JP2010233237A - Access point, system, station and setting method of wireless lan - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a load on a user for wireless LAN setting. <P>SOLUTION: A printer transmits advertisement data on the basis of respective connecting methods while switching the connecting methods in order (c.f., "advertisement 11" to "advertisement 3j"). These advertisement data are received by an access point, to which a connecting method at a time point of transmitting the advertisement data (c.f., "advertisement 12") and the access point notifies the printer about it that wireless connection using the same connecting method as the received advertisement data is enabled, by redirecting request reminding data (c.f., "request remind"). Then, the printer that receives the reply sets the reported connecting method, namely, the same connecting method as a connecting method that has been set at the access point. Thus, the printer is set to the same connecting method as the access point and brought into a state where wireless connection is enabled between both. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a wireless LAN access point, a wireless LAN system, a wireless LAN station, and a wireless LAN setting method .

  Currently, so-called wireless LANs that realize wireless data communication between a plurality of wireless stations or between a wireless station and an external network are widely used.

  In wireless LAN networks, there are communication methods such as “infrastructure mode” in which each wireless station performs wireless communication via a relay station and “ad hoc mode” in which wireless stations directly communicate with each other. The communication system can be switched according to the application, but it is generally used in the “infrastructure mode”.

  In such an “infrastructure mode” network, a wireless station can access a wireless access point by performing various settings such as a connection method on the wireless station side. The above-mentioned “connection method” refers to, for example, a wireless LAN standard (for example, IEEE802.11b, -a, -g, etc.) adopted when performing wireless connection, and a frequency band used in these wireless LAN standards ( This is a wireless connection method defined by a so-called channel).

  Here, for various settings on the wireless station side, if the wireless station has a user interface with high operability such as a personal computer (hereinafter referred to as “PC”), the setting operation is performed by this user interface. It is easy to do.

  However, in a wireless station that does not have a user interface with higher operability than a PC such as a printer that provides services via a network, setting with this user interface is very troublesome and laborious. It is.

  For this reason, in some of these wireless stations, the communication method for both other wireless stations is switched to “ad-hoc mode”, and data related to settings is exchanged between the two wireless stations to indirectly Configuration (remote setup), or by connecting the PC directly with a cable and exchanging data related to the configuration with the PC, it can be configured indirectly from the PC side. Some are.

  However, in this case, it is necessary to move wireless stations whose communication methods have been switched to “ad hoc mode” to a position where wireless communication is possible, or to move a PC to a place where a cable can be laid. After all, remote setup is still a time-consuming task.

  In particular, when using a wireless station used in "Infrastructure Mode" for remote setup, it is necessary to switch the communication method from "Ad Hoc Mode" to "Infrastructure Mode" again after the remote setup is completed. It takes time and effort.

  As described above, a wireless station that does not have a user interface with higher operability than a PC, such as a printer that provides a service via a network, has a problem in that it takes time to perform various settings. It was.

  Therefore, in recent years, various techniques for reducing the labor of such work have been proposed. For example, add a function as a wireless access point (relay station) to a network device such as a printer that functions as a wireless station, establish an original wireless network with this function (relay function unit), and connect via this wireless network The function as a wireless access point is stopped after indirectly performing the necessary settings (remote setup) for connecting to other wireless networks from the other wireless station side using the wireless station function (terminal function unit) (See Patent Document 1).

With this technology, it is possible to reduce the labor required for work for performing various settings in a wireless station that does not have a user interface with high operability.
JP 2003-143156 A

  However, in the above-described technology, wireless stations whose communication methods are switched to “ad hoc mode” are moved to a position where wireless communication is possible, or a PC is moved to a place where a cable can be laid. Although it is possible to reduce the time and labor associated with the setting, the operation itself for setting must be performed.

  In order to construct a wireless LAN network, not only a setting related to a general LAN (wired LAN) but also a setting “connection method” unique to the wireless LAN is required. Since this setting requires various specialized knowledge, even users who have expertise in wired LANs often cannot easily make settings specific to wireless LANs, and even for users who are unfamiliar with LANs themselves. It can be said that the setting of the LAN is very difficult.

  As described above, the load on the user with respect to the setting of the wireless LAN is currently heavy, and this is considered to be one of the factors hindering the spread of the wireless LAN, and the load on the user with respect to the setting of the wireless LAN is reduced. There was a demand for technology.

  The present invention has been made on the basis of such a demand, and an object thereof is to reduce a load on a user with respect to setting of a wireless LAN.

The invention described in claim 1 for solving the above problem is a wireless LAN access point that functions as a relay station in a wireless LAN network, and stores a channel and an SSID to function as the relay station User, a data transmission / reception unit for transmitting / receiving data by wireless communication using a channel stored in the storage unit, and an SSID transmission instruction for transmitting the SSID stored in the storage unit to a wireless LAN station SSID transmission instruction reception means for receiving from the SSID transmission instruction received by the data transmission / reception means within a predetermined period after the SSID transmission instruction reception means has been received by the data transmission / reception means In this case, S stored in the storage means is stored in the data transmission / reception means. The second data including the ID, the SSID transmission control means for transmitting to the wireless LAN station said a first data source, with a, a wireless LAN access point, characterized in that.

  With an access point configured in this way,

  It is possible to greatly reduce the load on the user for setting the wireless LAN.

  When setting the connection method to the access point of the wireless station, if there are other access points besides this access point (for example, adjacent houses), it is set at the other access point The same connection method may be set regardless of the user's intention. However, it is possible to prevent an incorrect connection method from being set.

  It is also possible to prevent the access point from inadvertently setting the connection method in the wireless station. This indicates that the connection method in the wireless station can be set at an arbitrary timing of the access point.

  Hereinafter, as a best mode for carrying out the present invention, a wireless LAN system in which a plurality of network devices (hereinafter simply referred to as “devices”) are LAN-connected will be described as an example.

[First Embodiment]
As shown in FIG. 1, the wireless LAN system includes an access point 10, a network printer (hereinafter simply referred to as “printer”) 20, and the like.

  The access point 10 is a wireless access point that relays data communication between a device (or external network) connected via the cable 100 and a wireless station. The access point 10 is a CPU 11, ROM 12, RAM 13, network controller 14, wireless A LAN controller 15, an operation panel 16, a display panel 17 and the like are provided.

  The CPU 11 provided in the access point 10 controls the operation of the access point 10 as a whole by sending commands to each component while recording the processing result in the RAM 13 according to the processing procedure recorded in the ROM 12.

The ROM 12 stores an SSID (service set identifier or ESSID: extended SSID) used when the access point 10 itself communicates with a wireless station.
This is a readable / writable nonvolatile memory having storage areas for storing parameters indicating a wireless connection method (hereinafter referred to as “connection method”). The “connection method” means any one of the first to i-th wireless LAN standards (for example, three types of IEEE802.11a, IEEE802.11b, and IEEE802.11g), and this wireless LAN. It is defined by any one of a plurality of channels that can be used in the standard, and shows a method for realizing wireless connection with a wireless station as a wireless access point.

  The network controller 14 is an interface for realizing data communication with other devices (or an external network) such as the PC 30 connected via the cable 100.

  The wireless LAN controller 15 is an interface for realizing communication in accordance with the wireless LAN standard based on each parameter stored in the ROM 12, and is connected to the wireless station according to the connection method indicated by “parameter indicating connection method”. A communication function as a wireless access point is realized by establishing a connection.

  In the access point 10 configured as described above, after the “SSID” and the “parameter indicating the connection method” are stored in the ROM 12, the wireless station that has accessed according to the connection method described above using the same SSID as the SSID. Wireless communication is allowed.

The access point 10 exchanges data related to settings with other devices wirelessly or by wire, and when an indirect setting (remote setup) is performed from the other device side, the “SSID” The “parameter indicating the connection method” is generated and stored in the ROM 12. In the present embodiment, the “parameter indicating the connection method” is stored (set) in the ROM 12 through remote setup that indicates the connection method defined by the second channel in the first wireless LAN standard. To do.

  Next, the printer 20 is a device having a function as a wireless station, and includes a CPU 21, a ROM 22, a RAM 23, a wireless LAN controller 24, a PC interface unit (PC I / F) 25, an operation panel 26, a display panel 27, and a print. An engine 28 and the like are provided.

  The CPU 21 of the printer 20 controls the overall operation of the printer 20 by sending commands to each component while recording the processing results in the RAM 23 according to the processing procedure recorded in the ROM 22.

  The ROM 22 is a readable / writable nonvolatile memory having storage areas for storing an SSID used when the printer 20 communicates with a wireless access point as a wireless station, a parameter indicating a connection method, and the like.

  The wireless LAN controller 24 is an interface for realizing communication in accordance with the wireless LAN standard based on each parameter stored in the ROM 22 and is indicated by “parameter indicating connection method” as described above. A communication function as a wireless station is realized by establishing a wireless access point according to the connection method.

  Further, the PC interface unit 25 is an interface for connecting the printer 20 to another PC via a communication cable, thereby enabling data communication between the printer 20 and the PC.

In the printer 20 configured as described above, after “SSID” and “parameter indicating connection method” are stored in the ROM 22, data communication using the SSID can be performed through wireless connection according to this connection method. Become. In the printer 20, “SSID” and “parameter indicating connection method” are generated and stored (set) in the ROM 22 in connection method determination processing (FIG. 2) described later.
A connection method determination process performed by the printer 20 A connection method determination process executed by the CPU 21 of the printer 20 will be described below with reference to FIG. This connection method confirmation processing is received by the operation panel 16 for operations such as power-on, restart (reset), and initialization (returning the setting state of the printer 20 to the factory default and restarting). Be started when.

  First, it is checked whether or not the printer 20 is in a factory shipment state (s100). In this process, if the “parameter indicating the connection method” is not stored in the ROM 22, it is determined that the factory shipment state is set.

  In the process of s100, if the printer 20 is not in the factory-shipped state (s100: NO), the present connection method determination process is terminated. If the printer 20 is in the factory-shipped state (s100: YES), the variable M is initialized ( s110). In this process, the variable M is set to “1” (1 → M). Note that “m” described below indicates a value set in the variable M.

  Next, the variable N is initialized (s120). In this process, the variable N is set to “1” (1 → N). Note that “n” described below indicates the value set in the variable N.

Next, the method of wireless connection to the wireless access point (hereinafter referred to as “connection method”) is switched to the connection method using the n-th channel in the m-th wireless LAN standard (s130). In this process, a parameter for realizing the communication function by the connection method defined by the n-th channel in the m-th wireless LAN standard is stored in the storage area for “parameter indicating connection method” in the RAM 23, and the connection method is stored. Is controlled according to the stored contents of the RAM 23 to switch the connection method to the access point 10 by the wireless LAN controller 24. In this way, control is performed according to the stored contents of the RAM 23 until switching to control according to the stored contents of the ROM 22 in subsequent processing (processing of s301). If a parameter is already stored in the storage area for “parameter indicating connection method”, it is rewritten to a new parameter.

  Next, advertisement data for advertising (advertisement) the connection method switched in the process of s130 to the surroundings is generated and transmitted (s140). In this process, first, as the “advertisement data”, a subtype indicating that it is advertisement data is set in the header information, and a device name and a device ID (MAC address in this embodiment) for identifying the device are set. Frame data (management frame) stored in the data body (body) is generated. Then, the frame data is broadcast (transmitted with the destination as a broadcast address) by the connection method using the n-th channel in the m-th wireless LAN standard (see “advertisement 11 to advertisement 3j” in FIG. 3). From the access point 10 that has received the advertisement data, if the advertisement data (content indicated by) is already registered in the connection method instruction process (FIG. 4) described later, the request prompting data is returned. (Refer to “request prompt” in FIG. 3) If it is not already registered, the advertisement data is only registered and the request prompt data is not returned (see “advertisement 12” in FIG. 3). The “request prompt data” is frame data for prompting the access point 10 to request permission (association request) for wireless connection to the access point 10, and the access point 10 is wireless. The SSID used for data communication with the station is stored.

  Next, the timer count is started (s150). The timer that is started in this process is for checking whether the above-mentioned request prompting data is returned within the time limit.

  Next, it is checked whether or not a time-out (that is, time-out) has occurred for the transmission of the advertisement data (s160). In this process, if the count value of the timer that started counting in the process of s150 has reached a predetermined value (250 ms in the present embodiment), it is determined that a timeout has occurred.

  If no timeout has occurred in the process of s160 (s160: NO), it is checked whether or not the request prompt data has been received from the access point 10 side (s170). If not received (s170: NO), s160 Return to the process.

  Thereafter, the processing of s160 and s170 is repeated, and if the time-out for the advertisement data transmission is reached in the processing of s160 (s160: YES), the timer that started counting in the processing of s150 is stopped and reset (s180). Then, “1” is added to the variable N (n + 1 → N) (s190).

  Next, it is checked whether or not the transmission of advertisement data by all channels in the mth wireless LAN standard has been completed (s200). Since each wireless LAN standard defines the number of channels that can be used, the value n of the variable N is larger than the number of channels j that can be used in the m-th wireless LAN standard (n If <j), it is determined that the transmission of advertisement data by all channels has been completed.

  If the transmission of the advertisement data by all channels in the m-th wireless LAN standard has not been completed in this process of s200 (s200: NO), the process returns to s130. Thereafter, by repeating the processes from s130 to s200, the advertisement data is transmitted in order by each channel in the m-th wireless LAN standard (see “advertisement 11 to advertisement 1j” in FIG. 3).

  In this way, after the processing from s130 to s200 is repeated, if the transmission of the advertisement data by all channels in the m-th wireless LAN standard is completed in the processing of s200 (s200: YES), “1” is set to the variable M. Addition (m + 1 → M) is performed (s210).

  Next, it is checked whether or not the transmission of advertisement data according to all wireless LAN standards has been completed (s220). In this process, if the value m of the variable M is larger than the number i of wireless LAN standards that can be communicated by the wireless LAN controller 24 (i <m), the transmission of advertisement data according to all wireless LAN standards is completed. It is determined that

  If the transmission of advertisement data based on all wireless LAN standards has not been completed in the process of s220 (s220: NO), the process returns to s120.

  Thereafter, in the processing after s120, advertisement data is transmitted according to the next wireless LAN standard (see “advertisement 21 to advertisement 2j” in FIG. 3), and by repeating the processing from s120 to s220, all wireless LANs are transmitted. Transmission of advertisement data according to the standard is performed (see “advertisement 11 to advertisement ij” in FIG. 3).

  In this way, after the processing from s120 to s220 is repeated, if the transmission of the advertisement data according to all wireless LAN standards has been completed in the processing of s220 (s220: YES), the processing returns to s110.

  When the request prompt data is received in the process of s170 while the processes of s120 to s220 are repeatedly performed (s170: YES), the timer that started the count in the process of s150 is stopped and reset (s230), and then the request is made. The SSID specified by the reminder data is stored in the RAM 23 as the SSID used for data communication with the wireless access point (s240). After the SSID is stored in this process, the printer 20 is in a state in which data communication can be realized with a wireless access point (access point 10) that can establish communication using the same SSID as this SSID.

  Next, an association request for requesting permission for wireless connection is transmitted to the access point 10 (s250). The “association request” is frame data (management frame) for requesting permission of wireless connection to the access point 10, and in the process of s250, the SSID recorded in the RAM 23 in the process of s240 is stored. (See “association request” in FIG. 3). In this association request, the device ID (MAC address) of the printer 20 is set in the header information. The access point 10 that has received this association request transmits an association response that is frame data (management frame) for permitting wireless connection to the access point 10 (see “association response” in FIG. 3).

  Next, the timer count is started (s260). The timer started in this process is for checking whether or not the above-mentioned association response is returned within the time limit.

  Next, it is checked whether or not a timeout has occurred for transmission of the association request (s270). In this process, if the count value of the timer that started counting in the process of s260 has reached a predetermined value (250 ms in the present embodiment), it is determined that a time-out has occurred.

  If no timeout has occurred in the process of s270 (s270: NO), it is checked whether an association response has been received from the access point 10 side (s280). If not received (s280: NO), the process of s270 Return to processing.

  After this, the processing of s270 and s280 is repeated, and if the time-out occurs for the transmission of the association request in the processing of s270 (s270: YES), the timer that started counting in the processing of s260 is stopped and reset (s290) , S110 is returned to.

  On the other hand, if an association response is received in the process of s280 (s280: YES), the timer that started the count in the process of s260 is stopped and reset (s300), and then the “parameter indicating connection method” in the RAM 23 is processed in the process of s130. The parameters and the SSID stored in the storage area are stored (copied) in the ROM 22 and the connection method is controlled according to the stored contents of the ROM 22 (s301), and then the connection method determination process is terminated.

Thus, when the connection method confirmation process is completed, the switching of the connection method by the process of s130 is stopped. Thus, the connection method (m-th wireless LAN standard, n-th standard) at the time of the stop is stopped. Channel) is determined (determined) as a connection method to the wireless access point.
Connection Method Instruction Processing by Access Point 10 Hereinafter, a processing procedure of connection method instruction processing executed by the CPU 11 provided in the access point 10 will be described with reference to FIG. In this connection method instruction processing, an instruction operation (for example, pressing a specific button) for switching the operation mode of the access point 10 to the support mode that supports setting of the connection method in the wireless station is performed by the operation panel 26. Be started when. Note that this support mode is an operation mode only during the execution of the connection method instruction process, and the operation mode of the access point 10 is switched from the support mode to the normal mode at the end of the connection method instruction process. Will be.

  First, counting by a timer is started (s310). The timer that starts in this process is for checking whether or not the advertisement data is transmitted from the printer 20 within the time limit (the process of s140 in FIG. 2) after the above-described instruction operation is performed. . That is, the user starts the connection method instruction processing by the access point 10 and then starts the connection method determination processing (FIG. 2) described above by the printer 20, thereby connecting the printer 20 to the access point 10. The method is set (see “Instruction Operation” for the access point 10 and “Startup” for the printer 20 in FIG. 3).

  Next, it is checked whether or not a timeout has occurred with respect to the start of this connection method instruction process (s320). In this process, if the count value of the timer that started counting in the process of s310 has reached a predetermined value (15 s in the present embodiment), it is determined that a timeout has occurred.

If no timeout has occurred in the process of s320 (s320: NO), it is checked whether or not data has been received from the printer 20 (s330).
330: NO), the process returns to s320. If the access point 10 is not transmitted in accordance with the connection method in which the “connection method” described above is set for the access point 10 itself (indicated by the parameter stored in the ROM 12), normal data is obtained. In this processing of s330, data transmitted according to the connection method set for the access point 10 itself ("Ad 12" in FIG. 3 in this embodiment) is received. It is checking whether or not.

  On the other hand, if data is received from the printer 20 in the process of s330 (s330: YES), it is checked whether the received data is advertisement data (s340). This “advertisement data” is data transmitted by the printer 20 in the process of s140 in FIG.

  In the process of s340, if the received data is advertisement data (s340: YES), it is checked whether or not the advertisement data is already registered (s350). In this connection method instruction process, the device name indicated by the advertisement data is registered in the subsequent processes (see “registration” in FIG. 3). Therefore, in the process of s350, the device name indicated by the received advertisement data Is registered, it is determined that it is already registered. The advertisement data determined to be registered in the process of s350 is the advertisement data received for the second time after the start of this connection method instruction process (see “Advertisement 12” in FIG. 3). ).

  If the advertisement data is not already registered in the process of s350 (s350: NO), the device name and device ID indicated by the advertisement data are registered in the specific storage area in the RAM 13 (for example, Registered in the data table) (s360).

  On the other hand, if the advertisement data is already registered in the process of s350 (s350: YES), request prompting data for requesting transmission of the association request is returned to the printer 20 that is the transmission source of the advertisement data. (S370). In this processing, frame request data for requesting transmission of an association request, which is “request prompt data” in which “SSID” stored in the ROM 12 is stored, is transmitted to the printer 20 (in FIG. 3). (See “Request reminder”). The request prompt data is data that the printer 20 receives in the process of s170 in FIG. 2, and after receiving the request prompt data, the printer 20 transmits an association request instead of advertisement data (in FIG. 3). (See Association Request).

  In this way, after finishing the process of s360 or s370, it returns to the process of s320.

  If the received data is not advertisement data (s340: NO) in the process of s340 described above, it is checked whether the request is an association request (s380). This “association request” is data transmitted by the printer 20 in the process of s250 in FIG.

  In the process of s380, if the received data is an association request (s380: YES), an association response for permitting wireless connection to the access point 10 itself is returned to the printer 20 that is the transmission source of the association request. After (s400), the process returns to s320. The association response is data that the printer 20 receives in the process of s280 in FIG. 2 (see “association response” in FIG. 3). On the printer 20 side, the connection method at the time of receiving the association response is the access point. 10 is set as a connection method.

  Although detailed description is omitted, in the present embodiment, before the association request and response are exchanged, the request prompt data from the access point 10 is received by the printer 20 in the same manner as the normal wireless connection procedure. Then, an authentication request and a response are exchanged (see “Authentication Request to Authentication Response” in FIG. 3). However, since the data communication is not encrypted in the first embodiment, authentication requests and responses are exchanged by open authentication (that is, not encrypted).

  On the other hand, if the received data is not an association request in the process of s380 (s380: NO), the process based on the received data (other process) is performed (s410), and the process returns to the process of s320.

  Thus, after the processing from s320 to s410 is repeated, if the time-out occurs in the processing of s320 (s320: YES), the timer that started counting in the processing of s310 is stopped and reset (s420), and this connection method The instruction process is terminated. Thus, along with the end of the connection method instruction process, the operation mode of the access point 10 is switched again from the support mode to the normal mode.

[Effect of the first embodiment]
In the wireless LAN system configured as described above, the printer 20 transmits advertisement data based on each connection method while sequentially switching the connection methods (see “advertisement 11” to “advertisement 3j” in FIG. 3). . These advertisement data are received by the access point 10 set in the connection method at the time of transmission of the advertisement data (see “advertisement 12” in FIG. 3), and the access point 10 has the same connection as the received advertisement data. The printer 20 is notified by replying the request prompting data that the wireless connection by the method is possible (see “request prompting” in FIG. 3). Upon receiving this reply, the printer 20 sets the connection method notified by the request prompt, that is, the same connection method as the connection method set in the access point 10. Thus, the printer 20 is set to the same connection method as that of the access point 10, so that wireless connection can be established between the two.

  In this way, in the printer 20, the connection method to the access point 10 is automatically set through the switching of the connection method and the transmission of the advertisement data. Therefore, the load on the user with respect to the setting of the wireless LAN can be greatly reduced.

  Further, the printer 20 sequentially switches the connection method every predetermined time counted by the timer (processing of s110 to s220 in FIG. 3), and after receiving the request prompting data reply, the connection method. Stop switching. In this way, it is possible to set the same connection method as the connection method set in the access point 10 at the time of stopping by simply stopping the switching of the connection methods switched in order. it can.

  Further, by explicitly instructing from the outside by starting up the printer 20, setting of the connection method for the printer 20 (execution of connection method determination processing (FIG. 2)) can be performed.

  In addition, when a connection method is set in the printer 20, an association request and response are exchanged between the printer 20 and the access point 10, so that a wireless connection between the two can be realized immediately.

In the connection method instruction process (FIG. 4), the access point 10 returns the request prompt data to the wireless station (printer 20) that has repeatedly transmitted the advertisement data by the same connection method, and sets the connection method. (Refer to “Requesting Request” in FIG. 3).

  In addition, after the operation mode of the access point 10 is switched to the support mode, the mode is switched back to the normal mode when the connection method instruction process (FIG. 4) ends after a predetermined period has elapsed. Therefore, the operation mode can be automatically switched back to the normal mode without performing an operation to switch back to the normal mode from the state switched to the support mode. Therefore, it is possible to prevent the access point 10 from remaining in the support mode from inadvertently setting the connection method in the wireless station.

  Further, the printer 20 can set the connection method to the access point 10 only when the printer 20 is in the factory-shipped state (the process of s100 in FIG. 2).

  Further, the access point 10 collects (registers) the advertisement data in the process of s340 to s360 in FIG. 4, and then transmits the advertisement data transmitted based on the same connection method as the advertisement data thus collected to the wireless station. Is received, the prompt request data is returned to the wireless station (processing of s370). Therefore, the access point 10 can transmit the request prompting data at a timing when the wireless station transmits the advertisement data, that is, at a timing when data transmission / reception is enabled on the wireless station side. Thereby, the request prompt data transmitted from the access point 10 can be reliably received on the wireless station side.

[Configuration that can be modified with respect to the first embodiment]
In the first embodiment, as shown below, a part of the configuration can be changed to another configuration. In addition, the structure shown below is applicable also to the same structure in other embodiment.

  For example, in the process of s100 in FIG. 3, when the printer 20 is in the factory shipment state, the process configured to perform the process after s110 is illustrated. However, even in a state other than the factory-shipped state, if it is necessary to set a connection method, the processing after s110 may be performed. Specifically, this is the case where some of the “parameters indicating connection methods” stored in the ROM 12 are insufficient.

  Moreover, in this embodiment, after exchanging an authentication request | requirement and a response, what was comprised so that an association request | requirement and a response might be exchanged was illustrated. However, it is also possible to configure to exchange only the association request and response without exchanging the authentication request and response.

  In this embodiment, the access point 10 can receive data only by a connection method set in advance, and when the advertisement data is received, the connection method advertised by the advertisement data is transmitted to the access point 10 itself. The specified connection method is specified. Therefore, the “advertisement data” transmitted by the printer 20 does not include the parameter itself indicating the connection method. However, such parameters themselves may be stored in the advertisement data.

  Further, in the present embodiment, an example in which the setting of the connection method for the printer 20 is instructed by the activation of the printer 20 is illustrated. However, the setting of the connection method for the printer 20 may be configured to be instructed by a specific operation using the operation panel 26 (see “command” in FIG. 3). Further, the printer 20 may be configured to be instructed by data from another communication terminal connected so as to be able to perform data communication.

  Moreover, in this embodiment, what was comprised so that the operation mode of the access point 10 might be switched by designation | designated operation was illustrated. However, the switching of the operation mode may be configured to be instructed by data from another communication terminal connected to the access point 10 so as to be able to perform data communication.

  In the present embodiment, the access point 10 is configured to repeatedly return the request prompting data until a timeout occurs in the connection method instruction process (to return to the process from s370 to s320). However, after the request prompting data is returned, the connection method instruction process may be terminated (specifically, the process proceeds to the process of s420). In this case, even within the predetermined period after the operation mode is switched to the support mode, when the request prompting data is returned once, it can be switched back to the normal mode. In other words, connection method setting can be supported only for the same number of wireless stations as the number of transmissions of the request prompt data “1”. In this configuration, when the request prompting data is returned, the number of replies may be counted, and the process may proceed to s420 only when the predetermined number of times is reached. In this case, as soon as the advertisement data is received from one wireless station, the request prompting data is returned and then the mode is switched back to the normal mode, and the advertisement data may not be registered.

  In the above-described embodiment, when the connection method determination process starts, the printer 20 performs a process after s110 after checking whether it is in a factory-shipped state (see the process of s100 in FIG. 2). Although it is configured as described above, the check as to whether or not it is in the factory-shipped state may not be performed immediately after the connection method determination process is started. For example, it may be between the process of s240 and the process of s250.

  Further, in the above-described embodiment, an example in which dedicated frame data is adopted as “advertisement data” and “request prompting data” is illustrated. However, as the “advertisement data” and “request prompting data”, well-known data defined in the wireless LAN standard may be adopted. Here, as data to be adopted, for example, a probe request and a response can be considered. However, when the probe request and response are employed in this way, the printer 20 wirelessly connects indiscriminately in response to probe responses from other wireless access points except the access point 10, and It may be difficult to realize a wireless connection. This is not desirable from the viewpoint of ensuring network security. Accordingly, when the access point 10 receives a probe request transmitted as “advertisement data”, a probe response including a parameter explicitly indicating that the printer 20 is to be set is transmitted as “request prompting data”. In addition, the printer 20 is preferably configured to perform the setting only when a probe response including a parameter explicitly indicating that the setting is to be performed is received as “request prompting data”.

[Second Embodiment]
The wireless LAN system according to the present embodiment has the same configuration as the wireless LAN system according to the first embodiment, and only part of the processing contents in the access point 10 is different. Therefore, only this difference will be described in detail. .
Connection Method Instruction Processing by Access Point 10 Hereinafter, a processing procedure of connection method instruction processing executed by the CPU 11 provided in the access point 10 will be described with reference to FIG. This connection method instruction process is performed according to the following procedure from the connection method instruction process (FIG. 4) according to the first embodiment. The same processes as those in the first embodiment are denoted by the same step numbers, and detailed description thereof is omitted.

  First, if the advertisement data is not already registered in the process of s350 (s350: NO), the parameter indicated by this advertisement data is registered by storing it in a specific storage area in the RAM 13 (for example, in the data table). Registration) (s352). This process is the same process as the process of s360 in FIG. 4, but is associated with not only the device name and device ID but also the reception level (radio wave intensity) when the advertisement data is received in the process of s330. It is registered with. An example of a data table in which parameters indicated by the request prompting data are registered is shown in FIG.

  After the process of s352 is completed or if the advertisement data has already been registered in the process of s350 (s350: YES), the process returns to the process of s320.

  When the process of s340 is performed, the request prompting data is not transmitted and the association request is not transmitted. Therefore, when the data received in the process of s340 is not advertisement data (s340: NO) After performing “other processing” (s410), the process returns to s320.

  Thereafter, after the processing of s320 to s410 is repeated, if the time-out occurs in the processing of s320 (s320: YES), the timer that started counting in the processing of s310 is stopped and reset (s420).

  Next, it is checked whether or not parameters have been registered through the process of s352 (s510). In this process, if the data by the process of s352 is stored in a specific storage area in the RAM 13, it is determined that the parameter has been registered by the process of s352.

  If the parameter is not registered in the process of s510 (s510: NO), the present connection method instruction process is terminated. If the parameter is registered (s510: YES), the timer is started. (S520). The timer that is started in this process is for checking whether or not the advertisement data is transmitted again from the printer 20 within the time limit after registration of the advertisement data.

  Next, it is checked whether or not the advertisement data registration has timed out (s530). In this process, if the count value of the timer that started counting in the process of s520 has reached a predetermined value (15 s in the present embodiment), it is determined that a timeout has occurred.

  If no timeout has occurred in the process of s530 (s530: NO), it is checked whether data has been received from the printer 20 (s540). If not received (s540: NO), the process proceeds to s530. Return.

  On the other hand, if data is received from the printer 20 side in the process of s540 (s540: YES), it is checked whether or not the received data is advertisement data (s550). This process is the same as the process of s340 in FIG.

  In the process of s550, if the received data is advertisement data (s550: YES), it is checked whether or not the advertisement data is already registered (s560). This process is the same as the process of s350 in FIG.

  If the received advertisement data is not already registered in the process of s560 (s560: NO), the process returns to the process of s530.

  On the other hand, if the received advertisement data is already registered in the process of s560 (s560: YES), the reception level in the parameter registered for this advertisement data is the maximum reception level among all parameters. It is checked whether or not (s570).

  In this process, if it is not the maximum reception level (s570: NO), the process returns to the process of s530. On the other hand, if it is the maximum reception level (s570: YES), the request prompt data is returned (s370). Return to processing.

  If the received data is not advertisement data (s550: NO) in the process of s550 described above, it is checked whether the request is an association request (s380).

  In the process of s380, if the received data is an association request (s380: YES), an association response for permitting wireless connection to the access point 10 itself is returned to the printer 20 that is the transmission source of the association request. After (s400), the process returns to s530.

  On the other hand, if the received data is not an association request in the process of s380 (s380: NO), the process based on the received data (other processes) is performed (s580) and the process of s530 is performed as in the process of s410. Return to processing.

  In this way, after the processing after s530 is repeated, if the time-out occurs in the processing of s530 (s530: YES), the timer that started counting in the processing of s520 is stopped and reset (s590), and this connection method instruction The process ends.

[Effects of Second Embodiment]
In the wireless LAN system configured as described above, the following operations and effects can be obtained in addition to the operations and effects obtained by the same configuration as the first embodiment.

  The access point 10 can return the request prompt data to the wireless station that has transmitted the advertisement data having the highest reception level, and set the connection method (processing of s570 and s370 in FIG. 5).

[Configuration that can be modified with respect to the second embodiment]
In the second embodiment, as shown below, a part of the configuration may be changed to another configuration. In addition, the structure shown below is applicable also to the same structure in other embodiment.

  For example, in the process of s570, an example is shown in which it is configured to check whether or not the reception level in the parameter registered for the received advertisement data is the maximum reception level among all the parameters. However, in the process of s570, it may be configured to check whether the device ID in the parameter registered for the received advertisement data matches the device ID at the time of receiving the advertisement data in the process of s540. Good. In this case, even if the access point 10 receives the same advertisement data as the registered advertisement data, the device ID specified by the advertisement data must match the device ID when the advertisement data is registered first. For example, the connection method is not set without transmitting the request prompting data. As a result, it is possible to prevent a wireless station attempting to make a wireless connection to the access point 10 by impersonating and transmitting the advertisement data registered on the access point 10 side from being wirelessly connected to the access point 10.

[Third Embodiment]
The wireless LAN system of the present embodiment has the same configuration as that of the wireless LAN system of the second embodiment, and only part of the processing contents in the access point 10 is different. Therefore, only this difference will be described in detail. .
Connection Method Instruction Processing by Access Point 10 Hereinafter, a processing procedure of connection method instruction processing executed by the CPU 11 provided in the access point 10 will be described with reference to FIG. In this connection method instruction process, in the connection method instruction process (FIG. 5) in the second embodiment, after the process of s510 is performed, the processes of s512 and s514 described later are performed, and instead of the process of s570. Therefore, only s562 will be described in detail.

  First, if the parameter is registered in the process of s510 (s510: YES), the user is notified of each device name indicated by the parameter registered for each advertisement data (s512). In this process, notification is performed by causing the display panel 17 to display a list of device names indicated by the registered parameters. After the list is displayed on the display panel 17, the user can perform a selection operation for selecting one or more device names from the list using the operation panel 16.

  Next, it waits until selection operation is performed by the user (s514: NO).

  If a selection operation is performed in the process of s514 (s514: YES), the process proceeds to the process of s520. At this time, for the parameter indicating the device name selected by the selection operation, a selection flag indicating that the device name has been selected by the selection operation is set (a state in which “1” is set from the initial value “0”) And).

  If the received advertisement data is already registered in the process of s560 (s560: YES), the parameter registered for the advertisement data is set with the selection flag instead of the process of s570. It is checked whether or not there is (s562).

  If the selection flag is set in this process of s562 (s562: YES), the process proceeds to the process of s370. If the selection flag is not set (s562: NO), the process proceeds to s530. Return.

[Effect of the third embodiment]
In the wireless LAN system configured as described above, the following operations and effects can be obtained in addition to the operations and effects obtained by the same configuration as the second embodiment.

  The access point 10 can return the request prompt data only to the wireless station (for example, the printer 20) having the device name arbitrarily selected by the user and set the connection method (s512, s514, s562 in FIG. 7). Refer to the process.)

[Configuration that can be modified with respect to the third embodiment]
In the third embodiment, as shown below, a part of the configuration may be changed to another configuration. In addition, the structure shown below is applicable also to the same structure in other embodiment.

  For example, in the processing of s512 and s514 in FIG. 7, the configuration configured to allow the user to perform a selection operation based on the device name is illustrated. However, in these processes, the selection operation may be performed based on the device ID instead of the device name. In this case, only the wireless station having the device ID arbitrarily selected by the user can return the request prompting data and set the connection method.

[Fourth Embodiment]
The wireless LAN system of this embodiment has the same configuration as the wireless LAN system of the third embodiment. In the third embodiment, device name notification and selection operations (s512 and s514 in FIG. 7) performed by the access point 10 are performed. This processing is configured to be performed on the side of a well-known personal computer (hereinafter referred to as “PC”) 30 connected to the access point 10 via the cable 100 so that data communication is possible.
Connection Method Instruction Processing by Access Point 10 Hereinafter, a processing procedure of connection method instruction processing executed by the CPU 11 provided in the access point 10 will be described with reference to FIG. This connection method instruction process is configured such that, in the connection method instruction process (FIG. 7) in the third embodiment, the processes of s516 and s518 described later are performed instead of the processes of s512 and s514. Only these processes will be described in detail. This connection method instruction process is started after receiving start command data from the PC 30 (see “start command” in FIG. 9).

  First, if parameters are registered in the process of s510 (s510: YES), list data indicating a list of device names indicated by the registered parameters is generated and the PC 30 (source of the above start command data) is generated. (S516). In the PC 30 that has received this list data (see “List Data” in FIG. 9), the list indicated by the list data is displayed on the display, so that each device name is notified. When a selection operation for selecting one or more device names from the device names is performed, selection data capable of specifying the selected device name is transmitted (see “Selection Data” in FIG. 9).

After the list data is transmitted in the process of s516, the process waits until selection data is received from the PC 30 side (s518: NO). When the selection data is received (s518: YES), the process proceeds to s520. In the process of s370 performed thereafter, based on the selection data received in the process of s518, based on the parameters (SSID and connection method) corresponding to the device name specified by the selection data, a request for prompting is made to the wireless station. Send data.
Setting Command Processing by PC 30 Hereinafter, a processing procedure of setting command processing executed by the PC 30 will be described with reference to FIG. This setting command process is a process executed in accordance with a program incorporated in the PC 30.

  First, start command data is transmitted to the access point 10 (s610). The access point 10 that has received this start command data starts the above-described connection method instruction processing (FIG. 8) (see “start command” in FIG. 9), and transmits the above-described list data after a predetermined time has elapsed. Come.

  Next, it waits until list data is received from the access point 10 (s620: NO).

  When the list data is received in the process of s620 (s620: YES), the contents indicated by the list data are displayed on the display (s630). After the list of device names indicated by the list data is displayed in this way (see FIG. 11), the user can perform a selection operation for selecting one or more device names with a keyboard or a mouse.

And it waits until selection operation is performed (s640: NO), and if selection operation is performed (s640: YES), the selection data which can specify the device name selected by this selection operation will be produced | generated, and the access point 10 will be generated. (S650).

[Effect of Fourth Embodiment]
In the wireless LAN system configured as described above, the following operations and effects can be obtained in addition to the operations and effects obtained by the same configuration as that of the third embodiment.

  The access point 10 prompts only the device name indicated by the selection data received from the PC 30 among the registered device names, that is, the wireless station (for example, the printer 20) of the device name arbitrarily selected by the user in the PC 30. Data can be transmitted to set the connection method (see the processing of s516, s518, and s562 in FIG. 8).

[Configuration that can be modified with respect to the fourth embodiment]
In this 4th Embodiment, as shown below, it can also implement in the state which changed a part structure into another structure. In addition, the structure shown below is applicable also to the same structure in other embodiment.

  For example, in the processing of s516 and s518 in FIG. 8, an example is shown that is configured to generate list data indicating a list of device names. However, in these processes, the list data indicating the list of device IDs is generated and transmitted in the process of s516, so that the selection operation is performed based on the device ID instead of the device name. May be. In this case, only the wireless station having the device ID arbitrarily selected by the user on the PC 30 side can return the request prompting data and set the connection method.

  In the present embodiment, the access point 10 is configured to transmit the list data generated based on the parameter after the parameter is registered (collected) for a predetermined time. However, the list data may be generated and transmitted at a timing when a transmission request is received from the PC 30 side (see “list request” in FIG. 9). For this purpose, for example, a step of waiting for an operation for requesting list data (s612) between the processing of s610 and s620 in FIG. 10, and the transmission of the list data is requested in response to this operation. Step (s614) is provided (see FIG. 12), and a step (s515) for waiting for a request from the PC 30 side is provided between the processes of s510 and s516 in FIG. 8 (see FIG. 13). do it. Further, in this configuration, as described above, the selection operation may be performed based on the device ID instead of the device name.

  In the present embodiment, after the access point 10 transmits the request prompt data to the wireless station (printer 20), the PC 30 side is notified that the connection method is set (or set) on the wireless station side. You may comprise as follows. For this purpose, for example, after the processing of s400 in FIG. 8, a step (s402) of transmitting setting notification data for notifying that the setting has been made to the PC 30 is provided (see FIG. 13), and s650 in FIG. 10 is provided. Step (s652) of waiting for the transmission of the setting notification data after the process of step (s652) and a step (s654) of notifying that the connection method is set on the wireless station side when the setting notification data is received are provided. (See FIG. 12).

[Fifth Embodiment]
In each of the embodiments described above, even if the printer 20 is wirelessly connected to the access point 10, if the access point 10 is set to perform data communication encryption, the printer 20 side is usually the same. Unless data is encrypted and set to perform data communication, data communication cannot be performed normally. Therefore, the wireless LAN system according to the present embodiment is configured such that the wireless LAN system according to the fifth embodiment can perform data communication normally without being operated by the user.

  First, if a “security parameter” is stored in the ROM 12, the access point 10 communicates with a security measure based on this parameter. Here, as the “security parameter”, for example, there is an encryption key (in this embodiment, WEP key; Wired Equivalent Privacy) for performing communication in an encrypted state. If the encryption key is stored, the access point 10 (CPU 11) performs communication with the wireless station in a state encrypted with the encryption key. The encryption key is generated through remote setup and stored in the ROM 12 as described above.

Further, if “parameters related to security” are stored in the ROM 22, the printer 20 communicates with security measures based on these parameters. Here, the “security parameter” includes an encryption key as described above. If the encryption key is stored, the printer 20 (CPU 21) performs communication with the wireless access point in a state encrypted with the encryption key.
Connection Method Instruction Processing by Access Point 10 Hereinafter, a processing procedure of connection method instruction processing executed by the CPU 11 provided in the access point 10 will be described with reference to FIG. This connection method instruction process includes a process of s372 described later after the process of s370 in the connection method instruction process (FIG. 8) in the fourth embodiment, and the processes of s592, s594, and s596 after the process of s590. Therefore, only these processes will be described in detail.

  First, in the present embodiment, in the process of s370, an encryption key different from the normal encryption key stored in the ROM 12 (hereinafter referred to as “temporary encryption key”) is randomly generated, and this temporary encryption key is added. Send in state.

  After transmitting the requested reminding data in the process of s370, before returning to the process of s530, the temporary encryption key in which the device name and device ID of the wireless station that transmitted the requested reminding data are added to the requested prompting data in the process of s370. Is registered in the reminder list in a state associated with (s372). This “reminder list” is a data table in which data is registered after being generated in the RAM 13.

  In addition, after completing the process of s590, the process waits until the wireless connection with any of the wireless stations registered in the prompt list in the process of s372 is released (s592: NO), and when the wireless connection is released (s592). : YES), the registered content for the wireless station whose wireless connection has been canceled is deleted from the prompt list (s594).

After the process of s594 is completed, it is checked whether or not the registered content remains in the prompt list (s596). If it remains (s596: YES), the process returns to s592. And it repeats until there is no registered content in the reminder list, and if no registered content remains in the process of s596 (s596: NO), this connection method instruction process is terminated.
A connection method determination process performed by the printer 20 A connection method determination process executed by the CPU 21 of the printer 20 will be described below with reference to FIG. This connection method determination process is configured such that the following process is performed after the process of s301 in the connection method determination process (FIG. 5) in the other embodiment. Note that the same steps as those of the other embodiments are denoted by the same step numbers, and detailed description thereof is omitted.

  First, after the request prompt data is received in the process of s170, the SSID specified by the request prompt data is stored in the ROM 22 in the process of s174, and the temporary encryption key is stored in the storage area for “security parameters” in the RAM 23. Remember me. Thereafter, by switching the connection method in the process of s224, data communication with the wireless access point (access point 10) is performed in the state encrypted with the temporary encryption key stored in the storage area for “security parameters”. .

  In addition, after completing the processing of s301, the encryption key of the access point 10 is acquired (s700). This process is a process for obtaining the encryption key of the access point 10 from the PC 30 by the public key encryption method (see “Encryption key (encryption with random number)” in FIG. 16), and the detailed processing procedure will be described later. This will be described in the encryption key acquisition process (FIG. 17).

  If the encryption key has been acquired in the process of s700 (s302: YES), this encryption key is stored in the ROM 22 (s304). In this processing, the temporary encryption key is deleted from the RAM 23 as well as the encryption key is stored in the ROM 22.

  Next, the wireless connection with the access point 10 is canceled (s306). Here, the wireless connection with the access point 10 is canceled by transmitting the authentication cancellation to the access point 10 (see “authentication cancellation” in FIG. 16).

  Then, the wireless connection with the access point 10 is established again (s308). In this process, as described above, the wireless connection is established by exchanging the authentication request and response with the access point 10. After the wireless connection is established by this process, data communication is performed in the state encrypted by the encryption key stored in the process of s304.

In this way, after completing the process of s308, or if the encryption key has not been acquired in the process of s302 (s302: NO), this connection method determination process is terminated.
O Encryption Key Acquisition Processing by Printer 20 Hereinafter, a processing procedure of encryption key acquisition processing executed by the CPU 21 provided in the printer 20 will be described with reference to FIG. This encryption key acquisition process is a detailed processing procedure of the process of s700 in FIG.

  First, a public key / private key pair used in the public key cryptosystem is generated (s710).

  Next, the public key generated in the process of s710 is transmitted to the PC 30 (s720). In this process, public key data is transmitted to the PC 30 which is a preset device. Upon receiving this public key, the PC 30 returns a random number randomly generated with this public key and returns it, and then transmits print data indicating a predetermined message image encrypted with this random number.

  Next, the encrypted random number is received from the PC 30 (s730).

  Next, the encrypted print data is received from the PC 30 (s740).

Next, the message image indicated by the print data received in the process of s740 is decrypted with the secret key generated in the process of s710, and then printed by the print engine 28 (s750). The message image printed in this process includes a message for allowing the user to confirm that the random number received in the process of s730 is surely transmitted to the printer 20.
The user who has confirmed this will perform a confirmation operation, which will be described later, using the PC 30 (see a setting command process (FIG. 18) described later). After this confirmation operation, the encryption key encrypted by the process of s730 is transmitted from the PC 30.

  Next, a timer is started (s760).

  Next, it is checked whether an encryption key has been received from the PC 30 (s770).

  When the encryption key is received in the process of s770 (s770: YES), the timer started in the process of s760 is stopped and reset (s780), and then the encryption key acquisition process is terminated.

  On the other hand, if an encryption key has not been received in the process of s770 (s770: NO), it is checked whether or not a timeout has occurred (s790). In this process, if the count value of the timer started in the process of s760 has reached a predetermined value (30 s in this embodiment), it is determined that a timeout has occurred.

If no timeout has occurred in the process of s790 (s790: NO), the process returns to the process of s770. If the timeout has occurred (s790: YES), the process proceeds to the process of s780 to obtain an encryption key. The encryption key acquisition process is terminated without any processing.
Setting Command Processing by PC 30 Hereinafter, a processing procedure of setting command processing executed by the PC 30 will be described with reference to FIG. This setting command process is a process executed in accordance with a program incorporated in the PC 30. This setting command process is configured such that the following process is performed after the process of s650 in the setting command process (FIG. 10) in the other embodiment. The same processes as those in the fifth embodiment are denoted by the same step numbers, and detailed description thereof is omitted.

  First, after the process of s650 is performed, the process waits until a public key is received from the printer 20 (s810: NO). This public key is data transmitted by the printer 20 in the process of s720 in FIG.

  When the public key is received in the process of s810 (s810: YES), a random number randomly generated with this public key is encrypted and returned (s820). This encrypted random number is data received by the printer 20 in the process of s730 in FIG.

  Next, the print data indicating the message image is encrypted and transmitted using the public key received in the process of s810 (s830). This encrypted print data is data received by the printer 20 in the process of s740 in FIG. In the printer 20 that has received the print data, the message image is printed as described above. After the message image is printed, the user performs a confirmation operation on the PC 30. The confirmation operation is an operation such as pressing a specific key or button or pressing a plurality of buttons or keys in a specific procedure.

  Next, it waits until confirmation operation is performed (s840: NO).

  If a confirmation operation is performed in the process of s840 (s840: YES), the encryption key is encrypted with the random number generated in the process of s820 and transmitted (s850). This encrypted encryption key is data received by the printer 20 in the process of s770 in FIG. The encryption key is stored in advance in a memory or the like.

In this way, after finishing the process of s850, this setting command process is complete | finished.
○ Cryptographic switching process by the access point 10 The access point 10 is configured to perform a cryptographic switching process when it is time to perform data communication (data transmission / reception) with a wireless station after being activated. Hereinafter, the processing procedure of the encryption switching processing will be described with reference to FIG.

  First, it is checked whether or not the wireless station to which data communication is to be performed is a wireless station having a device name or device ID registered in the prompting table in the RAM 12 (s910).

  In the process of s910, if the wireless station has a device name or device ID registered in the reminder table (s910: YES), data communication is performed in a state encrypted with a temporary encryption key corresponding to the device name or device ID. (S920).

  On the other hand, if it is not a wireless station with the device name or device ID registered in the prompting table in the processing of s910 (s910: NO), normal data communication encrypted with the encryption key is performed (s930).

  In this way, after finishing the process of s920 or s930, this encryption switch process is complete | finished.

[Effect of Fifth Embodiment]
In the wireless LAN system configured as described above, the following operations and effects can be obtained in addition to the operations and effects obtained by the configuration similar to the above-described embodiments.

  The access point 10 switches the encryption method to perform data communication encrypted with the temporary encryption key to the wireless station that has returned the request prompt data (see the process of s910 in FIG. 19), while the request prompt is requested. The printer 20 that has received the data is set to perform data communication with the access point 10 by encrypting with the temporary encryption key (see the process of s224 in FIG. 15). In this way, data communication can be normally performed between the access point 10 and the printer 20 while being encrypted with the temporary encryption key. Thereby, the data communication between the access point 10 and the printer 20 can be realized in a state where a certain security level is secured while maintaining the security level for the data communication performed by the access point 10 with the external network.

  Subsequently, when the printer 20 can acquire the encryption key by the encryption key acquisition process (FIG. 17), the data communication between the access point 10 and the printer 20 is performed from the PC 30 by performing wireless connection to the access point 10 again. Encryption is performed using the encryption key delivered to the printer 20 (see the processing in s306 and s308 in FIG. 15). At this time, the access point 10 deletes the parameter corresponding to the wireless station whose wireless connection has been canceled from the prompt list (see the process of s594 in FIG. 14), and thereafter, data communication with the printer 20 is performed using the encryption key. It will be returned to encrypt. Therefore, data communication between the access point 10 and the printer 20 can be realized at the same security level as the data communication performed by the access point 10 with other wireless stations or external networks.

  Further, since the encryption key is transferred from the PC 30 to the printer 20 by the public key cryptosystem, the possibility of leakage in the process of transmitting the encryption key to the printer 20 is naturally reduced.

  Further, the printer 20 prints the message image indicated by the print data delivered from the PC 30 before the encryption key (see the process of s750 in FIG. 17). Therefore, the user can confirm that the printer 20 is a correct wireless station to which the encryption key is to be delivered from the PC 30 depending on whether or not a message image is printed from the printer 20. Then, after confirming this message image, the user can perform a confirmation operation on the PC 30 (see the process of s840 in FIG. 18), so that the encryption key can be transferred from the PC 30 to the printer 20.

[Modification]
As mentioned above, although embodiment of this invention was described, this invention is not limited to said specific embodiment, It can implement with a various form besides this.

  For example, in the above-described embodiment, the printer 20 is applied as the wireless station of the present invention. However, the wireless station of the present invention can be applied to devices other than the printer 20 as long as the device functions as a wireless station.

  In the above embodiment, the configuration in which the PC 30 is connected to the access point 10 via the cable 100 is illustrated. However, when the PC 30 has a function as a wireless station, the PC 30 is wirelessly connected. It is good also as composition which has.

  Further, in each of the above-described embodiments, an example in which all processing including transmission of advertisement data is not performed when it is determined that the printer 20 is in a factory shipment state (FIG. 2). , See the process of s100 in FIG. 15). However, on the printer 20 side, the advertisement data is transmitted in a state where it can be determined whether or not the printer 20 itself is in a factory-shipped state, and the access point 10 side is prevented from registering the advertisement data or returning the request prompting data. Also good.

For this reason, on the printer 20 side, for example, as shown in FIG. 20, the process of s100 is provided after the process of s130, and if “YES” is determined in the process of s100, the factory shipment state is indicated. While the advertisement data with the “Unconfigure device” flag indicating “1” set is transmitted (s142), if it is determined “NO”, the “Unconfiguredevice” flag is not set (“0 ”After sending the ad data (s1
44), it may be configured to shift to the processing of s150.

  Further, on the access point 10 side, the following processing may be provided in FIGS. 4, 5, 7, 8, 13, and 14. For example, as shown in FIG. 21, if the wireless station (printer 20) is in the factory-shipped state as a result of checking the “Unconfigure device” flag of the received advertisement data after the process of s340 (s342: YES), s350 On the other hand, if the process is not in the factory-shipped state (s342: NO), the process returns to s320. Or, as shown in FIG. 22, after the process of s550, if the result of checking the “Unconfigure device” flag of the received advertisement data is that the wireless station is in the factory shipment state (s552: YES), the process proceeds to the process of s560. On the other hand, if it is not in the factory-shipped state (s552: NO), the process returns to s530.

  With this configuration, the access point 10 can perform registration and request prompt data transmission based on advertisement data and set a connection method only when the wireless station is in a factory-shipped state.

In the present embodiment, the order in which the printer 20 switches the connection method is exemplified from the first channel in the first wireless LAN standard to the number order. However, the order is not particularly limited. For example, the order in the same wireless LAN standard may be such that radio wave interference does not occur.

  As a specific example, a plurality of channels are divided into a plurality of groups (for example, two groups of a high frequency side and a low frequency side which are divided into two frequency bands), and after a jth channel (j is an arbitrary number) in a certain group. It is preferable that the switching to the j-th channel in another group is performed in order on all channels in each group. In this case, it is not possible to continuously switch to a channel in the same group having a close frequency band, so that radio wave interference can be suppressed.

  Similarly, after switching a plurality of channels in order at a predetermined channel number k (for example, 5 channels) from the first channel in order, switching from the second channel in order at a predetermined channel number interval, You may comprise so that it may repeat from the 1st-k-1th channel. In this case, radio wave interference can be reliably suppressed by setting the predetermined number k of channels to an interval at which radio wave interference can be sufficiently suppressed.

[Correspondence with the present invention]
In the present invention, the method switching means provided in the wireless station is the processing of s110 to s290 in FIGS. The advertisement transmission means is the process of s140 in FIGS. The method setting means is the process of s280 in FIGS. 2 and 15 (when it is determined “YES”). Further, the notification collection means is the processing of s160 to s174 in FIG. The encryption setting means is the process of s224 in FIG. The cipher acquisition unit is the process of s700 in FIG. The cipher changing means is the process of s304 in FIG. The message output means is the process of s750 in FIG. The content determination means is the process of s100 in FIGS. The non-setting means is the process of s100 in FIGS. 2 and 15 (when it is determined “YES”).

  Further, the notification return means provided in the wireless access point is the processing of s370 and s400 in FIGS. 4, 5, 7, 8, 13, and 14. Further, the advertisement collecting means is the process from s320 to s360 in FIG. 4 and the process from s320 to s352 in FIGS. 5, 7, 8, 13, and 14. The first and second user selection means are the processes of s512 and s514 in FIG. The list transmission means is the process of s516 in FIGS. The cipher switching means is the processing from s910 to s930 in FIG. The mode switching means is the CPU 11 that executes connection method instruction processing. The content determination means is the processing of s342 and s542 in FIG.

  Further, the request transmission means included in the communication terminal is the process of s614 in FIG. The third and fourth user selection means are the processes of s630 and s640 in FIG. The selective transmission means is the process of s650 in FIG. Further, the encryption delivery means is the processing of s810 to s850 in FIG. The confirmation operation means is the process of s840 in FIG.

Diagram showing network configuration The flowchart which shows the process sequence of the connection method determination process in 1st Embodiment. Sequence diagram showing exchange of data between an access point and a printer in the first embodiment The flowchart which shows the process sequence of the connection method instruction | indication process in 1st Embodiment. The flowchart which shows the process sequence of the connection method instruction | indication process in 2nd Embodiment. Diagram showing data structure of data table The flowchart which shows the process sequence of the connection method instruction | indication process in 3rd Embodiment. The flowchart which shows the process sequence of the connection method instruction | indication process in 4th Embodiment. Sequence diagram showing exchange of data between access point and printer in the fourth embodiment The flowchart which shows the process procedure of the setting command process in 4th Embodiment (the 1) The figure which shows the state where the contents which are indicated with list data are displayed Flowchart showing the procedure of setting command processing in the fourth embodiment (No. 2) The flowchart which shows the process sequence of the connection method instruction | indication process in 4th Embodiment. The flowchart which shows the process sequence of the connection method instruction | indication process in 5th Embodiment. The flowchart which shows the process sequence of the connection method determination process in 5th Embodiment. Sequence diagram showing exchange of data between access point and printer in the fifth embodiment The flowchart which shows the process sequence of the encryption key acquisition process in 5th Embodiment. The flowchart which shows the process sequence of the setting command process in 5th Embodiment. The flowchart which shows the process sequence of the encryption switching process in 5th Embodiment. The flowchart which shows the process sequence of the connection method determination process in another embodiment. The flowchart which shows the process sequence of the connection method instruction | indication process in another embodiment. The flowchart which shows the process sequence of the connection method instruction | indication process in another embodiment.

  DESCRIPTION OF SYMBOLS 10 ... Access point, 11 ... CPU, 12 ... ROM, 13 ... RAM, 14 ... Network controller, 15 ... Wireless LAN controller, 16 ... Operation panel, 17 ... Display panel, 20 ... Printer, 21 ... CPU, 22 ... ROM, DESCRIPTION OF SYMBOLS 23 ... RAM, 24 ... Wireless LAN controller, 25 ... PC interface part, 26 ... Operation panel, 27 ... Display panel, 28 ... Print engine, 30 ... Personal computer, 100 ... Cable.

Claims (4)

  A wireless LAN access point that functions as a relay station in a wireless LAN network,
  Storage means for storing a channel and an SSID to function as the relay station;
  Data transmitting and receiving means for transmitting and receiving data by wireless communication using a channel stored in the storage means;
  SSID transmission instruction receiving means for receiving from the user an SSID transmission instruction for transmitting the SSID stored in the storage means to the wireless LAN station;
  When the data transmission / reception unit receives first data including identification information of a wireless LAN station within a predetermined time period after the SSID transmission instruction reception unit receives the SSID transmission instruction, the data transmission / reception unit receives the data SSID transmission control means for transmitting second data including the SSID stored in the storage means to the wireless LAN station that is the transmission source of the first data;
A wireless LAN access point comprising:   A wireless LAN system,
  A wireless LAN access point that functions as a relay station in the wireless LAN network, and a wireless LAN station,
  The wireless LAN access point is
  Storage means for storing a channel and an SSID to function as the relay station;
  Data transmitting and receiving means for transmitting and receiving data by wireless communication using a channel stored in the storage means;
  SSID transmission instruction receiving means for receiving from the user an SSID transmission instruction for transmitting the SSID stored in the storage means to the wireless LAN station;
  When the data transmission / reception unit receives first data including identification information of a wireless LAN station within a predetermined time period after the SSID transmission instruction reception unit receives the SSID transmission instruction, the data transmission / reception unit receives the data SSID transmission control means for transmitting second data including the SSID stored in the storage means to the wireless LAN station that is the transmission source of the first data;
With
  The wireless LAN station is
  SSID storage instruction receiving means for receiving an SSID storage instruction for storing the SSID of the wireless LAN access point from a user;
  Channel selection means for selecting one of the channels as a selection channel when the SSID storage instruction reception means receives the SSID storage instruction;
  First data transmission means for transmitting the first data including identification information of the wireless LAN station using the selected channel when the channel selection means selects the selected channel;
  When the second data transmitted to the wireless LAN station itself is received within a predetermined period from the transmission of the first data, the SSID included in the second data and the selected channel are stored, When the second data transmitted to the wireless LAN station itself is not received within a predetermined period from the transmission of the first data, the channel selection unit is controlled to select another channel as the selected channel. SSID storage control means;
With
A wireless LAN system characterized by the above.   A wireless LAN station,
  SSID storage instruction for receiving from the user an SSID storage instruction for storing the SSID of the wireless LAN access point that functions as a relay station in the wireless LAN network
Receiving means;
  Channel selection means for selecting one of the channels as a selection channel when the SSID storage instruction reception means receives the SSID storage instruction;
  First data transmitting means for transmitting, using the selected channel, first data including identification information of the wireless LAN station when the channel selecting means selects the selected channel;
  When the second data transmitted to the wireless LAN station itself is received within a predetermined period from the transmission of the first data, the SSID included in the second data and the selected channel are stored, and the wireless SSID for controlling the channel selection means to select another channel as the selected channel when the second data transmitted to the LAN station itself is not received within a predetermined time limit from the transmission of the first data. Memory control means;
With
A wireless LAN station comprising:   A wireless LAN setting method for allowing a wireless LAN station to participate in a wireless LAN network in which a wireless LAN access point functions as a relay station,
  In the wireless LAN access point, an SSID transmission instruction reception step for receiving an SSID transmission instruction for transmitting an SSID used when the wireless LAN access point functions as the relay station to the wireless LAN station;
  In the wireless LAN access point, when the first data including the identification information of the wireless LAN station is received within a predetermined time period after receiving the SSID transmission instruction in the SSID transmission instruction receiving step, the storage means stores SSID transmission control step of transmitting the second data including the SSID being transmitted to the wireless LAN station that is the transmission source of the first data;
  In the wireless LAN station, an SSID storage instruction receiving step for receiving an SSID storage instruction for storing the SSID of the wireless LAN access point from a user;
  In the wireless LAN station, when the SSID storage instruction is received in the SSID storage instruction reception step, a channel selection step of selecting any channel as a selection channel;
  In the wireless LAN station, when the selected channel is selected in the channel selection step, a first data transmission step of transmitting the first data including identification information of the wireless LAN station itself using the selected channel;
  In the wireless LAN station, when the second data transmitted to the wireless LAN station itself is received within a predetermined period from the transmission of the first data, the SSID included in the second data and the selected channel SSID storage for selecting another channel as the selected channel when the second data transmitted to the wireless LAN station itself is not received within a predetermined period from the transmission of the first data Control steps;
Run the
A wireless LAN setting method.

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