KR100668286B1 - Intellectual access point device capable of accessing to wireless sensor network and wireless communication network system with the same - Google Patents

Abstract

The present invention relates to an intelligent access point device for accessing a wireless sensor network and a wireless communication network system including the same, and mutually support communication between a wireless LAN communication network, a wireless sensor network, and a wired communication network, and sense information from the wireless sensor network. Generating status information based on the information, and transmitting the status information to the wireless LAN communication network or the wired communication network, and transferring sensor control signals from the wireless LAN communication network or the wired communication network to the wireless sensor network. Provides a ubiquitous environment by increasing the economic efficiency of a communication system by allowing users connected to a communication network to recognize the situations sensed by the wireless sensor network, and allowing the users to control the wireless sensor network appropriately. It can work.

Wireless LAN, Wireless Sensor Network, Station, Sensor Node

Description

Intelligent access point device capable of accessing a wireless sensor network, and a wireless communication network system including the same {Intellectual access point device capable of accessing to wireless sensor network and wireless communication network system with the same}

1 is a block diagram of a conventional wireless LAN communication system.

2 is a block diagram of a conventional wireless sensor network system.

3 is a block diagram of an access point apparatus according to an embodiment of the present invention.

4 is a diagram illustrating a software structure of the second microprocessor illustrated in FIG. 3.

5 is a block diagram illustrating a wireless communication network system including an access point device according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: access point device 110: wireless transceiver

120: MAC engine 130: central processing unit

300: wireless communication network system 310: wireless sensor network

320: communication channel 330: wired network

341-343: wired terminal device

The present invention relates to a communication system, and more particularly, to an access point apparatus used in a wireless communication system and a wireless communication network system including the same.

In general, an access point device used in a wireless local area network (LAN) communication system is a device that supports communication between a wireless LAN and a wired network. That is, the access point device is a device that delivers an Ethernet packet from the wireless LAN to the wired network, converts the Ethernet packet from the wired network into a wireless Ethernet packet, and delivers it to the wireless LAN. Such a conventional access point apparatus is shown in FIG. 1 is a block diagram of a conventional wireless LAN communication system 10. The wireless communication system 10 includes a wired network 11, an access point device 13, and stations 14, 15, 16. The access point device 13 is connected with the wired network 11 and communicates with the stations 14, 15, 16 via a wireless communication channel 12. The access point device 13 communicates with each other so that the stations 14, 15, and 16 included in the communication cell area by the wireless communication channel 12 can access the wired network 11. Relays

On the other hand, one of the technologies used in the ubiquitous network environment is a wireless sensor network (wireless sensor network) system. Wireless sensor network system is a technology that senses various surrounding environments without any user's consciousness in life regardless of place or time by large sensor nodes and collects the sensed information and informs the user. . 2 is a block diagram of a conventional wireless sensor network system 20. The wireless sensor network system 20 includes a wireless sensor network 21 including a plurality of wireless sensor nodes 24-29, a sink node 22, and a terminal device 23. Each of the wireless sensor nodes 24-29 communicates with each other organically, and the sink node 22 collects sensing information of each of the wireless sensor nodes 24-29 and transmits them to the terminal device 23. As a result, the user can recognize various changes in the environment currently occurring through the terminal device 23.

As described above, in the conventional wireless LAN communication system, a connection scheme for sensor networking for implementing ubiquitous computing technology is not considered. Thus, additional devices are required to combine the equipment for wireless LAN communication network and sensor networking, increasing the complexity of the system. In addition, since the wireless LAN communication system and the wireless sensor network system exist independently of each other and cannot share information with each other, there are limitations in providing more various services to users. On the other hand, as users' demands for more various services have recently increased, technologies for integrating a wireless LAN communication system and a wireless sensor network system are required. However, there is a problem that these functions are not supported in the conventional wireless communication technology.

Accordingly, the technical problem to be achieved by the present invention is to support communication between a wireless LAN communication network, a wireless sensor network, and a wired communication network, and generate context information based on sensing information from the wireless sensor network, thereby generating the wireless LAN communication network or the An access point apparatus capable of transmitting to a wired communication network and transmitting sensor control signals from the wireless LAN communication network or the wired communication network to the wireless sensor network.

Another technical problem to be solved by the present invention is to mutually support communication between a wireless LAN communication network, a wireless sensor network, and a wired communication network, and generate situation information based on sensing information from the wireless sensor network, thereby generating the wireless LAN communication network or the The present invention provides a wireless communication network system including an access point device capable of transmitting to a wired communication network and transmitting sensor control signals from the wireless LAN communication network or the wired communication network to the wireless sensor network.

An access point apparatus according to the present invention for achieving the above technical problem, the access control of the wired network by a plurality of stations sharing a communication channel, medium access control (MAC) frame from one of the plurality of stations A MAC engine that converts the received data into first digital data and outputs the converted data; Send first digital data to a plurality of sensor nodes in a wired network or a wireless sensor network, transmit second digital data received from the wired network to a MAC engine or a plurality of sensor nodes, and receive from the plurality of sensor nodes. A central processing unit generating situation information data based on the sensed data and transmitting the situation information data to a wired network or a MAC engine; And a wireless transceiver supporting wireless communication between the plurality of stations and the MAC engine and supporting wireless communication between the plurality of sensor nodes and the central processing unit.

In accordance with another aspect of the present invention, there is provided a wireless communication network system, comprising: forming a wireless sensor network, each sensing a situation of a surrounding environment to generate sensing data, and including first control data or sensing control information. A plurality of sensor nodes controlling driving of corresponding devices in response to second digital data including sensing control information; A plurality of stations sharing a predetermined communication channel and wirelessly communicating over the communication channel; A plurality of wired terminal devices connected to a wired network; And a situation in a plurality of stations or a plurality of wired terminal devices connected to a wired network and providing a communication channel within their wireless communication cell area, generating situation information data based on sensing data, and requesting the situation information data. Provide information data, transmit first digital data received from one of the plurality of stations to a wired network or a plurality of sensor nodes, and transmit second digital data received from the wired network a plurality of stations or a plurality of sensors Access point device transmitting to the nodes.

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

3 is a block diagram of an access point apparatus according to an embodiment of the present invention. Referring to FIG. 3, the access point apparatus 100 includes a wireless transceiver 110, a medium access control (MAC) engine 120, and a central processing unit 130. The wireless transceiver 110 includes a first RF unit 111, a modem 112, and a second RF unit 113. The first RF unit 111 converts the first RF reception signal RFRV1 received through the first wireless communication channel into PHY (Physical layer) frame reception data (PHRV), and outputs it to the modem 112, The PHY frame transmission data PHTX received from the modem 112 is converted into a first RF transmission signal RFTX1 and transmitted through the first wireless communication channel. Here, the first RF received signal RFRV1 may include communication information or request information or sensor control information of a plurality of stations (not shown) sharing the first wireless communication channel. The request information is information for requesting contextual information data sensed by a plurality of sensor nodes (not shown) of a wireless sensor network, and the sensor control information is information for controlling the plurality of sensor nodes.

The modem 112 converts the PHY frame received data PHRV into MAC frame received data MARV and outputs the MAC frame 120 to the MAC engine 120. The MAC frame transmitted data MAX is received from the MAC engine 120. ) Is converted into the PHY frame transmission data (PHTX) and output to the first RF unit 111. In general, it is called a physical layer including the first RF unit 111 and the modem 112.

The second RF unit 113 converts the second RF received signal RFRV2 received through the second wireless communication channel into sensing data SNDT, and outputs the sensing data SNDT to the central processing unit 130, and the central processing unit 130. First digital data (FDAT) or second digital data (SDAT) received from the) is converted into a second RF transmission signal (RFTX2) and transmitted through the second wireless communication channel. Here, the second RF received signal RFRV2 includes sensing information that the sensor nodes sense the surrounding environment. Here, the first digital data FDAT or the second digital data SDAT converted by the second RF unit 113 into the second RF transmission signal RFTX2 includes the sensor control information. .

The MAC engine 120 includes a physical layer interface 121, a first microprocessor 122, a first host bus interface 123, and a first memory 124. The physical layer interface 121 receives the MAC frame received data (MARV) received from the modem 112, outputs it to the first microprocessor 122, and is received from the first microprocessor 122 The MAC frame transmission data (MATX) is output to the modem 112. Preferably, the physical layer interface 121 interfaces the first microprocessor 122 and the wireless transceiver 110.

The first microprocessor 122 receives the MAC frame received data MARV. In general, data in a MAC frame format includes a receiving MAC address and a sending MAC address. The first microprocessor 122 determines whether the receiving MAC address included in the MAC frame receiving data (MARV) matches its MAC address, and if it matches, determines the MAC frame receiving data (MARV). The memory 124 stores the same. Thereafter, when it is determined to transmit, the first microprocessor 122 reads the MAC frame received data MARV stored in the memory 124, converts the MAC frame received data into first digital data FDAT, and converts the first microprocessor 122 into the first digital data FDAT. One digital data FDAT is transmitted to the central processing unit 130 through the first host bus interface 123. Preferably, the first host bus interface 123 interfaces the first microprocessor 122 and the central processor 130. In this case, the first digital data FDAT may include the communication information or the request information or the sensor control information of the plurality of stations.

In addition, the microprocessor 122 controls access of a wired network by the plurality of stations and receives second digital data SDAT received from the central processing unit 130 through the first host bus interface 123. Or situation information data SNDT is converted into MAC frame transmission data MATX and stored in the first memory 124. Thereafter, when it is determined to transmit, the first microprocessor 122 reads the MAC frame transmission data MATX stored in the memory 124, and transmits the radio transceiver through the physical layer interface 121. Output to 110).

In general, in a wireless local area network (LAN), many users share a single wireless channel. If the user does not properly control the transmission between users, the information is collided on the wireless channel, and thus the information cannot be transmitted. The case of degradation occurs. As such, a technique of controlling the use authority for a transmission medium shared by a plurality of users is called a medium access control (MAC) method. In the wireless LAN's standard, which has been finalized by the IEEE 802.11 committee, the MAC engine controls the use of wireless channels shared by the terminals efficiently (ie, co-transmission) in order to ensure that multiple terminals have minimal interference and maximum performance. To control the competition when data is sent), and detect whether there is an abnormality in the transmission path.

The CPU 130 may include a second host bus interface 131, a wireless sensor interface 132, a wired media interface 133, a wired transceiver 134, a second microprocessor 135, and a second memory 136. ). The second host bus interface 131 interfaces the second microprocessor 135 and the MAC engine 120, and the wireless sensor interface 132 connects the second microprocessor 135 and the wireless transceiver ( The second RF unit 113 of the 110 is interfaced. The wired media interface 133 interfaces the second microprocessor 135 and the wired network 200. The wired transceiver 134 transmits and receives communication signals between the wired media interface 133 and the wired network 200.

The second microprocessor 135 converts the first digital data FDAT received from the MAC engine 120 into a wired packet to transmit the wired data through the wired media interface 133 and the wired transceiver 134. Or transmit the first digital data FDAT to the second RF unit 113 through the wireless sensor interface 132. Preferably, when the first digital data FDAT includes communication information of one of the plurality of stations, the second microprocessor 135 transmits the first digital data FDAT to the wired network 200. To be sent). Also, when the first digital data FDAT includes the sensor control information, the second microprocessor 135 transmits the first digital data FDAT to the second RF unit 113.

In addition, the second microprocessor 135 transmits the second digital data SDAT received through the wired media interface 133 to the MAC engine 120 or the second RF unit 113. Preferably, when the second digital data SDAT includes the communication information, the second microprocessor 135 transmits the second digital data SDAT to the MAC engine 120. In addition, when the second digital data SDAT includes the sensor control information, the second microprocessor 135 transmits the second digital data SDAT to the second RF unit 113.

In addition, the second microprocessor 135 collects and interprets the sensing data SNDT received from the second RF unit 113 through the wireless sensor interface 132 to obtain meaningful context information data SIFD. Occurs. The second microprocessor 135 transmits the situation information data SIFD to the MAC engine 120 when the first digital data FDAT includes the request information. As a result, the situation information data SIFD is transmitted to the plurality of stations through the MAC engine 120 and the radio transceiver 110. The second microprocessor 135 transmits the context information data SIFD to the wired network 200 when the second digital data SDAT includes the request information. As a result, the situation information data SIFD is transmitted to wired terminal devices (not shown) connected to the wired network 200. The second memory 136 stores programs executed by the second microprocessor 135.

Meanwhile, the structure of software executed in the second microprocessor 135 is shown in FIG. 4. Referring to FIG. 4, the software executed in the second microprocessor 135 may include an information collection area 141, a kernel area 142, an information conversion area 143, and a user application area 144. ), Kernel network region 145, and device driver region 146. In the information collecting area 141, sensing information of sensing data SNDT received from the second RF unit 113 is collected. In the kernel region 142, an operation of controlling an overall schedule of software executed in the second microprocessor 135 is performed. In the information conversion area 143, the collected sensing information is converted into meaningful situation information data SIFD. Various control operations are performed in the user application area 144. The kernel network area 145 supports protocols for communication, such as Transmission Control Protocol (TCP), User Datagram Protocol (UDP), Internet Protocol (IP), and the like. In the device driver area 146, operations for controlling software executed in the second microprocessor 135 to interwork with the MAC engine 120 and the wired network 200 are performed. The function of the user application area 144 will be described in more detail, in response to the first digital data FDAT including the request information from one of the plurality of stations, the situation information data SIFD. Control to transmit to the MAC engine 120. In addition, the user application area 144 may include the second digital data (SDAT) including the request information from one of wired terminal devices communicating with the second microprocessor 135 through the wired network 200. In response to the control, the situation information data SIFD is transmitted to the wired terminal devices. In addition, the user application area 144 controls the first digital data FDAT including sensor control information from one of the plurality of stations to be transmitted to the plurality of sensor nodes, and the wired terminal device. And control the second digital data (SDAT) including the sensor control information from one of them to be transmitted to the plurality of sensor nodes.

As described above, the access point apparatus 100 according to the present invention may control a communication between each other by matching a wireless LAN and a wireless sensor network. In addition, the access point apparatus 100 may be applied to communication networks capable of connecting two different heterogeneous networks, such as an Internet (IP network) network and a wireless sensor network, as well as a wireless LAN.

5 is a block diagram illustrating a wireless communication network system 300 to which an access point device according to an embodiment of the present invention is applied. Referring to FIG. 5, the wireless communication network system 300 includes a plurality of sensor nodes 311-316, an access point device 321, a plurality of stations 322-324, and wired terminal devices 341. -343). The number of stations, wired terminal devices, and sensor nodes included in the wireless communication network system 300 may be increased or decreased. In addition, the configuration and specific operation of the access point device 321 is substantially the same as the access point device 100 described above with reference to FIG. Therefore, the configuration and detailed operation description of the access point device 100 will be omitted. In addition, the operation of the wireless communication network system 300 will be described with reference to the access point apparatus 100 illustrated in FIG. 3.

The plurality of sensor nodes 311-316 form a wireless sensor network 310, and each of the sensor nodes 311-316 generates sensing data SNDT by sensing various situations of a surrounding environment. Here, the shape of the wireless sensor network formed by the plurality of sensor nodes 311-316 may be variously changed according to the control of the user or the user through an organic communication method. Such a wireless sensor network may be formed of various types of wireless sensor networking topologies such as, for example, a star, a mesh, a hybrid, and the like. In addition, the plurality of sensor nodes 311-316 may include first digital data (FDAT) (see FIG. 3) or sensing control information including sensing control information received from the access point device 321. In response to the digital data SDAT (see FIG. 3), driving of the corresponding devices is controlled. For example, when the sensor node 311 senses a temperature, the sensor node 311 responds to the first digital data FDAT or the second digital data SDAT including sensing control information. It is possible to control the driving of the heating and cooling device. Meanwhile, the plurality of sensor nodes 311-316 may communicate with each other. For example, the sensor node 313 located near the access point device 321 transmits a signal received from the access point device 321 to the sensor node 311 far from the access point device 321. I can relay it.

The access point device 321 is connected to a wired network 330 and provides a communication channel 320 within its wireless communication cell area, and the wired network 330 by the plurality of stations 322-324. ) To control the connection. In addition, the access point apparatus 321 generates situation information data SIFD based on the sensing data SNDT, and the stations 322-324 or the plurality of stations that request the situation information data SIFD. The situation information data SIFD is provided to a plurality of wired terminal devices 341-343.

In addition, the access point apparatus 321 transmits the first digital data FDAT including sensor control information received from the plurality of stations to the plurality of sensor nodes 311-316. The second digital data SDAT including sensor control information received from wired terminal devices 341-343 of the plurality of sensors is transmitted to the plurality of sensor nodes 311-316. The wired terminal devices 341-343 are connected to the wired network 330, and the plurality of sensor nodes 311-316 of the wireless sensor network 310 through the access point device 321, or Communicate with the plurality of stations 322-324.

As described above, according to the present invention, users recognize situation information sensed from the plurality of sensor nodes 311-316 through the stations 322-324 or the wired terminal devices 341-343. The driving of the devices may be controlled by controlling the plurality of sensor nodes 311-316. As a result, in the communication network system 300, communication between the wireless sensor network 310, the wireless LAN network (or communication channel) 320, and the wired network 330 is possible and information exchange between each other is possible.

Although the preferred embodiments of the present invention have been described with reference to the embodiments shown in the drawings, the present invention is not limited thereto, and the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the accompanying drawings. It is possible and this also belongs to the present invention.

As described above, the access point device and the wireless communication network system including the same can support communication between a wireless LAN communication network, a wireless sensor network, and a wired communication network, and are connected to the wireless LAN communication network or the wired communication network. It is possible to recognize the situation sensed by the wireless sensor network and to allow the users to control the wireless sensor network appropriately, thereby increasing the economic efficiency of the communication system to provide a ubiquitous environment. have.

Claims (9)

An access point device connected to a wired network and providing a communication channel within its wireless communication cell area, Controlling access of the wired network by a plurality of stations sharing the communication channel, converting medium access control (MAC) frame received data from one of the plurality of stations into first digital data, and outputting the first digital data; A MAC engine for converting the second digital data or context information data into MAC frame transmission data and outputting the same; Transmit the first digital data to a plurality of sensor nodes of the wired network or a wireless sensor network, and transmit the second digital data received from the wired network to the MAC engine or the plurality of sensor nodes, and A central processing unit generating the contextual information data based on sensing data received from a plurality of sensor nodes and transmitting the contextual information data to the wired network or the MAC engine; And And a wireless transceiver supporting wireless communication between the plurality of stations and the MAC engine, and supporting wireless communication between the plurality of sensor nodes and the central processing unit. The method of claim 1, The central processing unit transmits the first digital data to the wired network when the first digital data includes communication information, and the first digital data when the first digital data includes sensor control information. And an access point device for transmitting to the plurality of sensor nodes via the wireless transceiver. The method of claim 1, The central processing unit transmits the second digital data to the MAC engine when the second digital data includes communication information, and transmits the second digital data to the MAC engine when the second digital data includes sensor control information. And an access point device for transmitting to the plurality of sensor nodes via the wireless transceiver. The method of claim 1, The central processing unit transmits the contextual information data to the MAC engine when one of the plurality of stations requests the contextual information data, and one of the wired terminal devices communicating with the central processing unit via the wired network. And requesting the contextual information data, transmitting the contextual information data to the wired network. According to claim 1, The wireless transceiver, A modem for converting physical layer (PHY) frame received data into the MAC frame received data and outputting the MAC frame received data to the MAC engine; Converting the first RF received signal received from the plurality of stations into the PHY frame received data and outputting the converted PHY frame received data to the modem, and converting the PHY frame transmitted data into a first RF transmitted signal and transmitting the first RF transmitted signal to the plurality of stations; A first RF unit; And Converts the second RF received signals received from the plurality of sensor nodes into the sensing data and outputs them to the central processing unit, and converts the first or second digital data received from the central processing unit into a second RF transmission signal; And a second RF unit to transmit to the plurality of sensor nodes. The method of claim 1, wherein the central processing unit, Converts the first digital data received from the MAC engine into a wired packet and transmits it to the wired network, or transmits the first digital data to the plurality of sensor nodes, and transmits the second digital data to the MAC engine or The microcomputer transmits to the plurality of sensor nodes, collects and analyzes sensing data received from the plurality of sensor nodes, generates the context information data, and transmits the context information data to the wired network or the MAC engine. A processor; A wireless sensor interface for interfacing the microprocessor and the wireless transceiver; A host bus interface that interfaces the microprocessor and the MAC engine; A wired media interface for interfacing the microprocessor with the wired network; A wired transceiver for transmitting and receiving communication signals between the wired media interface and the wired network; And And a memory storing programs to be executed in the microprocessor. The method of claim 6, wherein the microprocessor, Means for gathering contextual information from the sensing data; Means for converting the aggregated contextual information into meaningful contextual information data; And When the first digital data includes request information of the contextual information data from one of the plurality of stations, the contextual information data is transmitted to the MAC engine, and the first digital data is transmitted to the plurality of stations. Among the wired terminal devices, when including the sensor control information from one of the, the first digital data to the plurality of sensor nodes, the second digital data communicates with the microprocessor over the wired network. When the request information of the contextual information data from one is included, the contextual information data is transmitted to the wired terminal devices, and the second digital data includes the sensor control information of one of the wired terminal devices. And means for transmitting the second digital data to the plurality of sensor nodes. Access point device. Forming a wireless sensor network, each sensing the circumstances of the surrounding environment to generate sensing data, and in response to the first digital data including the sensing control information or the second digital data including the sensing control information, A plurality of sensor nodes for controlling driving; A plurality of stations sharing a predetermined communication channel and wirelessly communicating over the communication channel; A plurality of wired terminal devices connected to a wired network; And The plurality of stations or the plurality of wires connected to the wired network and providing the communication channel within its wireless communication cell area, generating situation information data based on the sensing data, and requesting the situation information data. Providing the contextual information data to terminal devices, transmitting the first digital data received from one of the plurality of stations to the wired network or the plurality of sensor nodes, and receiving from the wired network. 2) an access point device for transmitting digital data to the plurality of stations or the plurality of sensor nodes. The method of claim 8, wherein the access point device, Controlling access of the wired network by the plurality of stations, converting medium access control (MAC) frame received data from one of the plurality of stations into first digital data, and outputting the second digital data; A MAC engine that converts the situation information data into MAC frame transmission data and outputs it; Transmitting the first digital data to the wired network or the plurality of sensor nodes, transmitting the second digital data received from the wired network to the MAC engine or the plurality of sensor nodes, and transmitting the plurality of sensors. A central processing unit generating the contextual information data based on sensing data received from nodes, and transmitting the contextual information data to the wired network or the MAC engine; And And a wireless transceiver supporting wireless communication between the plurality of stations and the MAC engine, and supporting wireless communication between the plurality of sensor nodes and the central processing unit.

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