JP2019009650A - Radio communication device and radio wave interference avoidance method - Google Patents

Abstract

To obtain a radio communication device which can achieve an avoidance function of radio wave interference with a radar device, and can prevent a standby state or a suspension state of a radio communication function.SOLUTION: A radio communication device includes a controller which performs an information acquisition function and a control function. The controller acquires information which is information related to an avoidance function of radio wave interference with a radar device and is set based on a position and a frequency band of a radar device. The controller determines, as a frequency to be used for radio communication, a use frequency excluding a frequency band having possibility of occurrence of radio wave interference with a radar device, using the information acquired by information acquisition means and position information of a self-device.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a wireless communication apparatus and a method for avoiding radio wave interference.

  In recent years, a wireless communication device such as a wireless LAN has been promoted to use a higher frequency for the purpose of large-capacity communication. For this reason, there is a high possibility that radio wave interference will occur between the wireless communication device and a radar device such as a weather radar because the frequency bands used by both devices overlap.

  Conventionally, in the case of a wireless LAN using a frequency band of 5 GHz, for example, the frequency band is also used in a radar device such as a weather radar, so that radio wave interference may occur. As a countermeasure for avoiding such radio wave interference, for example, a wireless LAN access point is equipped with a radio wave interference avoidance function generally called DFS (Dynamic Frequency Selection).

JP 2012-120033 A JP 2007-274659 A JP 2001-285301 A

  Although the DFS function is effective as a measure for avoiding radio wave interference, the wireless communication apparatus cannot execute transmission for a certain period of time by the DFS function at the time of activation, and therefore the communication function is in a standby state. Further, if the DFS function is activated when approaching the radar apparatus, the wireless communication apparatus may not perform transmission for a certain period of time but only receive, and the communication function may be suspended.

  The occurrence of such a standby state or interruption state of the wireless communication device is ignored by the user when, for example, a smartphone or a wireless LAN router is used as the wireless communication device to realize a car navigation function with a tablet terminal or the like. Inconvenience that can not be. Specifically, when the user moves such as a car, there is a possibility that the car navigation function cannot be used for a certain period of time after activation of the wireless communication device or for a certain period of time after activation. Further, as a matter of course, when the DFS function does not function effectively, there is a high possibility that radio wave interference occurs with the radar apparatus.

  Therefore, there is a problem of realizing a wireless communication apparatus that can realize a function of avoiding radio wave interference with the radar apparatus and can prevent a standby state or a suspended state of the wireless communication function.

  The wireless communication apparatus according to the present embodiment includes an information acquisition unit and a control unit. The information acquisition unit is information regarding a function of avoiding radio wave interference with a radar apparatus, and acquires the information set based on a position and a frequency band of the radar apparatus. The control unit uses the information acquired by the information acquisition unit and the position information of its own device as a frequency used for wireless communication, and selects a frequency band in which radio wave interference with the radar device may occur. Except for this, the operating frequency is determined.

The block diagram for demonstrating the structure of the radio | wireless communication apparatus regarding embodiment. The figure which shows an example of the table information regarding the embodiment. The figure which shows the partial specific example of the table information regarding the embodiment. 6 is a flowchart for explaining the operation of the wireless communication apparatus according to the embodiment. The block diagram for demonstrating the structure of the radio | wireless communication apparatus regarding the modification of the embodiment.

Embodiments will be described below with reference to the drawings.
[Configuration of wireless communication device]
FIG. 1 is a block diagram illustrating a configuration of a wireless communication apparatus according to the present embodiment. The wireless communication apparatus of the present embodiment is applicable to, for example, a wireless LAN access point (AP), a wireless LAN router, a smartphone, and the like.

  As shown in FIG. 1, the wireless communication device 10 of the present embodiment wirelessly communicates with a wireless terminal 15 and is connected to a communication line 16 such as a public communication line. The wireless terminal 15 is, for example, a portable information terminal such as a smartphone or a tablet terminal or a communication terminal. The wireless communication apparatus 10 can access the server 17 on the network via the communication line 16 and can receive radar information managed by the server 17 as described later.

  The wireless communication device 10 includes a controller 11 for realizing a function of avoiding radio wave interference with the radar device, in addition to a configuration (not shown) that realizes a normal wireless communication function. The controller 11 includes a processor and software, and includes a determination unit 14 that generates table information 12 and position information 13 and stores the table information 12 and position information 13 in a memory (not shown) and a function of determining a use frequency. .

  The table information 12 is information for executing a function of avoiding radio wave interference with the radar device, as will be described later with reference to FIGS. 2 and 3. The position information 13 is the position (coordinate information composed of longitude and latitude) of the own apparatus that is the wireless communication apparatus 10. The determination unit 14 determines a use frequency that is not affected by radio wave interference except for a frequency band in which radio wave interference with the radar apparatus may occur when performing wireless communication.

In the present embodiment, the server 17 stores radar information managed by, for example, an international organization, a government organization, or an industry group, and can provide the radar information in response to an access request from the wireless communication device 10. Suppose that The server 17 may be configured to provide the radar information to the wireless communication apparatus 10 that has been granted access permission through an authentication process using a predetermined password or the like.
[Operational effects of this embodiment]
Hereinafter, the operation of the wireless communication apparatus 10 according to the present embodiment will be described with reference to FIGS.

  FIG. 4 is a flowchart for explaining processing executed by the controller 11 of the wireless communication apparatus 10. First, the controller 11 accesses the server 17 via the communication line 16 and receives (acquires) radar information (step S1). Here, the controller 11 may acquire radar information when the wireless communication device 10 is activated, or may periodically access the server 17 to receive and store or update the radar information.

  The controller 11 uses or processes the radar information received from the server 17, creates table information 12 and stores it in the memory (step S2). Here, the radar information includes, for example, information indicating the specifications of the radar device (latitude and longitude indicating the installation position, center frequency of use frequency, bandwidth, antenna center altitude, operating elevation angle range, minimum reception sensitivity, etc.). .

  2 and 3 are diagrams illustrating an example of the table information 12. As shown in FIG. 2, the table information 12 is based on the installation position of the radar device, and the range on the map that causes radio wave interference to the radar device is divided into each mesh area by dividing the latitude and longitude by a constant step size. Is information that associates the coordinate information that defines the frequency with the frequency information related to the used frequency FT corresponding to the coordinates.

  As shown in FIG. 3, the frequency information 120 corresponds to a mesh area defined by coordinate information in a frequency band of, for example, 5 GHz used by the wireless communication device 10 and the radar device, and a frequency that causes radio wave interference to the radar device. And a frequency band to which a flag for identifying a frequency that is not affected by radio wave interference is added. Here, the flag “1” indicates a frequency that causes radio wave interference to the radar apparatus, and the flag “0” indicates a frequency that is not affected by radio wave interference. Based on the radar information received from the server 17, the controller 11 calculates a frequency that may cause radio wave interference to the radar apparatus and a frequency that is not affected by the radio wave interference, and creates the frequency information 120. To do.

  Next, returning to FIG. 4, the controller 11 acquires position information 13 indicating the position of the device 10 (coordinate information including longitude and latitude) (step S <b> 3). Here, if the controller 11 is, for example, a smartphone that can move, the controller 11 stores the position information detected by the built-in GPS in the memory as the position information 13. Further, the controller 11 may acquire the position information set in advance in the memory as the position information 13 if the own apparatus 10 is an AP or a wireless LAN router fixedly installed.

  The controller 11 refers to the table information 12 and collates the position of the device 10 detected by the position information 13 (coordinates composed of longitude and latitude) with the coordinates defining the mesh area of the table information 12 (step) S4). That is, the controller 11 specifies a mesh area that matches the position of the own device 10.

  The controller 11 refers to the frequency information 120 corresponding to the coordinates of the identified mesh area from the table information 12, and executes a process of determining the use frequency (step S5). That is, the controller 11 disables a frequency that may cause radio wave interference to the radar device in the frequency band of the radio wave transmitted from the position of the own device 10, and determines a usable frequency. Here, as shown in FIG. 3, the controller 11 cannot use the frequency of the flag “1” as a frequency that may cause radio wave interference to the radar apparatus from the frequency information 120 corresponding to the coordinates of the mesh area. And On the other hand, the controller 11 determines the frequency of the flag “0” as a frequency that has no influence of radio wave interference on the radar device.

  The controller 11 holds the frequency that cannot be used until the position of the own device 10 is changed. Therefore, if the own device 10 is an AP or a wireless LAN router that is fixedly installed, the controller 11 maintains a frequency that cannot be used as it is. On the other hand, if the own device 10 is a movable smartphone, for example, the controller 11 executes steps S3 to S5, and selects a frequency that may cause radio wave interference to the radar device according to the position change of the own device 10. The process of determining the usable frequency is repeated with the use disabled.

  As described above, according to the present embodiment, the wireless communication device 10 may cause radio wave interference to the radar device based on the table information 12 and the position information 13 when performing wireless communication with the wireless terminal 15. A certain frequency band cannot be used, and wireless communication can be performed at a frequency determined to be usable. Therefore, when the use frequency bands (for example, 5 GHz) of the radar apparatus and the wireless communication apparatus 10 overlap, the wireless communication apparatus 10 may cause radio wave interference to the radar apparatus based on the table information 12 and the position information 13. A certain frequency band can be set as unusable.

  Accordingly, the wireless communication device 10 can perform wireless communication using a frequency band that is not affected by radio wave interference with the radar device without using the conventional DFS function. In other words, according to the present embodiment, radio wave interference with the radar apparatus can be avoided and the conventional DFS function can be reduced, so that a standby state or an interrupted state of the wireless communication function caused by the DFS function can be prevented.

  This embodiment is effective for a specific example in which the wireless communication device 10 is applied to a smartphone or a wireless LAN router connected to a public line, and a car navigation function is realized by a wireless terminal 15, for example, a tablet terminal. . In other words, it is possible to start the car navigation function without waiting time when the smartphone or the wireless LAN router is activated. Moreover, even when approaching the radar device, a situation in which the car navigation function is interrupted can be avoided.

  Furthermore, in recent years, high-speed wireless communication services such as 4G / LTE (registered trademark) have become widespread, but when many users receive large amounts of data such as moving images, sufficient speed may not be obtained. . On the other hand, some communication carriers and the like deploy a wireless LAN AP like a base station and provide a service provided free of charge to its own users. For these services, a wireless LAN using a frequency band of 2.4 GHz is currently employed, but it is conceivable that a wireless LAN using a frequency band of 5 GHz will be used in the future. In such a case, as described above, in order to avoid the occurrence of radio wave interference with a radar apparatus that uses the same frequency band as the wireless LAN (here, 5 GHz), the application of this embodiment is effective. .

  Here, since the wireless LAN AP deployed in the same manner as the base station is assumed to operate fixedly without moving, the function for acquiring the positional information 13 such as GPS is not necessarily built in the main body. There is no need to do. In this case, an apparatus different from the AP provides the same function by acquiring coordinate information indicating the latitude and longitude of the installation position of the AP by using, for example, a position information acquisition apparatus equipped with GPS and inputting the information to the AP. Is possible. When such an AP is used outdoors with a high output specification, a mechanism may be considered in which specification information such as the coordinate information and output power is managed by a management supervisory organization such as a country and stored in a server.

  In the present embodiment, the wireless communication device 10 uses radar information indicating the specifications of the radar device acquired from the server 17, and uses the radar information indicating the position and frequency band of the radar device as information on the function of avoiding radio wave interference with the radar device. The table information 12 based on the above is created. Here, if the server 17 side can store and provide the radar apparatus related information corresponding to the table information 12, the controller 11 can eliminate the function of creating the table information 12, and the function of the wireless communication apparatus 10 can be eliminated. Simplification can be achieved. Further, since the server 17 side can also update the radar apparatus related information corresponding to the table information 12 in accordance with the update of the specifications of the radar apparatus, the wireless communication apparatus 10 accesses the server 17 and performs as necessary. The latest table information 12 can be acquired.

  In the present embodiment, the wireless communication apparatus 10 uses a general function that can acquire the position information 13 of its own apparatus by GPS or the like, for example, in the case of a smartphone. No function is required. When location information with poor accuracy such as base station information is used, it may be necessary to take into account the error and determine an unusable frequency with a spatial margin. In addition, when the frequency of acquiring position information is low and the wireless communication apparatus 10 is moving at high speed, a spatial margin may be required as well.

Furthermore, the table information 12 of the present embodiment has a configuration having coordinate information that divides a range on the map that gives radio wave interference to the radar apparatus into mesh areas and defines them. By such coordinate information, it is possible to specify a range in which the function of avoiding radio wave interference with the radar apparatus can be applied. However, there are cases where it is not possible to specify a range in which the present embodiment can be applied with the function of avoiding radio wave interference, such as in foreign countries. Therefore, when the apparatus 10 is located outside the applicable range, for example, the conventional DFS function is instructed to turn on, and conversely, when the apparatus 10 is located within the applicable range, the conventional DFS function is provided. The table information 12 may include information instructing to turn off.
[Modification]
FIG. 5 is a block diagram showing a configuration relating to a modification of the present embodiment. As shown in FIG. 5, the present modification has a configuration in which the radio communication device 10 of the present embodiment is applied to a base station 20 for mobile radio communication. That is, the base station 20 has a configuration in which, for example, a wireless LAN router, which is the wireless communication apparatus 10 of the present embodiment, is connected to a conventional base station main body 21.

  In this modification, for example, the wireless terminal 15 such as a smartphone can execute, for example, packet data communication via the wireless communication device 10 of the present embodiment, which is a router for wireless LAN, without passing through the base station main body 21. . In this case, as described above, the wireless LAN router exhibits a function of avoiding radio wave interference with the radar device of the present embodiment, and relays data communication of the radio terminal 15 without causing radio wave interference with the radar device. Is possible.

  In the case of this modified example, the same operational effects as those of the above-described embodiment can be obtained, and thus the description of the operational effects is omitted.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

10 ... wireless communication device, 11 ... controller, 12 ... table information section,
13 ... Location information part, 14 ... Use frequency determination part, 15 ... Wireless terminal,
16 ... communication line, 17 ... server, 20 ... base station.

Claims (11)

Information regarding a function of avoiding radio wave interference with a radar apparatus, information acquisition means for acquiring the information set based on the position and frequency band of the radar apparatus;
As the frequency used for wireless communication, using the information acquired by the information acquisition means and the position information of its own device, except for the frequency band where radio wave interference with the radar device may occur, the used frequency is A wireless communication apparatus comprising a control means for determining. The information acquisition means includes
As information on the function of avoiding radio wave interference, coordinates indicating each area affected by radio wave interference based on the position of the radar device are associated with a frequency band in which radio wave interference with the radar device may occur. The wireless communication apparatus according to claim 1, wherein the table information is acquired. The table information is
Including frequency information indicating a frequency band corresponding to the coordinates indicating each area,
The radio communication apparatus according to claim 2, wherein the frequency information is configured to include a flag for identifying a frequency that causes radio wave interference to the radar apparatus and a frequency that is not affected by the radio wave interference. The information acquisition means includes
Means for receiving from the outside radar information indicating a radar specification including an installation position and a use frequency of the radar device;
4. The wireless communication apparatus according to claim 1, further comprising: a unit that generates information related to the radio wave interference avoidance function using the radar information. 5.   The wireless communication apparatus according to claim 1, further comprising means for generating position information of the own apparatus. The control means includes
Until the position of the device changes, the frequency band where the radio wave interference may occur is maintained as unusable,
The process for determining a use frequency is re-executed except for a frequency band in which radio wave interference with the radar apparatus may occur when the position of the own apparatus is changed. The wireless communication device according to item.   A base station for mobile radio communication, comprising the radio communication device according to any one of claims 1 to 6, and configured to execute mobile radio communication via the radio communication device. A method of avoiding radio wave interference applied to a wireless communication device,
Processing related to a function of avoiding radio wave interference with a radar apparatus, and obtaining the information set based on the position and frequency band of the radar apparatus;
A process of determining a use frequency, except for a frequency band in which radio interference with the radar apparatus may occur, using the acquired information and the position information of the own apparatus as a frequency used for wireless communication; To avoid radio interference. The process of acquiring the information includes
The table information in which coordinates indicating each area affected by radio wave interference based on the position of the radar device and frequency bands in which radio wave interference with the radar device may occur is acquired. Method for avoiding radio wave interference described in 1. The table information is
Including frequency information indicating a frequency band corresponding to the coordinates indicating each area,
The method of avoiding radio wave interference according to claim 9, wherein the frequency information is configured to include a flag for identifying a frequency that causes radio wave interference to the radar device and a frequency that is not affected by the radio wave interference. The process of acquiring the information includes
Processing for receiving from the outside radar information indicating radar specifications including the installation position of the radar device and the frequency used;
The method of avoiding radio wave interference according to any one of claims 8 to 10, wherein processing for generating information related to the radio wave interference avoidance function is performed using the radar information.