JP6766952B2 - Wireless device, wireless system and communication frequency allocation method - Google Patents

Description

The present invention relates to a wireless device, a wireless system, and a communication frequency allocation method for wireless communication.

There are multiple systems that use the same frequency in the Industrial Science Medical (ISM) band. For example, the 2.4 GHz band includes Wi-Fi (registered trademark), Bluetooth (registered trademark), mobile router, amateur radio, and the like. The 5 GHz band includes Wi-Fi, various radars for weather, amateur radio, and the like.

The ISM band does not require a radio station license and radio wave usage fee, and the number of systems using this ISM band is increasing year by year, and each system can coexist in the same frequency of the ISM band without causing interference with each other. Desired. In order to grasp the state of interference, it is necessary to measure continuous radio waves for a certain period of time.

Conventionally, there is a technique for evaluating wireless communication quality and switching communication with a client through the best communication channel (see, for example, Patent Document 1 below). Further, there is a technique in which an access point transmits a beacon and sets an appropriate channel according to the beacon strength for each channel (see, for example, Patent Document 2 below).

Special Table 2007-506379 Japanese Unexamined Patent Publication No. 2013-201629

In the prior art, when the access point selects a channel, the channel is selected based on the radio wave environment of each channel, for example, the received power of the channel search. However, in this case, the access point may not have selected the appropriate channel.

For example, it is assumed that the area of the Bluetooth communication device, which is another system of the same ISM band, overlaps with a part of the area of the access point of the wireless LAN. Since the local wireless LAN access point selects the channel without considering the radio wave environment of the terminal located in the local area, it is judged that the channel can be selected even if the terminal is interfered by another system. To do. In this case, the access point cannot select the optimum channel for communication with the terminal, and communication performance such as throughput deteriorates.

In one aspect, it is an object of the present invention to be able to communicate on an optimum channel in consideration of the radio wave environment of the wireless device for communication.

In one proposal, the wireless device sets the channel having the maximum communication speed as the other wireless device based on the respective communication speeds of the current channel and the other channel that have communicated with the other wireless device. It has a control unit, which is selected as a new channel to be used for communication with, and the control unit receives the signal when the other wireless device transmits a signal to its own device on a predetermined current channel of the uplink. The uplink communication speed of the current channel obtained by reception and the uplink communication speed of a plurality of other channels other than the current channel are obtained, and the channel having the maximum communication speed is communicated with the other wireless device. It is required to select it as a new channel to be used for .

According to one embodiment, it is possible to communicate on the optimum channel in consideration of the radio wave environment of the wireless device for communication.

FIG. 1 is a block diagram showing a configuration example of a terminal of the wireless device according to the first embodiment. FIG. 2 is a chart showing a setting example of the SINR-communication speed correspondence table stored in the terminal of the first embodiment. FIG. 3 is a block diagram showing a configuration example of an access point of the wireless device according to the first embodiment. FIG. 4 is a diagram showing a hardware configuration example of the control unit of the wireless device according to the first embodiment. FIG. 5 is a flowchart showing an operation processing example of the wireless device according to the first embodiment. FIG. 6 is a diagram showing various systems using the ISM band. FIG. 7 is a diagram illustrating a channel selection process of an access point by an existing technique. FIG. 8 is a diagram illustrating a channel selection process of the access point according to the first embodiment. FIG. 9 is a block diagram showing a configuration example of a terminal of the wireless device according to the second embodiment. FIG. 10 is a block diagram showing a configuration example of an access point of the wireless device according to the second embodiment. FIG. 11 is a flowchart showing an operation processing example of the wireless device according to the second embodiment.

(Embodiment 1)
FIG. 1 is a block diagram showing a configuration example of a terminal of the wireless device according to the first embodiment. The wireless system of the embodiment includes one wireless device and the other wireless device, both of which wirelessly communicate with each other using, for example, the frequency band of the ISM band.

One wireless device is an access point (AP) of a wireless LAN such as Wi-Fi, and the other wireless device will be described with reference to an example of a terminal (STA) that performs wireless communication with the access point. The terminal is, for example, a mobile mobile phone, a smartphone, a mobile router, or the like.

In the first embodiment, a configuration in which the access point (AP) selects a channel by downlink (DL) communication from the access point (AP) to the terminal (STA) 100 will be described.

As shown in FIG. 1, the terminal 100 includes a baseband (BB) unit 101, a radio frequency (RF) unit 102, and a signal processing unit 103.

The baseband unit 101 processes signals transmitted and received by the terminal 100. The baseband unit 101 includes a modulator 111, a digital-to-analog converter (DAC) 112, and an oscillator 113 as a configuration for processing a transmission signal.

The modulator 111 digitally modulates the digital transmission signal according to a predetermined wireless system. An oscillation signal having a predetermined frequency of the oscillator 1 (113) is supplied to the DAC 112, and a digital signal to be wirelessly transmitted is converted into an analog signal.

Further, the baseband unit 101 includes an analog-to-digital converter (ADC) 123 and a demodulator 124 as a configuration for processing a received signal.

The oscillation signal of the oscillator 1 (113) is supplied to the ADC 123, and the received signal is converted from an analog signal to a digital signal. The demodulator 124 demodulates the received signal.

The high frequency unit 102 includes an amplifier (PA: Power Amp) 114 and an oscillator 2 (115) as a configuration on the transmitting side. The amplifier 114 receives the supply of the oscillation signal of the predetermined frequency of the oscillator 2 (115) from the signal of the baseband band input from the baseband unit 101, and amplifies the transmission signal by high frequency (radio frequency, RF: Radio Frequency). Then, radio transmission is performed from the antenna 116.

Further, the high frequency unit 102 includes an amplifier (LNA: Low Noise Amp) 122 as a configuration on the receiving side. The amplifier 122 receives the supply of the oscillation signal of the predetermined frequency of the oscillator 2 (115), amplifies the radio signal received by the antenna 116, amplifies it, and outputs it to the baseband unit 101.

The signal processing unit 103 of the first embodiment acquires information on its own radio wave environment and notifies the access point. At this time, the signal processing unit 103 controls to calculate the communication speed based on the communication quality of each channel during DL communication from the access point to the terminal 100 and notify the access point. For example, the communication quality of the channel (for example, 1ch) communicating with the access point and the communication quality of the other channel are calculated. Other channels include, for example, the possibility of being interfered with by another system.

The signal processing unit 103 includes a received signal processing unit 131 and a transmission signal processing unit 141. The reception signal processing unit 131 includes a channel transition unit 132, a SINR calculation unit 133, a communication speed calculation unit 134, and a storage unit 135. The channel transition unit 132 scans a plurality of channels that can communicate with the access point, and changes and controls the frequency of the oscillator 2 (115).

The SINR calculation unit 133 calculates the communication quality SINR (Signal to Interference Noise Ratio) of the received signal RD output by the baseband unit 101 (demodulator 124). At this time, the SINR calculation unit 133 obtains the SINR of each of the plurality of channels capable of communicating with the access point.

Specifically, the SINR calculation unit 133 calculates the SNIR of DL communication from the access point in the own terminal _l (100) based on the following formula (1).

SINR _l (ch): Communication quality of terminal _l in ch-th channel RSSI _l : Average received power received from AP to which terminal _l is connected Σ {RSSI _k (ch)} Item: With other APs in ch-th channel Average received power from terminals connected to other APs N (ch): Average received power (including noise power) other than wireless LAN signals in the chth channel
α, β: Adjustment parameters (default value: 1, 0 ≤ α ≤ 1, 0 ≤ β ≤ 1)

As shown in the above equation (1), the terminal _l (100) uses the reception strength (reception average power RSSI _l ) for one channel that actually communicates with the access point (AP) as the numerator to obtain the SINR. It is calculated.

The communication speed calculation unit 134 calculates the communication speed based on the SINR calculated by the SINR calculation unit 133. Correspondence information between SINR and communication speed (SINR-communication speed correspondence table 201) is preset in the storage unit 135. The communication speed calculation unit 134 refers to the storage unit 135 and reads out the communication speed corresponding to the communication speed of the received signal RD calculated by the SINR calculation unit 133.

FIG. 2 is a chart showing a setting example of the SINR-communication speed correspondence table stored in the terminal of the first embodiment. In the SINR-communication speed correspondence table 201 stored in the storage unit 135, the communication speed corresponding to the SINR for each of a plurality of ranges is set.

For example, if the SINR of the received signal RD is 4 to 6 [dB], the communication speed is calculated to be 9 [Mbps]. In the SINR-communication speed correspondence table 201, the larger the SINR value, the higher the communication speed is set.

The communication speed calculated by the communication speed calculation unit 134 is the communication speed of the channel currently communicating in the downlink DL from the access point to the terminal 100 (DL_Comm_Speed _l (ch)). The communication speed data F calculated by the communication speed calculation unit 134 is output to the transmission signal processing unit 141.

The transmission signal processing unit 141 transmits the communication speed data F calculated by the communication speed calculation unit 134 to the access point as the transmission signal SD.

FIG. 3 is a block diagram showing a configuration example of an access point of the wireless device according to the first embodiment. The access point (AP) 300 includes a baseband (BB) unit 301, a radio frequency (RF) unit 302, and a signal processing unit 303.

The baseband unit 301 processes signals transmitted and received by the access point 300. The baseband unit 301 includes a modulator 311, a digital-to-analog converter (DAC) 312, and an oscillator 313 as a configuration for processing a transmission signal.

The modulator 311 digitally modulates the digital transmission signal according to a predetermined wireless system. An oscillation signal having a predetermined frequency of the oscillator 1 (313) is supplied to the DAC 312, and a digital signal to be wirelessly transmitted is converted into an analog signal.

Further, the baseband unit 301 includes an analog-to-digital converter (ADC) 323 and a demodulator 324 as a configuration for processing a received signal.

The oscillation signal of the oscillator 1 (313) is supplied to the ADC 323, and the received signal is converted from an analog signal to a digital signal. The demodulator 324 demodulates the received signal.

The high frequency unit 302 includes an amplifier (PA) 314 and an oscillator 2 (315) as a configuration on the transmitting side. The amplifier 314 receives the supply of the oscillation signal of the predetermined frequency of the oscillator 2 (315) from the baseband band signal input from the baseband unit 301, amplifies the transmission signal by high frequency (RF), and wirelessly transmits the transmission signal from the antenna 316. Send.

Further, the high frequency unit 302 includes an amplifier (LNA) 322 as a configuration on the receiving side. The amplifier 322 receives the supply of the oscillation signal of the predetermined frequency of the oscillator 2 (315), amplifies the radio signal received by the antenna 316, amplifies it, and outputs it to the baseband unit 301.

The signal processing unit 303 includes a received signal processing unit 331 and a transmission signal processing unit 341. The signal processing unit 303 controls to select a channel (communication frequency) from which the optimum communication state can be obtained, based on the communication speed of each channel acquired from the access point 300.

The reception signal processing unit 331 performs channel selection processing based on the reception signal RD. The transmission signal processing unit 341 performs data processing on the transmission signal SD and the like in connection with the channel selection processing performed by the reception signal processing unit 331.

The received signal processing unit 331 includes a total communication speed calculation unit 332, a comparison unit 333, a selection unit 334, and a channel transition unit 335.

The total communication speed calculation unit 332 calculates and transmits the communication speed (communication speed data F) of each channel from the terminal 100 based on the reception signal RD output by the baseband unit 301 (demodulator 324). Acquire and calculate the total communication speed for each channel.

The total communication speed is the total speed of the downlink (DL: access point → communication to the terminal) acquired from each of the plurality of terminals 100 having a communication request to the access point 300.

Here, the total communication speed calculation unit 332 simply connects to the access point 300 in calculating the total communication speed, but the communication speed of the terminal 100 that is not communicating is not included in the total communication speed. That is, the total communication speed calculation unit 332 obtains the total communication speed of the current channel and the total communication speed of the other channels for the plurality of terminals 100 that can actually communicate. For example, the total communication speed (DL_Total_Comm_Speed (ch) is calculated based on the following formula (2). L is the number of terminals.

The comparison unit 333 stores and holds the information of the total communication speed RD1 of the current channel (for example, 1ch) calculated by the total communication speed calculation unit 332 and the total communication speed RDn of the other channels in an updateable manner. Then, the comparison unit 333 compares the total communication speed RD1 of the current channel with the total communication speed RDn of the other channel. For example, the total communication speed RD1 of the current channel and the total communication speed RD2 of each of the plurality of channels are compared.

The selection unit 334 selects the channel having the maximum total communication speed as a result of comparison by the comparison unit 333. Then, the channel transition unit 335 shifts to the channel having the maximum total communication speed. For example, if the total communication speed RD2 of the other channel (ch5) is larger than that of the current channel (Ch1), the subsequent communication channel is set to ch5, and the channel is shifted from the current channel 1ch to 5ch. If the total communication speed of the current channel (1ch) is higher than any of the other channels, the current channel (1ch) is left as it is, and channel transition is not performed.

The channel transfer unit 335 changes the oscillation frequency of the oscillator 2 (315) to a frequency corresponding to the channel to be transferred for channel transfer. As a result, the transmission frequency of PA314 of the transmission signal and the reception frequency of LNA322 of the reception signal are channel-changed (communication frequency allocation). Further, the channel transition unit 335 notifies the transmission signal processing unit 341 of the channel change at the time of channel transition.

The transmission signal processing unit 341 includes a beacon transmission unit 342 and a channel change notification unit 343. The beacon transmission unit 342 transmits a predetermined beacon signal to the terminal 100 at a predetermined timing or periodically. That is, each time the optimum channel (communication frequency) is set with the terminal 100 at the access point 300, the beacon transmission unit 342 transmits a beacon for measurement to the terminal 100 as a transmission signal SD. This beacon transmits on the current communication frequency (channel) or a predetermined initial value channel (for example, 1ch).

When the channel change notification unit 343 receives the notification of the channel transition from the reception signal processing unit 331 (channel transition unit 335), the channel change notification unit 343 transmits the notified channel information after the change to the terminal 100 as a transmission signal SD. The terminal 100 changes the channel according to the channel information included in the transmission signal SD. As a result, communication with the terminal 100 can be continued even if the channel is changed at the access point 300.

FIG. 4 is a diagram showing a hardware configuration example of the control unit of the wireless device according to the first embodiment. In the terminal 100 shown in FIG. 1 and the access point 300 shown in FIG. 3, the control unit 400 shown in FIG. 4 controls each unit of the device in an integrated manner. Then, the control unit 400 provided in the terminal 100 executes the functions of the baseband unit 101 and the signal processing unit 103 of the terminal 100. Further, the control unit 400 provided in the access point 300 executes the functions of the baseband unit 301 and the signal processing unit 303 of the access point 300.

The CPU (Central Processing Unit) 401 shown in FIG. 4 reads and executes the program stored in the memory 402, and at that time, a part of the area of the memory 402 is used for the work area. As a result, in the terminal 100, the terminal 100 can be controlled in an integrated manner, and the functions of the baseband unit 101 and the signal processing unit 103 of FIG. 1 can be realized. Further, in the access point 300, the access point 300 can be controlled in an integrated manner, and the functions of the baseband unit 301 and the signal processing unit 303 of FIG. 3 can be realized. The baseband portions 101 and 301 can also be configured by using a dedicated DSP or IC.

As the memory 402, ROM, RAM, or the like can be used. Further, an extended memory 403 such as an HDD or a flash memory can also be used as a data storage area or the like. For the storage unit 135 of FIG. 1, for example, memories 402 and 403 can be used. 404 is a bus.

The wireless communication unit 405 realizes the function related to the wireless communication of the high frequency unit 102 in the terminal 100, and realizes the function related to the wireless communication of the high frequency unit 302 in the access point 300. The communication interface (I / F) unit 406 realizes the function of a communication interface with an external device at each of the terminal 100 and the access point 300.

FIG. 5 is a flowchart showing an operation processing example of the wireless device according to the first embodiment. An example of channel selection processing performed by a control unit 400 (CPU 401) provided in cooperation between a plurality of terminals (STA) 100 and an access point (AP) 300 constituting a wireless system will be described.

The access point (AP) 300 transmits a beacon signal to the terminal 100 on a channel currently communicating with the terminal 100 or a channel having an initial value (for example, 1ch) (step S501). The AP 300 starts the channel selection process of the wireless system shown in FIG. 5 by transmitting a beacon signal to the terminal 100 at a predetermined timing or periodically.

After that, the AP 300 acquires the communication speed (DL_Comm_Speed _l (ch)) for each channel transmitted from each terminal 100, and calculates the total communication speed (DL_Total_Comm_Speed (ch)) for each channel (step S502).

Next, the AP300 compares the total communication speed of the current channel with the total communication speed of the other channel (step S503). At this time, if the total communication speed of the other channel is higher than the total communication speed of the current channel communicating with the terminal 100 (step S503: Yes), the AP 300 proceeds to step S504. If the total communication speed of the current channel communicating with the terminal 100 is equal to or higher than the total communication speed of the other channel (step S503: No), the process returns to the process of step S501 without changing the channel of the current channel.

In step S504, the AP 300 changes the channel to the channel having the maximum total communication speed (step S504), notifies the terminal (STA) 100 of the channel to be changed (step S505), and ends the above processing.

Next, a processing example of each of a plurality of terminals (STA _l ) 100 communicated and connected to the AP 300 will be described. The STA _l (100) receives the radio wave from the AP 300 that reaches the own device, and calculates the communication speed (DL_Comm_Speed _l (ch)) in the current channel (for example, 1ch) (step S510). The communication speed is calculated based on, for example, SINR as described above.

On the other hand, STA _l (100) determines whether all channels have been scanned (step S511). If not all channels have been scanned (step S511: No), STA _l (100) changes the channel (step S512) and returns to the process of step S510. For example, the next channel (for example, 1ch → 2ch) of the current channel is sequentially scanned.

If scanning of all channels is completed (step S511: Yes), STA _l (100) changes the channel to the current channel communicating with AP300 (step S513). Then, the STA _l (100) transmits the communication speed data of each channel obtained in the processes of steps S510 to S512 to the AP300 (step S514).

After that, the STA _l (100) is set to the same channel as the changed channel notified from the AP 300 (step S515), and the above processing is completed.

(Comparison with existing technology)
Next, the channel selection process will be described in comparison with the existing technique and the first embodiment. FIG. 6 is a diagram showing various systems using the ISM band. The horizontal axis is frequency. There are multiple systems that use the same frequency in the ISM band. For example, the 2.4 GHz band includes Wi-Fi (registered trademark), mobile router, Bluetooth (registered trademark), ZigBee, amateur radio, medical microwave heating device, microwave oven and the like. In the 5 GHz band, there are Wi-Fi, various radars such as meteorology, fixed / search satellites, radio astronomy, microwave landing guidance, aeronautical radio navigation, amateur radio, and the like.

The ISM band does not require a radio station license and radio wave usage fee, and the number of systems using this ISM band is increasing year by year, and each system can coexist in the same frequency of the ISM band without causing interference with each other. Desired. In order to grasp the state of interference, it is necessary to measure continuous radio waves for a certain period of time and create statistical information and the like.

FIG. 7 is a diagram illustrating a channel selection process of an access point by an existing technique. FIG. 7A shows the arrangement state of AP1, 2 (300) of a plurality of wireless LANs and 700 of another system (for example, a Bluetooth communication device). It is assumed that AP1, 2 (300) and the other system 700 are arranged so that a part of the radio wave reachable range (corresponding to a cell) overlaps.

The terminals (STA1, 2) 100 are located so as to be able to communicate with the AP1 and the other system 700. The STA1 (100) is in a position where it can communicate with the AP1 (300) and another system 700. It is assumed that STA2 (100) is in a position where it can communicate with AP1 (300) and AP2 (300). AP1 (300) is located outside the radio wave range of AP2 (300) and other system 700, and AP1 (300) cannot grasp the existence of AP2 (100) by AP1 (300). is there. In the other system 700, the communication channel is ch1, and the communication channel of AP2 (300) is ch2.

In such a radio wave environment, as shown in FIG. 7B, the existing AP1 (300) communicates with all of ch1 to ch3 of STA1 and 2 (100) due to the received power at the time of channel search. It is judged that it can be used for (S701).

However, STA1 (100) is interfered by ch1 of another system 700, and STA2 (100) is interfered by ch2 of AP2 (300) (S702). In this case, when communicating with these STAs 1 and 2 (100), the AP1 (300) preferably selects a channel (ch3) that does not cause interference in consideration of the radio wave environment of the STAs 1 and 2 (100). Desirable (S703).

Here, in the existing technology, the AP1 (300) determines that all of ch1 to ch3 can be used for communication without considering the radio wave environment (S702) of the STAs 1 and 2 (100) that perform communication (S701). The transmission / reception channel is selected based on. Therefore, when communication is actually performed, there is a high possibility that the communication performance (throughput) between the STAs 1 and 2 (100) will deteriorate.

FIG. 8 is a diagram illustrating a channel selection process of the access point according to the first embodiment. FIG. 8A shows the arrangement state of AP1, 2 (300) of a plurality of wireless LANs and 700 of another system (for example, a Bluetooth communication device), similarly to FIG. 7A.

In AP1 (300) of the first embodiment, as shown in FIG. 8B, communication speed data of each channel when communication is performed from STAs 1 and 2 (100) is acquired based on the above channel selection process. And channel selection is performed (S801). As a result, the AP1 (300) selects the channel for communication in consideration of the radio wave environment of the STAs 1 and 2 (100). In this case, AP1 (300) selects a channel (for example, ch3) other than ch1 and 2 affected by other systems 700 and AP2 (300), and communicates with STA1 and 2 (100).

As described above, according to the first embodiment, the access point (AP) 300 has the downlink communication speed of the channel actually communicated with the terminal (STA) 100 and the communication speed of the other channel. Based on, change to the channel with the maximum communication speed. At this time, the AP 300 shifts to the channel having the maximum total communication speed, which is the sum of the communication speeds for each channel acquired from the plurality of STAs 100. In this way, the AP 300 autonomously selects the optimum channel for communication with the STA 100 in consideration of the radio wave environment of the STA 100. As a result, the AP 300 can improve the wireless communication performance (communication speed, communication quality, throughput, etc.) with the STA 100.

(Embodiment 2)
Next, the second embodiment of the wireless device will be described. In the second embodiment, the access point 300 selects a channel when performing uplink (UL) communication from the terminal 100 to the access point 300. Therefore, in the second embodiment, the configuration for calculating the SINR and the communication speed is provided in the access point 300.

FIG. 9 is a block diagram showing a configuration example of a terminal of the wireless device according to the second embodiment. Regarding the terminal (STA) 100 of the second embodiment, the same components as those of the first embodiment (see FIG. 1) are designated by the same reference numerals.

In the terminal 100 of the second embodiment, the configuration of the signal processing unit 103 is different from that of the first embodiment. The received signal processing unit 131 of the signal processing unit 103 has a channel transition unit 132 that changes to the channel notified from the AP 300. The transmission signal processing unit 141 transmits the transmission signal SD on the current channel.

FIG. 10 is a block diagram showing a configuration example of an access point of the wireless device according to the second embodiment. Regarding the access point (AP) 300 of the second embodiment, the same components as those of the first embodiment (see FIG. 3) are designated by the same reference numerals.

The access point 300 of the second embodiment has a different configuration of the signal processing unit 303 from the first embodiment. The reception signal processing unit 331 of the signal processing unit 303 includes a total communication speed calculation unit 332, a comparison unit 333, a selection unit 334, and a channel transition unit 335, as in the first embodiment. Further, the received signal processing unit 331 includes a SINR calculation unit 1001 and a communication speed calculation unit 1002.

The SINR calculation unit 1001 calculates the communication quality SINR of the received signal RD output by the baseband unit 301 (demodulator 324). At this time, the SINR calculation unit 133 obtains the SINR of each of the plurality of channels capable of communicating with the terminal 100.

Specifically, the SINR calculation unit 1001 calculates the SNIR of UL communication with the terminal _l (100) connected to the own access point 300 based on the following formula (3).

SINR _l (ch): Communication quality of AP in ch-th channel RSSI _l : Average received power received from terminal _l connected to AP Σ {RSSI _k (ch)}: Other AP and others in ch-th channel Average received power from the terminal connected to the AP N (ch): Average received power other than the wireless LAN signal in the chth channel (including noise power)
α, β: Adjustment parameters (default value: 1, 0 ≤ α ≤ 1, 0 ≤ β ≤ 1)

The communication speed calculation unit 1002 calculates the communication speed based on the SINR calculated by the SINR calculation unit 1001. Correspondence information between SINR and communication speed (SINR-communication speed correspondence table 201, see FIG. 2) is preset in the storage unit 1003. The communication speed calculation unit 134 refers to the storage unit 1003 and reads out the communication speed corresponding to the communication speed of the received signal RD calculated by the SINR calculation unit 1001.

The communication speed calculated by the communication speed calculation unit 1002 is the communication speed of the channel currently communicating in the uplink UL from the terminal 100 to the access point 300 (UL_Comm_Speed _l (ch)). The communication speed data F calculated by the communication speed calculation unit 1002 is output to the total communication speed calculation unit 332.

The total communication speed calculation unit 332 calculates the total communication speed for each channel with respect to the communication speed (communication speed data F) of the channel calculated by the communication speed calculation unit 1002.

The total communication speed is the total speed of the uplinks (UL: communication from the terminal to the access point) of each of the plurality of terminals 100 that perform UL communication with the access point 300.

Here, the total communication speed calculation unit 332 simply connects to the access point 300 in calculating the total communication speed, but the communication speed of the terminal 100 that is not communicating is not included in the total communication speed. That is, the total communication speed calculation unit 332 obtains the total communication speed of the current channel and the total communication speed of the other channels for the plurality of terminals 100 that can actually communicate. For example, the total communication speed (UL_Total_Comm_Speed (ch) is calculated based on the following formula (4). L is the number of terminals.

The comparison unit 333 stores and holds the information of the total communication speed RD1 of the current channel (for example, 1ch) calculated by the total communication speed calculation unit 332 and the total communication speed RDn of the other channels in an updateable manner. Then, the comparison unit 333 compares the total communication speed RD1 of the current channel with the total communication speed RDn of the other channel. For example, the total communication speed RD1 of the current channel and the total communication speed RD2 of a plurality of other channels are compared.

The selection unit 334 selects the channel having the maximum total communication speed as a result of comparison by the comparison unit 333. Then, the channel transition unit 335 shifts to the channel having the maximum total communication speed. For example, if the total communication speed RD2 of the other channel (ch5) is larger than that of the current channel (Ch1), the subsequent communication channel is set to ch5, and the channel is shifted from the current channel 1ch to 5ch. If the total communication speed of the current channel (1ch) is higher than any of the other channels, the current channel (1ch) is left as it is, and channel transition is not performed.

The channel transfer unit 335 changes the oscillation frequency of the oscillator 2 (315) to a frequency corresponding to the channel to be transferred for channel transfer. As a result, the transmission frequency of PA314 of the transmission signal and the reception frequency of LNA322 of the reception signal are channel-changed (communication frequency allocation). Further, the channel transition unit 335 notifies the transmission signal processing unit 341 of the channel change at the time of channel transition.

The transmission signal processing unit 341 includes a channel change notification unit 343. When the channel change notification unit 343 receives the notification of the channel transition from the reception signal processing unit 331 (channel transition unit 335), the channel change notification unit 343 transmits the notified channel information after the change to the terminal 100 as a transmission signal SD. The terminal 100 changes the channel according to the channel information included in the transmission signal SD. As a result, communication with the terminal 100 can be continued even if the channel is changed at the access point 300.

The terminal 100 and the access point 300 of the second embodiment are also controlled by the control unit 400 shown in FIG. As a result, in the terminal 100, the control unit 400 controls the terminal 100 in an integrated manner, and also executes and controls the functions of the baseband unit 101 and the signal processing unit 103 of the terminal 100. Further, in the access point 300, the control unit 400 controls the access point 300 in an integrated manner, and also executes and controls the functions of the baseband unit 301 and the signal processing unit 303 of the access point 300.

FIG. 11 is a flowchart showing an operation processing example of the wireless device according to the second embodiment. An example of channel selection processing performed by a control unit 400 (CPU 401) provided in cooperation between a plurality of terminals (STA) 100 and an access point (AP) 300 constituting a wireless system will be described.

Each of the plurality of terminals (STA) 100 capable of communicating with the AP 300 transmits a UL transmission signal SD to the access point (AP) 300 on the current channel (for example, 1ch) (step S1101). After that, if the AP300 notifies the channel change, the STA 100 adjusts to the same channel as the notified AP300 (step S1102), and ends the above processing.

On the other hand, the AP300 receives the radio wave reaching the own device and calculates the UL communication speed (UL_Comm_Speed _l (ch)) in the current channel (for example, 1ch) (step S1111). Then, the AP 300 calculates the total communication speed (UL_Total_Comm_Speed (ch)) for each channel transmitted from each terminal 100 (step S1112).

Next, the AP300 determines whether all channels communicating with the STA 100 have been scanned (step S1113). If all the channels have not been scanned (step S1113: No), the AP300 changes the channel (step S1114) and returns to the process of step S1111. For example, the next channel (for example, 1ch → 2ch) of the current channel is sequentially scanned.

If the scanning of all channels is completed (step S1113: Yes), the AP300 compares the total communication speed of the current channel with the total communication speed of the other channel (step S1115). At this time, if the total communication speed of the other channel is higher than the total communication speed of the current channel communicating with the terminal 100 (step S1115: Yes), the AP 300 shifts to the process of step S1116. When the total communication speed of the current channel communicating with the terminal 100 is equal to or higher than the total communication speed of the other channel (step S1115: No), the process returns to the process of step S1111 without changing the channel of the current channel.

In step S1116, the AP300 changes the channel to the channel having the maximum total communication speed (step S1116), notifies the terminal (STA) 100 of the channel to be changed (step S1117), and ends the above processing.

As described above, according to the second embodiment, the access point (AP) 300 has an uplink communication speed when actually communicating with the terminal (STA) 100, and a communication speed of another channel. Based on, change to the channel with the maximum communication speed. At this time, the AP 300 shifts to the channel having the maximum total communication speed, which is the sum of the communication speeds for each of the plurality of channels. In this way, the AP 300 autonomously selects the optimum channel for communication with the STA 100 in consideration of the radio wave environment of the STA 100. As a result, the AP 300 can improve the wireless communication performance (communication speed, communication quality, throughput, etc.) with the STA 100.

Further, the configuration of the first embodiment and the configuration of the second embodiment may be combined. That is, the channel selection based on the communication speed of the downlink DL according to the first embodiment and the channel selection based on the communication speed of the uplink UL according to the second embodiment may be combined. For example, the access point (AP) 300 switches between DL and UL based on the amount of communication, the ratio of the amount of DL / UL data, and the like. The AP 300 may select a channel based on the total communication speed of DL when the communication volume of DL increases, and may perform channel selection based on the total communication speed of UL when the communication volume of UL increases.

At the time of the above combination, the signal processing unit 103 of the terminal 100 includes the configurations of the first embodiment (FIG. 1) and the second embodiment (FIG. 9). The signal processing unit 303 of the AP 300 may include the configurations of the first embodiment (FIG. 3) and the second embodiment (FIG. 10).

According to each of the above-described embodiments, the wireless device can select a channel in consideration of the radio wave environment such as interference from another system received by the other wireless device communicating with the wireless device. At this time, the wireless device changes to the channel having the maximum communication speed based on the respective communication speeds of the current channel and the other channel when actually communicating with the other wireless device. Further, the wireless device shifts to the channel having the maximum total communication speed, which is the sum of the communication speeds for each channel acquired from the plurality of wireless devices.

Then, the wireless device can autonomously select the optimum channel for communication with another wireless device that communicates. As a result, the wireless device can improve the wireless communication performance (communication speed, communication quality, throughput, etc.) with other wireless devices.

Then, according to each embodiment, the wireless device has a simple configuration and wireless communication with the wireless device of the communication partner without being affected by interference and noise from other systems using the same frequency such as the ISM band. Will be able to do. In addition, it becomes possible to adapt to the actual installation environment of the wireless device, and even if the installation environment changes, it becomes possible to always communicate with other wireless devices using the optimum channel.

The communication frequency allocation method described in the present embodiment can be realized by executing a control program prepared in advance by a computer (CPU or the like) of the target device (terminal or access point which is the wireless device). it can. This control program is recorded on a computer-readable recording medium such as a magnetic disk, an optical disk, or a USB (Universal Social Bus) flash memory, and is executed by being read from the recording medium by the computer. Further, the control program may be distributed via a network such as the Internet.

The following additional notes are further disclosed with respect to the above-described embodiment.

(Appendix 1) It is a wireless device and
Based on the communication speeds of the current channel and the other channel that communicated with the other wireless device, the channel with the maximum communication speed is used as a new channel for communication with the other wireless device. Control unit to select,
A wireless device characterized by having.

(Appendix 2) The control unit compares the communication speed of the current channel that has communicated with the other wireless device with the communication speed of a plurality of the other channels other than the current channel, and the communication speed is the maximum. The wireless device according to Appendix 1, wherein the channel is a new channel used for communication with the other wireless device.

(Appendix 3) The control unit transmits a beacon signal for measurement to the other wireless device on a predetermined channel.
Information on the downlink communication speed of the current channel obtained by the other radio device by receiving the beacon signal and the downlink communication speed of a plurality of the other channels other than the current channel is obtained from the other radio. Received from the device
The wireless device according to Appendix 1, wherein the channel having the maximum communication speed is selected as a new channel used for communication with the other wireless device.

(Appendix 4) When the terminal transmits a signal to its own device on a predetermined current channel of the uplink, the control unit has a communication speed of the uplink of the current channel obtained by receiving the signal and a communication speed other than the current channel. Find the uplink communication speed of multiple other channels
The wireless device according to Appendix 1, wherein the channel having the maximum communication speed is selected as a new channel used for communication with the other wireless device.

(Appendix 5) The control unit sums the communication speeds of a plurality of channels capable of communicating with the other wireless devices, and sets the channel having the maximum total communication speed with the other wireless devices. The wireless device according to Appendix 1, characterized in that it is selected as a new channel used for communication in the above.

(Supplementary Note 6) The control unit obtains a communication quality when communicating with the other wireless device, and obtains a preset communication speed corresponding to the communication quality. Wireless device.

(Appendix 7) A wireless device
A control unit that obtains the communication speeds of the current channel and other channels that have communicated with other wireless devices and transmits the communication speeds to the other wireless devices.
A wireless device characterized by having.

(Supplementary Note 8) The control unit obtains the communication quality when communicating with the other wireless device, and obtains a preset communication speed corresponding to the communication quality. Wireless device.

(Supplementary Note 9) The wireless device according to Appendix 7 or 8, wherein the control unit changes the channel for communicating with the other wireless device based on the notification of the channel change from the other wireless device.

(Appendix 10) A wireless system including a wireless device and a terminal.
The wireless device is
Based on the communication speeds of the current channel and other channels that have communicated with the terminal, the channel with the maximum communication speed is selected as a new channel to be used for communication with the terminal, and the above-mentioned It has a control unit that notifies the terminal
The terminal
It has a control unit that performs communication using the channel notified from the wireless device.
A wireless system characterized by that.

(Appendix 11) A method of assigning a communication frequency in a wireless device.
Based on the communication speeds of the current channel and the other channel that communicated with the other wireless device, the channel that maximizes the communication speed is used for communication with the other wireless device. Select as,
A communication frequency allocation method characterized by that.

(Appendix 12) The communication speed of the current channel that communicates with the other wireless device is compared with the communication speed of a plurality of channels other than the channel, and the channel having the maximum communication speed is compared with the other wireless device. Change to a new channel used for communication,
The communication frequency allocation method according to Appendix 11, wherein the communication frequency is assigned.

100 terminals (STA, wireless device)
101, 301 Baseband section 102, 302 High frequency section 103, 303 Signal processing section 131 Received signal processing section 132 Channel transition section 133 SINR calculation section 134 Communication speed calculation section 135, 1003 Storage section 141 Transmission signal processing section 201 Communication speed correspondence table 300 access points (AP, wireless device)
331 Received signal processing unit 332 Total communication speed calculation unit 333 Comparison unit 334 Selection unit 335 Channel transition unit 341 Transmission signal processing unit 342 Beacon transmission unit 343 Channel change notification unit 400 Control unit 401 CPU
402 Memory 403 Extended memory 405 Wireless communication unit 1001 SINR calculation unit 1002 Communication speed calculation unit

Claims (6)

It ’s a wireless device,
Based on the communication speeds of the current channel and the other channel that communicated with the other wireless device, the channel with the maximum communication speed is used as a new channel for communication with the other wireless device. Has a control unit, to select
When the other wireless device transmits a signal to its own device on a predetermined current channel of the uplink, the control unit has a communication speed of the uplink of the current channel obtained by receiving the signal and a communication speed other than the current channel. Find the uplink communication speed of multiple other channels
A wireless device characterized in that the channel having the maximum communication speed is selected as a new channel used for communication with the other wireless device. The control unit transmits a beacon signal for measurement to the other wireless device on a predetermined channel.
Information on the downlink communication speed of the current channel obtained by the other radio device by receiving the beacon signal and the downlink communication speed of a plurality of the other channels other than the current channel is obtained from the other radio. Received from the device
The wireless device according to claim 1, wherein the channel having the maximum communication speed is selected as a new channel used for communication with the other wireless device. The control unit totals the communication speeds of the plurality of other wireless devices for each of a plurality of channels capable of communicating with the plurality of other wireless devices, and determines the channel at which the total communication speed is maximum. The wireless device according to claim 1, wherein the wireless device is selected as a new channel used for communication with the other wireless device. The wireless device according to claim 1, wherein the control unit obtains a communication quality when communicating with the other wireless device, and obtains a communication speed set in advance corresponding to the communication quality. .. A wireless system that includes wireless devices and terminals
The wireless device is
Based on the communication speeds of the current channel and other channels that have communicated with the terminal, the channel with the maximum communication speed is selected as a new channel to be used for communication with the terminal, and the above-mentioned It has a control unit that notifies the terminal
When the terminal transmits a signal to its own device on a predetermined current channel of the uplink, the control unit has the uplink communication speed of the current channel obtained by receiving the signal and a plurality of other devices other than the current channel. Find the uplink communication speed of the channel of
The channel with the maximum communication speed is selected as the new channel used for communication with the terminal, and the channel is selected.
The terminal
It has a control unit that performs communication using the channel notified from the wireless device.
A wireless system characterized by that. It is a communication frequency allocation method in wireless devices.
Based on the communication speeds of the current channel and the other channel that communicated with the other wireless device, the channel that maximizes the communication speed is used for communication with the other wireless device. Select as
When the other wireless device transmits a signal to its own device on a predetermined current channel of the uplink, the communication speed of the uplink of the current channel obtained by receiving the signal and a plurality of other channels other than the current channel. Find the communication speed of the uplink of
The channel with the maximum communication speed is selected as a new channel used for communication with the other wireless device.
A communication frequency allocation method characterized by that.

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