KR100446614B1 - Method and apparatus for controlling wireless data communication networks - Google Patents

Abstract

A wireless data communication network control method and apparatus are disclosed. The method for controlling an independent group having a plurality of homogeneous or heterogeneous dense wireless data communication networks connected to an underlying network to exchange information includes the steps of being notified of first activation information, which is information required when requesting activation from the wireless data communication network; Determining whether the first activation information overlaps or interferes with the second activation information of the at least one other wireless data communication network currently in use; and when it is determined that the first activation information does not overlap and interfere with the second activation information. And, if it is determined that the first activation information is redundant or may interfere with the second activation information, updating the first activation information and allowing the use of the updated first activation information. Characterized in that it comprises a step. Therefore, in an environment in which a plurality of homogeneous or heterogeneous wireless data networks are concentrated, there is an effect of eliminating redundancy of mutual frequency use between wireless data networks and interference between frequencies used in advance, thereby eliminating a sudden deterioration in quality. .

Description

Method and apparatus for controlling wireless data communication network

The present invention relates to a wireless data communication network such as a wireless local area network or a wireless personal area network, and more particularly, to a method and apparatus for controlling a wireless data communication network.

With the recent development of wireless data systems, it is expected that the construction of wireless data communication networks in offices and homes using wireless personal network systems such as wireless LAN systems or Bluetooth will become common. However, in an environment such as a building having a large number of independent groups or an apartment with a large number of households, serious quality degradation is inevitable due to mutual interference between homogeneous or heterogeneous wireless LANs and wireless private networks.

Currently commercially available wireless LANs can operate in the frequency band 2.4-2.4835 GHz. The conventional method using the Direct Spread Spectrum (DSS) method divides the aforementioned frequency band into 5 MHz intervals to form 14 channels. At this time, when one wireless LAN system is configured in an office or home, one of 14 channels is used. If another wireless LAN system is installed in an adjacent area, the frequency interval between them must be at least 30 MHz. . As such, when four or more wireless LAN systems are installed in a densely populated area, there is a problem in that a quality deterioration may occur due to overlap of use frequency sections according to the conventional method. That is, it is practically impossible to provide a plurality of independent wireless LAN services in apartments and buildings.

In addition, the conventional method using the Frequency Hopping Spread Spectrum (FHS) method has a plurality of wireless LANs or wireless personal networks because frequency hopping patterns between independent wireless LANs or wireless private networks each have random characteristics. You can install the system. However, since installing multiple independent wireless LANs or wireless personal network systems in a dense area increases the frequency overlap probability, the conventional method has a problem that can cause quality deterioration.

In addition, in the conventional method using Orthogonal Frequency Division Multiplexing (OFDM) using the 5.15-5.25 GHz band, the WLAN has four carriers and 52 subcarriers per carrier. Has Like the above-described methods, the conventional method has a problem in that quality may be caused due to overlap of frequency bands when five or more wireless LAN systems are installed in a dense area.

The present invention has been made in an effort to provide a wireless data communication network control method capable of eliminating duplication or interference between frequencies used by heterogeneous or homogeneous multiple wireless data communication networks.

Another object of the present invention is to provide a wireless data communication network control apparatus for performing the wireless data communication network control method.

1 is a flowchart illustrating a method for controlling a wireless data communication network according to the present invention.

2 is a view for explaining a wireless data communication network control apparatus according to the present invention.

3 is a block diagram of a preferred embodiment of the present invention of the apparatus for controlling a wireless data network shown in FIG. 2 for performing the method shown in FIG.

4 is a diagram illustrating a signal exchange between a wireless data communication network control apparatus and a wireless data communication network according to the present invention.

In order to achieve the above object, a wireless data communication network control method according to the present invention for controlling an independent group having a plurality of homogeneous or heterogeneous wireless data communication networks connected to an underlying network and exchanging information may require activation from the wireless data communication network. Receiving first activation information, which is information necessary for determining information, determining whether the first activation information may overlap or interfere with second activation information of at least one other wireless data communication network currently in use; If it is determined that the activation information does not overlap and interfere with the second activation information, and permitting use of the first activation information and when it is determined that the first activation information may overlap or interfere with the second activation information. Update the first activation information, and update the first activation information. It is formed of a step for allowing for preferable.

In order to achieve the above object, the apparatus for controlling a wireless data network according to the present invention, which performs the method for controlling the wireless data network, converts a format of an activation request signal having the first activation information and outputs the converted result. A conversion unit, an update scheme for updating the first activation information and a network register for storing positions of the wireless data communication networks, a network resource manager for storing the second activation information, and a network register in response to an address signal; A main manager that reads the stored locations and the second activation information stored in the network resource manager and updates the second activation information stored in the network resource manager in response to a first control signal, the locations and the first information; 2 analyzing the possibility of duplication or interference from the activation information, and outputting the analyzed result The address signal is generated in response to the frequency allocation controller and the result of the format conversion, and outputs the positions and the second activation information input from the main management unit to the frequency allocation controller, and inputs the frequency allocation controller. And a main controller for outputting an activation permission signal and the first control signal in response to the analyzed result, wherein the wireless data communication network requesting the activation is based on the first activation information in response to the activation permission signal. It is preferred to be activated.

Hereinafter, a wireless data communication network control method according to the present invention will be described with reference to the accompanying drawings.

1 is a flowchart illustrating a method for controlling a wireless data communication network according to the present invention, wherein updating the first activation information according to whether the first activation information notified has a possibility of duplication or interference (steps 10 to 18) And authorizing the use of updated or unupdated first activation information (20th and 22nd steps).

The method for controlling a wireless data communication network according to the present invention serves to control an independent group having a plurality of dense wireless data communication networks connected to an underlying network to exchange information. Here, the base network means a core IP (Inter network Protocol) network, and the independent group means an apartment or a building in which wireless data communication networks for offices or homes are concentrated. To this end, the wireless data communication method according to the present invention first receives the first activation information from the wireless data communication network (step 10).

After the tenth step, it is determined whether the notified first activation information overlaps or possibly interferes with second activation information of at least one other wireless data communication network currently in use (step 12). Here, the first or second activation information means a carrier frequency, a required band, and / or a spreading scheme to be used or used. If it is determined that there is no possibility of duplication and interference with the second activation information, the use of the first activation information is permitted (step 22).

However, if it is determined that the first activation information may overlap or interfere with the second activation information, the first activation information is updated, and the use of the updated first activation information is allowed (steps 14 to 20).

For example, if it is determined that the first activation information may overlap or interfere with the second activation information, a frequency band that is not currently used in a frequency band that can be used by wireless data communication networks existing in the independent group, that is, an available frequency band, that is, US It is determined whether there is a use frequency band (step 14). If it is determined that there is an unused frequency band in the usable frequency band, the requested first activation information is updated using the unused frequency band (step 16). For example, the first activation information is updated by changing the carrier frequency included in the requested first activation information to an appropriate frequency in an unused frequency band. However, if it is determined that there is no unused frequency band in the usable frequency band, the first activation information is updated by dividing a resource used by at least one other wireless data communication network currently being used (step 18). In this case, the first activation information may be updated by dividing a resource used by a wireless data communication network having a low use level among at least one other wireless data communication network currently in use.

According to an embodiment of the present invention, there are a time division multiplexing scheme and a frequency division multiplexing scheme as a scheme for updating the first activation information to perform the eighteenth step. Here, the time division multiplexing method of updating the first activation information by time division multiplexing a resource means differently allocating a use time zone for each wireless data communication network. Since the data communication time varies in each home, it can be used very efficiently for updating the first activation information. In addition, a frequency division multiplexing scheme for updating the first activation information by frequency division multiplexing resources includes an orthogonal frequency division multiplexing scheme or a frequency hopping spread spectrum scheme. Here, the orthogonal frequency division multiplexing scheme means different allocation of subcarriers for each wireless data communication network within the same carrier, and the frequency hopping spread spectrum scheme means different allocation of hopping ranges for each wireless data communication network.

On the other hand, after the sixteenth or eighteenth steps, use of the updated first activation information is permitted (step 20).

Hereinafter, the configuration and operation of a wireless data communication network control apparatus according to the present invention for performing the method of controlling a wireless data communication network according to the present invention shown in FIG. 1 will be described with reference to the accompanying drawings.

2 is a view for explaining a wireless data communication network control apparatus according to the present invention, which is composed of the base network 40 and the independent groups 42, ... and 44. Here, the independent group 42 is composed of a wireless data communication network control device 60 and wireless data communication networks 62, ..., and 64, and the independent group 44 is a wireless data communication network control device 80 and a wireless data communication network. It is composed of the 82, ... and 84.

Wireless data communication network control device 60, ... or 80 according to the present invention may be embedded in the independent group 42, ... or 44 as shown in Figure 2, unlike the independent group shown in Figure 2 It may be provided outside of 42, ... or 44. As described above, each independent group 42, ... or 44 is a plurality of dense wireless data communication networks [(62, ... and 64) or (82, ...) connected to the underlying network 40 to exchange information. .. and 84)]. Here, the wireless data network control device 60, ... or 80 according to the present invention controls the wireless data communication networks [(62, ... and 64) or (82, ... and 84)]. Do it. According to the present invention, the wireless data communication network 62, ..., 64, 82, ..., or 84 shown in FIG. 2 corresponds to a wireless LAN or a wireless personal network, and one independent group 42, ... Or 44) may have homogeneous or heterogeneous wireless data communications networks.

3 is a block of a preferred embodiment of the present invention of the apparatus 60, ... or 80 of the apparatus for controlling a wireless data network according to the present invention shown in FIG. 2 for performing the method for controlling the wireless data network shown in FIG. 4, a network registration unit 100, a network source management unit 102, a utilization management unit 104, a main management unit 106, a main control unit 108, a frequency allocation control unit 110, It is composed of a frequency checker 112, a sharing control section 114 and a format converter 116.

Referring to FIG. 3, the format conversion unit 116 has an activation request signal having first activation information input from a wireless data communication network (hereinafter referred to as a first wireless data communication network) requesting activation through an input terminal IN from the outside. Format is converted, and an activation request signal having the converted format is output to the main control unit 108. Here, the format converter 116 is optionally provided. That is, when the format conversion unit 116 is not provided, the activation request signal is directly input to the main control unit 108.

The network registration unit 100 stores information on an update method for updating the first activation information, that is, whether to update the first activation information to the time division multiplexing method or the frequency division multiplexing method. Stores locations of communication networks [62, ... and 64 or 82, ... and 84]. At this time, the network resource management unit 102 stores second activation information which is information on a wireless data communication network currently being used. That is, the network resource manager 102 stores a carrier frequency, a required band, and the like of a wireless data communication network currently in use.

The main management unit 106 reads the positions stored in the network registration unit 100 and the second activation information stored in the network resource management unit 102 in response to the address signal input from the main control unit 108, and the read positions and The second activation information is output to the main controller 108. In addition, the main manager 106 updates the second activation information stored in the network resource manager 102 in response to the first control signal input from the main controller 108.

At this time, the frequency allocation control unit 110 analyzes whether the first activation information and the second activation information overlap or interference from the first activation information, locations, and second activation information input from the main controller 108, The analyzed result is output to the main controller 108. For example, the frequency allocation control unit 110 determines that there is a possibility of interference when the position corresponding to the first activation information and the position corresponding to the second activation information are close, and the position corresponding to the first activation information and the second activation are determined. If the location corresponding to the information matches, it is determined to be a duplicate.

When the activation request signal is input from the format conversion unit 116, the main control unit 108 generates an address signal, outputs the address signal to the main management unit 106, and outputs the positions and the second activation information input from the main management unit 106. It outputs to the frequency allocation control unit 110, generates an activation permission signal and a first control signal in response to the analysis result input from the frequency allocation control unit 110, the generated first control signal to the main management unit 106 On the other hand, the generated activation permission signal is output to the format converter 116, respectively. At this time, the format conversion unit 116 converts the format of the activation permission signal input from the main control unit 108 and transmits the activation permission signal having the converted format to the first wireless data communication network through the output terminal OUT. Therefore, the first wireless data communication network is activated based on the first activation information in response to the activation permission signal input from the format converter 116.

Through the above-described configuration and operation, in order to perform the tenth step, the apparatus for controlling a wireless data communication network according to the present invention shown in FIG. 3 converts an activation request signal having first activation information through an input terminal IN to a format conversion unit ( 116).

At this time, in order to perform the twelfth step, when the activation request signal is input from the format conversion unit 116, the main control unit 108 analyzes the unique number of the first wireless data communication network included in the activation request signal and performs the address. A signal is generated and output to the main management unit 106. At this time, the main management unit 106 reads from the network registration unit 100 the positions stored in the address designated by the address signal input from the main control unit 108, and the address designated by the address signal input from the main control unit 108. Reads the second activation information stored in the network resource manager 102 and outputs the read positions and the second activation information to the main controller 108. At this time, the main control unit 108 outputs the positions and the second activation information input from the main management unit 106 to the frequency allocation control unit 110. The frequency allocation controller 110 performs a twelfth step by using the positions input from the main controller 108 and the second activation information and the first activation information included in the activation request signal input from the format converter 116. do.

In order to perform the twenty-second step, when the main controller 108 determines that the first activation information does not overlap with the second activation information and there is no possibility of interference based on the result analyzed by the frequency allocation controller 110, the activation permission signal Is output to the format converter 116. At this time, the format conversion unit 116 converts the format of the activation permission signal and outputs it to the first wireless data communication network through the output terminal OUT. Accordingly, the first wireless data communication network may be activated at a carrier frequency and a required band included in the first activation information to exchange information with the underlying network. At this time, the main control unit 108 outputs the first control signal to the main management unit 106, and the main management unit 106 based on the first activation information in which the first wireless data communication network is activated in response to the first control signal. The second activation information stored in the network resource manager 102 is updated.

Meanwhile, in order to perform the fourteenth step illustrated in FIG. 1, the apparatus for controlling a wireless data communication network illustrated in FIG. 3 further includes a frequency checker 112. Here, the frequency inspecting unit 112 checks the presence or absence of the unused frequency band in the usable frequency band in response to the second control signal input from the main control unit 108, and outputs the checked result to the main control unit 108. do. At this time, the main controller 108 generates a second control signal by generating a second control signal if it is recognized that the first activation information overlaps with or may interfere with the second activation information based on the analysis result input from the frequency allocation controller 110. Output to the inspection unit 112.

In this case, in order to perform the sixteenth step, if the main controller 108 recognizes that the unused frequency band exists through the result of the test by the frequency inspecting unit 112, the first activation information uses the unused frequency band. And update the first activation information through the format conversion unit 116 to the first wireless data communication network. In addition, the main controller 108 generates an activation permission signal and a first control signal in response to the updated first activation information. At this time, the main management unit 106 recognizes the updated first activation information from the first control signal generated by the main control unit 108 and updates the second activation information of the network resource management unit 102 based on the recognized result. do.

Meanwhile, in order to perform the eighteenth step, the apparatus for controlling a wireless data communication network illustrated in FIG. 3 further includes a utilization management unit 104 and a sharing control unit 114. Here, when it is recognized that the unused frequency band does not exist through the inspected result input from the frequency inspecting unit 112, the main control unit 108 controls the sharing control unit 114 to generate a utilization request signal. At this time, when the utilization request signal is input from the sharing controller 114, the main controller 108 generates a third control signal and outputs the third control signal to the main management unit 106. The main management unit 106 controls the utilization management unit 104 to generate a monitor request signal in response to the third control signal input from the main control unit 108. In this case, the utilization management unit 104 uses the utilization rate of the wireless data communication network, for example, the wireless data communication networks [(62, ... and 64) or (82, ... and 84)] using the base network 40. The time, amount used, and / or grade used are stored as utilization rates. At this time, the utilization management unit 104 outputs the generated monitor request signal to the format conversion unit 116 through the main management unit 106 under the control of the main management unit 106. The format conversion unit 116 converts the format of the monitor request signal input from the main management unit 106 and outputs it to at least one wireless data communication network (hereinafter referred to as a second wireless data communication network) except for the first wireless data communication network. Transmit via terminal OUT. At this time, the second wireless data communication network analyzes its utilization rate when the monitor request signal input from the format converter 116 is input, and outputs the monitor response signal having the analyzed result to the format converter 116. . The format converter 116 converts the format of the monitor response signal input from the second wireless data communication network and outputs the format to the utilization manager 104 through the main manager 106. The utilization management unit 104 updates or maintains the stored utilization according to the monitor response signal input from the main management unit 106. Next, the main management unit 106 reads the updated or maintained utilization rate from the utilization rate management unit 104 and outputs it to the main control unit 108. The main control unit 108 shares the utilization rate input from the main management unit 106 with the shared control unit. Output to (114). At this time, the sharing control unit 114 analyzes the utilization rate input from the main control unit 118, and the analysis result and the update information input from the network registration unit 100 through the main management unit 106 and the main control unit 108. Correspondingly, an update request signal is generated, and the generated update request signal is output to the format converter 116 via the main controller 108. The format conversion unit 116 converts the format of the update request signal input from the sharing control unit 114 through the main control unit 108, and shares the resource in the second wireless data communication network with the update request signal having the converted format. Transmit to the corresponding wireless data network determined by. At this time, the corresponding wireless data communication network inputting the update request signal checks whether other wireless data communication networks allow the resources used by the wireless data communication network to be shared, and uses the format conversion unit 116 as the update response signal. Will output At this time, the format conversion unit 116 converts the format of the update response signal input through the input terminal IN from the corresponding wireless data communication network in the second wireless data communication network to the sharing control unit 114 through the main control unit 108. Output At this time, when the sharing control unit 114 recognizes that the corresponding wireless data communication network permits sharing through the update response signal input from the main control unit 108, the sharing control unit 114 generates an activation permission signal and outputs the activation permission signal to the main control unit 108. . At this time, the main controller 108 generates a first control signal in response to the activation permission signal input from the sharing controller 114, outputs the activation permission signal to the format conversion unit 116, and permits sharing. The first activation information is updated by dividing a resource used by the corresponding second wireless data communication network, and the updated first activation information is transmitted to the first wireless data communication network through the format converter 116. At this time, the main management unit 106 recognizes the updated first activation information through the first control signal input from the main control unit 108 and based on the recognized result, the second activation information stored in the network resource management unit 102. Update the.

In order to perform the twentieth step, the activation permission signal and the updated first activation information generated by the main control unit 108 after the sixteenth or eighteenth steps are converted into a format by the format converter 116 and then the first wireless data. The first wireless data communication network is activated when the activation permission signal is input based on the updated first activation information input from the format converter 116 to exchange information with the underlying network.

In order to facilitate understanding of the present invention, assuming that there are three wireless data communication networks, the wireless data communication method and the operation of the wireless data communication apparatus performing the method shown in FIG. 1 will be described as follows. .

4 is a diagram illustrating a signal exchange between a wireless data communication network control device and wireless data communication networks according to the present invention, and includes a wireless data communication network control device 140 and three wireless data communication networks 142, 144, and 146. .

First, in reference numeral “150” shown in FIG. 4, when an activation request signal Activate_req is input from the wireless data network 142, the wireless data network control device 140 analyzes the possibility of redundancy and interference, and then independently If it is determined that the in channel can be allocated to the wireless data communication network 142, an activation response signal (Activate_resp) having the first activation information and the activation permission signal is transmitted to the wireless data communication network 142.

Next, in reference numeral 152 shown in FIG. 4, when the activation request signal Activate_req is input from the wireless data network 144, the wireless data network control device 140 not only has a possibility of redundancy and interference, If it is determined that the unused frequency band does not exist, the monitor request signal Monitor_req is transmitted to the wireless data communication networks 142 and 146 to confirm or update the utilization rate of the wireless data communication networks. At this time, the wireless data network control device 140 determines to update or maintain the utilization rate using the monitor response signals Monitor_resp input from the wireless data communication networks 142 and 146, and then transmits an update request signal Update_req. Transmit to wireless data communication network 142. That is, the wireless data communication network control device 140 asks the wireless data communication network 142 by the update request signal Update_req whether the wireless data communication network 142 can share the resources currently being used. At this time, when the wireless data communication network 142 recognizes that the sharing is allowed through the update response signal Update_resp, the wireless data communication network controller 140 allocates and updates a resource being used by the wireless data communication network 142. The activation response signal Activate_resp having the first activation information and the activation permission signal is transmitted to the wireless data communication network 144.

As described above, the method and apparatus for controlling a wireless data communication network according to the present invention are redundant of mutual frequency use and interference between frequencies used in wireless data communication networks in an environment in which a plurality of homogeneous or heterogeneous wireless data communication networks are concentrated. By removing it has the effect of removing in advance a sudden degradation of quality. In particular, when the home networking is to be configured using a wireless LAN and a wireless personal network, wireless data communication networks may be usefully applied in a dense environment.

Claims (13)

A wireless data network control method for controlling an independent group having a plurality of homogeneous or heterogeneous wireless data communication networks connected to an underlying network to exchange information. (a) receiving first activation information, which is information required for requesting activation from the wireless data communication network; (b) determining whether the first activation information overlaps or interferes with second activation information of at least one other wireless data communication network currently in use; (c) permitting use of the first activation information if it is determined that the first activation information does not overlap and possibly interfere with the second activation information; And (d) if it is determined that the first activation information overlaps or interferes with the second activation information, updating the first activation information and allowing use of the updated first activation information. Wireless data network control method. The method of claim 1, wherein the first or second activation information includes a carrier frequency and a required band to be used. 2. The method of claim 1, wherein the first or second activation information comprises a spreading scheme. The method of claim 1, wherein step (d) (d1) if it is determined that the first activation information overlaps or interferes with the second activation information, determining whether there is an unused frequency band that is not currently used in a frequency band that can be used by the wireless data communication networks. ; (d2) if it is determined that the unused frequency band exists, updating the requested first activation information using the unused frequency band; (d3) if it is determined that the unused frequency band does not exist, dividing a resource used by the other wireless data communication network currently being used and updating the first activation information; And and (d4) authorizing the use of the updated first activation information after the step (d2) or the step (d3). 5. The method of claim 4, wherein the step (d3) updates the first activation information by time division multiplexing the resource. 5. The method of claim 4, wherein the step (d3) updates the first activation information by frequency division multiplexing the resource. The method of claim 6, wherein step (d3) And allocating subcarriers differently for each of the wireless data networks within the same carrier to perform the frequency division multiplexing of the resource. The method of claim 6, wherein step (d3) And allocating different hopping ranges for each of the wireless data networks to perform frequency division multiplexing of the resources. The wireless data communication network control apparatus for performing the wireless data communication network control method of claim 1, A format conversion unit for converting a format of the activation request signal having the first activation information and outputting the converted result; An update scheme for updating the first activation information and a network register for storing positions of the wireless data communication networks; A network resource manager which stores the second activation information; Reading the positions stored in the network registration unit and the second activation information stored in the network resource management unit in response to an address signal, and updating the second activation information stored in the network resource management unit in response to a first control signal; Management; A frequency allocation controller for analyzing whether there is a possibility of duplication or interference from the positions and the second activation information, and outputting an analyzed result; And The analyzed result of generating the address signal in response to the format conversion result, outputting the positions and the second activation information input from the main management unit to the frequency allocation controller, and inputting the frequency allocation controller. A main controller for outputting an activation permission signal and the first control signal in response to the response; And the wireless data communication network requesting the activation is activated based on the first activation information in response to the activation permission signal. The apparatus of claim 9, wherein the wireless data communication network control device comprises: And a frequency checker for checking a frequency band not currently used in the frequency bands available to the wireless data communication networks existing in the independent group in response to a second control signal, and outputting a checked result. The main controller generates the second control signal in response to the analyzed result input from the frequency allocation controller, updates the first activation information in response to the result checked by the frequency checker, and updates the first Generating the activation permission signal and the first control signal in response to activation information; And the wireless data communication network requesting the activation is activated in response to the activation permission signal based on the updated first activation information. The apparatus of claim 10, wherein the wireless data communication network control device comprises: A utilization request signal is generated in response to the checked result input from the frequency checker, an update request signal is generated in response to a result of analyzing the input utilization rate, and the activation permission signal is generated in response to an update response signal. A sharing control unit; And A utilization rate management unit for storing the utilization rate of the wireless data communication network, generating a monitor request signal, and updating or maintaining the stored utilization rate in response to a monitor response signal; The format conversion unit converts the format of the monitor request signal and transmits the format to the at least one wireless data communication network except for the wireless data communication network requiring activation, and converts the format of the monitor response signal input from the at least one wireless data communication network. Converts and outputs the update request signal to a utilization management unit through the main management unit, converts a format of the update request signal, transmits only the corresponding communication among the at least one wireless data communication network, and inputs the update response input from the corresponding wireless data communication network; Converts the format of the signal and outputs it to the sharing control unit through the main control unit; The main management unit controls the utilization management unit to generate the monitor request signal in response to a third control signal, and reads out the updated or maintained utilization rate from the utilization rate management unit to output to the main control unit, The main controller generates the third control signal in response to the utilization request signal, outputs the utilization rate input from the main management unit to the sharing control unit, and responds to the activation permission signal input from the sharing control unit. Generate a first control signal and update the first activation information by dividing a resource used by a wireless data communication network allowing sharing; The wireless data communication network requesting activation analyzes its utilization rate in response to the monitor request signal input from the format converter, and outputs the analyzed result as the monitor response signal to the format converter. Data network control device. 10. The apparatus of claim 9, wherein the wireless data communication network corresponds to a wireless LAN. 10. The apparatus of claim 9, wherein the wireless data communication network corresponds to a wireless personal network.