operations of the parts having the same names and symbols in the mobile station that communicates with the mobile station in the example of FIG.
the receiving unit 210 also outputs information about the presence or absence of errors in received information obtained as a result of processing such as demodulation and decoding, and information such as received power, interference power, and noise power to the received quality determining unit 211.
the movement state determination unit 230 in the mobile station that communicates with the fixed station in this example creates a movement state used for transmission method determination based on the movement state of the own station input from the movement state detection unit 231 and transmits the transmission state.
the data is output to the method determination unit 221.
the movement state used for determining the transmission method for example, the table in FIG.
a mobile station that communicates with the mobile station of this example includes a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a quality information signal generation unit 212, and a quality information signal extraction unit. 213, a movement information signal extraction unit 214, a transmission unit 220, a transmission method determination unit 221, a movement state determination unit 230, a movement state detection unit 231, and a movement information signal generation unit 232.
FIG. 2 Functions and operations of the wireless station control unit 200, the wireless transmission / reception unit 201, the interface unit 202, the movement information signal extraction unit 214, the movement state determination unit 230, the movement state detection unit 231, and the movement information signal generation unit 232 in this example are illustrated in FIG. This is the same as the function and operation of the part having the same name and the same symbol in the mobile station that communicates with the mobile station of Example 2.
the function and operation of the reception quality determination unit 211 in this example is to communicate with the mobile station in the example of FIG. 2 except that the reception quality determination information is output to the quality information signal generation unit 212 instead of the reception method determination unit 221. This is the same as the function and operation of the reception quality determination unit 211 in the mobile station to be performed.
the function and operation of the transmission method determination unit 221 of this example is the same as that of the mobile station of the example of FIG. 2 except that reception quality determination information is received as an input from the quality information signal extraction unit 213 instead of the reception quality determination unit 211. This is the same as the function and operation of the reception quality determination unit 211 in the mobile station that performs communication.
the receiving unit 210 of this example performs processing such as demodulation and decoding on the received signal input from the wireless transmitting / receiving unit 201 according to the control signal included in the received signal and the parameter notified from the wireless station control unit 200,
the reception information obtained as a result is output to the interface unit 202
the quality information signal is output to the quality information signal extraction unit 213
the movement information signal is output to the movement information signal extraction unit 214
the control information is transmitted to the radio station control unit 200.
the receiving unit 210 also outputs information about the presence or absence of errors in received information obtained as a result of processing such as demodulation and decoding, and information such as received signal power, interference power, and noise power to the received quality determining unit 211.
the transmission unit 220 in this example includes transmission information input from the interface unit 202, quality information signal input from the quality information signal generation unit 212, movement information input from the movement information signal generation unit 232, and the radio station control unit 200.
the control information and the like input from the base station are subjected to processing such as encoding and modulation according to the parameters notified from the wireless station control unit 200 and the transmission method information input from the transmission method determining unit 221.
a necessary control signal or the like is added to create a transmission signal, which is output to the wireless transmission / reception unit 201. A specific example of this transmission signal will be described later with reference to FIG.
the quality information signal generation unit 212 of this example encodes the reception quality of the signal received by the local station input from the reception quality determination unit 211, and outputs the encoded quality information signal to the transmission unit 220.
the quality information signal extraction unit 213 of this example decodes the quality information signal input from the reception unit 210, extracts the reception quality of the signal received by the opposite station, and inputs the extracted quality information signal to the transmission method determination unit 221.
FIG. 9 is a diagram illustrating a second example of the functional configuration of the fixed station that performs communication with the mobile station according to the present embodiment.
the fixed station that communicates with the mobile station of this example includes a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a quality information signal generation unit 212, and a quality information signal extraction unit. 213, a movement information signal extraction unit 214, a transmission unit 220, a transmission method determination unit 221, and a movement state determination unit 230.
the functions and operations of the mobile information signal extraction unit 214 and the transmission method determination unit 221 are the same as the functions and operations of the parts having the same names and symbols in the mobile station that communicates with the mobile station in the example of FIG.
the transmission unit 220 in the fixed station that communicates with the mobile station of this example includes transmission information input from the interface unit 202, quality information signal input from the quality information signal generation unit 212, and input from the radio station control unit 200. Control signals necessary for carrying out wireless communication are performed on control information, etc. according to parameters notified from the radio station controller 200 and transmission scheme information input from the transmission scheme determining section 221. And so on, a transmission signal is created and output to the wireless transmission / reception unit 201.
the movement state determination unit 230 in the fixed station that communicates with the mobile station of this example creates a movement state used for transmission method determination based on the movement information of the opposite mobile station input from the movement information signal extraction unit 214. Then, the data is output to the transmission method determination unit 221. For creating the movement state used for determining the transmission method, for example, the table of FIG.
FIG. 10 is a diagram illustrating a second example of the functional configuration of the mobile station that communicates with the fixed station in the present embodiment.
the mobile station that communicates with the fixed station of this example includes a radio station control unit 200, a radio transmission / reception unit 201, an interface unit 202, a reception unit 210, a reception quality determination unit 211, a quality information signal generation unit 212, and a quality information signal extraction unit. 213, a transmission unit 220, a transmission method determination unit 221, a movement state determination unit 230, a movement state detection unit 231, and a movement information signal generation unit 232.
the functions and operations of the transmission method determination unit 221, the movement state detection unit 231, and the movement information signal generation unit 232 are the same as the functions and operations of the parts having the same names and symbols in the mobile station that communicates with the mobile station in the example of FIG. It is.
the receiving unit 210 also outputs information about the presence or absence of errors in received information obtained as a result of processing such as demodulation and decoding, and information such as received signal power, interference power, and noise power to the received quality determining unit 211.
the mobile state determination unit 230 in the mobile station that communicates with the fixed station of this example creates a mobile state used for transmission method determination based on the mobile station's mobile location input from the mobile state detection unit 231, and transmits The data is output to the method determination unit 221.
the movement state used for determining the transmission method for example, the table in FIG.
FIG. 11 is a diagram illustrating an outline of an example of a hardware configuration of a radio station mainly including a DSP (Digital Signal Processor) and a CPU (Central Processing Unit) in each of the embodiments described above.
the configuration apparatus illustrated in FIG. 11 includes a CPU and DSP module 601, a memory 602, a logic circuit module 603, and an interface 605, which are connected via a bus 606.
each functional unit for example, each unit shown in FIG. 2
each functional configuration diagram in each wireless station requires one or both of a program in the CPU / DSP module 601 and an arithmetic circuit in the logic circuit 603, and is necessary.
the memory 602 is used.
information required by each function unit in each function configuration diagram for example, operation parameters stored in the radio station control unit 200, is held in the memory 602.
the CPU and the DSP module 601 correspond to the mobile station that communicates with the mobile station shown in FIG. 2 as an example. It was shown to execute the program.
the logic circuit 603 in the figure the movement information signal extraction unit 214, the movement state detection unit 231, the reception unit 210, the transmission unit 220, and the like can be realized.
the interface 605 corresponds to the interface unit 202 in each functional configuration diagram, and connects to functions other than those related to wireless communication, for example, wired communication, measurement sensors, and a user interface.
modules and buses in FIG. 6 are not necessarily single. For example, there may be a plurality of CPU / DSP modules 601 and a plurality of buses 606. When there are a plurality of buses 606, it is not always necessary that all buses are connected to all modules. For example, in addition to the buses connected to all modules, only the memory 602 and the logic circuit 603 are provided. There may be a bus to connect.
the logic operation module 603 may be omitted.
the CPU / DSP module 601 may be omitted as long as the signal processing operation and the control of the signal processing in all functions can be executed in the logic operation module 603.
FIG. 12 is a diagram illustrating a first example of a transmission signal output from the transmission unit 220 in the above-described embodiment. From the transmission unit 220 in the first example of the mobile station that communicates with the mobile station in FIG. 2 or the transmission unit 220 in the first example of the mobile station that communicates with the fixed station in FIG. The transmission signal shown in FIG.
the transmission signal shown in the example of FIG. 12 includes a control signal 701, data 702, and a movement information signal 703, which are multiplexed using time, frequency, code, and the like.
FIG. 13 is a second example of the transmission signal output from the transmission unit 220 in the above-described embodiment. From the transmitter 220 in the second example of the mobile station that communicates with the mobile station in FIG. 8 or the transmitter 220 in the second example of the mobile station that communicates with the fixed station in FIG. The transmission signal shown in FIG.
the transmission signal shown in the example of FIG. 13 includes a control signal 701, data 702, a movement information signal 703, and a quality information signal 704, which are multiplexed using time, frequency, code, and the like.
the radio stations described in the above-described embodiments can achieve a stable data communication speed even when the propagation environment varies due to movement of the radio stations.
the present invention is useful as a radio communication system and a radio station used in the radio communication system.
each of the above-described configurations, functions, processing units, and the like may be realized by hardware, for example, by designing them with an integrated circuit, or a program that realizes part or all of them. As described above, it may be realized by software by creating.

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