JP2008199463A - Network connection method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a network connection method in which a variable gain amplifier is adopted to an amplifier for transmission as a method for restricting transmission distance of a communication signal of radio access connection and by which gain is sharply suppressed only in restriction of transmission power. <P>SOLUTION: In the network connection method for connecting a radio electronic device to a radio network via restricted radio access connection, the transmission power is sharply suppressed in restriction as a restriction method of radio access and the variable gain amplifier to the amplifier for transmission as a means for suppressing the transmission power is adopted in that case. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a network connection method for connecting a wireless electronic device to a wireless network via a restricted wireless access connection.

  A wireless network connection method performed by restricted wireless access connection is disclosed in Patent Document 1. According to this, by restricting the communication distance of the wireless access connection, it is possible to prevent the communication signal of the wireless access connection from reaching another room in, for example, a neighbor or an office and leaking network information to the outside. A technique for ensuring the security of the system is disclosed.

For example, when considering a wireless network communication connection setting method using Diffie Hellman method encrypted communication, Diffie Hellman method is a key exchange method for securely transmitting and receiving a secret key using an insecure communication path. The key information used for both encryption and decryption of the ciphertext needs to be shared by both the sender and the receiver, and the problem is how to securely pass this secret key to the other party. Patent Document 1 is a technology that provides a safe environment in which a wireless access connection is restricted in order to safely pass a secret key to a partner so that the secret key is not eavesdropped from another room in a neighboring house or office.
JP 2004-80755 A

  However, since Patent Document 1 does not disclose any technology for limiting the transmission distance of communication signals for wireless access connection, it is technically impossible to limit the transmission distance of communication signals for wireless access connection.

  The present invention has been made in view of such circumstances, and as a method for limiting the transmission distance of a communication signal for wireless access connection, a variable gain amplifier is employed as a transmission amplifier, and gain is greatly increased only when transmission power is limited. An object of the present invention is to provide a network connection method that can be suppressed.

  The present invention relates to a network connection method for connecting a wireless electronic device to a wireless network via a restricted wireless access connection, and as a wireless access restriction method, the transmission power is greatly suppressed at the time of restriction, and the transmission power at that time As a means for suppressing this, a variable gain amplifier is adopted as a transmission amplifier.

  Also, a network connection method for connecting a wireless electronic device to a wireless network via a restricted wireless access connection, which significantly reduces transmission power at the time of restriction as a wireless access restriction method, and suppresses transmission power at that time A variable gain amplifier is adopted as a transmission amplifier as a means for performing the exchange, and an encryption key that can be known only by the wireless electronic device and the wireless control device is exchanged through a restricted wireless access connection, and this encryption key is used. Encrypted communication is performed.

  A network connection method for setting a wireless electronic device to connect to a wireless network, wherein the wireless electronic device receives first network information for connecting to the wireless network via a restricted wireless access connection. The step of transmitting to the wireless control device (step 1), and the wireless control device transmits second network information necessary for connecting the wireless electronic device to the network via the restricted wireless access connection. And a step of changing a wireless access connection restriction state after setting wireless connection between the wireless electronic device and the wireless control device using the two network information (step 3). As a wireless access restriction method, the transmission power is greatly suppressed at the time of restriction, and the transmission power at that time is suppressed. It is obtained by employing the variable gain amplifier to the transmission amplifier as that means.

  A network connection method for setting a wireless electronic device to connect to a wireless network, wherein the wireless electronic device receives first network information for connecting to the wireless network via a restricted wireless access connection. The step of transmitting to the wireless control device (step 1), and the wireless control device transmits second network information necessary for connecting the wireless electronic device to the network via the restricted wireless access connection. And a step of changing a wireless access connection restriction state after setting wireless connection between the wireless electronic device and the wireless control device using the two network information (step 3). And the first and second networks in the restricted wireless access connection environment after step 2. Step 4 for confirming that the exchange of the network information is performed correctly, Step 5 for changing the wireless access restriction method until the confirmation is obtained, and the wireless electronic device and the wireless control device after the confirmation is obtained. Step 6 of exchanging an encryption key that only two parties know is added via a restricted wireless access connection. After the exchange of the encryption key is completed and the wireless connection setting is completed, the restricted wireless access is performed. It has step 3 which cancels | releases the restriction | limiting of a connection.

  Further, as a method of restricting the radio access, a variable gain amplifier is adopted as a transmission amplifier as means for significantly suppressing transmission power at the time of restriction and suppressing transmission power at that time.

  As a method for limiting the transmission power, the steps 1 and 2 are performed until the exchange of network information exchanged between the wireless electronic device and the wireless control device is completed while gradually increasing the gain of the variable gain amplifier from 0. It is something to be repeated.

  Further, as a method of limiting the transmission power, instead of using a variable gain amplifier, a fixed gain amplifier and a variable attenuator inserted before or after it are used, and the attenuation of the attenuator is increased only when the transmission power is limited. It is a thing.

  Further, as a method for limiting the transmission power, steps 1 and 2 are performed until the exchange of network information exchanged between the wireless electronic device and the wireless control device is completed while gradually decreasing the attenuation value of the variable attenuator from the maximum value. Are repeated.

  Further, as a method of limiting the transmission power, the antenna switch is used in a transmission OFF state at the time of limitation instead of using a variable amplifier.

  Further, as a method of limiting the transmission power, instead of using a variable amplifier, a new output is obtained by multiplying the output amplitude value at the output end of the digital signal processing unit that generates the transmission baseband signal by a coefficient less than 1. By setting a value, the transmission power is limited.

  In the network connection method according to any one of claims 1 to 10, the transmission power of only one of the wireless electronic device and the wireless control device is limited.

  Therefore, according to the present invention, it is possible to obtain a restricted radio access connection environment by adopting a variable gain amplifier as a transmission amplifier.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  First, examples of alternative wireless communication protocols and techniques compatible with embodiments of the invention include, but are not limited to, ultra wideband radio (UWB), IEEE (Institute of Electrical and Electronics Engineers) 1394 radio implementation (“radio Firewire "), IEEE 802.11a, IEEE 802.11b (" Wi-Fi ", IEEE 802.11g, IEEE 802.15 (WPAN), Bluetooth, WirelessUSB, and RS-232 protocols are included.

  FIG. 1 shows an example of an embodiment relating to a system for managing and controlling a wireless network of electronic devices.

  This system has an office apparatus including a main server 100 having a display 101, printers 102 and 104, a scanner 106, and a fax machine 108. The system also includes portable terminals 110 and 112, entertainment device 114, home appliance 116, and environmental control device 118. As can be seen from FIG. 1, each of the devices 100-118 has an antenna represented on the main server 100 by a numbered symbol such as 121. In addition, one or all of the devices 100-118 are provided with access to the Internet 120, as further described below.

  The primary server 100 is a workstation, desktop computer or other suitable network node that provides management of computer and network resources from a single point of management. The main server has a wireless transceiver device that allows the main server 100 to transfer files and other data to other wireless electronic devices 102-118 via an antenna 121.

  Thus, the main server 100 provides a server function within a wireless local area network (LAN) that includes the electronic devices 102-118 of FIG. 1 as clients. The LAN is a bus, hub or other network type and has a firewall (not shown). A firewall is a hardware device or software that allows only authorized computers on one side of the firewall to connect to a network or computer on the other side of the firewall. A firewall is a known and commercially available device or software (eg, SunScreen and Firewall 1 from Sun Microsystems).

  The main server 100 is a general purpose computer, such as the computer of FIG. 2 (described below), including network operating system (NOS) software, such as Windows NT (registered trademark), Unix (registered trademark), Linux, or Novell Network. May be performed using:

  The primary server 100 may include a login server application, such as a Nobel Directory Service (“NDS”), which is a product that manages access to a computer network. Using NDS, the network administrator. Set up and control the user's database and manage them using a directory with a graphic user interface. Using NDS or the main server 100, users of computers and other devices can be remotely connected, updated and centrally managed. Login operations to the network are typically controlled by scripts that are executed or translated. As a directory service, Microsoft® Active Directory can be used instead of the Nobel Directory Service. In addition, any suitable software and / or hardware may be used to help control access to network resources and management of network resources.

  Main server 100 may also include a file server, an email server, and an Internet server application, if desired. The file server application allows files included in the main server 100 to be accessed by the devices 102-118.

  The e-mail server may be used to manage and control e-mail accounts on the network and allow Internet e-mail to be sent and received via the Internet 120. The internet server allows access to the internet 120. If desired, an Internet server may be used to allow browsing the World Wide Web, enable file transfer using a file transfer protocol, and such as mobile terminals 110 and 112 It may be possible to send and receive Internet electronic mail messages from any suitable network node.

  In addition to the server application described above, the main server 100 manages and controls the main server 100 and, in particular, each device connected to the entertainment device 114, the home appliance 116 and the environmental device 118. Includes applications. For example, the main server 100 may include software that automatically controls the thermostat or provides a uniform means of manually controlling each electronic device on the wireless LAN 150 as further described below.

  The LAN 150 office device is illustrated by the dashed circle in FIG. 1 and provides all the functionality of a conventional device that may be associated with a home or work office. For example, printers 102 and 104 may be implemented as impact or non-impact printers for printing text or images on print media. Similarly, the scanner 106 and the fax machine 108 may also provide conventional optical scanning and facsimile transmission functions, respectively.

  Regardless of these conventional functions, the printers 102 and 104, the scanner 106, and the fax machine 108 of the present invention are provided with wireless transceivers suitable for communicating with the main server 100 via respective antennas. . In this regard, a special server application, such as a print server, is provided on the main server 100 to allow all terminals on the network to share office equipment with printers 102 and 104 in general. ing.

  The portable terminals 110 and 112 function as portable computer terminals having transceivers that allow wireless access to the main server 100. The terminal is preferably a dumb terminal having only the minimum hardware necessary to access the main server 100, but a thin or fat having local hardware devices required for independent operation according to the user's requirements. It may be a client.

  in this way. Each mobile terminal 110 and 112 uses the resources of the main server 100. For example, either the portable terminal 110 or 112 can use the printers 102 and 104, the scanner 106, or the fax machine 108. Similarly, the mobile terminals 110 and 112 can access files and software applications stored in the main server 100 local storage. Since the terminals are wirelessly accessible and share the resources of the main server 100, they can be easily moved to any location within the wireless LAN 150 coverage area. In the preferred embodiment, this coverage can be adjusted to the desired size, as further described below.

  The entertainment device 114 may be one of a variety of electronic devices used to provide entertainment to the user. For example, entertainment device 114 may be a television, stereo, video game, video cassette recorder (VCR), digital video disc (DVD) player, compact disc (CD) player, or other electronic device that amuses the user. The functionality of these devices is well known in the prior art, and the entertainment device 114 of the present invention is provided with a transceiver suitable for allowing wireless communication with the main server 100 via the antenna 121.

  As described above, the entertainment device 114 is connected to the wireless LAN 150. In one embodiment of the present invention, the main server 100 includes software for managing and controlling the entertainment device, as described below.

  Home appliance 116 represents an electronic device that performs some physical work for a user of the home appliance. The appliance 116 is a dishwasher, coffee maker, refrigerator, washing machine or dryer, or other similar device. Home appliance 116 is also equipped with a transceiver that provides wireless communication with main server 100 via antenna 121 and is therefore connected to LAN 150. Like the entertainment device 114, the home appliance 116 is managed and controlled by the main server 100.

  The environmental control device 118 is found at home or at work, and controls the environment of such a place. For example, the environmental control device 118 may be a thermostat that controls the air conditioning of a home or building, a lighting device, a ceiling fan, a ventilation fan or an exhaust device, a humidity control device, or a similar device. Along with the other devices in FIG. 1, the environment control device 118 is provided with a transceiver that allows wireless communication via the antenna 121, and is thereby connected to the wireless LAN 150.

  As described above, the receivable range of the wireless LAN 150 is set to a predetermined range. In particular, in the preferred embodiment, the transceiver of the main server 100 has adjustable signal strength characteristics. By adjusting the output power of the primary server 100, a user can deploy a network node (ie, an electronic device) and maintain the network connection and share the resources of the primary server 100. Control the range within which 100 can communicate. In this regard, the transceivers of electronic devices 102-118 also have adjustable transmit power characteristics. In the preferred embodiment, the electronic devices 102-118 have an automatic adjustment feature that adjusts the transmit power based on the detected signal strength of the signal transmitted from the main server 100. Any known method or apparatus for detecting signal strength can be used to implement this aspect of the invention.

  As described above, the wireless network of FIG. 1 applies to a home or work environment. FIG. 2 shows the wireless LAN of the present invention running in a home environment.

  As can be seen, the house 216 has rooms 218, 220, 222, 224, 226, and 228 that are separated by walls or other physical structures. A room 218 of the house 216 includes a main server 200, a laser printer 202, and a scanner 204, and functions as a home office. The main server 200 is shown as a desktop computer with limited portability, but can be implemented as any general purpose computer such as the computer of FIG.

  Further, the main server 200 is connected to the Internet 120. Room 220 has desktop computer 206, while rooms 222 and 228 have portable terminals 208 and 212, respectively. Like the mobile terminal of FIG. 1, the mobile terminals 208 and 212 are preferably dumb terminals, which provide the light weight and small size desirable to increase portability. Room 224 has a refrigerator 210 and room 226 has a VCR 214.

  As in the system of FIG. 1, each of the devices of FIG. 3 has an antenna that allows the respective electronic device to be connected to a wireless network controlled by the main server 200. Thus, although laser printers 202 and 204 are shown in room 218, these devices may be located in other rooms within house 216 and maintain further communication with main server 200. To do. Further, the transmission power of the wireless device of FIG. 3 can be adjusted to control the network coverage. 3 is connected to a wireless LAN controlled by the main server 200, each electronic device in FIG. 3 can share the resources of the main server 200. In addition, the main server 200 has software for managing and controlling electronic devices on the home wireless network of FIG.

  FIG. 4 is a diagram showing a wireless LAN of the present invention executed in a work environment. Workplace 327 is within office building 326 and has rooms 328, 330, 332, 334, 336, 338, 340, 342, and 344 separated by walls or other physical structures. Room 336 has a main server 300, a printer 302, and a database 304 with the main server 300 connected to the Internet 120. The main server 300 and the printer 302 are the same as the respective apparatuses described in FIGS. 1 and 3.

  The database 304 is a file having a record for executing the work of the workplace 327. Rooms 328, 338, and 344 have mobile terminals 306, 324, and 316, respectively, and room 328 also has a printer 308. Room 332 has a desktop computer 312 and room 342 has a workstation 318 and a printer 320. The workstation 318 is similar to a portable terminal in that it relies heavily on the hardware of the main terminal 300 for operation, but the workstation 318 is a graphics and other special purpose provided by the main server 300. Has a relatively large monitor suitable for displaying software applications. Alternatively, the workstation 318 may be a powerful machine that has the processing power to interact with the disks and resources of the primary server 300.

  FIG. 5 shows a flow diagram of an exemplary start of a main server and establishment of a wireless LAN in accordance with the present invention. The processing steps of FIG. 5 are described with respect to wireless network 150 of FIG. As described above, each electronic device in FIG. 1 has an antenna for wireless communication. Thus, for all steps of FIG. 5 where data packets are sent between different devices, the data packets are transmitted wirelessly. Data packets may be encrypted for secure transmission.

  Step 400 shows the start of the system when the user powers on the main server 100. When the main server 100 is turned on, the main server must recognize all electronic devices that are turned on and can be connected to the wireless LAN 150. In step 402, the main server 100 examines information stored for all electronic devices that can exist in the wireless network 150.

  In this embodiment, the stored list is entered by a user of LAN 150 as the wireless device is connected to the LAN. In step 404, the primary server 100 transmits a data packet to each electronic device identified in step 402 to determine which electronic devices are actually within range of the wireless network 150.

  The data packet at step 404 includes, for example, the only identifier accessed at step 402 so that each electronic device can determine that it is being contacted by the main server 100.

  In step 406, each electronic device that is powered on and within range of the wireless network 150 responds to the request made by the primary server 100 in step 406. Each electronic device transmits to the main server 100 a data packet containing data indicating that the device is powered on and operating.

  Of course, only an electronic device that is within the signal range of the main server 100 and has sufficient output power to communicate with the main server 100 can send a response to the main server 100. Once the main server 100 has information about the status of each electronic device and terminal, at step 408, the main server 100 maintains information about the electronic device that is powered on and operating within the wireless LAN 150. In step 410, the main server 100 monitors the management start parameter and waits for a processing request from an electronic device connected to the wireless LAN 150.

  FIG. 5 shows processing for starting the main server 100 and establishing the wireless network 150. This process is performed using a medium access control (MAC) protocol. The MAC protocol is a protocol used in multiple access links that guarantees that only one device has access to a shared link at a time. The MAC protocol effectively assigns a talking time to each device on the network. For example, the MAC protocol typically divides one data frame into several time slots. Each device in the network transmits information in a specific time slot and receives it in all other slots of the frame.

  Since each device has a fixed amount of bandwidth, ie a fixed number of data bits that can be transmitted per second under the MAC protocol, a fixed amount of data can be transmitted in the device's time slot. A common MAC protocol used in wireless bridges is carrier sense multiple access / collision avoidance (CSMA / CA). Different MAC protocols perform the steps of FIG. 5 in different ways.

  For example, in one embodiment of the present invention, the MAC protocol of the main server 100 causes the main server to periodically send a “connection message” requesting that a new electronic device connect to the network. , Update the network. In other embodiments, the MAC protocol establishes a new link only if it sends a connection message and is prompted to do so by a new remote electronic device.

  In yet another embodiment, the primary server 100 keeps a count of the number of remote electronic devices with which a network link has been established, and the MAC protocol sends a connection message if the count does not exceed the maximum number. Only send a connection message. The maximum number is based on the bandwidth limit of the primary server 100 or is programmable by the primary server user.

  Examples of multiple access protocols include the IEEE 802.11 standard, whose final draft was approved on June 26, 1997, and the V.I. 1. OB, the Bluetooth specification of “Specification of the Blue Tooth System”, the entire contents of which are incorporated herein by reference. The features and benefits of the present invention are not dependent on a particular MAC protocol, and the above named protocol or any other MAC protocol may be used in the practice of the present invention as will be understood by those skilled in the art. It will be understood that you get.

  FIG. 8 is a flowchart illustrating a process of using a control device to connect a wireless electronic device to a wireless LAN. FIG. 16 is described with respect to an example of using the controller 800 to connect the wireless electronic device 1520 to the network associated with the A device 1500, but it is understood that the invention is not limited to this particular example. The The process begins at step 1601, where the user selects a function selection box 1420 on the control device 800 to connect the device to the network. This operation prompts the control device 800 to wait for a setting request for the wireless electronic device. In step 1603, the wireless electronic device transmits a setting request to the control device 800. The setting request includes information necessary for the control device 800 to set the wireless electronic device 1520 on the network. For example, this request includes not only the identifier of the format of the wireless electronic device making the request, but also the IP address / DHCP information, the netmask, and the network to which the wireless electronic device is to be connected (the network of the A device 1500 in the above example). Contains an identifier. In the preferred embodiment of the present invention, the configuration request sent from the wireless electronic device 1520 also includes a request for optional network services. An optional network service is a network service that is not required for the wireless electronic device 1520 to connect to the network associated with the A device 1500, such as encryption, backup storage, or other similar function.

  The setting request is either a request sent via a wired medium or a wireless request. If the request is transmitted over a wired medium, the user must physically connect the controller 800 to the wireless electronic device 1520 via a cable or special purpose connection port. Because of this wired connection, access to the wireless electronic device 1520 is limited to control devices that are actually connected to the wireless electronic device 1520. If the configuration request is sent wirelessly, the wireless electronic device 1520 may continuously transmit the configuration request or receive a prompt from the control device 800 when power is applied to the wireless electronic device 1520. The request may be sent only after it is received. Furthermore, the wireless electronic device 1520 transmits a wireless setting request with low power that limits the communication range of the wireless electronic device as indicated by a circle 1521 in FIG.

  Thus, the limited communication range limits the wireless electronic device 1520 to access to a controller within the reduced power communication range. In a preferred embodiment, the reduced power provides a limited communication range, for example 1 meter. By limiting the communication range of the wireless electronic device, the wireless electronic device can be connected wirelessly with one of these A devices 1500 and B devices 1510 enabled by the control device 800 before the A device 1500 and B device. Network communication related to 1510 is not possible.

  Once the wireless electronic device 1520 has sent a configuration request, the controller 800 receives the configuration request and connects the wireless electronic device 1520 to the requested network, as shown in step 1605. Generate a data package of necessary network information.

  The network information package is identified by the wireless electronic device 1520 in the configuration request, as well as the IP address / DHCP information, netmask, and software compatible with the wireless electronic device type identified in the configuration request. Includes network wireless communication protocols. In particular, the network information includes a communication encoding mechanism that allows the wireless electronic device 1520 to communicate only with the A device 1500 and not with the B device 1510 that includes a different encoding mechanism. In addition, if the configuration request includes a request for an optional network service, the controller 800 also includes the software tools necessary to perform the requested optional network service in the data package.

  Once the network information data package is generated, the controller 800 sends the data package to the wireless electronic device 1520 as shown in step 1607. As with the setup request, the network information data package can be sent wirelessly or over a wired medium.

  In step 1609, the wireless electronic device 1520 uses the received network information to connect to the network identified in the configuration request. As described above, the network information supplied to the wireless electronic device 1520 includes an encoding mechanism that allows the wireless electronic device 1520 to communicate wirelessly only with the network identified in the configuration request.

  Thus, returning to the previous example, in step 1609, the wireless electronic device 1520 establishes a wireless link with the network associated with the A device 1500. In the preferred embodiment, the wireless electronic device 1520 communicates with the network with the highest transmission power. Thus, if the exchange of data between the wireless electronic device 1520 and the control device 800 occurs wirelessly with reduced power as described above, step 1609 is indicated by the dashed circle 1522 in FIG. It also includes increasing the output power of the wireless electronic device 1520 to the maximum range of the wireless electronic device being connected. The encoding mechanism used by the wireless electronic device 1520 ensures that only such devices connect to the network of the A device 1500.

  The configuration of the wireless module in the wireless electronic device and the wireless control device for implementing the network connection method of the present invention will be described with reference to FIG. The wireless module according to the present invention includes a device interface 1111, a medium access control layer (MAC) 1101, a baseband 1102, an AD / DA converter 1103, an RF IC 1104, and an antenna 1105. Reference numerals 1108, 1109, and 1110 are amplifiers.

  In addition, a configuration example of a wireless electronic device and a wireless control device for implementing the network connection method of the present invention will be described with reference to FIG. The wireless module 1201 is controlled by the CPU 1201 via the system bus 1204, or all or part of the wireless network communication protocol. Data transmitted by wireless network communication is encrypted using an encryption key stored in the storage device 1203.

  The storage device 1203 has a nonvolatile memory function, and stores a host ID and a device ID used in WirelessUSB. The storage device 1203 has a RAM function, and stores key information exchanged by the Diffie Hellman method. The wireless electronic device and the wireless control device according to the present invention can include an input device 1205 such as a keyboard and buttons, and a display device 1204 such as an LED (light emitting diode) and a display.

  Further, a first configuration example of the wireless module in the wireless electronic device and the wireless control device for carrying out the network connection method of claims 1, 3, 5, and 6 will be described with reference to FIGS. In the first configuration example, at least one or all of the amplifiers 1108, 1109, and 1110 in FIG. 10 are variable gain amplifiers. This variable gain amplifier is a variable gain amplifier realized by a reconfigurable analog circuit capable of changing an output voltage waveform or a voltage gain, or a configuration utilizing the fact that the conductance of a MOS transistor changes depending on a bias current. The constituent requirements of the variable gain amplifier are not claimed by the present invention.

  Further, a second configuration example of claims 7 and 8 will be described with reference to FIGS. At least one or all of the amplifiers 1108, 1109, and 1110 in FIG. 10 are configured with a variable attenuator 1602 at the subsequent stage of the fixed amplifier 1601 as shown in FIG. Note that the variable attenuator 1602 may be arranged before the fixed amplifier 1601.

  Note that the control signals of the amplifiers 1108, 1109, and 1110 in the first configuration example and the second configuration example are connected to the system bus 1204, and the CPU 1201 controls the suppression of gain when the transmission power is limited. Further, the control signals of the amplifiers 1108, 1109, and 1110 in the first configuration example and the second configuration example are controlled by the CPU 1201 via the MAC 1111 and the BB 1102 to suppress the gain suppression when the transmission power is limited. Also good. The suppression of the gain of the transmission amplifier described in claims 3 and 5 to 8 takes any one of these configurations.

  Further, a third configuration example of the wireless module in the wireless electronic device and the wireless control device for carrying out the network connection method of claim 1 will be described using FIG. 10 and FIG. FIG. 13 shows the internal structure of the MAC 1301, which has a power setting register 1302 for transmission. The output of the power setting register 1302 is connected to the control signals of the amplifiers 1108, 1109, and 1110 in FIG. 10, and gain control according to the register value of the power setting register 1302 is performed.

  Furthermore, a wireless network connection protocol in the wireless electronic device and the wireless control device for implementing the network connection method of claim 2 will be described with reference to FIG.

  When receiving the wireless network connection request from the wireless electronic device, the wireless control device limits the gain of the transmission amplifier and transmits the reception of the wireless network connection request to the wireless electronic device. In response, the wireless electronic device limits the gain of the transmitting amplifier. Then, a secret key is exchanged between the wireless control device and the wireless electronic device by, for example, the Diffie Hellman method. After the exchange of the secret key is completed, both the wireless control device and the wireless electronic device release the limitation on the gain of the transmission amplifier, and perform network information exchange and data communication by encrypted communication using the encryption key.

  Furthermore, a wireless network connection protocol in the wireless electronic device and the wireless control device for implementing the network connection method of claims 3 and 4 will be described with reference to FIG.

  1401 is a step (step 1) in which the wireless electronic device transmits first network information for connection to the wireless network to the wireless control device via the restricted wireless access connection. In this example, the first network is connected to the wireless network. As information, a device ID necessary for wireless USB wireless connection is transmitted.

  Reference numeral 1402 denotes a step (step 2) in which the wireless control device transmits second network information necessary for connecting the wireless electronic device to the network via the restricted wireless access connection. In this case, the host ID necessary for wireless USB wireless connection is transmitted as the second network information.

  1403 is a step (step 3) of changing the wireless access connection restriction state after setting the wireless connection between the wireless electronic device and the wireless control device using the two network information. The device ID and host ID transmitted and received in 1401 and 1402 may be implemented by encrypted communication using a secret key exchanged by the Diffie Hellman method.

  In a limited radio access connection, the gain of the transmitting amplifier is limited, and even if the distance between the radio electronic device and the radio control device is within 1 m, depending on the surrounding noise, signal reflection, and interference situation It is assumed that the exchange of the first network information and the second network information cannot be completed correctly.

  For this reason, when the gain of the transmission amplifier is always suppressed uniformly, the user fails to exchange the first network information and the second network information due to a change in the surrounding environment, and the user is confused or convenient. It will impair the sex.

  In order to avoid such a situation, the wireless network connection protocol according to the present invention includes a step of confirming whether or not wireless communication is correctly transmitted and received even in a situation where the gain of the transmission amplifier is limited. . In FIG. 14, by exchanging hello messages 1404 and 1405, it is confirmed that radio communication is correctly transmitted and received even in a situation where the gain of the transmission amplifier is limited.

  As an embodiment of claims 6 and 8, confirmation of whether or not wireless communication is correctly performed is confirmed by exchanging hello messages, and if exchanging of hello messages could not be completed within a certain time This is done by providing a step for relaxing the gain limitation of the transmitting amplifier. The flow will be described with reference to FIG.

  This processing flow is performed by the wireless control device. Reference numeral 1501 denotes reception of the wireless network connection request 1406 illustrated in FIG. 1502 is a step of limiting 1407 the gain of the transmission amplifier.

  Reference numeral 1503 denotes transmission of a hello message (1404). Reference numeral 1504 denotes a check of whether or not a hello message has been received (1405) from the wireless electronic device within a predetermined time. If a hello message from the wireless electronic device can be received within a predetermined time by this check, secret key transmission / reception and device ID / host ID exchange according to the Diffie-Hellman method shown in FIG. 14 are performed. If a time-out occurs in the check of 1504, the suppression of the gain of the transmission / reception amplifier is relaxed by the step 1506, and the process proceeds to the step 1503 until a hello message from the wireless electronic device can be received within a certain time in 1504. The suppression of the gain of the transmission / reception amplifier is gradually eased.

  In 1505, a range is set for the suppression value of the gain, and the repetition of the steps 1503 to 1505 and 1506 is performed within the range. If the range is exceeded, abort (1507) is performed. Particularly, in claim 6, the gain is suppressed to 0 at 1502, and the suppression of the gain is gradually eased every time the step 1506 is executed. Further, according to the eighth aspect, the gain is suppressed to the maximum at 1502, and the gain suppression is gradually relaxed every time the step 1506 is executed. In addition, as described in claim 11, it is possible to confirm whether or not the transmission / reception of the wireless communication is correctly performed by performing only the process of FIG. 15 by either the wireless control apparatus or the wireless electronic apparatus.

  An embodiment of claim 9 will be described with reference to FIGS. An antenna switch 1106 is shown in FIG. The antenna switch 1106 is ON / OFF controlled from the CPU 1201 via the system bus 1204. By configuring in this way, the antenna switch is limited by turning off the antenna switch separately from the suppression of the gain when the transmission power is limited by the amplifiers 1108, 1109, and 1110 shown in the first and second configuration examples. A wireless access connection environment can be obtained.

  An embodiment of claim 10 will be described with reference to FIG. In FIG. 10, reference numeral 1107 denotes a digital operational amplifier. The digital operational amplifier 1107 is configured to digitally generate an attenuation signal under the output terminal of a digital signal processing unit that generates a transmission baseband signal. The digital attenuation signal generating means can be realized, for example, by shifting a digital numerical value to the LSB side by 1 bit. By doing so, a result equivalent to performing power control of 0.5 times can be obtained. With this configuration, in addition to the suppression of gain at the time of transmission power limitation by analog processing by the amplifiers 1108, 1109, and 1110 shown in the first and second configuration examples, the power is obtained by digital processing by a digital operational amplifier. Implement control and obtain a restricted wireless access connection environment. In this case, it is not necessary to suppress the gain when limiting the transmission power by analog processing using the amplifiers 1108, 1109, and 1110 shown in the first and second configuration examples.

  As described above, a limited radio access connection environment can be obtained by adopting a variable gain amplifier as a transmission amplifier. In the transmission amplifier, the variable attenuator is arranged in the front stage or the rear stage of the amplifier, and the gain can be suppressed only when the transmission power is suppressed by the MAC or CPU for wireless network communication. When control is possible with the CPU, for example, when the PHY and MAC are composed of a single LSI, variable gain control during transmission can be realized by changing the design of the system board and hanging the transmission amplifier on the system bus. Therefore, there is an advantage that backward compatibility of LSI can be easily secured. On the other hand, when it is possible to control by MAC, it can be realized simply by changing only the wireless module, so there is an advantage that it is not necessary to change the system of the wireless control device or the wireless electronic device.

  Further, in an environment where transmission power is limited, whether or not network information necessary for wireless network connection can be exchanged between the wireless control device and the wireless electronic device is confirmed in advance by exchanging messages. If network information exchange is not feasible, it is possible to detect the gain suppression value of the transmission signal that can be exchanged by checking the message exchange while gradually relaxing the suppression of the gain of the transmission signal. I made it. By doing so, it is possible to prevent the occurrence of a situation where the wireless network connection can be correctly completed or cannot be performed depending on the environment such as noise and the reflection state of the signal, and the convenience of the user is not impaired.

  In restricted wireless access connections, the encryption key is exchanged before the gain suppression of the transmission signal is released, and the wireless network communication after the gain suppression of the transmission signal is released is encrypted using this encryption key. I try to communicate. A wireless access connection in which the gain of the transmission signal is suppressed limits the reach of wireless communication.For example, a transmission signal with a suppressed gain does not reach the neighbor's house or the adjacent room. Subsequent encrypted communication can be performed by the encryption key.

  Further, since the gain suppression of the transmission signal can be realized by turning on / off the antenna switch, it can be realized at low cost by providing only one switch without the need for a variable gain amplifier.

  In addition to controlling the transmission power by analog processing, the attenuation signal is digitally generated at the output end of the digital signal processing unit that generates the transmission baseband signal. It is not necessary to change the analog part in the wireless module for connection, and it can be easily realized by changing only the baseband part. In addition, since only the wireless module needs to be changed, the systems of the wireless control device and the wireless electronic device do not need to be changed, so that the degree of spread is high.

  In addition, since the implementation of the above configuration and protocol can be performed only on one side, not on both the wireless electronic device and the wireless control device, a restricted wireless access connection environment can be obtained. Since either one of the wireless control devices should be purchased again or changed, the degree of spread is high.

1 is a system diagram illustrating a system for managing and controlling a local network of electronic devices according to one embodiment of the present invention. FIG. FIG. 2 illustrates a general purpose computer system in which an embodiment according to the present invention may be implemented. It is a figure which shows the wireless LAN of this invention performed in a home environment. It is a figure which shows the wireless LAN of this invention performed in a work environment. 4 is a flowchart illustrating an exemplary start of a primary server establishing a wireless LAN, according to one embodiment of the present invention. 6 is a flowchart illustrating a process for managing an electronic device of a wireless home LAN according to an embodiment of the present invention. FIG. 6 is a flowchart illustrating a process of a mobile terminal accessing a resource of a main server according to an embodiment of the present invention. 6 is a flowchart illustrating a process according to the present invention that uses a controller to connect a wireless electronic device to a wireless LAN. It is a figure which shows the example of the environment where a control apparatus is used as a registration apparatus which connects a new electronic device to LAN. The block diagram for demonstrating the structure of the radio | wireless module in the radio | wireless electronic apparatus and radio | wireless control apparatus for implementing the network connection method of this invention. The block diagram for demonstrating the structural example of the radio | wireless electronic apparatus for implementing the network connection method of this invention, and a radio | wireless control apparatus. The block diagram which showed the structural example of the amplifier. The block diagram which showed the other structural example of the wireless module. 6 is a timing chart for explaining a protocol for wireless network connection in the wireless electronic device and the wireless control device. 6 is a timing chart for explaining another example of a wireless network connection protocol in the wireless electronic device and the wireless control device. The timing chart which showed an example of the procedure at the time of confirming whether the transmission / reception of radio | wireless communication is implemented correctly by exchanging a hello message.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Main server 102, 104 Printer 106 Scanner 108 Fax machine 110, 112 Portable terminal 114 Amusement device 116 Home appliance 118 Environment control device 120 Internet 121 Antenna 150 Wireless LAN
200 Main Server 202 Laser Printer 204 Scanner 206 Desktop Computer 208, 212 Mobile Terminal 300 Main Server 302 Printer 304 Database 306 Mobile Terminal 308 Printer 310 Coffee Maker 314 Lighting Control Device 318 Workstation 320 Printer 321 Antenna 322 Air Conditioning Unit 326 Office Building 327 Workplace 800 Controller 801 CPU
802 RAM
804, 1201 ROM
806 Display controller 808 Input controller 810 Display 815 Input keypad 830 Network parameter processor 840 Network name setting processor 850 Network service setting processor 860 Network parameter storage device 870 Registered network name storage device 880 Registered service information storage device 1108, 1109 , 1110 amplifier 1101 medium access control layer (MAC)
1111 Device Interface 1102 Baseband 1103 AD / DA Converter 1104 RF IC
1500 A device 1510 B device 1520 C device 1520 Wireless electronic device 1601 Fixed amplifier 1602 Variable attenuator 1801 Computer system 1805 Processor 1807 Main memory 1813 Display 1815 Keypad 1817 Cursor control 1819 Communication interface

Claims (11)

A network connection method for connecting a wireless electronic device to a wireless network via a restricted wireless access connection, comprising:
A network connection method for a wireless electronic device, wherein a variable gain amplifier is adopted as a transmission amplifier as means for suppressing transmission power at the time of restriction as a wireless access restriction method, and as means for suppressing transmission power at that time. A network connection method for connecting a wireless electronic device to a wireless network via a restricted wireless access connection, comprising:
As a wireless access restriction method, the transmission power is largely suppressed at the time of restriction, and a variable gain amplifier is adopted as a transmission amplifier as a means for suppressing the transmission power at that time,
A wireless electronic device comprising: a wireless electronic device and a wireless control device exchanging an encryption key that can be known only by a wireless access device through a restricted wireless access connection, and performing encrypted communication using the encryption key. Network connection method. A network connection method for setting a wireless electronic device to connect to a wireless network, comprising:
The wireless electronic device transmitting first network information for connection to the wireless network via the restricted wireless access connection to the wireless control device (step 1), and via the restricted wireless access connection; A step (step 2) in which the wireless control device transmits second network information necessary for connecting the wireless electronic device to the network to the wireless electronic device, and the wireless electronic device and the wireless device using the two pieces of network information. And a step (step 3) of changing the restricted state of the wireless access connection after performing the wireless connection setting between the control devices,
A network connection method for a wireless electronic device, wherein a variable gain amplifier is adopted as a transmission amplifier as means for suppressing transmission power at the time of restriction as a wireless access restriction method, and as means for suppressing transmission power at that time. A network connection method for setting a wireless electronic device to connect to a wireless network, comprising:
The wireless electronic device transmitting first network information for connection to the wireless network via the restricted wireless access connection to the wireless control device (step 1), and via the restricted wireless access connection; A step (step 2) in which the wireless control device transmits second network information necessary for connecting the wireless electronic device to the network to the wireless electronic device, and the wireless electronic device and the wireless device using the two pieces of network information. And a step (step 3) of changing a wireless access connection restriction state after performing wireless connection setting between control devices.
Step 4 for confirming that the exchange of the first and second network information is correctly performed in the environment of the restricted wireless access connection after Step 2;
Step 5 of changing the wireless access restriction method until the above confirmation is obtained;
Adding a step 6 of exchanging an encryption key, which is known only to the two of the wireless electronic device and the wireless control device after the above confirmation, through a restricted wireless access connection;
A network connection method for a wireless electronic device, comprising the step of releasing the restriction of the restricted wireless access connection after the exchange of the encryption key is completed and the wireless connection setting is completed.   5. The wireless electronic device according to claim 4, wherein, as the wireless access limiting method, transmission power is significantly suppressed at the time of restriction, and a variable gain amplifier is employed as a transmission amplifier as means for suppressing transmission power at that time. Device network connection method.   As a method for limiting the transmission power, steps 1 and 2 are repeated until the exchange of network information exchanged between the wireless electronic device and the wireless control device is completed while gradually increasing the gain of the variable gain amplifier from 0. The network connection method for a wireless electronic device according to claim 3 or 5, characterized in that:   As a method of limiting the transmission power, instead of using a variable gain amplifier, a fixed gain amplifier and a variable attenuator inserted before or after the amplifier are used, and the attenuation of the attenuator is increased only when the transmission power is limited. The wireless electronic device network connection method according to claim 1, claim 2, claim 3, claim 5, or claim 6.   As a method for limiting the transmission power, steps 1 and 2 are repeated until the exchange of network information exchanged between the wireless electronic device and the wireless control device is completed while gradually decreasing the attenuation value of the variable attenuator from the maximum value. The network connection method for a wireless electronic device according to claim 7.   7. The method of limiting transmission power, wherein an antenna switch is used in a transmission OFF state at the time of limitation instead of using a variable amplifier. Network connection method for wireless electronic devices.   As a method for limiting the transmission power, instead of using a variable amplifier, a new output value is obtained by multiplying the output amplitude value at the output end of the digital signal processing unit that generates the transmission baseband signal by a coefficient less than 1. The wireless electronic device network connection method according to claim 1, wherein the transmission power is limited by the above.   11. The network connection method according to claim 1, wherein the transmission power of only one of the wireless electronic device and the wireless control device is limited, not both.