JP7314354B2 - Information processing device, control method and program - Google Patents

Description

The present invention relates to an information processing device, control method, and program.

2. Description of the Related Art A technology is known in which an information processing device such as a personal computer or a smart phone executes processing for connecting a communication device such as a printer and an external device such as an access point.
Patent Literature 1 describes that a communication partner device transmits AP information (such as SSID) that identifies an external device to the communication device, thereby connecting the communication device and the external device.

JP 2016-72728 A

By the way, in recent years, communication devices that can use multiple frequency bands (for example, 2.4 GHz and 5 GHz) have become widespread. Even if such a communication device receives information about an external device from an information processing device, it cannot specify which frequency band should be used for connection with the external device. Therefore, there is a problem that the processing for connecting the communication device and the external device may not be properly executed by the information processing device.

Accordingly, an object of the present invention is to appropriately execute processing for connecting a communication device that can use a plurality of frequency bands to an external device.

In order to solve the above problems, a program of the present invention is provided in a computer of an information processing device capable of communicating with a communication device,
a first control step of executing, when the information processing device is connected to an access point at a predetermined timing, setting information used for wirelessly connecting to a first access point, which is the access point to which the information processing device is connected at the predetermined timing, and frequency band information related to a frequency band used for wirelessly connecting to the first access point, to the communication device as control executed based on the fact that the information processing device is connected to the access point;
a second control step of executing control for transmitting to the communication device, if the information processing device is not connected to an access point at the predetermined timing, setting information used for wireless connection with a second access point searched and displayed by the information processing device and selected by the user, and frequency band information related to a frequency band used for wireless connection with the second access point, to the communication device as control executed based on the fact that the information processing device is not connected to the access point;
and
A frequency band corresponding to the frequency band information transmitted to the communication device is used from among a first frequency band and a second frequency band, and the communication device is connected to an access point corresponding to the setting information transmitted to the communication device.

ADVANTAGE OF THE INVENTION According to this invention, the process which connects the communication apparatus and external apparatus which can use several frequency bands can be performed appropriately.

1 is a configuration diagram of a communication system; FIG. 3 is a hardware configuration diagram of a communication device and an information processing device; FIG. 4 is a flowchart showing network setting processing executed by the information processing apparatus in the first embodiment; It is an example of an access point selection screen. 9 is a flowchart showing network setting processing executed by the information processing apparatus in the second embodiment; 4 is a flowchart showing a process of specifying an access point to which a communication device is connected by an information processing device; FIG. 11 is a flowchart showing network setting processing executed by an information processing apparatus in the third embodiment; FIG. It is an example of a manual setting screen.

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It should be noted that the following embodiments do not limit the present invention according to the claims, and not all combinations of features described in the embodiments are essential for the solution of the present invention.

(First embodiment)
An information processing device and a communication device included in the communication system of this embodiment will be described. As an information processing apparatus, a personal computer (PC) is exemplified in this embodiment, but the information processing apparatus is not limited to this. Various devices such as mobile terminals, smart phones, tablet terminals, PDAs (Personal Digital Assistants), and digital cameras can be applied as information processing devices. Further, although a printer is exemplified as a communication device in this embodiment, it is not limited to this, and various devices can be applied as long as they are capable of wirelessly communicating with an information processing device. For example, if it is a printer, it can be applied to an inkjet printer, a full-color laser beam printer, a monochrome printer, and the like. In addition to printers, the present invention can also be applied to copiers, facsimile machines, mobile terminals, smart phones, PCs, tablet terminals, PDAs, digital cameras, music playback devices, televisions, and the like. In addition, the present invention can also be applied to a multifunction machine having multiple functions such as a copying function, a FAX function, and a printing function.

First, configurations of the information processing apparatus of the present embodiment and a communication apparatus capable of communicating with the information processing apparatus of the present embodiment will be described. In addition, although the following configuration is described as an example in this embodiment, this embodiment is applicable to a device capable of communicating with a communication device, and the functions are not particularly limited as shown in this figure.

A hardware configuration diagram of the communication device 101 and the information processing device 102 will be described with reference to FIG.

The information processing apparatus 102 has an input I/F (interface) 202, a CPU 203, a ROM 204, a RAM 205, an external storage device 206, an output I/F (interface) 207, a display section 208, a keyboard 209, a mouse 210, and the like. Further, the information processing apparatus 102, a network interface (first communication unit) 211, a USB interface (second communication unit) 212, and the like.

An input I/F (interface) 202 is an interface for receiving data input and operation instructions from the user by operating a mouse 210 and keyboard 209 .

A CPU 203 is a system control unit and a processor that controls the entire information processing apparatus 102 .

A ROM 204 stores fixed data such as a control program executed by the CPU 203, a data table, and an embedded operating system (hereinafter referred to as OS) program. In this embodiment, each control program stored in the ROM 204 performs software execution control such as scheduling, task switching, and interrupt processing under the control of the built-in OS stored in the ROM 204 .

The RAM 205 is composed of an SRAM (Static Random Access Memory) or the like that requires a backup power supply. Note that the RAM 205 retains data by a primary battery for data backup (not shown), so important data such as program control variables can be stored without volatilization. The RAM 205 also includes a memory area for storing setting information of the information processing apparatus 102, management data of the information processing apparatus 102, and the like. The RAM 205 is also used as the main memory and work memory of the CPU 203 .

The external storage device 206 stores an application that provides a print execution function, a print job generation program that generates a print job that can be interpreted by the communication device 101, and the like. In addition, the external storage device 206 stores various programs such as an information transmission/reception control program to be transmitted/received to/from the communication device 101 connected via the network interface 211 or USB interface 212, and various information used by these programs. Note that a setup program, which will be described later, is also stored in the external storage device 206 .

An output I/F (interface) 207 is an interface that controls the display unit 208 to display data and notify the status of the information processing apparatus 102 .

A display unit 208 includes an LED (light emitting diode), an LCD (liquid crystal display), and the like, and displays data and notifies the state of the information processing apparatus 102 . Inputs from the user may be accepted via the display unit 208 by providing an operation unit such as a numeric input key, a mode setting key, an enter key, a cancel key, and a power key on the display unit 208 .

The network interface 211 controls communication via wireless communication and communication processing via a wired LAN cable. Specifically, the network interface 211 is a configuration for executing data communication by connecting to the communication device 101 or an external device existing outside the information processing device 102 and outside the communication device 101 via a wireless or wired LAN. For example, network interface 211 is connectable to an access point (not shown) within communication device 101 . By connecting the network interface 211 and the access point in the communication device 101, the information processing device 102 and the communication device 101 can communicate with each other. Note that the network interface 211 may directly communicate with the communication device 101 by wireless communication, or may communicate via an external device existing outside the information processing device 102 or the communication device 101 . Note that the external device includes an external access point and a device other than an access point that can relay communication. In this embodiment, the IEEE 802.11 series standard (Wi-Fi (Wireless Fidelity)) is used, but Bluetooth (registered trademark), for example, may also be used. Examples of wireless communication methods include Wi-Fi (Wireless Fidelity) (registered trademark) and Bluetooth (registered trademark). Also, examples of external access points include devices such as router devices. In this embodiment, a direct connection method is a method in which the information processing apparatus 102 and the communication apparatus 101 are directly connected to each other without using an external access point. A system in which the information processing apparatus 102 and the communication apparatus 101 are connected via an external access point is called an infrastructure connection system. Note that the information processing apparatus 102 may have a plurality of network interfaces 211 in order to perform communication using a plurality of communication methods. Specifically, for example, the information processing apparatus 102 may further have an interface for communicating by a short-range wireless communication method such as Bluetooth Low Energy, Near Field Communication, or WiFi Aware. Also, the information processing apparatus 102 may not have the network interface 211 for wireless communication. That is, the information processing apparatus 102 may have, for example, only a network interface 211 for wired communication and a USB interface 212, which will be described later, as interfaces for communicating with other apparatuses.

A USB interface 212 controls USB connections via a USB (Universal Serial Bus) cable. Specifically, the USB interface 212 is configured to connect to the communication device 101 or a device such as an external access point via USB to perform data communication.

The communication device 101 has a network I/F (interface) (communication unit) 252, a RAM 253, a print engine 256, a ROM 254, a CPU 255, a USB interface 257, and the like.

The network interface 252 controls communication via wireless communication and communication processing via a wired LAN cable. Specifically, the network interface 252 has, as an access point inside the communication device 101, an access point for connecting to a device such as the information processing device 102 or the like. Note that the access point can be connected to the network interface 211 of the information processing device 102 . Note that the network interface 252 may directly communicate with the information processing apparatus 102 by wireless communication, or may communicate with the information processing apparatus 102 via an external access point. That is, the network interface 252 may operate not only as an access point itself, but also as a slave device connected to an external access point. In this embodiment, the IEEE 802.11 series standard (Wi-Fi) is used, but Bluetooth (registered trademark), for example, may also be used. Also, the network interface 252 may include hardware that functions as an access point, or may operate as an access point using software for functioning as an access point. Note that the communication device 101 may have a plurality of network interfaces 252 in order to perform communication using a plurality of communication methods. Specifically, for example, the communication device 101 may further have an interface for communication by a short-range wireless communication method such as Bluetooth Low Energy, Near Field Communication, or WiFi Aware.

The RAM 253 is composed of an SRAM or the like that requires a backup power supply. The RAM 253 retains data by a data backup primary battery (not shown), so important data such as program control variables can be stored without volatilization. The RAM 253 is also provided with a memory area for storing setting information of the communication device 101, management data of the communication device 101, and the like. The RAM 253 is also used as a main memory and a work memory for the CPU 255, and stores a reception buffer for temporarily storing print information received from the information processing apparatus 102 or the like, and various information.

The ROM 254 stores fixed data such as control programs executed by the CPU 255, data tables, and OS programs. In this embodiment, each control program stored in the ROM 254 performs software execution control such as scheduling, task switching, and interrupt processing under the control of the built-in OS stored in the ROM 254 .

A CPU 255 is a system control unit and a processor that controls the communication apparatus 101 as a whole.

The print engine 256 executes an image forming process for forming an image on a recording medium such as paper by adding a recording agent such as ink to the recording medium based on information stored in the RAM 253 and a print job received from the information processing apparatus 102, etc., and outputs a print result. A print job is a job for causing the communication apparatus 101 to execute an image forming process.

In this embodiment, the communication device 101 uses at least one frequency band of 2.4 GHz and 5 GHz for wireless connection based on the IEEE 802.11 series standards. The communication device 101 has communication channels corresponding to available frequency bands. For example, if the 2.4 GHz frequency band is available, the communication device 101 has 14 communication channels assigned to predetermined frequency bands of the 2.4 GHz frequency band. again,. For example, if a 5 GHz frequency band is available, the communication device 101 has 19 communication channels assigned to predetermined frequency bands of the 5 GHz frequency band.

Here, as an example, the sharing of processing between the information processing apparatus 102 and the communication apparatus 101 is shown as described above, but the sharing is not limited to this form, and other forms may be used.

FIG. 1 is a configuration diagram of a communication system according to this embodiment. The information processing device 102 is connected to the access point 103 via a wired LAN or wireless LAN. Access point 103 is a router device. A router device is a device that relays data communication between devices (for example, between an information processing device and a communication device). In this embodiment, the router device serves as an access point and relays data communication between devices connected to the access point of the router device. The communication method used by the router device may be a wireless communication method, a wired communication method, or both.

Also, the communication device 101 is connected to the access point 103 via a wireless LAN. That is, the information processing device 102 is in a state of being able to communicate with the communication device 101 via the access point 103 . Such a method of connecting via an access point is generally called infrastructure (hereinafter referred to as infrastructure) connection. By building an infrastructure connection, the communication device 101 and the information processing device 102 can communicate with devices belonging to the network formed by the access point 103 . Also, when the access point 103 is connected to the Internet, the communication device 101 and the information processing device 102 can also use the Internet via the access point 103 .

In the present embodiment, a mode in which the information processing apparatus 102 executes setting processing (network setting processing) for establishing infrastructure connection by the communication apparatus 101, the information processing apparatus 102, and the access point 103 will be described. Specifically, the information processing apparatus 102 connects the communication apparatus 101 and the access point 103 by transmitting network setting information to the communication apparatus 101 .

Note that the communication device 101 may be able to connect to the access point 103 by operating the main body of the communication device 101 without receiving network setting information from the information processing device 102 . However, there are cases where the communication device 101 has a small display unit or an operation unit, or the communication device 101 does not have a display unit or an operation unit in the first place. In such a case, it is difficult to connect the communication device 101 and the access point 103 by operating the main body of the communication device 101 . Therefore, in this embodiment, the communication device 101 and the access point 103 are connected via the information processing device 102 .

Specifically, the information processing apparatus 102 transmits network setting information to the communication apparatus 101 connected wirelessly or by wire as the network setting process. Here, the network setting information is, for example, connection information (Service Set Identifier (hereinafter referred to as SSID), password, etc.) used for connecting to the access point 103 to which the communication apparatus 101 is connected. The connection information is transmitted from the communication device 101 to the access point 103 when the communication device 101 requests the access point 103 to connect. The information processing apparatus 102 wirelessly connects the communication apparatus 101 and the access point 103 by transmitting such information to the communication apparatus 101 .

By the way, a wireless connection is a connection made using a specific frequency band. In recent years, devices that can use multiple frequency bands (eg, 2.4 GHz and 5 GHz) have appeared as the communication device 101 . It is assumed that the communication device 101 in this embodiment is also capable of wireless connection using a plurality of frequency bands. When connecting to an access point, communication apparatus 101 first searches for an access point (AP search) using a communication channel corresponding to a usable frequency band. After that, the communication device 101 wirelessly connects with the access point by transmitting a connection request to the access point corresponding to the connection information received as described above using a communication channel corresponding to the available frequency band.

Such a communication apparatus 101 has a problem that even if it receives the connection information as described above, it cannot connect to the access point if it does not know which frequency band to use for wireless connection with the access point.

For example, even if the communication apparatus 101 does not know which frequency band to use, it may use a frequency band that it can use to perform an AP search and attempt to connect to an access point. However, since the communication device 101 cannot generally use multiple frequency bands at the same time, the communication device 101 sequentially uses the frequency bands that it can use one by one in the above embodiment. In that case, the communication device 101 may attempt connection using a frequency band other than the frequency band for connecting to the access point. That is, even in the above embodiment, the communication apparatus 101 may take time to connect to the access point, or may execute unnecessary processing.

Therefore, in the present embodiment, the communication device 101 is caused to specify which frequency band should be used for wireless connection with the access point, and then the communication device 101 attempts connection with the access point.

FIG. 3 is a flowchart showing network setting processing executed by the information processing apparatus 102 in the first embodiment. The flowchart shown in FIG. 3 is realized, for example, by the CPU 203 reading a program stored in the ROM 204, the external storage device 206 or the like into the RAM 205 and executing the program. Specifically, the processing shown in the flowchart shown in FIG. 3 is implemented by a setup program, which is a program for executing network setting processing. Further, the process shown in the flowchart shown in FIG. 3 is started when a user operation (instruction to execute the network setting process) that triggers the network setting process is performed on the screen displayed by the setup program. Further, for example, the processing shown in the flowchart shown in FIG. 3 is started when the setup program is activated.

First, in S301, the CPU 203 identifies a device to be subjected to network setting processing. Specifically, the CPU 203 acquires information on devices around the information processing apparatus 102 using an API (Application Program Interface) of the OS of the information processing apparatus 102 . More specifically, the CPU 203 acquires information on devices searched by the network interface 211 and devices connected by the USB interface 212 . Using the acquired information, the CPU 203 displays a list of devices connected to the interface of the information processing device 102 on the display unit 208 . A device searched by the network interface 211 is, for example, a device operating as an access point or a device belonging to the network to which the information processing device 102 belongs. Note that in this embodiment, when the user executes network setting processing for the communication device 101, the user operates the communication device 101 main body to operate the communication device 101 in a predetermined mode called a setup mode. The setup mode is a mode in which the communication device 101 can accept network setting processing, and is a mode in which the communication device 101 operates as a predetermined access point having a predetermined SSID. When the communication device 101 is operating in the setup mode, the communication device 101 is found in the search by the network interface 211, so the communication device 101 is displayed in the list. Note that the information processing apparatus 102 may not have the network interface 211 for wireless communication, or the network interface 211 for wired communication may not be connected to any apparatus. In that case, only devices connected by USB interface 212 are displayed in the list. When the user selects the communication device 101 from the displayed list, the CPU 203 identifies the communication device 101 as a target device for network setting processing.

Next, in S<b>302 , the CPU 203 acquires information as to whether the information processing apparatus 102 has the network interface 211 for wireless communication using API of the OS provided in the information processing apparatus 102 .

Then, in S303, the CPU 203 determines whether or not the information processing apparatus 102 has the network interface 211 for wireless communication based on the information acquired in S302. When the CPU 203 determines that the information processing apparatus 102 has the network interface 211 for wireless communication, the process proceeds to step S304. On the other hand, when the CPU 203 determines that the information processing apparatus 102 does not have the network interface 211 for wireless communication, the process proceeds to step S313.

In S<b>304 , the CPU 203 acquires information indicating whether or not the information processing apparatus 102 is connected to the access point 103 using the API of the OS of the information processing apparatus 102 .

In S<b>305 , the CPU 203 determines whether the information processing apparatus 102 is wirelessly connected to the access point 103 based on the information acquired in S<b>304 . If the CPU 203 determines that the information processing apparatus 102 is wirelessly connected to the access point 103, the process proceeds to S306, and if it is determined that the information processing apparatus 102 is not wirelessly connected to the access point 103, the process proceeds to S308.

In S<b>306 , the CPU 203 identifies the access point 103 to which the information processing apparatus 102 is wirelessly connected as an access point to which the communication apparatus 101 connects. Then, the CPU 203 inquires of the access point 103 to which the information processing apparatus 102 is wirelessly connected, and acquires setting information regarding the access point 103 . The setting information about the access point 103 is, for example, setting information (SSID, etc.) for connecting to the access point 103, information about the frequency band used by the access point 103, encryption method, and the like. In this embodiment, the access point 103 has a communication channel corresponding to at least one frequency band of 2.4 GHz and 5 GHz, and uses that communication channel for wireless connection.

In S307, the CPU 203 performs a setting packet generation process based on the setting information acquired in S306. A setting packet is information for connecting the communication device 101 to the access point 103, corresponding to network setting information. When the communication device 101 is connected to the access point 103 to which the information processing device 102 is wirelessly connected, infrastructure connection between the information processing device 102 and the communication device 101 is established. Therefore, here, a setting packet is generated for connecting the communication device 101 to the access point 103 to which the information processing device 102 is wirelessly connected. Specifically, the setting packet includes setting information (SSID, password) for connecting to the access point 103, information on the frequency band used by the access point 103, information on the encryption method, and the like. The frequency band used by the access point 103 is the frequency band used for wireless connection with the access point 103 . After S307, the CPU 203 proceeds to S312.

On the other hand, in S<b>308 , the CPU 203 uses the network interface 211 to search for access points around the information processing apparatus 102 (AP search (search processing)). Note that the AP search is performed by a well-known discovery process based on (compliance with) the IEEE 802.11 series of standards. Specifically, AP search is performed by passive scanning.

In S309, the CPU 203 inquires of the access point found by the search in S308, and acquires setting information regarding the access point. The details of the setting information are as described above. Here, the CPU 203 acquires setting information regarding all access points found by the search in S308.

In S310, the CPU 203 displays the list of access points found by the search in S308 on the display unit 208 based on the setting information acquired in S309. Specifically, an access point selection screen 401 as shown in FIG. 4A is displayed on the display unit 208 . The access point selection screen displays the SSID and encryption method of the access point found by the search in S308. It should be noted that the present invention is not limited to this form, and information regarding the frequency band used for wireless connection by the access point found by the search in S308, for example, may be displayed. CPU 203 causes the user to select one of the access points from the list, and specifies the selected access point (access point 103 here) as the access point to which communication apparatus 101 is to be connected. At this time, the CPU 203 also displays a cancel button 402 for canceling the network setting process together with the list. When the cancel button 402 is selected, the CPU 203 terminates the process. On the other hand, when the setting button 403 is selected, the CPU 203 displays a password (passphrase) input screen 404 as shown in FIG. The user enters a password for using the selected access point in input area 407 . When the cancel button 405 is selected, the CPU 203 terminates the process. On the other hand, when the setting button 406 is selected, the CPU 203 proceeds to S311.

In S311, the CPU 203 generates a setting packet based on the setting information acquired from the access point selected in S310 and the password entered in S310. The details of the setting packet are as described above.

In S<b>312 , the CPU 203 wirelessly connects the device to be set (here, the communication device 101 ) identified in S<b>301 and the information processing device 102 . If another device such as the access point 103 and the information processing device 102 are wirelessly connected at this time, the CPU 203 temporarily disconnects the connection between the other device and the information processing device 102 after saving the setting information regarding the other device. After that, the CPU 203 wirelessly connects the communication device 101 and the information processing device 102 . After S312, the CPU 203 proceeds to S319.

In S<b>313 , the CPU 203 detects the device identified in S<b>301 (here, the communication device 101 ) connected via the USB interface 212 or the network interface 211 for wired communication, using APIs of the OS of the information processing device 102 . At this time, the CPU 203 acquires information from the communication device 101 as to whether the communication device 101 has a network interface 252 for wireless communication. If there is no device connected via the USB interface 212 or the network interface 211 for wired communication, the CPU 203 terminates the process.

In S314, the CPU 203 determines whether or not the communication apparatus 101 has the network interface 252 for wireless communication based on the information acquired in S313. When the CPU 203 determines that the communication apparatus 101 has the network interface 252 for wireless communication, the process proceeds to S315. On the other hand, if it is determined that the communication device 101 does not have the network interface 252 for wireless communication, the processing ends.

The communication device 101 can also search for access points around the communication device 101 (perform an AP search) using the network interface 252 for wireless communication. Therefore, in S<b>315 , the CPU 203 requests the communication device 101 for the result of the AP search by the communication device 101 .

In S<b>316 , the CPU 203 acquires from the communication device 101 the result of the AP search by the communication device 101 (the setting information of the access point discovered by the AP search by the communication device 101 ). Note that the communication device 101 may execute the AP search when receiving the request in S315, or may execute it at any timing such as when the power of the communication device 101 is turned on.

In S317, the CPU 203 displays a list of access points discovered by the communication apparatus 101 on the display unit 208 based on the setting information acquired in S316. Specifically, an access point selection screen 401 as shown in FIG. 4A is displayed on the display unit 208 . The access point selection screen displays the SSID and encryption method of the access point discovered by the communication device 101 . It should be noted that the present invention is not limited to this form, and for example, information regarding the frequency band used for wireless connection by the access point discovered by the communication apparatus 101 may be displayed. CPU 203 causes the user to select one of the access points from the list, and specifies the selected access point (here, access point 103 ) as the access point to which communication apparatus 101 is connected. At this time, the CPU 203 also displays a cancel button 402 for canceling the network setting process together with the list. When the cancel button 402 is selected, the CPU 203 terminates the process. On the other hand, when the setting button 403 is selected, the CPU 203 displays a password (passphrase) input screen 401 as shown in FIG. The user enters a password for using the selected access point in input area 407 . When the cancel button 405 is selected, the CPU 203 terminates the process. On the other hand, when the setting button 406 is selected, the CPU 203 proceeds to S318.

In S318, the CPU 203 generates a setting packet based on the setting information obtained from the access point selected in S317 and the password input in S317. The details of the setting packet are as described above. Here, information about the frequency band used for wireless connection by the access point selected in S317 may not be included in the setting packet. This is because the communication device 101 recognizes which access point uses which frequency band when executing the AP search.

In S319, the CPU 203 transmits the created setting packet to the communication device 101 identified in S301. Specifically, the CPU 203 transmits a setting packet using SNMP (Simple Network Management Protocol). SNMP is a protocol for monitoring and controlling devices (including the communication device 101) on the network to which the information processing device 102 belongs. The CPU 203 can acquire and set information in a database called MIB (Management Information Base) of a device to be monitored and controlled by performing SNMP communication. When the communication device 101 receives the setting packet, based on the setting packet, the communication device 101 identifies the device to be connected (access point 103) and the frequency band used by the device to be connected for wireless connection (the frequency band corresponding to the information on the frequency band included in the setting packet). Then, the communication device 101 preferentially uses the specified frequency band to search for a device having the SSID included in the setting packet. Specifically, the communication device 101 executes only the search using the specified frequency band, and does not execute the search using frequency bands other than the specified frequency band. Note that this search is performed by a known discovery process based on the IEEE 802.11 series of standards. Specifically, the communication device 101 searches for a device having the SSID included in the setting packet by active scanning using the frequency band specified based on the setting packet. Specifically, the communication device 101 broadcasts using communication channels corresponding to the frequency bands specified based on the setting packet, and waits for a response from the device having the SSID included in the setting packet. The communication device 101 discovers the device having the SSID included in the setting packet by receiving the response to the broadcast. Then, the communication device 101 uses the password included in the setting packet to transmit a connection request to the discovered device. As a result, since the communication device 101 connects to the access point 103 , infrastructure connection is established between the communication device 101 and the information processing device 102 when the information processing device 102 connects to the access point 103 .

In S320, the CPU 203 restores the connection state of the information processing apparatus 102 to the connection state before the network setting process. Specifically, in S312, when the communication apparatus 101 and the information processing apparatus 102 are wirelessly connected after disconnecting the other apparatus and the information processing apparatus 102, the CPU 203 connects the other apparatus and the information processing apparatus 102 again using the setting information saved at that time. Note that the CPU 203 omits the processing of S320 when the connection state of the information processing apparatus 102 is the same as the connection state before the network setting process.

As described above, in this embodiment, the CPU 203 identifies the frequency band used by the access point 103 based on the acquired setting information, and then transmits a setting packet including information about the identified frequency band to the communication device 101. By adopting such a configuration, the communication device 101 can specify which frequency band should be used for wireless connection with the access point 103, and can quickly connect to the access point 103 using the setting packet.
(Second embodiment)
A second embodiment of the present invention will be described in detail. Specifically, the second embodiment is a form in which a device discovered by the communication device 101 is preferentially specified as a device to which the communication device 101 is connected, over devices connected to the information processing device 102 and devices discovered by the information processing device 102. Further, specifically, the second embodiment is a mode in which, when access points using different frequency bands have the same SSID, which one is to be preferentially used by the communication apparatus 101 is determined. It should be noted that the same communication system as in the first embodiment is used in the second embodiment as well, and parts that are not specifically described are assumed to be in the same form as in the first embodiment.

FIG. 5 is a flowchart showing network setting processing executed by the information processing apparatus 102 in the second embodiment. The flowchart shown in FIG. 5 is realized, for example, by the CPU 203 reading a program stored in the ROM 204, the external storage device 206 or the like into the RAM 205 and executing the program. Specifically, the processing shown in the flowchart shown in FIG. 5 is realized by the setup program. Further, the processing shown in the flowchart shown in FIG. 5 is started when a user operation that triggers the network setting processing is performed on the screen displayed by the setup program. Further, for example, the processing shown in the flowchart shown in FIG. 5 is started when the setup program is activated.

Since S301 to S320 are the same as in the first embodiment, description thereof is omitted.

In this embodiment, the CPU 203 first executes the processes of S313 and S314 before executing the processes of S301, S302, and S303.

Specifically, in step S<b>313 , the CPU 203 detects a device (the communication device 101 in this case) connected via the USB interface 212 or the network interface 211 for wired communication, using the API of the OS of the information processing device 102 . At this time, the CPU 203 acquires information from the communication device 101 as to whether the communication device 101 has a network interface 252 for wireless communication. If there is no device connected via the USB interface 212 or the network interface 211 for wired communication, the CPU 203 proceeds to step S301.

If the CPU 203 determines in S314 that the communication apparatus 101 has the network interface 252 for wireless communication, the process proceeds to S315. On the other hand, if it is determined that the communication device 101 does not have the network interface 252 for wireless communication, the process proceeds to S301.

If the CPU 203 determines in 303 that the information processing apparatus 102 has the network interface 211 for wireless communication, the process advances to step S304. When the CPU 203 determines that the information processing apparatus 102 does not have the network interface 211 for wireless communication, the process ends.

Further, in this embodiment, the CPU 203 executes the process of S501 after executing the process of S317. Note that in S317, the CPU 203 uses different frequency bands, but if the list includes access points with the same SSID, they are not displayed separately, but are displayed on the access point selection screen 401 as one access point. The case where access points using different frequency bands but having the same SSID are included in the list is the following case. That is, there is a case where one wireless LAN router supporting multiple frequency bands enables access points using different frequency bands by the band steering function. In this way, the band steering function enables multiple access points using different frequency bands, but the password for connecting to each access point is the same. In the process of S317, when the password input is completed, the CPU 203 proceeds to S501.

In S<b>501 , the CPU 203 identifies an access point to which the communication apparatus 101 is connected. Details of the processing of S501 will be described with reference to FIG.

FIG. 6 is a flowchart showing a process of specifying an access point to which the communication device 101 is connected by the information processing device 102 . The flowchart shown in FIG. 6 is realized, for example, by the CPU 203 reading a program stored in the ROM 204, the external storage device 206 or the like into the RAM 205 and executing the program. Specifically, the processing shown in the flowchart shown in FIG. 6 is implemented by a setup program. 6 is executed as the process of S501 in FIG.

In S601, the CPU 203 identifies the number of access points discovered by the communication device 101 based on the setting information acquired from the communication device 101 in S316.

In S602, the CPU 203 determines whether the SSID of the i-th access point among the access points discovered by the communication device 101 is the same as the SSID of the access point selected by the user in S317. Note that the initial value of the set value i is 1, and is incremented each time the process of S602 is repeated. If the CPU 203 determines that they are the same, the process proceeds to S603 and adds the i-th access point to the same AP list. On the other hand, if it is determined that they are not the same, the process of S602 is executed again after i is incremented. Note that if the incremented setting value i exceeds the number specified in S601, the process proceeds to S604.

With this processing, if the access point having the SSID of the access point selected by the user is the only access point selected by the user, only one access point is added to the same AP list. On the other hand, if there are multiple access points having the SSID of the access point selected by the user among the access points discovered by the communication device 101, multiple access points are added to the same AP list.

In S604, the CPU 203 automatically (without user operation) selects one access point from the access points added to the same AP list. By the way, an access point emits a beacon containing its own SSID and the like. The communication device 101 searches for access points around the communication device 101 by searching for beacons emitted by the access points (performs AP search). At this time, the greater the radio wave intensity of the beacon received by the AP search, the closer the communication apparatus 101 is to the access point that emitted the beacon. As a result, the higher the radio wave intensity of the received beacon, the faster the communication apparatus 101 can perform communication with the access point emitting the beacon. Therefore, in S604, the CPU 203 selects the access point emitting the beacon with the highest radio wave intensity from the access points added to the same AP list. In this embodiment, it is assumed that the setting information of the access point includes information regarding the radio wave intensity of the beacon emitted by the access point, and the CPU 203 refers to this information to execute the processing of S604. The CPU 203 identifies the access point selected in this manner as the access point to which the communication apparatus 101 is to be connected. After that, the CPU 203 ends the processing shown in the flowchart of FIG. 6 and proceeds to S318.

Thus, in this embodiment, different frequency bands are used, but even if multiple access points with the same SSID are discovered by the communication device 101, these access points are displayed as one access point in the list. This reduces the number of access points displayed in the list, thereby improving the visibility of the list. Further, when the access points grouped into one as described above are selected by the user, different frequency bands are used, but one of the multiple access points with the same SSID is automatically selected according to the radio wave intensity of the beacon. That is, it is automatically selected which frequency band information is added to the setting packet. By adopting such a form, usability in selecting an access point to which the communication apparatus 101 is connected can be improved.
<Third Embodiment>
A third embodiment of the present invention will be described in detail. Specifically, in the third embodiment, when the information processing apparatus 102 does not have the network interface 211 for wireless communication, the user manually sets the access point to which the communication apparatus 101 is connected.

It should be noted that the same communication system as in the first embodiment is used in the third embodiment as well, and parts that are not specifically described are assumed to be in the same form as in the first embodiment.

FIG. 7 is a flowchart showing network setting processing executed by the information processing apparatus 102 in the third embodiment. The flowchart shown in FIG. 7 is realized, for example, by the CPU 203 reading a program stored in the ROM 204, the external storage device 206 or the like into the RAM 205 and executing the program. Specifically, the processing shown in the flowchart shown in FIG. 7 is implemented by a setup program. Further, the processing shown in the flowchart shown in FIG. 7 is started when a user operation that triggers the network setting processing is performed on the screen displayed by the setup program. Further, for example, the processing shown in the flowchart shown in FIG. 7 is started when the setup program is activated.

Since S301 to S312, S319, and S320 are the same as in the first embodiment, description thereof is omitted.

If the CPU 203 determines in S303 that the information processing apparatus 102 does not have the network interface 211 for wireless communication, the process advances to S701.

In S<b>701 , the CPU 203 displays a manual setting screen on the display unit 208 . The manual setting screen is a screen for the user to input the setting information of the access point to which the communication device 101 is connected. The CPU 203 displays a screen 800 shown in FIG. 8 on the display unit 208 as a manual setting screen. Screen 800 includes, for example, areas 801-806. An area 801 is an area where the SSID of the access point to which the communication device 101 is connected is input. An area 802 is an area for inputting an encryption method (WEP, WPA, etc.) used for connection. An area 803 is an area where a password (passphrase) used for connection is entered. A field 804 is a field in which the frequency band used for connection is entered. An area 805 is a setting button that is pressed when the input is completed. Area 806 is a cancel button for canceling network settings. The CPU 203 terminates the process when the cancel button is selected. On the other hand, the CPU 203 advances to S702 when the setting button is selected after the input to the areas 801 to 804 has been completed.

In S702, a setting packet is created based on the information input by the user via the manual setting screen. Specifically, the setting packet includes the SSID, encryption method, password, and frequency band information input by the user via the manual setting screen. After that, the CPU 203 proceeds to step S<b>319 and transmits the setting packet to the communication device 101 .

By receiving the setting packet created as described above, the communication device 101 can connect to the access point corresponding to the information input by the user. Further, since the setting packet includes information about the frequency band, the communication device 101 can specify which frequency band should be used to connect to the access point corresponding to the information input by the user.
<Fourth embodiment>
In the above description, the communication device 101 is assumed to support at least one of the 2.4 GHz and 5 GHz frequency bands, but is not limited to this form. That is, any frequency band may be used as the frequency band with which the communication apparatus 101 is compatible. Also, the communication device 101 may support three or more frequency bands.

Also, the CPU 203 may execute the AP search result acquisition process of S315 and S316 before S306 and S307. Then, the CPU 203 may execute S306 and S307 when information on the access point 103 to which the information processing apparatus 102 is wirelessly connected is included in the acquired AP search result. In that case, first, before S306 and S307, wireless connection is established with the communication apparatus 101 in S312, and AP search result acquisition processing is executed. If the acquired AP search result does not include information on the access point 103 to which the information processing apparatus 102 is wirelessly connected, the CPU 203 may display the access point selection screen as in S317 without executing S307. Then, the CPU 203 may specify the access point selected via the access point selection screen as the access point to which the communication device 101 is to be connected.

Alternatively, the CPU 203 may execute the AP search result acquisition process of S315 and S316 instead of the processes of S308 and S309, and display information based on the setting information acquired by the AP search result acquisition process on the access point selection screen in S310. Also in this case, before S308 and S309, wireless connection with the communication apparatus 101 is performed in S312 to execute AP search acquisition processing. Also, by executing S701 and S702 instead of S308 to S310, a setting packet may be generated based on information manually input by the user.

The object of the present invention is also achieved by the following aspects. A recording medium recording a software program that implements the functions of the above-described embodiments is supplied to a system or apparatus, and the computer (including CPU and MPU) of the system or apparatus reads and executes the program stored in the recording medium. In this case, the program itself read from the storage medium implements the functions of the above-described embodiments, and the storage medium storing the program constitutes the present invention.

Examples of storage media for supplying programs include flexible disks, hard disks, optical disks, magneto-optical disks, CD-ROMs, CD-Rs, magnetic tapes, non-volatile memory cards, ROMs, and DVDs.

Further, the functions of the above-described embodiments are realized by executing the program read by the computer. However, in addition to this form, the present invention also includes a form in which the OS or the like running on the computer performs part or all of the actual processing based on the instructions of the program, and the functions of the above-described embodiments are realized by the processing.

First, a program read from a storage medium is written into a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer. After that, based on the instructions of the program, the CPU or the like provided in the function expansion board or function expansion unit performs part or all of the actual processing, and the processing implements the functions of the above-described embodiments. Such forms are also included in the present invention.

Claims (20)

In the computer of the information processing device that can communicate with the communication device,
a first control step of executing, when the information processing device is connected to an access point at a predetermined timing, setting information used for wirelessly connecting to a first access point, which is the access point to which the information processing device is connected at the predetermined timing, and frequency band information related to a frequency band used for wirelessly connecting to the first access point, to the communication device as control executed based on the fact that the information processing device is connected to the access point;
a second control step of executing control for transmitting to the communication device, if the information processing device is not connected to an access point at the predetermined timing, setting information used for wireless connection with a second access point searched and displayed by the information processing device and selected by the user, and frequency band information related to a frequency band used for wireless connection with the second access point, to the communication device as control executed based on the fact that the information processing device is not connected to the access point;
and
The frequency band corresponding to the frequency band information transmitted to the communication device, out of the first frequency band and the second frequency band, is used, and the communication device connects to an access point corresponding to the setting information transmitted to the communication device. a third control step of performing control for transmitting to the communication device configuration information used for wireless connection with a third access point found by a search performed by the communication device and selected by the user;
2. The program according to claim 1, further causing the execution of 3. The program according to claim 2, wherein in said third control step, frequency band information regarding a frequency band used for wireless connection with said third access point is further transmitted. The frequency band information is transmitted in the first control step and the second control step,
3. The program according to claim 2, wherein in said third control step, frequency band information regarding a frequency band used for wireless connection with said third access point is not transmitted. The program according to any one of claims 2 to 4, wherein the first control step or the second control step is executed when the communication device does not have a network interface for wireless communication, and the third control step is executed when the communication device has a network interface for wireless communication. a receiving step of receiving input from a user of setting information used for wireless connection with any access point and frequency band information relating to the frequency band used for wireless connection with any of the access points;
a fourth control step of executing control for transmitting the setting information and the frequency band information corresponding to the accepted input to the communication device;
2. The program according to claim 1, further causing the execution of 7. The program according to claim 6, wherein the first control step or the second control step is executed when the information processing device has a network interface for wireless communication, and the fourth control step is executed when the information processing device does not have a network interface for wireless communication. 8. The program according to any one of claims 1 to 7, wherein the first control step and the second control step are not executed when the information processing apparatus does not have a network interface for wireless communication. 9. The program according to any one of claims 1 to 8, wherein the setting information and the frequency band information are transmitted by wireless communication complying with IEEE 802.11 series standards. 10. The program according to any one of claims 1 to 9, wherein said frequency band information is information on a communication channel corresponding to a frequency band used for wireless connection with said access point. 11. The program according to any one of claims 1 to 10, wherein said setting information includes at least one of an SSID of said access point and a password used for connecting to said access point. When the setting information and the frequency band information are transmitted, the frequency band corresponding to the frequency band information transmitted to the communication device is preferentially used from among the first frequency band and the second frequency band, and the communication device searches for an access point corresponding to the setting information transmitted to the communication device,
12. The program according to any one of claims 1 to 11, wherein the access point found by the communication device and the communication device are connected according to the setting information by using the frequency band used for searching for finding the access point corresponding to the setting information transmitted to the communication device. When the setting information and the frequency band information are transmitted, out of the first frequency band and the second frequency band, the frequency band corresponding to the frequency band information transmitted to the communication device is used, and the access point corresponding to the setting information transmitted to the communication device is searched by the communication device. 13. The program according to any one of claims 1 to 12, wherein an access point corresponding to setting information is not searched by said communication device. 14. The program according to any one of claims 1 to 13, wherein the first frequency band is a frequency band of 2.4 GHz and the second frequency band is a frequency band of 5 GHz. 15. The program according to any one of claims 1 to 14, wherein the communication device is a printing device capable of printing with ink. further executing a determination step of determining whether the information processing device is connected to an access point;
The control executed based on the fact that the information processing device is connected to the access point is the control executed based on the determination that the information processing device is connected to the access point,
16. The program according to any one of claims 1 to 15, wherein the control executed based on the fact that the information processing device is not connected to the access point is the control executed based on the determination that the information processing device is not connected to the access point. Control for transmitting setting information used for wireless connection with the first access point and frequency band information regarding the frequency band used for wireless connection with the first access point to the communication device includes control for generating a packet including setting information used for wireless connection with the first access point and frequency band information regarding the frequency band used for wireless connection with the first access point;
17. The program according to any one of claims 1 to 16, wherein the control for transmitting setting information used for wireless connection with the second access point and frequency band information regarding the frequency band used for wireless connection with the second access point to the communication device includes control for generating a packet including setting information used for wireless connection with the second access point and frequency band information regarding the frequency band used for wireless connection with the second access point. Control for transmitting setting information used for wireless connection with the first access point and frequency band information related to the frequency band used for wireless connection with the first access point to the communication device includes control for transmitting a packet including setting information used for wireless connection with the first access point and frequency band information related to the frequency band used for wireless connection with the first access point;
The program according to any one of claims 1 to 17, wherein the control for transmitting setting information used for wirelessly connecting with the second access point and frequency band information regarding the frequency band used for wirelessly connecting with the second access point to the communication device includes control for transmitting a packet including setting information used for wirelessly connecting with the second access point and frequency band information regarding the frequency band used for wirelessly connecting with the second access point. A control method for an information processing device capable of communicating with a communication device,
a first control step of executing, when the information processing device is connected to an access point at a predetermined timing, setting information used for wirelessly connecting to a first access point, which is the access point to which the information processing device is connected at the predetermined timing, and frequency band information related to a frequency band used for wirelessly connecting to the first access point, to the communication device as control executed based on the fact that the information processing device is connected to the access point;
a second control step of executing control for transmitting to the communication device, if the information processing device is not connected to an access point at the predetermined timing, setting information used for wireless connection with a second access point searched and displayed by the information processing device and selected by the user, and frequency band information related to a frequency band used for wireless connection with the second access point, to the communication device as control executed based on the fact that the information processing device is not connected to the access point;
has
A control method, wherein a frequency band corresponding to the frequency band information transmitted to the communication device is used from among a first frequency band and a second frequency band, and the communication device connects to an access point corresponding to the setting information transmitted to the communication device. An information processing device capable of communicating with a communication device,
a first control means for executing, when the information processing device is connected to an access point at a predetermined timing, setting information used for wireless connection with a first access point, which is the access point to which the information processing device is connected at the predetermined timing, and frequency band information regarding a frequency band used for wireless connection with the first access point, to the communication device as control executed based on the fact that the information processing device is connected to the access point;
a second control means for executing, when the information processing device is not connected to an access point at the predetermined timing, setting information used for wireless connection with a second access point searched by the information processing device and selected by the user, and frequency band information regarding a frequency band used for wireless connection with the second access point, to the communication device as control executed based on the fact that the information processing device is not connected to the access point;
has
An information processing device, wherein the frequency band corresponding to the frequency band information transmitted to the communication device is used from among a first frequency band and a second frequency band, and the communication device connects to an access point corresponding to the setting information transmitted to the communication device.

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