JP3896824B2 - Wireless channel setting device and method, program, and wireless communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a radio channel setting apparatus and method, a program, and a radio communication apparatus for switching a frequency channel used for transmitting a radio signal according to a user's operation, and in particular, SS-DS (spread spectrum-direct sequence: direct spreading). The present invention relates to a radio channel setting device and method, a program, and a radio communication device for switching a frequency channel used for transmitting a radio signal according to a (spread spectrum) system.
[0002]
[Prior art]
In recent years, IEEE 802.11 using the 2.4 GHz band established by the Institute of Electrical and Electronics Engineers (IEEE) as a protocol for wireless local area network (LAN) systems has become widespread. .
[0003]
In IEEE 802.11, two types of network forms are used: an ad hoc network and an infrastructure network. The ad hoc network is a form in which terminals communicate with each other, and the infrastructure network is a form configured to communicate with a plurality of terminals 102 via an access point 101 as shown in FIG. In this infrastructure network, an SSID (Servese Set ID) is set in the access point 101 and each terminal 102, and wireless communication is performed between the access point 101 and the terminal 102 in which the same SSID is set.
[0004]
Also, in IEEE 802.11, a direct spread spectrum method, a frequency hopping method, and the like are defined as a use frequency setting method in the physical layer. In the direct spread spectrum system, for example, 14 frequency channels are set in the 2.4 GHz band, and the frequency bands overlap between adjacent frequency channels. Therefore, typically adjacent frequency channels are not used in the same network.
[0005]
In the infrastructure network, the access point 101 has a function of setting a frequency channel to be used in the network, and uses one frequency channel in one wireless network. Further, the terminal 102 detects the frequency channel of the access point 101 having the same SSID, and communicates with the access point 101 having the same frequency channel. The terminal 102 is controlled by the access point 101 to set a frequency channel to be used.
[0006]
In a wireless LAN system using the direct spread spectrum method, if the frequency channel used by the access point 101 overlaps with the frequency channel of another network, or if an adjacent frequency channel is used by another device, the frequency channel Radio interference occurs and communication throughput decreases. In order to avoid this, it is necessary for the network administrator to investigate the usage status of each frequency channel by using a channel survey tool or the like, and reset it to a frequency channel that is not being used. At this time, the parameter value relating to each frequency channel is investigated using a command system for investigating the communication quality and the received electric field strength by the channel investigation tool. This command system is defined in IEEE 802.11. In this way, by managing the channels of all the wireless LANs being used, it is possible to reset frequency channels that do not cause radio wave interference. That is, in the wireless LAN, the frequency channel used by the access point 101 is set by the network administrator.
[0007]
In recent years, DFS (Dynamic Freaquency Selection), which is a method for dynamically selecting a frequency channel to be used, has been proposed as a new standard proposal of IEEE 802.11h. This is used in a wireless LAN system using the 5 GHz band, and the frequency channel is automatically changed to a channel with a good radio wave condition using a control packet for channel change between the access point 101 and the terminal 102. Technology.
[0008]
There is a system in which communication of a control system is partially wireless using such a wireless LAN standard.
[0009]
For example, in a conventional lighting control system, there is a lighting control system in which a lighting device 111 and a console 112 are connected by an electric wire 113 as shown in FIG. In this lighting control system, a console 112 having an input unit such as a switch for controlling the operation of a plurality of lighting devices 111 generates a control signal corresponding to the input and transmits it to all the lighting devices 111. The received control signal is analyzed and an operation according to the control signal is performed.
[0010]
FIG. 15 shows a case where such a lighting control system is made wireless using a wireless LAN. In this lighting control system, the lighting control protocol control signal (first control signal) output from each console 112 is converted into a wireless LAN type second control signal by each conversion unit 114 and converted to the access point 101. Output. Then, the access point 101 transmits a radio signal to each terminal 102 on the reception side, and when the terminal 102 receives the radio signal, the conversion unit 115 converts the signal into an illumination control protocol and outputs the illumination control protocol as a first control signal. To do.
[0011]
That is, simply by connecting the conversion unit 114 and the conversion unit 115 to the console 112 and the lighting device 111 and adding the access point 101 and the terminal 102 to the lighting control system shown in FIG. be able to.
[0012]
[Problems to be solved by the invention]
However, when the lighting control system is made wireless using the 2.4 GHz band as shown in FIG. 15, the frequency channel of each system is changed when other control systems using the wireless LAN standard exist independently. In some cases, the frequency channel changing method of other systems is unknown.
[0013]
In addition, there are cases where the administrator who uses the lighting control system does not have wireless technical knowledge, or a special procedure is required to start a tool for changing the frequency channel, and it is not easy to change the frequency channel. is there.
[0014]
Furthermore, there is no 2.4GHz band wireless LAN that automatically changes the frequency channel, and in a lighting control system using the wireless LAN, for example, the frequency channel is automatically changed during a stage performance. Therefore, there is a possibility that the lighting control may be temporarily disabled during the change of the frequency channel.
[0015]
Therefore, the present invention has been proposed in view of the above-described circumstances, and it is possible to easily change the setting of a frequency channel to an optimum frequency channel and avoid changing the frequency channel during communication. An object is to provide a channel setting device and method, a program, and a wireless communication device.
[0016]
[Means for Solving the Problems]
  In order to solve the above-mentioned problem, a radio channel setting device according to claim 1Is,Access point for wireless LAN systemWireless that transmits and receives wireless data according to the direct spread spectrum method between the wireless communication device and the wireless communication terminalLANA wireless channel setting device for setting a frequency channel to be used in a system, wherein an operation input unit operated by a user, and a frequency channel change permission is recognized in response to an operation of the operation input unit. Investigation means for investigating parameter values relating to radio wave conditions for all frequency channels of data, determination means for selecting a frequency channel based on the parameter values investigated by the investigation means, and frequency channel selected by the determination means Setting means for controlling the wireless communication device to communicate with, During the wireless communication between the wireless communication device and the wireless terminal device, investigate the parameter value of the frequency channel being used, determine whether to change the frequency channel based on the investigated parameter value, Detecting means for presenting to the user when it is detected that the frequency channel is changed, and detecting the change of the frequency channel by the detecting means and presenting the user with the operation input means being operated. In response to this, the investigation means recognizes permission to change the frequency channel.
[0018]
  Claim2In the wireless channel setting device according toClaim 1The wireless channel setting device according to claim 1, wherein the number of packet losses or the number of packet retransmissions is investigated as the parameter value according to the presence or absence of a return packet for a packet transmitted from the wireless communication device to the wireless communication terminal. To do.
[0019]
  Claim3In the wireless channel setting device according toClaim 1The radio channel setting device according to claim 1, wherein the received electric field strength of the radio communication terminal is investigated as the parameter value.
[0020]
  Claim4In the wireless channel setting device according toClaim 1The wireless channel setting device according to claim 1, wherein the noise level of the wireless communication terminal is investigated as the parameter value.
[0021]
  Claim5The radio channel setting device according to claim 1 is the radio channel setting device according to claim 1, wherein the examining means selects a frequency channel from a plurality of frequency channels whose frequency bands do not overlap with other frequency channels. And
[0022]
  Claim6In the radio channel setting device according to claim 1, the claim 1 or claim5In the wireless channel setting device according to claim 1, the investigation means detects a frequency channel to be selected based on the parameter values of a plurality of frequency channels whose frequency bands do not overlap with other frequency channels, and detects the detected frequency The selection is based on the parameter value of the frequency channel adjacent to the channel.
[0023]
  In order to solve the above-mentioned problems, the claims7In the wireless channel setting method according toAccess point for wireless LAN systemWhen setting the frequency channel to be used when wireless data is transmitted and received between the wireless communication device and the wireless communication terminal according to the direct spread spectrum method, the frequency channel change permission is recognized by the user's operation, and all frequencies of the wireless data are Investigate the parameter value related to the radio wave condition for the channel, select the frequency channel based on the investigated parameter value, and set the frequency channel of the above wireless communication device to communicate with the selected frequency channelThen, during the wireless communication between the wireless communication device and the wireless terminal device, the parameter value of the frequency channel being used is investigated, and it is determined whether to change the frequency channel based on the investigated parameter value. , After presenting to the user that it has detected that the frequency channel is changed, recognizes the change permission of the frequency channel according to the user's operation..
[0025]
  In order to solve the above-mentioned problems, the claims8When the program according to is read by a computer, at leastWhen setting a frequency channel to be used when wireless data is transmitted / received in accordance with the direct spread spectrum method between a wireless communication device that is an access point of a wireless LAN system and a wireless communication terminal, the change of the frequency channel is permitted by a user operation. Recognize and investigate the parameter value related to the radio wave condition for all frequency channels of wireless data, select the frequency channel based on the investigated parameter value, and communicate with the selected frequency channel. Whether or not to change the frequency channel based on the investigated parameter value during the wireless communication between the wireless communication device and the wireless terminal device. To change the frequency channel That out did after presentation to the user, to execute the processing for recognizing the change permission frequency channels in accordance with the operation by the user.
[0026]
  In order to solve the above-mentioned problems, the claims9In the wireless communication device according toA wireless communication device that is an access point of a wireless LAN system, and accesses the access pointWireless communication means for transmitting and receiving wireless data directly with a wireless communication terminal according to the spread spectrum method, operation input means operated by the user, and permission to change the frequency channel in response to the operation input means being operated Recognizing and investigating the parameter values relating to the radio wave condition for all frequency channels of the radio data, the judging means for selecting the frequency channel based on the parameter values investigated by the investigating means, and the judging means Changing means for controlling the wireless communication means to change the frequency channel so as to perform wireless communication with the selected frequency channelThen, during the wireless communication with the wireless terminal device, the parameter value of the frequency channel being used is investigated, it is determined whether to change the frequency channel based on the investigated parameter value, and the frequency channel is changed. And detecting means for presenting to the user when it is detected, and detecting the change of the frequency channel by the detecting means and presenting it to the user so that the operation input means is operated in response to the operation. Recognize permission to change frequency channel by means of investigation.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0029]
[First Embodiment]
The present invention is applied to, for example, a lighting control system according to the first embodiment as shown in FIG. In this example, an illumination control system will be described that includes a plurality of illumination devices that illuminate a theater, for example, and performs dimming of each illumination device.
[0030]
“Configuration of Lighting Control System According to First Embodiment (FIG. 1)”
The lighting control system according to the first embodiment includes a lighting control device 1, a wireless channel setting device 2, and an access point 3 as a lighting control side, and a wireless communication terminal 4 that performs wireless communication with the access point 3 as a controlled side, The lighting device 5 is provided. In this illumination control system, the access point 3 and the wireless communication terminal 4 perform wireless communication, thereby transmitting dimming control data to the illumination device 5 and the frequency channel between the access point 3 and the wireless communication terminal 4. Set.
[0031]
In this lighting control system, the access point 3 and the wireless communication terminal 4 have a common SSID. The access point 3 and the wireless communication terminal 4 can transmit and receive wireless data by storing the SSID in the wireless data during wireless communication and recognizing that the common SSID is stored in the received wireless data. .
[0032]
In this lighting control system, the access point 3 and the wireless communication terminal 4 use the 2.4 GHz band as a frequency band, and perform wireless communication according to the direct spread spectrum system (SS-DS (spread spectrum-direct sequence)). To do. That is, the access point 3 and the wireless communication terminal 4 transmit the input signal by applying a pseudo-noise code of a predetermined frequency to make the wireless data a frequency band of a set frequency channel, and when the wireless data is received, Receive with a pseudo-noise code. In the access point 3, one frequency channel is set by the wireless channel setting device 2. The wireless communication terminal 4 detects the frequency channel set in the access point 3.
[0033]
In FIG. 1, only one lighting control system in which a single access point 3 and a single wireless communication terminal 4 communicate with each other is shown. The terminal 4 may be connected, and another lighting control system may be installed adjacent to illuminate the same theater.
[0034]
The lighting control device 1 includes a dimming console 11 operated by a user, and a first protocol conversion unit 12 that converts a first protocol signal into a second protocol signal.
[0035]
In this example, the first protocol is the DMX standard, which is a standard communication system for lighting control. The DMX standard is an EIA / TIA serial transmission standard, and is a standard for transmitting dimming control data to a single cable in which one or a plurality of lighting devices 4 are connected in the form of a bus. The second protocol is a general-purpose LAN (Local Area Network) standard, for example, called an Ethernet standard.
[0036]
In the following description, dimming control data according to the DMX standard is transmitted through the signal line 11 and the signal line 12, and UDP (User Datagram Protocol) / IP (IP) between the illumination control transmitter 2 and the illumination control receiver 3. An example in which a control packet including dimming control data according to the Internet Protocol standard and the LAN standard is transmitted will be described.
[0037]
The console 11 includes an operation unit for a user to remotely control the lighting device 5 such as a switch, a dial, and a fader. The dimming console 11 generates dimming control data indicating the dimming control content of the lighting device 5 by operating the operation unit. Specifically, the console 11 generates dimming control data for controlling lighting, extinction, brightness, and the like of the lighting device 5. When the dimming table 11 outputs the generated dimming control data to the first protocol conversion unit 12, the dimming table 11 uses a DMX signal in accordance with the DMX standard.
[0038]
When receiving the dimming control data from the dimming console 11, the first protocol conversion unit 12 stores, for example, address information of the transmission destination and creates a control packet according to the LAN standard. The first protocol conversion unit 12 outputs the created control packet to the access point 3.
[0039]
When the access point 3 receives the control packet from the first protocol conversion unit 12, the access point 3 converts the control packet into wireless data, and sends the wireless data to the wireless communication terminal 4 via a wireless antenna (not shown). In addition, when the wireless data from the wireless communication terminal 4 is detected by the wireless antenna, the access point 3 outputs the detected wireless data in a signal form that can be processed by the first protocol conversion unit 12. At this time, the access point 3 stores the SSID held in common with the wireless communication terminal 4 and transmits the wireless data, and receives the wireless data with reference to the SSID included in the wireless data detected by the wireless antenna. .
[0040]
Further, the access point 3 has a function of changing the frequency channel when transmitting wireless data by the wireless channel setting device 2. When the access point 3 receives a channel setting command from the wireless channel setting device 2, the access point 3 transmits and receives wireless data on the frequency channel specified by the channel setting command.
[0041]
Furthermore, the access point 3 has a function of examining parameter values that change due to radio wave interference of radio signals for each frequency channel. The access point 3 investigates, for example, the received electric field strength (RSSI (Received Signal Strength Indication)), noise level, or packet loss number (or packet loss rate) of the wireless communication terminal 4 as the parameter value. At this time, the access point 3 designates a frequency channel to be used and issues a survey command for investigating the parameter value to the wireless communication terminal 4. The access point 3 outputs the parameter value investigation result to the wireless channel setting device 2.
[0042]
The wireless channel setting device 2 includes a wireless channel setting unit 21 that outputs a channel setting command to the access point 3, an operation input unit 22 that is operated by the user, and an information presentation unit 23 that presents various information to the user.
[0043]
The operation input unit 22 includes a switch mechanism that is pressed by a user, for example, and the operation is detected by the wireless channel setting unit 21. The operation input unit 22 is operated when the wireless channel setting unit 21 is permitted to issue a channel setting command. In other words, the operation input unit 22 is operated when the change of the frequency channel used in the lighting control system is permitted.
[0044]
The wireless channel setting unit 21 includes a survey processing unit 31 that inputs a survey result from the access point 3, a determination processing unit 32, and a setting processing unit 33.
[0045]
When the investigation processing unit 31 detects that the operation input unit 22 has been operated, the investigation processing unit 31 issues an investigation command to the access point 3 to input the investigation result on the frequency channel. At this time, the survey processing unit 31 issues a survey command to the access point 3 so as to obtain a survey result for a frequency channel different from the currently used frequency channel, and the survey results for a plurality of frequency channels are displayed. get.
[0046]
The determination processing unit 32 analyzes the survey result of each frequency channel acquired by the survey processing unit 31, and selects a frequency channel with the best parameter value from a predetermined frequency channel that does not overlap the frequency band, and is a candidate channel to set next. Select as Then, the determination processing unit 32 refers to the investigation result of the frequency channel adjacent to the candidate channel, thereby confirming the parameter value of each adjacent frequency channel, and determines whether to determine the candidate channel as a new frequency channel. To do.
[0047]
When the determination processing unit 32 selects a new frequency channel, the setting processing unit 33 issues a channel setting command for changing from the currently used frequency channel to the new frequency channel and outputs the channel setting command to the access point 3.
[0048]
When the wireless communication terminal 4 receives wireless data from the access point 3 via a wireless antenna (not shown), the wireless communication terminal 4 converts the wireless data into a control packet and outputs the control packet to the illumination device 5. In addition, when the control packet is input from the lighting device 5, the wireless communication terminal 4 converts the signal into wireless data and transmits it from the wireless antenna. The wireless communication terminal 4 has an SSID that is common to the access point 3, stores the SSID in wireless data, transmits the wireless data, and receives wireless data by referring to the SSID included in the wireless data detected by the wireless antenna. .
[0049]
The wireless communication terminal 4 transmits and receives wireless data to and from the access point 3 by using the same frequency channel as the access point 3. The wireless communication terminal 4 searches for the access point 3 having the same SSID while sequentially changing the frequency channel at the initial setting or periodically, thereby detecting the frequency channel set by the access point 3 and detecting a new frequency channel. Is detected.
[0050]
Further, the wireless communication terminal 4 transmits an investigation command for examining the parameter value from the access point 3. The wireless communication terminal 4 performs processing according to the investigation command. Specifically, when the parameter value is a noise level, the noise of the received radio wave is measured, wireless data including the noise level is created and transmitted to the access point 3. If the parameter value is packet loss, a reply packet corresponding to the investigation command is created and transmitted. Further, when the parameter value is RSSI, the RSSI of the received radio wave is measured, and wireless data including RSSI is created and transmitted.
[0051]
The lighting device 5 includes a second protocol conversion unit 41 that converts a second protocol signal into a first protocol signal, and a lighting fixture 42.
[0052]
When the second protocol conversion unit 41 receives a LAN standard control packet from the wireless communication terminal 4, the second protocol conversion unit 41 converts the protocol into dimming control data according to the DMX standard, and outputs the data to the lighting fixture 42. The luminaire 42 operates according to the dimming control data according to the DMX standard.
[0053]
In such a lighting control system, the bandwidth of each frequency channel is set as shown in FIG. 2 in the 2.4 GHz band, and any frequency channel is used between the access point 3 and the wireless communication terminal 4. Wireless communication. In the access point 3, for example, when an RSSI investigation command is input from the wireless channel setting device 2, an investigation result as shown in FIG. 3 is acquired.
[0054]
In an example described with reference to FIG. 3, for example, the frequency channel “14” is a currently used frequency channel, and “1”, “6”, “11”, Assume that “14” is set. Then, the access point 3 outputs RSSI of all frequency channels shown in FIG.
[0055]
The investigation processing unit 31 selects a frequency channel “6” as a frequency channel with the highest RSSI among the predetermined frequency channels that can be candidate channels from the RSSI of each frequency channel, and sets it as a candidate channel. Then, the average value is calculated by referring to the RSSI for the two frequency channels “4”, “5”, “7”, and “8” adjacent to the frequency channel “6”. After confirming that the value is “90” or more, the frequency channel is set as a new frequency channel. Note that frequency channels “1” and “11” in FIG. 3 are considered to be able to use frequency channels that are the same or adjacent in other wireless LANs, and an example in which RSSI is low is shown.
[0056]
“Operation of Lighting Control System According to First Embodiment”
Next, an operation procedure of the illumination control system according to the first embodiment described above will be described with reference to FIG.
[0057]
In the lighting control system, the access point 3 and the wireless communication terminal 4 are communicating, and the channel can be changed by the investigation processing unit 31 when the user performs an operation for allowing the channel change to the operation input unit 22. Determination is made and the process proceeds to step S2.
[0058]
In step S <b> 2, the investigation processing unit 31 issues an investigation command for acquiring a parameter value for a certain frequency channel to the access point 3. Thereby, in the access point 3, the parameter value in the frequency channel designated by the investigation command is acquired and stored, and the process proceeds to step S3.
[0059]
In step S3, the access point 3 changes the frequency channel so as to investigate parameter values for a frequency channel different from the frequency channel investigated in step S2. On the other hand, the radio communication terminal 4 detects the changed frequency channel and changes the frequency channel.
[0060]
In the next step S4, the access point 3 determines whether or not parameter values have been acquired for all frequency channels, and when acquired, the survey result is output to the survey processing unit 31, and the survey processing unit 31 determines the determination processing unit 32. The survey result is output to and the process proceeds to step S5. On the other hand, in the access point 3, when parameter values are not acquired for all frequency channels, the process returns to step S2 so as to acquire the parameter values of the frequency channel set in step S3.
[0061]
In step S5, the determination processing unit 32 analyzes the investigation result acquired in step S4, and selects a frequency channel having the best parameter value as a candidate channel to be set next from predetermined frequency channels in which frequency bands do not overlap. Then, the process proceeds to step S6.
[0062]
In step S6, the determination processing unit 32 determines a candidate channel as a new frequency channel according to the result of the investigation of the frequency channel adjacent to the candidate channel selected in step S5, and proceeds to step S7.
[0063]
In step S7, the setting processing unit 33 issues a channel setting command for changing to the new frequency channel determined in step S6 and outputs it to the access point 3, and the process proceeds to step S8.
[0064]
In step S8, the access point 3 changes the frequency channel according to the channel setting command input in step S7 and starts operation. As a result, the wireless communication terminal 4 detects the frequency channel of the access point 3 by sequentially changing the frequency channel, and changes its own frequency channel.
[0065]
Next, in the operation of the illumination control system shown in FIG. 4, a processing procedure when the parameter value of each frequency channel is set to the noise level will be described with reference to FIG.
[0066]
When the parameter value of each frequency channel is set to the noise level, the access point 3 performs the processing corresponding to the above-described steps S2 to S4 after step S1, thereby obtaining the noise levels for all frequency channels. The survey result is acquired and stored by the survey processing unit 31 (step S11).
[0067]
At this time, the investigation processing unit 31 specifies that the noise level is to be investigated as an investigation command and outputs it to the access point 3. In response to this, the access point 3 issues a survey command for investigating the noise level to the wireless communication terminal 4, and the wireless communication terminal 4 measures the noise level of the received radio wave and returns it to the access point 3.
[0068]
In the next step S12, the determination processing unit 32 performs processing corresponding to the above-described step S5. That is, based on the noise level obtained in step S11 by the determination processing unit 32, out of the noise levels of frequency channels (for example, 1, 6, 11, and 14ch) that can be preset candidate channels without overlapping frequency bands. The frequency channel with the lowest noise level is selected as a candidate channel.
[0069]
In the next step S13 to step S15, processing corresponding to the above-described step S6 is performed. That is, in step S13, the determination processing unit 32 determines whether there is a frequency channel whose noise level within two channels adjacent to the candidate channel selected in step S12 is equal to or lower than a predetermined threshold (for example, 40 or lower). (Step S13). In this example, the case where the noise levels of two adjacent channels before and after the selected candidate channel are investigated will be described. However, the present invention is not limited to this.
[0070]
If it is determined that the channel exists, the candidate channel selected in step S12 is selected as a new frequency channel by performing the process corresponding to step S6, and the process proceeds to step S7.
[0071]
On the other hand, if it is determined that the channel does not exist, the process proceeds to step S14, and the frequency channel having the next lowest noise level is selected as a candidate channel from the frequency channels different from the frequency channel selected in step S12, and the process proceeds to step S13. To return.
[0072]
Next, in the operation of the illumination control system shown in FIG. 4, a processing procedure when the parameter value of each frequency channel is RSSI will be described with reference to FIG. In the example illustrated in FIG. 6, a case where a plurality of wireless communication terminals 4 are connected to the access point 3 will be described.
[0073]
When the parameter value of each frequency channel is RSSI, the RSSI for all frequency channels is obtained by performing the processing corresponding to the above-described steps S2 to S4 by the access point 3 after step S1, and the investigation result Is acquired and stored by the survey processing unit 31 (step S21).
[0074]
At this time, the investigation processing unit 31 specifies that the RSSI is to be investigated as an investigation command, and outputs it to the access point 3. In response to this, the access point 3 issues an investigation command for examining the RSSI to each wireless communication terminal 4, and each wireless communication terminal 4 measures the RSSI of the received radio wave and returns it to the access point 3. Thereby, in the access point 3, RSSI about all the radio | wireless communication terminals 4 connected is acquired.
[0075]
In the next step S22, the determination processing unit 32 performs processing corresponding to the above-described step S5. That is, the determination processing unit 32 calculates the RSSI maximum value, minimum value, and average value for each frequency channel from the RSSI survey results of all the wireless communication terminals 4 acquired in step S21. Then, the determination processing unit 32 selects a frequency channel having the highest RSSI average value among the RSSIs of frequency channels (for example, 1, 6, 11, and 14ch) that can be preset candidate channels, and sets them as candidate channels. That is, a frequency channel having a high RSSI for all the wireless communication terminals 4 is set as a candidate channel.
[0076]
In the next step S23 to step S25, processing corresponding to the above-described step S6 is performed. That is, in step S23, the determination processing unit 32 determines whether or not the average RSSI values for two channels adjacent to the candidate channel selected in step S22 are all equal to or greater than a predetermined threshold (for example, 90). (Step S23). Here, when frequency channel “6” is selected as a candidate channel, frequency channels “4”, “5”, “7”, and “8” are set as adjacent channels. In this example, the case where the noise levels of two adjacent channels before and after the selected candidate channel are investigated will be described. However, the present invention is not limited to this.
[0077]
When it is determined that the RSSI average values of the adjacent channels are all equal to or greater than the predetermined threshold value, the candidate channel selected in step S22 is determined as a new frequency channel by performing the process corresponding to step S6, and the process proceeds to step S7. Proceed with the process.
[0078]
On the other hand, when it is determined that all the RSSI average values of the adjacent channels are not equal to or greater than the predetermined threshold value, the process proceeds to step S24, and among the frequency channels different from the frequency channel selected in step S22, the RSSI average value is next. Is selected as a candidate channel, and the process returns to step S23.
[0079]
Next, in the operation of the lighting control system shown in FIG. 4, a processing procedure when the parameter value of each frequency channel is set to the packet loss number (or packet loss rate) will be described with reference to FIG. In the example illustrated in FIG. 4, a case where a plurality of wireless communication terminals 4 are connected to the access point 3 will be described.
[0080]
When the parameter value of each frequency channel is the number of packet losses, the processing corresponding to the above-described steps S2 to S4 is performed by the access point 3 after step S1, so that all frequency channels of all the radio communication terminals 4 are obtained. And the investigation result is obtained and stored by the investigation processing unit 31 (step S31).
[0081]
At this time, the investigation processing unit 31 specifies that the number of packet losses is to be investigated as an investigation command and outputs it to the access point 3. In response to this, the access point 3 transmits a packet requesting a reply to all the wireless communication terminals 4 to the wireless communication terminal 4 as an investigation command, and determines whether there is a reply packet from all the wireless communication terminals 4 for the transmitted packet. 3 detects. At this time, the access point 3 transmits a predetermined number of packets to each wireless communication terminal 4, counts the number of replies within a predetermined period, and acquires the packet loss number. By performing such processing for each frequency channel for all wireless communication terminals 4, the result of examining the number of packet losses for all frequency channels is acquired.
[0082]
In the next step S32, the determination processing unit 32 performs processing corresponding to the above-described step S5. That is, from the investigation result of the packet loss number acquired in step S31 by the determination processing unit 32, the packet loss is the largest of the packet loss numbers of the frequency channels (1, 6, 11, 14ch) that can be preset candidate channels. Select a frequency channel with a small number as a candidate channel.
[0083]
In the next step S33 to step S35, processing corresponding to step S6 described above is performed. That is, in step S33, the determination processing unit 32 determines whether or not there is a frequency channel whose number of packet loss within two channels adjacent to the candidate channel selected in step S32 is equal to or less than a predetermined threshold (for example, 40). To do. In this example, a case is described in which the number of packet losses in two adjacent channels before and after the selected candidate channel is investigated, but the present invention is not limited to this.
[0084]
In step S33, the present invention is not limited to such processing, and whether or not the number of packet losses in the two adjacent channels adjacent to the candidate channel is twice the number of packet losses in the frequency channel set as the candidate channel. May be determined.
[0085]
When it is determined that there is a frequency channel with the number of packet losses equal to or less than the predetermined threshold, the candidate channel selected in step S32 is selected as a new frequency channel by performing the process corresponding to step S6, and the process proceeds to step S7. Proceed.
[0086]
On the other hand, when it is determined that there is no frequency channel having the number of packet losses equal to or smaller than the predetermined threshold, the process proceeds to step S34, and the next number of packet loss is the frequency channel different from the frequency channel selected in step S32. The few frequency channels are selected as candidate channels, and the process returns to step S33.
[0087]
“Effect of the first embodiment”
As described above in detail, according to the lighting control system according to the first embodiment, when the user permits the change of the frequency channel, the parameter value for each frequency channel is acquired and a new frequency channel is obtained. The frequency channel can be set while the dimming control data is being transmitted. That is, according to this lighting control system, for example, during a performance, after the user confirms the operating state of the lighting fixture 42 and determines that the frequency channel needs to be changed, the operation input unit 22 changes the frequency channel. It is possible to easily change the frequency channel to the optimal frequency channel without affecting the communication of dimming control data and inconvenience to the user, and to change the frequency channel during lighting control. It can be avoided.
[0088]
In addition, according to this lighting control system, frequency channels that can be candidate channels are set in advance so that frequency bands do not overlap, and the frequency channel is changed to an optimum frequency channel, so that all frequency channels are candidates. There is no need to perform a process for obtaining a channel, and the process for setting a new frequency channel can be reduced.
[0089]
Further, according to this lighting control system, the new frequency channel is determined by referring to the parameter of the frequency channel adjacent to the frequency channel that can be the candidate channel, so the parameter value of the frequency channel adjacent to the candidate channel is in the excellent range. After confirming this, a new frequency channel can be set. That is, according to this illumination control system, it is possible to avoid radio wave interference that occurs when the parameter value of the frequency channel that interferes with the selected candidate channel is not good.
[0090]
[Second Embodiment]
The present invention is applied to a lighting control system according to the first embodiment as shown in FIG. 8, for example. In this example, an illumination control system will be described that includes a plurality of illumination devices that illuminate a theater, for example, and performs dimming of each illumination device. In the following description, the same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0091]
“Configuration of Lighting Control System According to Second Embodiment”
As shown in FIG. 8, the illumination control system according to the second embodiment is different from the illumination control system according to the first embodiment in that a detection processing unit 51 is provided in the wireless channel setting unit 21.
[0092]
The detection processing unit 51 acquires, for example, the parameter value of the frequency channel currently used by the access point 3 every predetermined time, and detects whether or not the currently used frequency channel needs to be changed. Perform detection processing. At this time, the detection processing unit 51 issues a survey command to the access point 3 every predetermined period.
[0093]
In the second embodiment, the processing by the detection processing unit 51 is referred to as “detection processing”, the processing by the above-described investigation processing unit 31 is “main investigation processing”, and the processing by the above-described determination processing unit 32 is “main determination processing”. Call.
[0094]
The detection processing unit 51 outputs to the access point 3 an investigation command for investigating the parameter value of the frequency channel currently used by the access point 3. In response to this, the detection processing unit 51 acquires the parameter value of the frequency channel currently used from the access point 3 and stores it. Then, the detection processing unit 51 determines whether or not to change from the currently used frequency channel to the new frequency channel based on the stored parameter value. When it is determined that the detection processing unit 51 is to be changed, the information presenting unit 23 notifies the user to that effect, and prompts the user to change the frequency channel.
[0095]
In the illumination control system including such a detection processing unit 51, the operation input unit 22 is operated after the access point 3 notifies that the frequency channel currently used is changed to the new frequency channel, The above processing is started by the investigation processing unit 31, the determination processing unit 32, and the setting processing unit 33.
[0096]
“Operation of Lighting Control System According to Second Embodiment”
Next, an operation procedure of the illumination control system according to the first embodiment described above will be described with reference to FIG.
[0097]
The detection processing unit 51 starts the process of step S41 when, for example, a predetermined period has elapsed since the previous detection process or frequency channel change, and checks the parameter value for the frequency channel currently used by the access point 3. Therefore, the investigation command is output to the access point 3, and the process proceeds to step S42.
[0098]
In step S42, when the detection processing unit 51 inputs and saves the parameter value corresponding to the survey command output in step S41 as the survey result, the process proceeds to step S43.
[0099]
In step S43, the investigation result stored in step S42 is notified to the investigation processing unit 31, and it is determined whether or not the investigation processing unit 31 needs to change the frequency channel by comparing the parameter value with a predetermined threshold. The investigation result is received by the detection processing unit 51. The detection processing unit 51 proceeds to step S44 when the frequency channel needs to be changed according to the investigation result, presents that fact by the information presentation unit 23, and ends the processing when there is no need to change the frequency channel.
[0100]
After presenting that it is necessary to change from the current frequency channel in step S44, when the operation input unit 22 is operated by the user, the survey processing unit 31 starts the main survey process after step S2. By performing the processing from step S2 to step S8, the frequency channel used at the time of step S41 is changed to the new frequency channel.
[0101]
10 to 12 show flowcharts of the processing procedure of the detection process.
[0102]
When the frequency channel parameter value is RSSI, first, in step S51 corresponding to step S41, the detection processing unit 51 issues an investigation command for examining the RSSI of the frequency channel currently used to the access point 3. In response to this, the RSSI of the wireless communication terminal 4 is acquired by the access point 3 and output to the detection processing unit 51. In step S51, the access point 3 may be controlled so that the detection processing unit 51 repeats or investigates RSSI over a plurality of times.
[0103]
When the detection result is obtained by the detection processing unit 51, the investigation result is notified to the investigation processing unit 31 (step S52), and the investigation result from the investigation processing unit 31 is obtained and analyzed by the detection processing unit 51, so that RSSI is obtained. It is determined whether or not there is a wireless communication terminal 4 having a predetermined threshold value or less (step S53), and if it exists, it is determined that the frequency channel needs to be changed, and the information presenting unit 23 determines that. Notification is made (step S44).
[0104]
When the frequency channel parameter value is the packet loss number (packet loss rate), first, in step S61 corresponding to step S41, the number of packet loss of the frequency channel currently used by the access point 3 from the detection processing unit 51 is calculated. Issue a survey command to investigate. In response to this, the access point 3 transmits a packet requesting a reply to the wireless communication terminal 4, detects the number of packet losses, and outputs it to the detection processing unit 51.
[0105]
When the detection result is obtained by the detection processing unit 51, the investigation result is notified to the investigation processing unit 31 (step S62), and the investigation result from the investigation processing unit 31 is obtained and analyzed by the detection processing unit 51, thereby packet loss. It is determined whether or not the number exceeds a predetermined threshold (step S63), and if it exceeds, it is determined that it is necessary to change the frequency channel, and the information presenting unit 23 notifies that fact ( Step S44). At this time, the information presentation unit 23 performs an operation such as blinking an LED or the like.
[0106]
When the frequency channel parameter value is set to the noise level, first, in step S71 corresponding to step S41, the detection processing unit 51 issues an investigation command for investigating the noise level of the frequency channel currently used to the access point 3. . In response to this, an investigation command for measuring the noise level is issued from the access point 3 to all the wireless communication terminals 4, the noise level of the wireless communication terminal 4 is acquired and output to the detection processing unit 51.
[0107]
When the investigation result is acquired by the detection processing unit 51, the investigation result is notified to the investigation processing unit 31 (step S72), and the investigation result from the investigation processing unit 31 is acquired and analyzed by the detection processing unit 51, thereby obtaining a noise level. Is determined to exceed the predetermined threshold (step S73), and if it exceeds, it is determined that the frequency channel needs to be changed, and the information presenting unit 23 notifies the fact (step S73). S44).
[0108]
As described above, when the operation input unit 22 is operated by performing FIGS. 10 to 12, steps S2 to S4 are performed by the survey processing unit 31 as the main survey processing, and steps are performed by the determination processing unit 32 as the main determination processing. Steps S5 and S6 are performed, and the processing of step S7 is performed by the setting processing unit 33, so that a new frequency channel is set and operated in step S8.
[0109]
“Effects of Second Embodiment”
As described above in detail, according to the illumination control system according to the second embodiment, the result of the inspection process performed by the detection processing unit 51 is notified to the user, thereby notifying that the radio wave condition is not good. After the operation for changing the frequency channel is performed, a new frequency channel can be set by performing the main investigation process and the main determination process.
[0110]
Therefore, according to this lighting control system, since a certain amount of time is required for the process of changing the frequency channel of the access point 3, communication of the dimming control data may be interrupted, but the radio wave condition is automatically detected. And when it is determined that the communication can be interrupted by the user, it is possible to change to a new frequency channel by performing the main investigation process and the main determination process. Therefore, according to this lighting control system, since the change of the frequency channel is started only when the change of the frequency channel is notified and the user's permission is obtained, the setting of the frequency channel can be easily changed to the optimum frequency channel. Thus, it is possible to avoid changing the frequency channel during communication, and it is possible to further improve user convenience.
[0111]
The above-described embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and various modifications can be made depending on the design and the like as long as the technical idea according to the present invention is not deviated from this embodiment. Of course, it is possible to change.
[0112]
That is, in the above-described embodiment, the case where determination is made to change the frequency channel by the wireless channel setting device 2 provided separately from the lighting control device 1 has been described. However, in the access point 3 or the first protocol conversion unit 12 The function of the wireless channel setting device 2 may be provided, and the frequency channel may be changed according to the operation of the user who operates the lighting control device 1.
[0113]
In the above-described example, the parameter value of the frequency channel is set to RSSI, packet loss, and noise level that change in response to the occurrence of radio wave interference, but other parameters that change in proportion to radio wave interference may be used. Even with these parameters, the present invention can be applied.
[0114]
Further, by causing the computer to execute the above-described processing by causing the computer to execute the function of the wireless channel setting device 2 described above, the effects of the first embodiment and the second embodiment described above can be obtained. It can be demonstrated.
[0115]
【The invention's effect】
  According to the wireless channel setting device of the first aspect, the operation input means is operated by the user.RuThe frequency channel change permission is recognized, the parameter values for all frequency channels are checked, and a new frequency channel is selected. Therefore, it is determined that the user needs to change the frequency channel, and the user After allowing the channel change, the frequency channel can be changed. Therefore, according to this radio channel setting device, the change of the radio channel does not affect the communication and does not inconvenience the user. It is possible to avoid changing the frequency channel.Further, according to the wireless channel setting device of the first aspect, during the wireless communication, when the detection means detects that the frequency channel is changed, it is presented to the user, and then the investigation means according to the user's operation. Since the change permission of the frequency channel is recognized, it is possible to change to the new frequency channel by notifying that the radio wave condition is not good, for example.
[0117]
  Claim2To claims4According to the wireless channel setting device according to the present invention, as the parameter value, the number of packet losses or the number of packet retransmissions, the received electric field strength of the wireless communication terminal, and the noise level of the wireless communication terminal are investigated. The frequency channel can be changed using a parameter that changes in accordance with radio wave interference.
[0118]
  Claim5According to the wireless channel setting device according to the above, since the frequency channel is selected from a plurality of frequency channels whose frequency bands do not overlap with other frequency channels by the investigation means, there is no need to perform a process of selecting from all the frequency channels. The processing when setting a simple frequency channel can be reduced.
[0119]
  Claim6According to the radio channel setting device according to the above, since the selection is based on the parameter value of the frequency channel adjacent to the frequency channel, it is confirmed that the parameter value of the frequency channel adjacent to the candidate frequency channel is in the excellent range. Can set a new frequency channel.
[0120]
  Claim7According to the wireless channel setting method according to the present invention, after recognizing the change permission of the frequency channel by the user's operation, the parameter values for all the frequency channels are investigated, and the frequency channel is selected based on the investigated parameter values. Determines that the frequency channel needs to be changed, and after the user allows the frequency channel to be changed, the frequency channel can be changed.Further, according to the radio channel setting method according to claim 7, after presenting to the user that the change of the frequency channel has been detected, the change permission of the frequency channel is recognized according to the user's operation. It is possible to change to a new frequency channel by notifying that the state is not good.
[0122]
  Claim8According to the program according to claim 1, at least is executed by being read by a computer,7The effect similar to the effect which concerns on can be exhibited.
[0123]
  Claim9According to the wireless communication apparatus according to the present invention, the change of the frequency channel is recognized in response to the operation input means being operated, the parameter values of all frequency channels are checked, the frequency channel is selected, and the wireless communication means is Since the control is performed, it is possible to change the frequency channel after determining that the user needs to change the frequency channel and allowing the user to change the frequency channel.According to the wireless communication device of the ninth aspect, the change of the frequency channel is permitted by the investigation means in response to the operation input means being operated after presenting to the user when the change of the frequency channel is detected. For example, it can be notified that the radio wave condition is not good and can be changed to a new frequency channel.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a lighting control system according to a first embodiment of the present invention.
FIG. 2 is a diagram showing the bandwidth of each frequency channel set in the 2.4 GHz band.
FIG. 3 is a diagram illustrating an example of an RSSI value in each frequency channel.
FIG. 4 is a flowchart showing a processing procedure when a new frequency channel is set in the illumination control system according to the first embodiment of the present invention.
FIG. 5 is a flowchart showing a processing procedure of an investigation processing unit when a parameter value is a noise level.
FIG. 6 is a flowchart showing a processing procedure of the investigation processing unit when the parameter value is RSSI.
FIG. 7 is a flowchart showing the processing procedure of the investigation processing unit when the parameter value is packet loss.
FIG. 8 is a block diagram showing a configuration of a lighting control system according to a second embodiment of the present invention.
FIG. 9 is a flowchart showing a processing procedure when a new frequency channel is set in the illumination control system according to the second embodiment of the present invention.
FIG. 10 is a flowchart showing a procedure of detection processing by the detection processing unit when the parameter value is RSSI.
FIG. 11 is a flowchart showing a procedure of detection processing by the detection processing unit when the parameter value is packet loss.
FIG. 12 is a flowchart showing a procedure of detection processing by a detection processing unit when a parameter value is a noise level.
FIG. 13 is a block diagram for explaining a conventional infrastructure network.
FIG. 14 is a block diagram showing a configuration of a conventional lighting control system.
FIG. 15 is a block diagram showing a configuration in which a part of the conventional lighting control system is wireless.
[Explanation of symbols]
1 Lighting control device
2 Radio channel setting device
3 access points
4 wireless communication terminals
5 Lighting equipment
11 Light control table
12 First protocol converter
21 Radio channel setting section
22 Operation input section
23 Information presentation section
31 Survey Processing Department
32 Judgment processing part
33 Setting processing section
41 Second protocol converter
42 Lighting equipment
51 Detection processing unit

Claims (9)

A wireless channel setting device that sets a frequency channel used in a wireless LAN system that transmits and receives wireless data according to a direct spread spectrum method between a wireless communication device that is an access point of a wireless LAN system and a wireless communication terminal,
Operation input means operated by the user;
Recognizing means for recognizing permission to change the frequency channel in response to the operation input means being operated, and investigating parameter values relating to radio wave conditions for all frequency channels of wireless data;
A determination means for selecting a frequency channel based on the parameter value investigated by the investigation means;
Setting means for controlling the wireless communication device to communicate on the frequency channel selected by the determination means ;
During the wireless communication between the wireless communication device and the wireless terminal device, the parameter value of the frequency channel being used is investigated, it is determined whether to change the frequency channel based on the investigated parameter value, and the frequency Detecting means for presenting to the user when it is detected that the channel is changed,
A wireless communication system that recognizes the change permission of the frequency channel by the investigating means in response to the operation input means being operated by detecting that the detecting means changes the frequency channel and presenting it to the user. Channel setting device. 2. The wireless channel setting according to claim 1 , wherein as the parameter value, the number of packet loss or the number of packet retransmissions is investigated according to presence / absence of a reply packet with respect to a packet transmitted from the wireless communication apparatus to the wireless communication terminal. apparatus. 2. The radio channel setting device according to claim 1 , wherein the received electric field strength of the radio communication terminal is examined as the parameter value. The radio channel setting device according to claim 1 , wherein a noise level of the radio communication terminal is examined as the parameter value.   2. The radio channel setting device according to claim 1, wherein the checking means selects a frequency channel from a plurality of frequency channels whose frequency bands do not overlap with other frequency channels. The investigation means detects a frequency channel as a candidate to be selected based on the parameter values of a plurality of frequency channels whose frequency bands do not overlap with other frequency channels, and sets the parameter values of the frequency channels adjacent to the detected frequency channel. radio channel setting device according to claim 1 or claim 5, wherein the selecting based. When setting a frequency channel to be used when wireless data is transmitted and received according to a direct spread spectrum method between a wireless communication device and a wireless communication terminal, which are access points of a wireless LAN system ,
Recognize permission to change frequency channel by user operation,
Investigate parameter values related to radio wave conditions for all frequency channels of wireless data,
Select a frequency channel based on the investigated parameter values,
Set the frequency channel of the wireless communication device to communicate with the selected frequency channel ,
During the wireless communication between the wireless communication device and the wireless terminal device, investigate the parameter value of the frequency channel being used,
After determining whether to change the frequency channel based on the investigated parameter value and presenting to the user that it has detected changing the frequency channel,
A wireless channel setting method characterized by recognizing change permission of a frequency channel according to a user operation . At least on the computer
In setting the frequency channel to be used when transmitting wireless data according to the direct spread spectrum method with a wireless communication device and the wireless communication terminal which is an access point of a wireless LAN system,
Recognize permission to change frequency channel by user operation,
Investigate parameter values related to radio wave conditions for all frequency channels of wireless data,
Select a frequency channel based on the investigated parameter values,
Set the frequency channel of the wireless communication device to communicate with the selected frequency channel,
During the wireless communication between the wireless communication device and the wireless terminal device, investigate the parameter value of the frequency channel being used,
After determining whether to change the frequency channel based on the investigated parameter value and presenting to the user that it has detected changing the frequency channel,
Recognize permission to change frequency channel according to user operation
A computer-readable program that executes processing . A wireless communication device that is an access point of a wireless LAN system,
Wireless communication means for transmitting and receiving wireless data according to a direct spread spectrum method with a wireless communication terminal accessing the access point ;
Operation input means operated by the user;
Recognizing means for recognizing permission to change the frequency channel in response to the operation input means being operated, and investigating parameter values relating to radio wave conditions for all frequency channels of wireless data;
A determination means for selecting a frequency channel based on the parameter value investigated by the investigation means;
Changing means for controlling the wireless communication means to change the frequency channel so as to perform wireless communication on the frequency channel selected by the judging means ;
During the wireless communication with the wireless terminal device, investigate the parameter value of the frequency channel being used, determine whether to change the frequency channel based on the investigated parameter value, and change the frequency channel Detecting means for presenting to the user when detecting
A wireless communication system that recognizes the change permission of the frequency channel by the investigating means in response to the operation input means being operated by detecting that the detecting means changes the frequency channel and presenting it to the user. Communication device.

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