JP2006101147A - Communication apparatus for radio lan, communication method of radio lan, and program for communication apparatus for radio lan - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent deterioration in information quality even when a plurality of types of communication information having different priority of communication are used as communication information through radio LAN. <P>SOLUTION: The communication apparatus for radio LAN monitors the length of the idle time of the radio LAN prior to sending a transmission packet, and sends the transmission packet to the radio LAN when the idle time is not less than a predetermined length. The apparatus is provided with a priority determining means 117 for determining whether or not the transmission information of the transmission packet has high priority. The apparatus is also provided with a radio LAN monitoring means 120 for allocating a predetermined value as the set value of the idle time to monitor the radio LAN when the priority determining means determines that the transmission packet is transmission information having low priority, and allocating a value lower than the predetermined value to monitor the radio LAN when the priority determining means determines that the transmission packet is transmission information having high priority. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention uses a wireless LAN (Local Area Network), for example, a wireless LAN communication device applied to a wireless LAN system for transmitting streaming information such as audio information or video information, computer data, and the like. The present invention relates to a communication method and a wireless LAN communication device program.

  As a wireless LAN, for example, an IEEE (The Institute of Electrical and Electronics Engineers, Inc.) 802.11 standard is becoming widespread.

  In the case of the wireless LAN of the IEEE 802.11 standard, there is one connection between a wireless LAN access point device (hereinafter simply referred to as an access point device) and a wireless LAN terminal side station device (hereinafter simply referred to as a station device). Frequency is used. A CSMA / CA (Carrier Sense Multiple Access Collision Avoidance Method) system avoids wireless communication conflicts, and enables simultaneous communication between a plurality of station devices and access point devices. (See, for example, Patent Document 1 (Japanese Patent Laid-Open No. 11-308673)).

  That is, the access point device and the station device check whether the wireless LAN is in use by checking whether a carrier wave exists in the wireless LAN. Then, after confirming that the wireless LAN is free, transmission information is transmitted.

  In this case, the access point device or the station device does not send the transmission information immediately upon detecting the availability of the wireless LAN. For example, as shown in FIG. The transmission information is transmitted for the first time when it is detected that the idle time of the wireless LAN has continued for the set time or longer.

  Recently, the setting value of the vacant monitoring time for sending transmission information to the wireless LAN can be set by a user by inputting a setting, and a frame transmission interval (AIFS; Arbitration Interchange) can be set. This is called “Frame Space”. Hereinafter, this set value is referred to as an AIFS set value.

  In the case of a wireless LAN of the IEEE 802.11 standard, the maximum value of the data amount that can be transmitted in one packet is determined to be 1.5 KB, and data having a data amount larger than this maximum value is 1.5 KB. The data is divided into the following packets, and transmitted in units of divided data packets. The wireless LAN vacancy monitoring process is performed for each packet transmission.

The above-mentioned patent documents are as follows.
JP 11-308673 A

  By the way, even if the AIFS setting value can be set by the user, conventionally, the AIFS setting value is a value common to all information. However, there are various types of information communicated by the wireless LAN, and when the AIFS setting value is a value common to all information, the communication quality may be deteriorated depending on the information.

  That is, for example, streaming information such as audio information and video information (information that is reproduced simultaneously while reading information) has a so-called real-time property, and therefore must be communicated with priority as much as possible. Don't be.

  However, as described above, when the AIFS setting value is a value common to all information, when there is another communication request for computer data or the like, depending on the timing, only the computer data is transmitted through the wireless LAN, and streaming is performed. Information transmission is awaited. When the streaming information exceeds the buffer capacity and is in a waiting state for transmission, so-called packet discard occurs, and sound quality and image quality are impaired.

  In view of the above points, an object of the present invention is to prevent deterioration of information quality even when a plurality of types of transmission information having different communication priorities are used as communication information via a wireless LAN. And

In order to solve the above problems, the invention of claim 1
In a wireless LAN communication device that monitors the length of a wireless LAN idle time before sending a transmission packet and sends the transmission packet to the wireless LAN when the idle time is equal to or greater than a set value. ,
Priority determination means for determining the priority of transmission information of the transmission packet;
When the priority determination means determines that the transmission packet is transmission information with a low priority, the wireless LAN is monitored with the set value of the idle time as a predetermined value, and the transmission packet has the priority A wireless LAN communication device comprising: a wireless LAN monitoring unit configured to monitor the wireless LAN by setting a setting value of the idle time smaller than the predetermined value when it is determined that the transmission information is high. provide.

  In the first aspect of the invention, the priority determining means determines whether the transmission information has a high priority, for example, streaming information, or has a lower priority than the streaming information, such as computer data. . When it is determined that the transmission information has a low priority, the wireless LAN vacancy monitoring is performed by setting the vacant time setting value to a predetermined value that is normally used, for example.

  On the other hand, when the priority determination unit determines that the transmission information has a high priority, such as streaming information, the setting value of the idle time is set to a value smaller than the predetermined value. LAN vacancy monitoring is performed.

  Accordingly, when the transmission information is high priority information such as streaming information, the transmission information is more often sent to the wireless LAN in preference to the low priority information, thereby preventing deterioration of information quality. be able to.

According to a second aspect of the present invention, in the wireless LAN communication device according to the first aspect,
A communication status determining means for determining whether or not the transmission packet of the transmission information with high priority is in a state of communicating through the wireless LAN;
When the communication status determining means determines that the transmission packet of the transmission information with high priority is not communicating through the wireless LAN, the free time for the transmission packet of the transmission information with low priority When the communication status determination unit determines that the transmission packet of the transmission information having a high priority is in a state of being communicated through the wireless LAN, the setting value of is changed to a value smaller than the predetermined value. There is provided a wireless LAN communication device, comprising: a vacant time setting value changing unit that sets the vacant time setting value for a transmission packet of transmission information having a low priority as the predetermined value.

  In the invention of claim 2, when it is determined by the communication status determination means that communication of transmission information with high priority is not being performed through the wireless LAN, a setting value of free time for transmission information with low priority However, the value is changed to a value smaller than a predetermined value, and the wireless LAN vacancy is monitored.

  Therefore, at this time, even if the transmission information has a low priority, the total transmission time can be shortened.

  According to the first aspect of the present invention, even when a plurality of types of transmission information having different communication priorities are used as communication information through the wireless LAN, it is possible to prevent deterioration of information quality. According to the invention of claim 2, in addition to preventing the deterioration of information quality, the wireless LAN can be effectively used, and the transmission rate as a whole can be improved.

  Embodiments of the present invention will be described below with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram showing an example of the overall configuration of a wireless LAN system in which an embodiment of a wireless LAN communication apparatus according to the present invention is used. This example is an example of a system that enables telephone communication using a wireless LAN. The wireless LAN in this example conforms to the IEEE 802.11 standard, and all information is transmitted and received in packets, in addition to the voice information and information for call control.

  In FIG. 1, reference numeral 10 denotes a wireless LAN access point device (hereinafter simply referred to as an access point device), which is connected to the server device 12 through a wired LAN 11. In the case of the wireless LAN system of this example, the server device 12 also serves as a telephone communication relay / switching device (for example, corresponding to the main device of the button telephone device). In the example, it is also connected to a public switched telephone network (PSTN) 14.

  The access point device 10 is an embodiment of a wireless LAN communication device according to the present invention. The access point device 10 is provided with one or a plurality of wireless LAN terminal side station devices (hereinafter simply referred to as station devices) 20, which are connected by wireless links. A wireless link formed between the access point device 10 and one or a plurality of station devices 20 constitutes a wireless LAN 15.

  The station apparatus 20 is also an embodiment of a wireless LAN communication apparatus according to the present invention. In this example, a packet telephone 30 and a personal computer 31 as examples of communication terminals are connected to each of the station devices 20.

  The server device 12 manages address information on the wireless LAN 15 for the packet telephone 30 and the personal computer 31 connected to the wireless LAN 15 via the station device 20.

  The server device 12 manages a communication path for telephone communication through the wireless LAN 15 and a communication path between the personal computer 31 and another communication network. For example, the server device 12 uses the address information managed by the wireless LAN 15 and the server device between any one of the packet telephones 30 and the other packet telephone 30. Communication control and management of extension calls through 12 are performed.

  The server device 12 also controls and manages communication (external line call) between other telephone terminals via the external network 14 and the packet telephone 30 via the access point device 10 and the wireless LAN 15.

  Incoming calls coming from the other party through the external network 14 are delivered to the server device 12 through the gateway 13. The server device 12 analyzes the information of the incoming call, and when the information specifying the specific packet telephone among the plurality of packet telephones 30 is included, the server apparatus 12 is addressed to the packet telephone 30 and in other cases In this case, the incoming call information is packetized to all packet telephones 30 and sent to the station device 20 through the access point device 10 and the wireless LAN 15.

  The station device 20 transfers the incoming call to the packet telephone 30. The packet phone 30 notifies the user of the incoming call by, for example, ringing a bell. When the user of one of the plurality of packet telephones 30 responds to this incoming call, the response message is transmitted from the packet telephone 30 that has made the response to the access point apparatus 10 through the station apparatus 20 and through the wireless LAN 15. Is done.

  The access point device 10 sends this response to the server device 12, and the server device 12 sends this response to the external network 14 through the gateway 13 to notify the other party. As a result, a call path through the wireless LAN 15 is formed, and voice packets are transmitted through the wireless LAN 15 to make a call.

  When one of the users of the plurality of packet telephones 30 performs a call origination operation, the call is received at the call destination by a reverse route to that described above. A voice communication path is formed, and voice packets are transmitted through the wireless LAN 15 to make a call.

  In this embodiment, the personal computer 31 can access a communication network such as the Internet through the wireless LAN 15 and the server device 12, and data is transmitted from the server device connected to the communication network. Data can be downloaded or uploaded to the server device.

  In this embodiment, in the access point device 10 and the station device 20, the transmission information transmitted to the wireless LAN 15 is divided into priority information and information that does not need to be prioritized. For example, streaming information such as telephone call voice is set as priority information, and computer data other than streaming information (including audio data and image data to be reproduced later) is set as non-priority information. Information that is to be transmitted with priority as much as possible, such as a response packet to an incoming call of telephone communication and a call packet, is also regarded as priority information.

  In this way, whether it is priority information or non-priority information is determined in advance. For example, by checking information identification information such as a port number included in the packet header, it is priority information or non-priority information. Can be determined.

  In this embodiment, the access point device 10 and the station device 20 include a transmission buffer for transmission packets to be transmitted to the wireless LAN 15, a priority buffer unit that sequentially accumulates priority information packets as a queue, The priority information packets are managed separately in a non-priority buffer unit that sequentially accumulates as a queue.

  In this specification, in the following description, the queue of priority information packets stored in the priority buffer unit is referred to as a priority queue, and the queue of non-priority information packets stored in the non-priority buffer is referred to as a queue. This is called a non-priority queue.

  In this embodiment, the AIFS setting value FSp for the priority queue is different from the initial value of the AIFS setting value FSn for the non-priority queue, and the packet in the priority queue is given priority to the wireless LAN 15 as FSp <FSn. Control to be sent out. In this embodiment, the AIFS setting value FSp for the priority queue is a fixed value. However, the AIFS setting value FSn for the non-priority queue monitors the communication status of the wireless LAN and transmits packet communication of priority information through the wireless LAN 15. If not, the AIFS setting value FSn for the non-priority queue is changed to a smaller value, for example, the same value as the AIFS setting value FSp for the priority queue.

  This is because when the AIFS setting value for the non-priority queue is set to a fixed value, the AIFS setting value remains relatively large even though the priority information packet is not communicated, and the throughput of the non-priority information This is in order to avoid remaining in a lowered state.

  In other words, in an environment where priority queues and non-priority queues coexist, transmission of packets in priority queues is prioritized, so there is no way to reduce the throughput of packets in non-priority queues. In an environment where only packets in the non-priority queue exist, in this embodiment, the AIFS setting value for the packets in the non-priority queue is changed to a small value so as to improve the throughput.

  In particular, when the non-priority information is large-capacity information, as described above, since it is divided into a plurality of packets of 1.5 KB and transmitted, the throughput deteriorates by the AIFS setting value. In form, it is improved.

<Hardware Configuration of Access Point Device 10>
FIG. 2 is a block diagram illustrating a hardware configuration example of the access point device 10.

The access point device 10 in this example includes a control unit 101 made of, for example, a microcomputer, a wired LAN interface (in the figure, the interface is described as I / F; the same applies hereinafter) 102, a transmission processing circuit 103, and a reception process. The circuit 104 includes a transmission amplifier 105, a reception amplifier 106, an antenna switching circuit 107, a transmission / reception antenna 108, and a transmission / reception antenna 109.

  In this example, the wired LAN interface 102 is connected to the server device 12 through the wired LAN 11. The two transmission / reception antennas 108 and 109 constitute a diversity antenna and are used for transmitting and receiving packets through the wireless LAN 15.

  In the access point device 10, a transmission packet from the server device 12 obtained through the wired LAN interface 102 is transmitted / received via the transmission processing circuit 103 and the amplifier 105 and the antenna switching circuit 107 in accordance with the control of the control unit 101. The signal is supplied to one of the antennas 108 and 109 and wirelessly transmitted to the station apparatus 20.

  A packet from the station apparatus 20 received through one of the transmission / reception antennas 108 and 109 is supplied to the reception processing circuit 104 through the antenna switching circuit 107 and the amplifier 106. The packet from the reception processing circuit 104 is supplied to the control unit 101. The control unit 101 sends the received packet to the server device 12 through the wired LAN interface 102 and the wired LAN 11.

  The server device 12 analyzes the call control packet when the received packet is a call control packet, and sends the packet to the external network 14 through the gateway 13 when the packet is transmitted to the outside. As a result of the analysis, if it is a call control packet for an extension call, it is sent to the access point device 10 through the wired LAN 11.

  The access point device 10 receives this via the wired LAN interface 102 and supplies it to the transmission processing circuit 103 and the amplifier 105 and also to one of the transmission / reception antennas 108 or 109 via the antenna switching circuit 107 to the station device 20. Wirelessly transmit.

  The control unit 101 is configured by a microcomputer, and has, for example, a block configuration as shown in FIG. That is, for a CPU (Central Processing Unit) 110, a ROM (Read Only Memory) 112, a RAM (Random Access Memory) 113, a packet decomposition / generation unit 114, a reception buffer 115, and the like via a system bus 111. The transmission buffer 116, the wireless transmission priority determination unit 117, the wireless LAN availability monitoring unit 118, the AIFS setting value dynamic determination unit 119, and the AIFS setting value holding unit 120 are connected.

  Although omitted in FIG. 2, the control unit 101 also includes a port connected to the wired LAN interface 102, a transmission processing circuit 103, a port for exchanging control information and transmission / reception information with the reception processing circuit 104, and the like. Is.

  As described above, the transmission buffer 116 has a priority queue buffer 116a that sequentially accumulates priority information packets as a queue, and a non-priority information buffer that sequentially accumulates non-priority information packets as a queue. The priority queue buffer unit 116b is divided.

  The wireless transmission priority determination unit 117 recognizes transmission information of the packet from the port number of the header of the packet from the server device 12 received through the wired LAN interface 102, and determines whether the information is priority information or non-priority information. Then, the packet determined as the priority information by the wireless transmission priority determination unit 117 is written in the priority queue buffer unit 116a of the transmission buffer 116, and the packet determined as the non-priority information is not stored in the transmission buffer 116. It is written in the buffer unit 116b for the priority queue.

  The AIFS setting value holding unit 118 holds the AIFS setting value FSp for the priority queue and the AFIS setting value FSn for the non-priority queue. In this embodiment, the initial values of the AIFS setting value FSp for the priority queue and the AFIS setting value FSn for the non-priority queue are set in advance. The user may be able to set initial values of the AIFS setting value FSp for the priority queue and the AFIS setting value FSn for the non-priority queue.

  In this embodiment, the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118 is dynamically changed according to the communication status of the wireless LAN 15.

  In this embodiment, the AIFS setting value dynamic determination unit 119 monitors the communication status of the wireless LAN 15 and determines that the priority information packet communication is not performed in the wireless LAN 15 as will be described later. The AFIS setting value FSn for the non-priority queue in the holding unit 118 is changed to a value smaller than the initial value. When the AIFS setting value dynamic determination unit 119 determines that the communication of the priority information packet is being performed in the wireless LAN 15, the AFIS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118 is set to the initial value. Set.

  The wireless LAN availability monitoring unit 120 performs availability monitoring for the wireless LAN 15, but when the transmission packet is a packet in the priority queue, the availability monitoring is performed using the AIFS setting value FSp for the priority queue of the AIFS setting value holding unit 118. Also, when the transmission packet is a packet in the non-priority queue, idle monitoring is performed using the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118. When the wireless LAN availability monitoring unit 120 confirms that the wireless LAN 15 is available, the control unit 110 transmits a transmission packet to the wireless LAN 15.

  Note that the wireless transmission priority determination unit 117, the AIFS set value dynamic determination unit 119, and the wireless LAN availability monitoring unit 120 are software that the CPU 110 performs using the RAM 113 as a work area based on a software program stored in the ROM 112. Wear processing.

<Hardware configuration of station device>
The station apparatus 20 basically has the same configuration as that of the access point apparatus 10. FIG. 3 shows a block diagram of a configuration example of the station apparatus 20.

  That is, the station device 20 includes, for example, a control unit 201 including a microcomputer, a terminal interface 202, a transmission processing circuit 203, a reception processing circuit 204, a transmission amplifier 205, a reception amplifier 206, An antenna switching circuit 207 and transmission / reception antennas 208 and 209 are provided.

  In this example, the terminal interface 202 is connected to the packet telephone 30 or the personal computer 31. The transmission / reception antennas 208 and 209 are for transmitting and receiving packets through the wireless LAN 15.

  When the packet telephone 30 is connected through the terminal interface 202, the station apparatus 20 transmits a call setup message packet or a voice communication information packet from the packet telephone 30 to the access point apparatus 10 through the transmission / reception antenna 208 or 209. Send. Also, the received packet from the access point device 10 is sent to the packet telephone 30 through the terminal interface 202.

  When the personal computer 31 is connected through the terminal interface 202, the station device 20 sends an access request packet or a packet such as upload data from the personal computer 31 to the access point device 10 through the transmission / reception antenna 208 or 209. Send. Also, a received packet such as download data from the access point device 10 is sent to the personal computer 31 through the terminal interface 202.

  And the control part 201 is provided with the structure similar to the control part 101 of the access point apparatus 10, and is set as a block structure as shown in FIG. 3 in this embodiment. That is, for the CPU 210 via the system bus 211, the ROM 212, the RAM 213, the packet decomposition / generation unit 214, the reception buffer 215, the transmission buffer 216, the wireless transmission priority determination unit 217, and the wireless LAN free space A monitoring unit 218, an AIFS setting value dynamic determination unit 219, and an AIFS setting value holding unit 220 are connected.

  As in the case of the access point device 10, the transmission buffer 216 stores a priority queue buffer 116a that sequentially stores priority information packets as a queue, and sequentially stores non-priority information packets as a queue. It is divided into a non-priority queue buffer unit 116b.

  In addition, the wireless transmission priority determination unit 217, the wireless LAN availability monitoring unit 218, the AIFS setting value dynamic determination unit 219, and the AIFS setting value holding unit 220 have the same configuration as that of the access point device 10 described above. The same operation is performed.

<Example of hardware configuration of packet phone>
FIG. 4 shows a hardware configuration example of the packet telephone 30 of this embodiment. As shown in FIG. 4, the packet telephone 30 of this embodiment includes a terminal main body 300 and a handset HS. Although not shown, the handset HS includes a microphone that constitutes a transmitter, a transmission amplifier, a speaker that constitutes a receiver, and a reception amplifier.

  The terminal main body 300 is configured by a computer, and with respect to the CPU 310 via the system bus 311, ROM 312, RAM 313, display controller 314, operation input interface 316, station interface 318, packet decomposition / generation The unit 319 and the audio data input / output interface 320 are connected.

  A display 315 is connected to the display controller 314, and a display according to the control of the CPU 310 is performed on the display screen of the display 315.

  The operation input interface 316 is connected to an operation input unit 317 including numeric keys, cursor keys, and other operation keys. The CPU 310 recognizes which input key the user has operated through the operation input unit 317 via the operation input interface 316, and executes processing corresponding to the key input operation according to the program of the ROM 312 based on the recognition result. To do.

  The ROM 312 stores a program for executing a processing sequence at the time of transmission or reception according to a status signal of the wireless LAN 15, a program for executing other processing, and the like.

  The RAM 313 is mainly used as a work area when the program of the ROM 312 is executed by the CPU 310.

  The station interface 318 is connected to the station device, and has a function of capturing packetized data transmitted through the station device and transmitting the packetized data to the LAN 31A.

  The packet disassembly / generation unit 319 disassembles the packetized data received by the interface 318 to obtain control data and audio data, and generates packetized data that is packetized from the control data and audio data to be transmitted and transmitted. It has a function. The packet decomposition / generation unit 319 includes a buffer memory for decomposing and generating packetized data.

  The packet decomposition processing function and the generation processing function of the packet decomposition / generation unit 319 can also be realized as software by the CPU 310 and the ROM 312.

  The audio data input / output interface 320 converts audio data obtained by packet decomposition into an analog audio signal and supplies the analog audio signal to the handset HS, and converts an analog audio signal input from the handset HS into a digital signal and takes it in. It has a function.

<Transmission Control Processing Operation of Access Point Device>
FIG. 5 shows an example of the AIFS setting value FSp for the priority queue and the AFIS setting value FSn for the non-priority queue held in the AIFS setting value holding unit 118. In this example, the initial values of the AIFS setting value FSp for the priority queue and the AFIS setting value FSn for the non-priority queue are, for example, FSp = 2 (microseconds) and FSn = 17 (microseconds).

  In this embodiment, the AFIS setting value FSn for the non-priority queue is FSn in this example in an environment where the priority information packet is not communicated by the AIFS setting value dynamic determination unit 119 through the wireless LAN. = 2 (microseconds). When the communication of the priority information packet is resumed through the wireless LAN, the AIFS setting value dynamic determination unit 119 returns the AFIS setting value FSn for the non-priority queue to FSn = 17.

  The wireless LAN availability monitoring unit 120 monitors the availability of the wireless LAN 15 using the setting values FSp and FSn of the AIFS setting value holding unit 118. FIG. 6 shows a flowchart of the processing operation of the wireless LAN availability monitoring unit 120. Here, the wireless LAN availability monitoring unit 120 is a part of software processing by the CPU 110, and the flowchart in FIG. 6 is described as processing performed by the CPU 110 using the RAM 113 as a work area according to the program of the ROM 112.

  First, the CPU 110 determines whether or not the packet to be transmitted is a priority information packet (step S1). In the case of this embodiment, when there is a packet waiting for transmission in the priority queue, this step S1 determines whether or not there is a packet waiting for transmission in the priority queue in order to preferentially send out the packet in the priority queue. It is possible to determine whether it is a packet of priority information. Of course, the port number in the header of the packet to be transmitted may be checked to determine whether it is a priority information packet.

  If it is determined in step S1 that the packet to be transmitted is a packet of priority information, the CPU 110 uses the AIFS setting value FSp for the priority queue held in the AIFS setting value holding unit 118, and the wireless LAN 15 Is monitored (step S2).

  The CPU 110 determines whether the wireless LAN 15 is available and determines whether or not the transmission packet can be transmitted (step S3). When determining that the transmission packet can be transmitted, the CPU 110 determines whether or not the transmission packet can be transmitted. Then, the transmission packet is transmitted to the wireless LAN 15 (step S4).

  When it is determined in step S1 that the packet to be transmitted is a packet of non-priority information, the CPU 110 uses the AIFS setting value FSn for the non-priority queue held in the AIFS setting value holding unit 118 to perform wireless communication. The vacancy of the LAN 15 is monitored (step S5).

  The CPU 110 determines whether or not the wireless LAN 15 is available and determines whether or not the transmission packet can be transmitted (step S6). When determining that the transmission packet can be transmitted, the CPU 110 determines whether or not the transmission packet can be transmitted. Then, the transmission packet is transmitted to the wireless LAN 15 (step S4).

  Next, the processing operation of the AIFS set value dynamic determination unit 119 in the first embodiment will be described with reference to the flowchart of FIG. Here, the AIFS setting value dynamic determination unit 119 is a part of software processing by the CPU 110, and the flowchart of FIG. 7 is described as processing performed by the CPU 110 using the RAM 113 as a work area according to the program of the ROM 112. .

  The process of the flowchart of FIG. 7 is started from the start every time the access point device 10 receives a packet from the wireless LAN 15.

  First, when receiving a packet from the wireless LAN 15, the CPU 110 stores the received packet in the reception buffer 115 (step S11). The CPU 110 checks the port number in the packet header and determines whether the received packet is a priority information packet or a non-priority information packet (step S12).

  When it is determined in step S13 that the packet is priority information, the CPU 110 sets the AIFS setting value FSn for the non-priority queue held in the AIFS setting value holding unit 118 to FSn = 17 in this example. Set (step S13). Subsequently, when the non-priority information packets are continuously communicated in the wireless LAN 15, the CPU 110 calculates the count number of the consecutive non-priority information packets (hereinafter referred to as non-priority continuous count value) CT. , CT = 0 is cleared (step S14). Then, the process routine is exited.

  If it is determined in step S12 that the received packet is a packet of non-priority information, the CPU 110 increments the non-priority continuous count value CT by 1 (step S15). It is determined whether or not a predetermined constant, for example, 3 or more (step S16).

  In other words, in the first embodiment, whether or not priority information packets are not being communicated in the wireless LAN 15 is determined in step S16 by a predetermined number or more of non-priority information packets. Judgment is made based on whether or not communication is being performed.

  In step S16, when it is determined that the non-priority continuous count value CT is equal to or larger than a predetermined constant, it is determined that the wireless LAN 15 is not in communication with the packet of priority information. The CPU 110 changes and sets the AIFS setting value FSn for the non-priority queue held in the AIFS setting value holding unit 118, which is smaller than the initial value, in this example, FSn = 2 (step S17).

  Subsequently, the CPU 110 clears the non-priority continuous count value CT as CT = 0 (step S18). Then, the process routine is exited.

  As described above, in the above-described embodiment, the AIFS setting value FSp when sending the priority information packet is smaller than the AIFS setting value FSn when sending the non-priority information packet. The priority information can always be given priority over non-priority information such as computer data, and communication can be performed via the wireless LAN 15. For this reason, when the priority information is call voice, packet discarding can be prevented and a voice quality call can be made.

  In an environment in which communication of priority information packets is not performed through the wireless LAN 15, the AIFS setting value FSn when sending the non-priority information packets is changed to a value smaller than the initial value. Thereby, the throughput of transmission of non-priority information can be improved.

<Transmission Control Processing Operation of Station Device 20>
Also in the station device 20, the same operation and effect as in the case of the access point device 10 described above can be obtained by performing the same transmission control processing operation as that of the access point device 10 described above.

  However, in the case of the station device 20, unlike the case of the access point device 10, normally, not all packets sent through the wireless LAN 15 are received, but only packets addressed to the own device are received. As it is, the AIFS setting value dynamic determination unit 119 can also dynamically change the setting of the AIFS setting value only based on the packet addressed to the own apparatus.

  However, in this case, use through the wireless LAN 15 in other station devices is hindered. Therefore, in order to avoid this, the AIFS set value dynamic determination unit 119 receives not only packets addressed to itself but all packets sent through the wireless LAN 15, and performs processing as shown in FIG. Make the action.

[Second Embodiment]
In the second embodiment, the configuration of the wireless LAN system and the hardware configurations of the access point device 10, the station device 20, and the packet telephone 30 are the same as those in the first embodiment. In the second embodiment, only the operation of the AIFS set value dynamic determination unit 119 is different, and the other software processing operations are completely the same as those in the first embodiment.

  In the first embodiment described above, when the non-priority information packets are continuously communicated through the wireless LAN 15, the number of consecutive non-priority information packets is counted as the non-priority continuous count value CT. When the priority continuous count value CT reaches a predetermined number or more, it is determined that the packet communication of the priority information is not performed in the wireless LAN 15, and the AIFS setting value FSn for the non-priority queue is changed from FSn = 17 to FSn = 2. Changed to improve the throughput of non-priority information.

  In the second embodiment, the non-priority continuous count value CT is not used, but when a state in which the priority information packet is not communicated through the wireless LAN 15 for a predetermined time or longer is detected, the state is changed. It is determined that the priority information packet communication is not performed in the wireless LAN 15, and the AIFS setting value FSn for the non-priority queue is changed from FSn = 17 to FSn = 2 to improve the throughput of the non-priority information. To do.

  The predetermined time is set to an appropriate time for detecting that the priority information packet is not being communicated through the wireless LAN 15. This time may be set in advance in the apparatus, or may be set by the user.

<Transmission Control Processing Operation of Access Point Device>
The AIFS set value dynamic setting unit 119 of the second embodiment will also be described as being configured by software processing performed by the CPU 110 using the RAM 113 as a work area in accordance with the program of the ROM 112.

  First, the AIFS set value dynamic setting unit 119 of the second embodiment includes a monitoring task that is executed at regular intervals. That is, the CPU 110 always performs the process shown in the flowchart of FIG. First, the CPU 110 monitors whether or not a predetermined time has elapsed (step S21). When the fixed time has not elapsed, the process proceeds to other processing (step S22), and the processing routine of FIG. 8 is exited. When it is determined in step S21 that the fixed time has elapsed, the monitoring task is executed (step S23), and the process routine of FIG. 8 is exited.

  Next, the monitoring task executed in step S23 will be described with reference to the flowchart of FIG.

  The CPU 110 determines whether or not priority information packets have been received from the wireless LAN 15 for a predetermined time (step S31). When it is determined that priority information packets have been received, the CPU 110 sets the AIFS setting value FSn for the non-priority queue. The priority packet reception flag indicating that the priority information packet has been received is cleared without changing (step S32), and the monitoring task is terminated.

  If it is determined in step S31 that the priority information packet has not been received from the wireless LAN 15 during the predetermined time, the CPU 110 sets the AIFS setting value FSn for the non-priority queue to a value smaller than the initial value FSn = 2 is changed (step S32). Then, the priority packet reception flag indicating that the priority information packet has been received is cleared (step S32), and the monitoring task is terminated.

  In the second embodiment, the AIFS setting value dynamic setting unit 119 performs the process shown in the flowchart of FIG. 10 every time a packet is received from the wireless LAN 15, and if necessary, the non-priority queue. The AIFS setting value FSn for is returned to the initial value.

  That is, when the CPU 110 receives a packet from the wireless LAN 15, the CPU 110 determines whether the received packet is a packet of priority information or a packet of non-priority information, for example, by checking the port number of the packet header ( Step S41).

  When it is determined in step S41 that the received packet is a non-priority information packet, the process routine is exited as it is.

If it is determined in step S41 that the received packet is a packet of priority information, the CPU 110 returns the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118 to the initial value as FSn = 17 ( Step S42). Then, a priority packet reception flag indicating that a packet of priority information has been received is set (step S43), and this processing routine ends.

<Transmission Control Processing Operation of Station Device 20>
Also in the second embodiment, the station device 20 performs the same transmission control processing operation as the above-described transmission control processing operation of the access point device 10, so that it is the same as that of the access point device 10 described above. The effect is obtained.

  However, also in the second embodiment, the station apparatus 20 receives not only packets addressed to itself but also all packets sent through the wireless LAN 15 at the AIFS setting value dynamic determination unit 219. The processing operation as shown in FIGS. 9 and 10 is performed.

[Third Embodiment]
In the first and second embodiments described above, the access point device 10 or the station device 20 discriminates the communication status in the wireless LAN 15 and recognizes the state where the priority information packet is not communicated.

  In contrast, in the third embodiment, the access point device 10 or the station device 20 does not determine the communication status in the wireless LAN 15, but the server device 12 manages the communication status in the wireless LAN 15. The server device 12 sends an instruction to change the AIFS setting value to the access point device 10 or the station device 20 in accordance with the communication status of the wireless LAN 15.

  In the third embodiment, the access point device 10 and the station device 20 are provided with a reception port for receiving a change instruction sent from the server device 12, and the AIFS from the server device 12 that receives the change instruction through the reception port. According to the setting value change instruction, the AIFS setting value FSn of the AIFS setting value holding unit 118 is dynamically changed.

  FIG. 11 is a flowchart for explaining the AIFS setting value change instruction process of the server device 12 in the third embodiment.

  The CPU (not shown) of the server device 12 determines whether or not the priority information packet is transmitted / received through the wireless LAN 15 by determining the main information of the packet based on the port number of the packet header, for example (step S51). ). At this time, the server device 12 can also determine whether or not the packet to be transmitted to the wireless LAN 15 from the access point device 10 is a priority information packet.

  When it is determined in step S51 that the priority information packet is transmitted / received through the wireless LAN 15, the CPU of the server device 12 indicates that the AIFS setting value FSn for the packet in the non-priority queue is set to FSn = 17. An instruction to change the AIFS setting value to be generated is generated and sent to the access point device 10 (step S52). Then, this processing routine ends.

  The instruction content of the instruction to change the AIFS setting value in step S52 does not directly indicate that the AIFS setting value FSn for the packet in the non-priority queue is set to FSn = 17. Any information may be used as long as the information indicates that there is information transmission.

  When it is determined in step S51 that the priority information packet is not transmitted or received through the wireless LAN 15, the CPU of the server device 12 determines whether or not the transmission of the non-priority information packet through the wireless LAN 15 has continued for a certain period of time. Then, it is determined whether or not there is no transmission / reception of priority information packets through the wireless LAN 15 for a predetermined time (step S53).

  When it is determined in step S53 that transmission of non-priority information packets through the wireless LAN 15 has not continued for a certain period of time, the CPU of the server device 12 ends this processing routine as it is.

  If it is determined in step S53 that the transmission of the non-priority information packet through the wireless LAN 15 continues for a certain period of time, the CPU of the server device 12 sets the AIFS setting value FSn for the packet in the non-priority queue as follows: An instruction to change the AIFS set value with the instruction content of FSn = 2 is generated and sent to the access point apparatus 10 (step S52). Then, this processing routine ends.

  The instruction content of the instruction to change the AIFS setting value in step S52 does not directly indicate that the AIFS setting value FSn for the packet in the non-priority queue is set to FSn = 2. Any information may be used as long as the information indicates that no information is transmitted.

  FIG. 12 is a flowchart of the process of the access point device 10 when an instruction to change the AIFS setting value from the server device 12 is received.

  That is, the CPU 110 of the access point apparatus 10 determines whether or not an instruction to change the AIFS setting value has been received (step S61). When it is determined that no instruction to change the AIFS setting value has been received, the CPU 110 proceeds to other processing ( Step S62).

  If it is determined in step S61 that an AIFS setting value change instruction has been received, the CPU 110 transfers the AIFS setting value change instruction packet to all the station apparatuses 20 (step S63). Then, the AIFS setting value FSn for the non-priority queue in the AIFS setting value holding unit 118 is set to either FSn = 17 or FSn = 2 according to the contents of the change instruction (step S64).

  In this embodiment, the instruction to change the AIFS setting value sent from the server device 12 is a multicast packet for transfer to all the station devices 20 through the wireless LAN 15.

  When the station apparatus 20 receives the instruction to change the AIFS setting value sent from the access point apparatus 10 through the wireless LAN 15, the station apparatus 20 performs the non-operation of the AIFS setting value holding unit 218 in the same manner as in step S64 in FIG. The AIFS set value FSn for the priority queue is set to either FSn = 17 or FSn = 2 according to the contents of the change instruction.

  In the third embodiment, the AIFS setting value dynamic determination units 119 and 219 of the access point device 10 and the station device 20 check the communication status of the wireless LAN 15 as in the first embodiment and the second embodiment. The checking process is unnecessary, and it is sufficient to have a function of receiving an instruction to change the AIFS setting value and changing the AIFS setting value FSn for the non-priority queue in accordance with the changing instruction.

<Fourth Embodiment>
The fourth embodiment is a modification of the third embodiment. In the fourth embodiment, the priority information is streaming information such as call voice. The server device 12 then transmits a packet (hereinafter referred to as RTP) for notifying whether or not a communication path (hereinafter referred to as RTP path) of RTP (Real Time Packet) that is a packet of this streaming information has been generated through the wireless LAN 15. In this example, the generated RTP notification packet is transmitted to the access point device 10 as a multicast packet addressed to all the station devices 20.

  In this case, when the server apparatus 12 recognizes that the RTP path has been generated through the wireless LAN 15, the server apparatus 12 generates an RTP path notification packet notifying that the RTP path has been generated, and the RTP path through the wireless LAN 15. When there is no more, an RTP path notification packet for notifying that is generated.

  Upon receiving this RTP path notification packet, the access point apparatus 10 transmits it to the station apparatus 20 by multicast, and at the same time, sets the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118 as the RTP path. It changes dynamically according to the contents of the notification packet.

  Similarly, when receiving the RTP path notification packet, the station apparatus 20 dynamically changes the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 218 in accordance with the contents of the RTP path notification packet.

  FIG. 13 is a flowchart for explaining an RTP path notification packet generation / transmission process of the server apparatus 12 in the fourth embodiment.

  That is, in this embodiment, the CPU of the server device 12 determines whether or not an RTP path has been generated (step S71), and when it is determined that an RTP path has been generated, the content of the RTP is that an RTP path exists. A path notification packet is generated as a multicast packet and sent to the access point device 10 (step S72). Then, this processing routine ends.

  If it is determined in step S71 that the RTP path does not exist, the CPU of the server device 12 determines whether or not the RTP path has continued for a predetermined time period after the RTP path does not exist (step S71). S73).

  If it is determined in step S73 that the RTP path does not exist and has not continued for a predetermined time or more, this processing routine is terminated as it is. In step S73, when it is determined that the RTP path has been continued for a certain period of time after the RTP path no longer exists, the CPU of the server device 12 generates an RTP path notification packet having the content that no RTP path exists as a multicast packet. Then, it is sent to the access point device 10 (step S74). Then, this processing routine ends.

  Step S73 is provided in consideration of the fact that the RTP path may be formed immediately after the RTP path is lost, and that the RTP path has been lost without waiting for the predetermined time. You may make it notify by a RTP path | pass notification packet.

  FIG. 14 is a flowchart of processing of the access point device 10 when an RTP path notification packet from the server device 12 is received.

  That is, the CPU 110 of the access point device 10 determines whether or not an RTP path notification packet has been received (step S81). When it is determined that an RTP path notification packet has not been received, the CPU 110 proceeds to other processing (step S82).

  When determining in step S81 that the RTP path notification packet has been received, the CPU 110 transfers the RTP path notification packet (multicast packet) to all the station devices 20 (step S83).

  Then, the CPU 110 analyzes the content of the received RTP path notification packet to determine whether or not there is an RTP path including the wireless LAN 15 (step S84), and when determining that the RTP path exists, The AIFS setting value FSn for the non-priority queue in the AIFS setting value holding unit 118 is set to FSn = 17 (step S85). If it is determined in step S84 that no RTP path exists, the AIFS setting value FSn for the non-priority queue of the AIFS setting value holding unit 118 is set to FSn = 2 (step S86).

  When the station device 20 receives the RTP path notification packet transmitted from the access point device 10 through the wireless LAN 15, the station device 20 stores the AIFS setting value holding unit 218 in the same manner as in steps S84 to S86 in FIG. The AIFS setting value FSn for the non-priority queue is set to FSn = 17 when there is an RTP path and FSn = 2 when there is no RTP path, depending on whether or not there is an RTP path.

  According to the fourth embodiment, when applied to a telephone system, when a speech path is generated as an RTP path through the wireless LAN 15, the AIFS set value FSn of non-priority information other than speech voice is increased. Thus, when the call quality is maintained and the communication path as the RTP path does not exist, the AIFS setting value FSn of the non-priority information can be reduced to improve the throughput of the non-priority information.

  In the third and fourth embodiments, an AIFS setting value change instruction or RTP path notification packet is generated from the server apparatus, and the change instruction or RTP path notification packet is transmitted to the access point apparatus and the station apparatus. However, when a wireless LAN switch is provided in the wireless LAN system, the wireless LAN switch is provided with the same function as the server device 12 of the third embodiment and the fourth embodiment described above, An instruction to change the AIFS setting value or an RTP path notification packet may be generated from the wireless LAN switch.

[Other variations]
In the above description of the embodiment, the priority is two types, priority and non-priority. However, the priority may be set to two or more levels according to transmission information. Even in this case, if there is no transmission packet with a high priority, the AIFS setting value of the transmission packet to be transmitted may be set to a small value.

  In the above-described embodiment, only the AIFS setting value FSn for the non-priority queue is dynamically changed according to the communication state of the wireless LAN. However, the AIFS setting value FSp for the priority queue is also changed to the wireless LAN 15. It may be changed dynamically according to the communication status.

  In the above-described embodiment, the station device has a configuration of an adapter that is separate from the terminal device. However, the configuration of the adapter is not limited to a configuration that is connected to the terminal device with a cable. . For example, the station device may have a card type configuration, and the terminal device and the station device may be connected by inserting the card into the terminal device.

  The station device may be built in a terminal device such as a packet telephone or a personal computer. In this case, the configuration of the control unit other than the wireless communication function can be provided as a software program of a microcomputer provided in the terminal device.

1 is a block diagram showing an embodiment of a wireless LAN system in which an embodiment of a wireless LAN communication device according to the present invention is used. FIG. It is a block diagram which shows the structural example of the access point apparatus as embodiment of the communication apparatus for wireless LAN by this invention. It is a block diagram which shows the structural example of the station apparatus as embodiment of the communication apparatus for wireless LAN by this invention. It is a block diagram which shows the structural example of a packet telephone as an example of the terminal device used for the wireless LAN system of embodiment. It is a figure used in order to demonstrate the principal part of embodiment of this invention. It is a flowchart for demonstrating the processing operation of embodiment of this invention. It is a flowchart for demonstrating the processing operation of 1st Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 2nd Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 2nd Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 2nd Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 3rd Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 3rd Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 4th Embodiment of this invention. It is a flowchart for demonstrating the processing operation of 4th Embodiment of this invention. It is a figure for demonstrating the AIFS setting value in wireless LAN.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Access point apparatus 12 Server apparatus 20 Station apparatus 101,201 Control part 110,210 CPU
114, 214 Packet disassembly / generation unit 116, 216 Transmission buffer 117, 217 Wireless transmission priority determination unit 118, 218 AIFS setting value holding unit 119, 219 AIFS setting value dynamic determination unit 120, 220 Wireless LAN empty monitoring unit

Claims (11)

Prior to transmission of a transmission packet, the length of a free time of a wireless LAN (Local Area Network; hereinafter the same) is monitored, and when the free time is equal to or greater than a set value, the transmission packet is transmitted to the wireless LAN. In the wireless LAN communication device to be
Priority determination means for determining the priority of transmission information of the transmission packet;
When the priority determination means determines that the transmission packet is transmission information with a low priority, the wireless LAN is monitored with the set value of the idle time as a predetermined value, and the transmission packet has the priority A wireless LAN communication device comprising: a wireless LAN monitoring unit that monitors the wireless LAN by setting the idle time setting value to a value smaller than the predetermined value when it is determined that the transmission information is high. The wireless LAN communication device according to claim 1,
A communication status determining means for determining whether or not the transmission packet of the transmission information with high priority is in a state of communicating through the wireless LAN;
When the communication status determining means determines that the transmission packet of the transmission information with high priority is not communicating through the wireless LAN, the free time for the transmission packet of the transmission information with low priority When the communication status determination unit determines that the transmission packet of the transmission information having a high priority is in a state of being communicated through the wireless LAN, the setting value of is changed to a value smaller than the predetermined value. A wireless LAN communication device comprising: a free time setting value changing unit that sets the free time setting value for a transmission packet of low-priority transmission information as the predetermined value. The wireless LAN communication device according to claim 2,
The communication status determining means communicates the high-priority transmission information through the wireless LAN when the low-priority transmission information packet continues to be communicated more than a predetermined number of times through the wireless LAN. The wireless LAN communication device, wherein the wireless LAN communication device is characterized in that the set value of the idle time for the transmission information with low priority is changed to the small value. The wireless LAN communication device according to claim 2,
The communication status determination means sends the high-priority transmission information to the wireless LAN when a state in which a packet of high-priority transmission information is not communicated through the wireless LAN continues for a predetermined time period or longer. The communication device for wireless LAN, wherein it is determined that communication is not performed through, and the setting value of the idle time for the transmission information with low priority is changed to the small value. The wireless LAN communication device according to claim 2,
Means for receiving an instruction to change the setting value of the idle time for the transmission information with low priority through the wireless LAN or through another communication network;
The wireless LAN communication device, wherein the setting value of the idle time for the transmission information with a low priority is changed according to the change instruction. The wireless LAN communication device according to claim 1,
A priority buffer for temporarily storing the transmission packets with high priority in the order of transmission;
A non-priority buffer for temporarily storing the low-priority transmission packets in the order of transmission;
Holding means for holding the setting value of the idle time for the transmission packet from the priority buffer and the setting value of the idle time for the transmission packet from the non-priority buffer;
The wireless LAN monitoring unit uses the set value of the idle time held in the holding unit according to whether the next packet to be sent is from the priority buffer or the non-priority buffer. A wireless LAN communication device that monitors the idle time of the wireless LAN. In the wireless LAN communication device according to any one of claims 1 to 6,
The wireless LAN communication device, wherein the transmission information with high priority is streaming information. In a wireless LAN communication method for monitoring the length of a wireless LAN idle time before sending a transmission packet and sending the transmission packet to the wireless LAN when the idle time is equal to or greater than a set value. ,
A priority determination step of determining the priority of transmission information of the transmission packet;
When it is determined in the priority determination step that the transmission packet is transmission information with a low priority, the wireless LAN is monitored with the set value of the idle time as a predetermined value, and the transmission packet has the priority A wireless LAN communication method comprising: a wireless LAN monitoring step of monitoring the wireless LAN by setting the idle time setting value to a value smaller than the predetermined value when it is determined that the transmission information is high. The wireless LAN communication method according to claim 8,
A communication status determination step for determining whether or not the high-priority transmission information is in a state of communicating through the wireless LAN;
When it is determined in the communication status determination step that the transmission packet of the transmission information with high priority is not communicating through the wireless LAN, the free time for the transmission packet of the transmission information with low priority When the communication status determination unit determines that the transmission packet of the transmission information with high priority is in a state of being communicated through the wireless LAN, the setting value of A wireless LAN communication apparatus comprising: a free time setting value changing step in which the free time setting value for a transmission packet of transmission information having a low priority is the predetermined value. A wireless LAN communication device that detects the length of a wireless LAN idle time before sending a transmission packet and sends the transmission packet to the wireless LAN when the idle time is equal to or greater than a set value. On the computer,
A priority determination step of determining the priority of transmission information of the transmission packet;
When it is determined in the priority determination step that the transmission packet is transmission information with a low priority, the wireless LAN is monitored with the set value of the idle time as a predetermined value, and the transmission packet has the priority A wireless LAN communication device program for executing a wireless LAN monitoring step of monitoring the wireless LAN by setting the idle time setting value to a value smaller than the predetermined value when it is determined that the transmission information is high . The wireless LAN communication device program according to claim 10,
A communication status determination step for determining whether or not the high-priority transmission information is in a state of communicating through the wireless LAN;
When it is determined in the communication status determination step that the transmission packet of the transmission information with high priority is not communicating through the wireless LAN, the free time for the transmission packet of the transmission information with low priority When the communication status determination unit determines that the transmission packet of the transmission information having a high priority is in a state of being communicated through the wireless LAN, the setting value of is changed to a value smaller than the predetermined value. A program for a wireless LAN communication device, comprising: a vacant time setting value changing step in which the vacant time setting value for a transmission packet of transmission information having a low priority is the predetermined value.

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