JP6061389B2 - Wireless communication system and transmission power control method - Google Patents

Description

  The present invention relates to a radio communication system and a transmission power control method.

  In a wireless LAN (Local Area Network), the number of channels that can be used is limited, and the same channel must be reused by different AP devices. Therefore, in a wireless LAN, throughput is degraded due to co-channel interference (hereinafter referred to as CCI “co-channel interference”). Until now, for the purpose of channel reuse to reduce CCI, application of dynamic channel allocation based on channel segregation (hereinafter referred to as CS-DCA “channel segregation based dynamic channel assignment”) to wireless LANs has been studied. (For example, refer nonpatent literature 1). CS-DCA is an algorithm in which each access point device (hereinafter referred to as an AP “Access Point” device) independently determines a use channel, and all channels received from peripheral terminal devices (hereinafter referred to as STA “Station” devices). The received CCI is measured to form a channel reuse pattern that minimizes the CCI given to the neighboring STA devices.

  For example, as illustrated in FIG. 13, each AP device 50 includes a CCI table indicating channel priority, and measures the uplink (link from the STA device to the AP device) CCI from neighboring cells at regular intervals. And each AP apparatus 50 memorize | stores the average CCI power value of each channel, ie, the average value of the past CCI power value, in a CCI table. At the time of transmission, the channel having the smallest average CCI power value is used. As a result, a channel reuse pattern that minimizes the CCI applied to the other STA devices 60 is autonomously formed in response to changes in the radio wave environment around the AP device 50.

  By the way, in a wireless LAN, it is common to perform communication with a predetermined transmission power. However, when the STA device is close to the AP device, the transmission loss is small, and excessive transmission power is generated. For this reason, CCI is given to adjacent cells using the same channel, and throughput is reduced. Therefore, in such a case, transmission power control (hereinafter referred to as TPC “transmit power control”) is performed so as to obtain the minimum necessary transmission power that satisfies the required quality in order to keep the CCI applied to the peripheral AP device and the peripheral STA device low. There is a need to do. For example, in the technique described in Non-Patent Document 2, the STA device measures the received electric field level and transmits the measured value to the AP device. The AP device increases or decreases the transmission power value based on the difference between the predetermined received electric field level determined to be optimal and the received electric field level received from the STA device, thereby controlling the transmission power so that it does not become excessive. ing.

Y. Matsumura, S. Kumagai, T. Obara, T. Yamamoto, and F. Adachi, “Channel Segregation Based Dynamic Channel Assignment for WLAN,” 2012 IEEE The 13th International Conference on Communication Systems, Singapore, 21-23 Nov. 2012 . Takayuki Arai, Toshihiko Wakahara, Mitsuji Matsumoto, “Proposal of Transmission Power Control Method for IEEE802.11b Wireless LAN”, IEICE General Conference, B-5-211, March 2003

  However, in an actual environment, the optimum received electric field level is a value that varies depending on the intensity of interference power from other AP devices and the like. Therefore, with the technique described in Non-Patent Document 2, when the optimum value of the reception electric field level is fluctuating, it is not possible to obtain an appropriate transmission power. As a result, there is a problem that the reception electric field level becomes a value more than necessary, and conversely, the reception quality is deteriorated.

  The present invention has been made to solve the above-described problem, and an object of the present invention is to provide a radio communication system and a transmission capable of selecting an appropriate transmission power value while considering the influence of interference from other devices. It is to provide a power control method.

  In order to solve the above problem, an aspect of the present invention is a wireless communication system including a wireless access point device and a wireless terminal device, and the wireless access point device is affected by interference from other devices. An average interference power calculation unit that calculates an average interference power value for each channel based on instantaneous reception interference power values measured at a fixed interval for a plurality of channels to be obtained, and a minimum value of the average interference power value calculated for each calculation And a transmission / reception unit that transmits a beacon signal including information indicating a channel corresponding to the minimum value at a predetermined transmission power value through the channel, and the wireless terminal device receives the beacon signal Total propagation loss value based on transmission / reception unit, reception power value of the beacon signal measured at the time of reception, and transmission power value of the beacon signal A total propagation loss calculation unit to calculate, the wireless terminal device or the wireless access point device, the transceiver unit based on the total propagation loss value and the minimum value of the average interference power value, A wireless communication system comprising a transmission power calculation unit that calculates a transmission power value when transmitting a transmission signal through a channel corresponding to a minimum value of an average interference power value.

One aspect of the present invention is the above-described invention, wherein the transmission power calculation unit of the wireless terminal device is included in the total propagation loss value calculated by the total propagation loss calculation unit and the beacon signal. The transmission power value at the time of transmitting the transmission signal is calculated based on the minimum value of the average interference power value, and the transmission / reception unit of the wireless terminal device uses information indicating the channel included in the beacon signal. A corresponding channel is selected, and the transmission signal is transmitted through the selected channel.

One aspect of the present invention is the above-described invention, wherein the transmission / reception unit of the wireless terminal device calculates the total propagation loss calculation unit for the transmission signal when the transmission signal is transmitted. In the wireless access point device, the transmission / reception unit receives the transmission signal, reads the total propagation loss value, and the transmission power calculation unit reads the total propagation loss value. Is used to calculate the transmission power value when transmitting the transmission signal .

One embodiment of the present invention is the above-described invention, wherein the transmission power calculation unit of the wireless terminal device or the transmission power calculation unit of the wireless access point device transmits the transmission signal. The transmission power value is calculated by adding a predetermined target value of the received signal-to-interference and noise power ratio to the minimum value of the total propagation loss value and the average interference power value.

  Further, according to one aspect of the present invention, the wireless access point apparatus measures instantaneous reception interference power values for a plurality of channels that may be affected by interference from other apparatuses, and calculates an average interference power value for each channel. A beacon signal including a minimum value of the average interference power value and information indicating a channel corresponding to the minimum value is transmitted at a predetermined transmission power value through the channel, and the wireless terminal device receives the beacon signal. And repeatedly calculating a total propagation loss value based on the reception power value of the beacon signal measured at the time of reception and the transmission power value of the beacon signal at regular intervals, and the wireless terminal device or the wireless The access point device calculates a transmission power value based on the total propagation loss value and the minimum value of the average interference power value, and the average interference power value of the minimum value Through the corresponding channel, the calculated transmission power value, characterized in that it comprises transmitting a transmission signal.

Another embodiment of the present invention, the the invention described above, the wireless terminal device, based and calculated the total propagation loss value and to the minimum value of the average interference power value included in the beacon signal The transmission power value for transmitting a transmission signal is calculated, and the wireless terminal device selects a channel corresponding to information indicating the channel included in the beacon signal, and transmits the transmission signal through the selected channel. It is characterized by that.

Further, according to one aspect of the present invention, in the above-described invention, the wireless terminal device transmits the transmission signal including the calculated total propagation loss value when transmitting the transmission signal, and the wireless terminal device The access point device receives the transmission signal, reads the total propagation loss value, and uses the read total propagation loss value to calculate the transmission power value when transmitting the transmission signal. To do.

One aspect of the present invention is the above-described invention, wherein the wireless terminal device or the wireless access point device calculates the transmission power value when transmitting the transmission signal when calculating the transmission power value. It is calculated by adding a predetermined target value of the received signal-to-interference and noise power ratio to the value and the minimum value of the average interference power value.

  According to the present invention, it is possible to select an appropriate transmission power value while considering the influence of interference from other devices.

It is a block diagram which shows the structure of the radio | wireless communications system by embodiment of this invention. It is a figure explaining the radio | wireless cell which the radio | wireless communications system by the embodiment forms. It is a figure which shows the data structure of the interference table by the same embodiment, and a memory | storage part. It is a flowchart which shows the process (the 1) of the wireless access point apparatus by the same embodiment. 5 is a flowchart showing a process (part 1) of the wireless terminal device according to the embodiment. 5 is a flowchart showing a process (part 2) of the wireless terminal device according to the embodiment. It is a flowchart which shows the process (the 2) of the wireless access point apparatus by the same embodiment. It is a flowchart which shows the process (the 3) of the wireless access point apparatus by the same embodiment. It is a graph which shows the received SINR PDF of the uplink and downlink by computer simulation to which the embodiment is applied. It is a figure which shows the error root mean square with the target value of SINR by the computer simulation to which the same embodiment is applied. It is a graph which shows CDF of the reception SINR of the uplink / downlink by the computer simulation to which the embodiment is applied. It is a graph which shows CDF of the transmission power normalized by the computer simulation to which the same embodiment is applied. It is a figure explaining an example of CS-DCA.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a wireless communication system 1 according to an embodiment of the present invention. The wireless communication system 1 includes a wireless access point device 10 (hereinafter referred to as a wireless AP device 10) and a wireless terminal device 30, and includes an uplink (transmission from the wireless terminal device 30 to the wireless AP device 10) and a downlink (wireless). (Transmission from the AP device 10 to the wireless terminal device 30). As a communication method, for example, a wireless LAN method using dynamic channel allocation based on channel segregation is applied, and a time division duplex (TDD) method is applied. The overall configuration of the wireless communication system 1 is as shown in FIG. 2, and a plurality of wireless AP apparatuses 10-1, 10-2,... Form, for example, a square wireless cell, and between these wireless cells. A plurality of wireless terminal devices 30-1, 30-2,... Move, and each wireless AP device 10-1, 10-2,. ,... Are configured to communicate with each other. All of the wireless AP devices 10-1, 10-2,... Have the same internal configuration, and the wireless AP device 10 shown in FIG. Also, all the wireless terminal devices 30-1, 30-2,... Have the same internal configuration, and the wireless terminal device 30 shown in FIG. .

  In the wireless AP apparatus 10, the instantaneous reception interference power measurement unit 11 measures instantaneous reception interference power values (hereinafter referred to as instantaneous reception CCI power values) of all channels at regular intervals. As a method of measuring the instantaneous reception CCI power value, for example, there is a method of estimating the instantaneous reception CCI power value by transmitting and receiving a known signal to and from the wireless terminal device 30. The average interference power calculation unit 12 calculates an average interference power value (hereinafter referred to as an average CCI power value) of all channels based on the instantaneous reception CCI power value measured by the instantaneous reception interference power measurement unit 11. The average interference power calculation unit 12 arranges the calculated average CCI power values of all the channels in ascending order, and writes the average CCI power value and the channel in association with each other in the order in the order. If previous information is written in the interference table 13, it is overwritten and updated. As shown in FIG. 3A, the interference table 13 has a table configuration having items of a channel number and an average CCI power value, and the average CCI power value and the channel number corresponding to the value in order of increasing average CCI power value. Remember. That is, the information with the minimum average CCI power value is written in the first rank, which is the first row. The wireless communication unit 14 is connected to the antenna 15 and performs communication with the wireless terminal device 30 existing in the cell formed by the wireless AP device 10 by the wireless LAN through the antenna 15. The beacon signal transmission unit 16 reads the minimum average CCI power value written in the first row of the interference table 13 and the first rank channel number corresponding to the average CCI power value. Moreover, the beacon signal transmission part 16 produces | generates the beacon signal containing the read average CCI electric power value and channel number. In addition, the beacon signal transmission unit 16 causes the wireless communication unit 14 to select the channel having the read channel number, and notifies the beacon signal generated according to the beacon transmission power value defined in advance, that is, all existing in the wireless cell. To the wireless terminal device 30.

  The packet transmitting / receiving unit 17 receives a packet from the wireless terminal device 30 through the wireless communication unit 14 (hereinafter, a packet transmitted from the wireless terminal device 30 to the wireless AP device 10 is referred to as an uplink packet). Further, the packet transmitting / receiving unit 17 performs loss due to fluctuation (distance fluctuation) associated with a change in distance calculated in the wireless terminal device 30 in the control field of the received uplink packet, loss due to shadowing (median fluctuation), and fading. When the total propagation loss value that is the sum of the loss due to (instantaneous value fluctuation) is included, the total propagation loss value is read and written in the storage unit 19. When the packet transmitting / receiving unit 17 detects a request to transmit a packet to the wireless terminal device 30 (hereinafter, a packet transmitted from the wireless AP device 10 to the wireless terminal device 30 is referred to as a downlink packet), The minimum average CCI power value written in the first row and the first rank channel number corresponding to the average CCI power value are read, and the read average CCI power value is output to the transmission power calculation unit 18. The transmission power value is calculated. Further, the packet transmitting / receiving unit 17 causes the wireless communication unit 14 to select the channel with the read channel number, and causes the wireless communication unit 14 to transmit the downlink packet according to the transmission power value calculated by the transmission power calculation unit 18. The request for transmitting the packet is requested from a functional unit configured by executing an application program or the like provided in the device itself or connected to the outside of the device, for example. The transmission power calculation unit 18 receives the average CCI power value received from the packet transmission / reception unit 17, the total propagation loss value stored in the storage unit 19, and a predetermined target received signal-to-interference and noise power ratio, that is, a target A transmission power value is calculated based on SINR (Signal-to-Interference and Noise power Ratio). As shown in FIG. 3B, the storage unit 19 is written with the total propagation loss value described above, and a beacon transmission power value, which is a transmission power value when transmitting a beacon signal defined in advance, A predetermined target SINR value is stored in advance.

  In the wireless terminal device 30, the wireless communication unit 32 is connected to the antenna 31 and performs communication with the wireless AP device 10 through the antenna 31 through the wireless LAN. The beacon signal receiving unit 33 receives the beacon signal notified by the wireless AP device 10 through the wireless communication unit 32. Further, the beacon signal receiving unit 33 reads the channel number and the average CCI power value included in the received beacon signal and writes them in the storage unit 38. When the beacon signal reception unit 33 receives a beacon signal, the beacon signal reception power measurement unit 34 measures and outputs the reception power value of the beacon signal received by the wireless communication unit 32. The total propagation loss calculation unit 35 is based on the reception power value of the beacon signal measured by the beacon signal reception power measurement unit 34 and the transmission power value of the beacon signal stored in the storage unit 38 in advance, A total propagation loss value that is the sum of the shadowing loss and the loss due to fading is calculated, and the calculated total propagation loss value is written in the storage unit 38. The packet transmitting / receiving unit 36 receives the downlink packet from the wireless AP device 10 through the wireless communication unit 32. Further, when the packet transmission / reception unit 36 detects a request to transmit an uplink packet, the packet transmission / reception unit 36 reads the channel number and the average CCI power value stored in the storage unit 38, outputs the read average CCI power value, and calculates transmission power. The unit 37 is caused to calculate the transmission power value. Further, the packet transmission / reception unit 36 causes the wireless communication unit 32 to select the channel having the read channel number, and causes the wireless communication unit 32 to transmit the uplink packet according to the transmission power value calculated by the transmission power calculation unit 37. Further, when generating the uplink packet, the packet transmitting / receiving unit 36 generates the total packet loss value stored in the storage unit 38 in the control field of the uplink packet. The request for transmitting the packet is requested from a functional unit configured by executing an application program or the like provided in the device itself or connected to the outside of the device, for example. The transmission power calculation unit 37 calculates a transmission power value based on the average CCI power value received from the packet transmission / reception unit 36, the total propagation loss value stored in the storage unit 38, and a predetermined target SINR. As shown in FIG. 3C, the storage unit 38 is written with the above-mentioned total propagation loss value, channel number, and average CCI power value, and also sets a predetermined beacon transmission power value and a predetermined target SINR. Store in advance.

  Next, transmission power control (TPC) processing in each of the uplink and downlink by the wireless communication system 1 will be described with reference to FIGS. 4 to 8.

(Interference table update and total propagation loss value calculation processing)
First, processing performed continuously by the wireless AP device 10 and the wireless terminal device 30 will be described with reference to FIGS. 4 and 5. FIG. 4 is a flowchart illustrating processing in which the wireless AP device 10 updates the interference table 13. First, the instantaneous reception interference power measurement unit 11 is activated at regular intervals, and measures the instantaneous reception CCI power values of all channels (step SAa1). The average interference power calculation unit 12 calculates the average CCI power value of all the channels based on the equation (1) based on the instantaneous reception CCI power value measured by the instantaneous reception interference power measurement unit 11 (step SAa2).

In Equation (1), I _ch (t) is the instantaneous received CCI power value for each channel calculated by the instantaneous received interference power measurement unit 11, β is a forgetting coefficient, and 0 ≦ β ≦ 1 Value. The symbol with “-” on the left side I _ch (t) and the symbol with “-” on the second item I _ch (t−1) on the right side are time t and The average CCI electric power value in the time t-1 is shown. That is, the average CCI power value is calculated based on the forgetting factor β, the instantaneous received CCI power value I _ch (t), and the past average CCI power value. After calculating the average CCI power value of all the channels, the average interference power calculation unit 12 arranges the calculated average CCI power values in ascending order, and writes the average CCI power value and the channel in the order in association with each other in the interference table 13 ( Step SAa3). When the average interference power calculation unit 12 newly writes the average CCI power value and the channel number in the interference table 13, the beacon signal transmission unit 16 first average CCI power written in the first row of the interference table 13. The value and the first rank channel number, that is, the minimum average CCI power value and the channel number corresponding to the average CCI power value are read. The channel number of the first rank at time t is expressed by Expression (2), and the average CCI power value of the first rank is expressed by Expression (3).

The beacon signal transmission unit 16 outputs the channel having the read channel number of the first rank to the wireless communication unit 14, and the wireless communication unit 14 selects the channel (step SAa4). The beacon signal transmission unit 16 generates a beacon signal including the read first rank channel number and the average CCI power value, and in accordance with the beacon transmission power value Pt _AP stored in the storage unit 19 in advance, the wireless communication unit 14 Through the wireless terminal device 30 (step SAa5). The wireless AP device 10 repeats the processing from steps SAa1 to SAa5 at regular intervals.

FIG. 5 is a flowchart showing processing of the wireless terminal device 30 that has received the beacon signal transmitted from the wireless AP device 10 in the processing of FIG. The beacon signal receiving unit 33 receives a beacon signal through the wireless communication unit 32 (step SSa1). The beacon signal receiving unit 33 reads out the first rank channel number and the average CCI power value from the received beacon signal and writes them into the storage unit 38 to acquire these values (step SSa2). When the beacon signal reception power measurement unit 34 detects that the beacon signal reception unit 33 has received the beacon signal, the beacon signal reception power measurement unit 34 measures and outputs the reception power value Pr _STA of the beacon signal received by the wireless communication unit 32 (step SSa3). ). The total propagation loss calculation unit 35 uses the received power value Pr _STA of the beacon signal output from the beacon signal received power measurement unit 34 and the beacon transmission power value Pt _AP stored in advance in the storage unit 38, to formula (4). Based on this, the total propagation loss value L is calculated, and the calculated total propagation loss value L is written in the storage unit 38 (step SSa4).

  The wireless terminal device 30 repeats steps SSa1 to SSa4 every time it receives a beacon signal.

(Uplink packet transmission processing)
Next, processing when a packet is transmitted from the wireless terminal device 30 to the wireless AP device 10 will be described with reference to FIGS. 6 and 7. The packet transmitting / receiving unit 36 of the wireless terminal device 30 detects a request for an uplink packet (step SSb1). The packet transmitting / receiving unit 36 reads the first rank channel number and the average CCI power value stored in the storage unit 38, and outputs the read channel number to the wireless communication unit 32. The wireless communication unit 32 selects the channel having the channel number received from the packet transmitting / receiving unit 36 (step SSb2). The packet transmission / reception unit 36 outputs the read average CCI power value to the transmission power calculation unit 37. When the transmission power calculation unit 37 receives the average CCI power value from the packet transmission / reception unit 36, the transmission power calculation unit 37 reads the total propagation loss value and the target SINR stored in the storage unit 38, and calculates the transmission power value according to Expression (5). (Step SSb3).

  When generating the uplink packet, the packet transmitting / receiving unit 36 writes the total propagation loss value stored in the storage unit 38 in the control field of the packet (step SSb4). The wireless communication unit 32 transmits the uplink packet generated by the packet transmitting / receiving unit 36 to the wireless AP device 10 through the already selected first-order channel according to the transmission power value calculated by the transmission power calculating unit 37 (step S1). SSb5).

  Next, processing when the wireless AP device 10 receives an uplink packet will be described with reference to FIG. The packet transmitting / receiving unit 17 of the wireless AP device 10 receives the uplink packet transmitted by the wireless terminal device 30 through the wireless communication unit 14 (step SAb1). The packet transmitting / receiving unit 17 reads the total propagation loss value included in the control field of the packet and writes it in the storage unit 19 (step SAb2). Note that the data included in the packet is output to a functional unit configured by executing an application program or the like provided in the device itself or connected to the outside of the device, for example. Is done.

(Process of downlink packet transmission)
Next, downlink packet transmission processing by the wireless AP device 10 will be described with reference to FIG. The packet transmitting / receiving unit 17 of the wireless AP device 10 detects a request for transmitting a downlink packet to be transmitted to the wireless terminal device 30 (step SAc1). The packet transmitting / receiving unit 17 reads the first rank channel number and the first rank average CCI power value written in the first row of the interference table 13, and sends the read first rank channel number to the radio communication unit 14. Output. The wireless communication unit 14 selects a channel having the channel number received from the packet transmitting / receiving unit 17 (step SAc2). The packet transmitting / receiving unit 17 outputs the read average CCI power value to the transmission power calculating unit 18. When the transmission power calculation unit 18 receives the average CCI power value from the packet transmission / reception unit 17, the transmission power calculation unit 18 reads the total propagation loss value and the target SINR stored in the storage unit 19 and calculates the transmission power value according to Expression (6). (Step SAc3).

  When the packet transmission / reception unit 17 outputs the downlink packet to be transmitted to the wireless communication unit 14, the wireless communication unit 14 passes the already selected first rank channel according to the transmission power value calculated by the transmission power calculation unit 18. The downlink packet is transmitted to the wireless terminal device 30 (step SAc4).

In the configuration of the above embodiment, the wireless AP device 10 calculates the instantaneous received CCI power values of all the channels at regular intervals, and calculates the latest average by the calculated instantaneous received CCI power value and the past average CCI power value. A CCI power value is calculated. The minimum value is selected from the calculated average CCI power values, and the minimum average CCI power value and the channel number corresponding to the average CCI power value are notified to the wireless terminal device 30 by a beacon signal. The wireless terminal device 30 measures the received power value of the received beacon signal, and calculates a total propagation loss value based on the measured received power value of the beacon signal and a predefined transmission power value. Then, when transmitting a packet to the wireless AP device 10, the wireless terminal device 30 is based on the target SINR value, the total propagation loss value, and the minimum average CCI power value notified from the wireless AP device 10. To calculate the transmission power value. The wireless terminal device 30 transmits a packet through a channel corresponding to the minimum average CCI power value according to the calculated transmission power value.
That is, the wireless AP device 10 measures the instantaneous received CCI power value of all channels at a constant interval, and the measured instantaneous received CCI power value and the total propagation loss value between the wireless AP device 10 and the wireless terminal device 30 are obtained. Based on this, the wireless terminal device 30 finally calculates the transmission power value. Therefore, it is possible to select an appropriate transmission power value in the wireless terminal device 30 while considering the degree of influence due to interference of other wireless cells. Thereby, it is possible to obtain an optimum received electric field strength, and it is possible to suppress the interference power and improve the communication quality. Further, the latest average CCI power value is calculated using the measured instantaneous reception CCI power value, the minimum value is selected from the calculated average CCI power values, and the transmission power is transmitted using the average CCI power value of the minimum value. The value is calculated. Accordingly, it is possible to transmit a packet with a minimum necessary transmission power value while keeping CCI applied to other wireless AP apparatuses 10 and wireless terminal apparatuses 30 existing in the vicinity low. Further, by calculating the transmission power value in consideration of the target SINR, it is possible to adaptively control the value of the transmission power so that the reception SINR of the wireless AP apparatus 10 becomes the target value. As a result, wireless communication can be performed in a situation where the SINR is close to the target value, so that the communication efficiency can be improved.

In the configuration of the above embodiment, when the wireless terminal device 30 transmits a packet to the wireless AP device 10, the wireless terminal device 30 transmits the packet including the total propagation loss value calculated in the control field of the packet to be transmitted. 10 is configured to read and store the total propagation loss value from the received packet. When the wireless AP device 10 transmits a packet to the wireless terminal device 30, the stored total propagation loss value, the target SINR value, and the minimum average CCI power stored in the interference table 13 are stored. The transmission power value is calculated based on the value. The wireless AP device 10 transmits a packet to the wireless terminal device 30 through a channel corresponding to the minimum average CCI power value according to the calculated transmission power value.
That is, the wireless AP device 10 measures the instantaneous received CCI power value of all channels at a constant interval, and the measured instantaneous received CCI power value and the total propagation loss value between the wireless AP device 10 and the wireless terminal device 30 are obtained. Based on this, the transmission power value is finally calculated. Therefore, it is possible for the wireless AP device 10 to select an appropriate transmission power value while considering the degree of influence due to interference of other wireless cells. Thereby, it is possible to obtain an optimum received electric field strength, and it is possible to suppress the interference power and improve the communication quality. Further, the latest average CCI power value is calculated using the measured instantaneous reception CCI power value, the minimum value is selected from the calculated average CCI power values, and the transmission power is transmitted using the average CCI power value of the minimum value. The value is calculated. Thereby, it is possible to transmit a packet with the minimum necessary transmission power while keeping CCI applied to other wireless AP apparatuses 10 and wireless terminal apparatuses 30 existing in the vicinity low. Further, by calculating based on the target SINR, it is possible to adaptively control the value of the transmission power so that the reception SINR of the wireless terminal device 30 becomes the target value. As a result, wireless communication can be performed in a situation where the SINR is close to the target value, so that the communication efficiency can be improved.

Note that, as described above, the beacon transmission power value when the wireless AP device 10 transmits a beacon signal is a predetermined value as described above, and is a known value in the wireless AP device 10 and the wireless terminal device 30. . In the above embodiment, the data is stored in advance in the storage unit 19 of the wireless AP device 10 and the storage unit 38 of the wireless terminal device 30. For example, when transmitting a beacon signal or a packet, the wireless AP device 10 May be notified to the wireless terminal device 30, and the wireless terminal device 30 may store it in the storage unit 38.
Similarly, the value of the target SINR is a predetermined value and is a known value in the wireless AP device 10 and the wireless terminal device 30. In the above embodiment, the data is stored in advance in the storage unit 19 of the wireless AP device 10 and the storage unit 38 of the wireless terminal device 30. For example, when transmitting a beacon signal or a packet, the wireless AP device 10 May be notified to the wireless terminal device 30, and the wireless terminal device 30 may store it in the storage unit 38.
Further, in the configuration of the above embodiment, the average interference power calculation unit 12 is arranged to store the calculated average CCI power value in order from the smallest when writing to the interference table 13, but in the embodiment of the present invention, It is not restricted to the said structure. For example, writing to the interference table 13 may be performed without depending on the magnitude of the average CCI power value, such as writing in ascending order of channel numbers or writing in the order in which the average CCI power value is calculated. In that case, when reading out from the interference table 13, the minimum value of the average CCI power value is searched, and the average CCI power value of the minimum value and the channel number corresponding to the average CCI power value are read out.
In the configuration of the above embodiment, as described in FIG. 6, the packet transmission / reception unit 36 of the wireless terminal device 30 transmits the total propagation loss value calculated by the total propagation loss calculation unit 35. However, the configuration of the present invention is not limited to this embodiment. For example, a control signal transmitted and received between the wireless AP device 10 and the wireless terminal device 30 on a regular basis without performing the processing of FIG. 6 in which the total transmission loss value is included in the control field of the packet for which the transmission power value is calculated. Then, the transmission power value may be transmitted by including the total propagation loss value in a control signal or the like that is determined in advance like a beacon signal. In this case, in the process of FIG. 7, the wireless terminal device 30 reads the total propagation loss value from the received control signal or the like.

  9 to 12 show simulation results by a computer to which this embodiment is applied. As a premise of numerical values related to the graphs and tables shown in FIGS. 9 to 12, Λ, which is the above-described target value of the received SINR, is 20 dB. In the following results, the transmission power given when there is no TPC (w / o TPC (without TPC) in the figure) is the average reception of the wireless AP device 10 when the wireless terminal device 30 is located at the wireless cell end. The transmission power is such that the signal to noise ratio (SNR) is 20 dB. The wireless cell formed by the plurality of wireless AP devices 10 is assumed to be a 10 × 10 square cell as shown in FIG. 2, and the wireless AP device 10 and the wireless terminal device 30 in the wireless cell communicate by TDD. It is said. Moreover, the transmission timing of the uplink and downlink is synchronized in all radio cells. The measurement interval of the instantaneous reception CCI power value is defined as a time slot, and in each time slot, the instantaneous reception interference power measurement unit 11 of the wireless AP apparatus 10 receives the uplink instantaneous reception CCI power from the wireless terminal apparatus 30 existing in the vicinity. The value is measured, and the average interference power calculation unit 12 calculates the average CCI power value and updates the interference table 13. The forgetting factor β in equation (1) when calculating the average CCI power value is β = 0.99. The propagation loss index α (Non-Patent Document 1) associated with the variation in distance is set to α = 3.5. The fading model assumes an equal power model with L = 16 paths. The time length of the trial by the computer simulation per time was 2000 time slots, and the position of the wireless terminal device 30 was not changed during this time. The measurement of uplink / downlink received SINR and transmission power value is performed at the time of 2000 time slots.

  FIG. 9 is a graph showing a probability density function (hereinafter referred to as PDF “Probability Density Function”) of uplink and downlink SINRs, and FIG. 11 is a cumulative distribution function of SINR of uplink and downlink (hereinafter referred to as CDF “Cumulative Distribution Function”). It is a graph showing). The numerical values shown in these graphs are calculated by repeating the trial by the computer simulation 200 times. In the graphs of FIG. 9 and FIG. 11, the graph indicated by the solid line indicates the result when the TPC according to the present embodiment is applied (w / TPC (with TPC)), and the graph indicated by the broken line applies the TPC. The result when not (w / o TPC) is shown. In FIG. 9, the vertical axis indicates PDF and the horizontal axis indicates SINR, and in FIG. 11, the vertical axis indicates CDF and the horizontal axis indicates SINR. Moreover, (a) of FIG.9 and FIG.11 showed the case of the uplink, and (b) of FIG.9 and FIG.11 has shown the case of the downlink.

  In the uplink and downlink shown in FIGS. 9 (a) and 9 (b), it is shown that the uplink / received link received SINR can be made close to the target value of 20 dB by using the TPC of this embodiment. FIG. 10 shows an error root-mean-square (hereinafter referred to as RMS “Root Mean Square”) from a target value Λ = 20 dB of received SINR. When the TPC according to the present embodiment is not used (w / o TPC), the upper and lower links have errors of 7.57 dB and 8.50 dB with respect to the target values, respectively. On the other hand, when the TPC according to the present embodiment is used (w / TPC), it can be 1.67 dB in the uplink and 2.39 dB in the downlink, and the uplink / receiver received SINR is the target. It is possible to make the value very close to the value. Accordingly, as shown in FIGS. 11A and 11B, by performing TPC according to the present embodiment, the outage probability that the received SINR is 15 dB or less is 1% in the uplink and downlink, respectively. It is possible to make it 4%. On the other hand, the outage probability when the TPC according to the present embodiment is not performed is 10% in both the upper and lower links from FIGS. 11A and 11B, and the outage probability by the TPC according to the present embodiment. It can be seen that it has been greatly improved.

  FIG. 12 is a graph showing the CDF of normalized transmission power, and the numerical values shown in the graph are also calculated by repeating the trial by the above computer simulation 200 times. In the graph of FIG. 12, the graph indicated by the solid line indicates the result when the TPC according to the present embodiment is applied (w / TPC (with TPC)), and the graph indicated by the broken line does not apply the TPC. Case (w / o TPC) results are shown. Further, the vertical axis represents CDF, and the horizontal axis represents normalized transmit power. As shown in FIG. 12, it can be seen that the transmission power can be reduced when TPC is used compared to when TPC is not used. When looking at the transmission power that gives 50% CDF, it is possible to reduce the transmission power by about 10 dB when TPC is used compared to when TPC is not used. Therefore, according to the present embodiment, it is possible to expect a reduction in transmission power in addition to a reduction in interference.

  The wireless AP device 10 and the wireless terminal device 30 in the above-described embodiment may be realized by a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be a program for realizing a part of the above-described functions, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system. You may implement | achieve using programmable logic devices, such as FPGA (Field Programmable Gate Array).

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 Wireless communication system 10 Wireless AP apparatus 11 Instantaneous reception interference power measurement part 12 Average interference power calculation part 13 Interference table 14 Wireless communication part 15 Antenna 16 Beacon signal transmission part 17 Packet transmission / reception part 18 Transmission power calculation part 19 Storage part 30 Wireless terminal Device 31 Antenna 32 Wireless communication unit 33 Beacon signal reception unit 34 Beacon signal reception power measurement unit 35 Total propagation loss calculation unit 36 Packet transmission / reception unit 37 Transmission power calculation unit 38 Storage unit

Claims (8)

A wireless communication system comprising a wireless access point device and a wireless terminal device,
The wireless access point device
An average interference power calculation unit that calculates an average interference power value for each channel based on an instantaneous reception interference power value measured at a constant interval for a plurality of channels that may be affected by interference from other devices;
A transmission / reception unit for transmitting a beacon signal including a minimum value of the calculated average interference power value and information indicating a channel corresponding to the minimum value at a predetermined transmission power value for each calculation; With
The wireless terminal device
A transceiver for receiving the beacon signal;
A total propagation loss calculation unit that calculates a total propagation loss value based on the received power value of the beacon signal measured at the time of reception and the transmission power value of the beacon signal;
The wireless terminal device or the wireless access point device is
Based on the total propagation loss value and the minimum value of the average interference power value, the transmission / reception unit calculates a transmission power value when transmitting a transmission signal through a channel corresponding to the minimum value of the average interference power value. A wireless communication system comprising a transmission power calculation unit. The transmission power calculation unit of the wireless terminal device,
Calculate the transmission power value when transmitting the transmission signal based on the total propagation loss value calculated by the total propagation loss calculation unit and the minimum value of the average interference power value included in the beacon signal,
The transceiver of the wireless terminal device is
The radio communication system according to claim 1, wherein a channel corresponding to information indicating the channel included in the beacon signal is selected, and the transmission signal is transmitted through the selected channel. The transceiver of the wireless terminal device is
When transmitting the transmission signal, transmit the transmission signal including the total propagation loss value calculated by the total propagation loss calculation unit,
In the wireless access point device,
The transceiver unit is
Receiving the transmitted signal and reading the total propagation loss value;
The transmission power calculation unit
The wireless communication system according to claim 2, wherein the transmission power value when transmitting the transmission signal is calculated using the read total propagation loss value. The transmission power calculation unit of the wireless terminal device, or the transmission power calculation unit of the wireless access point device,
When calculating the transmission power value when transmitting the transmission signal , a predetermined target value of the received signal-to-interference and noise power ratio is added to the minimum value of the total propagation loss value and the average interference power value. The wireless communication system according to claim 1, wherein the wireless communication system is calculated by: Wireless access point device
Measure the instantaneous received interference power value for multiple channels that can be affected by interference from other devices to calculate the average interference power value for each channel,
Transmitting a beacon signal including the calculated minimum interference power value and information indicating a channel corresponding to the minimum value at a predetermined transmission power value through the channel;
A wireless terminal device receives the beacon signal,
Repeatedly calculating a total propagation loss value based on the received power value of the beacon signal measured at the time of reception and the transmission power value of the beacon signal at regular intervals,
The wireless terminal device or the wireless access point device is
A transmission power value is calculated based on the total propagation loss value and the minimum value of the average interference power value, and a transmission signal is transmitted with the calculated transmission power value through a channel corresponding to the average interference power value of the minimum value. A transmission power control method comprising: transmitting. The wireless terminal device
Calculate the transmission power value when transmitting the transmission signal based on the calculated total propagation loss value and the minimum value of the average interference power value included in the beacon signal,
The wireless terminal device
The transmission power control method according to claim 5, wherein a channel corresponding to information indicating the channel included in the beacon signal is selected, and the transmission signal is transmitted through the selected channel. The wireless terminal device
When transmitting the transmission signal, transmit the transmission signal including the calculated total propagation loss value,
The wireless access point device
The transmission power value for transmitting the transmission signal is calculated using the read total propagation loss value by receiving the transmission signal and reading the total propagation loss value. The transmission power control method described. The wireless terminal device or the wireless access point device is
When calculating the transmission power value when transmitting the transmission signal , a predetermined target value of the received signal-to-interference and noise power ratio is added to the minimum value of the total propagation loss value and the average interference power value. The transmission power control method according to claim 5, wherein the transmission power control method is calculated by:

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