JP2016134894A - Communication device having radio wave interference prevention function, and control method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid radio wave interference generated in radio systems having different radio communication methods using the same frequency band.SOLUTION: A communication device on which a module capable of individually communicating with a first terminal connected to a sensor network and a second terminal connected to an IP system radio network is mounted comprises: means for predicting the first terminal's reception time of a data frame from the sensor network; means for predicting transmission time, immediately before the predicted reception time of the data frame, of a management frame out of management frames transmitted to the IP system radio network by the second terminal; and means for changing a frame transmission interval and contention window at the predicted management frame's transmission time, so that a radio wave for transmitting a control frame showing a response to a data frame and a radio wave for transmitting a data frame from the second terminal or a third terminal connected to the IP system radio network do not interfere with each other.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a communication apparatus and a control method for avoiding radio wave interference that occurs in radio systems of different radio communication systems that use the same frequency band, and more specifically, different radios of a sensor network and an IP radio network The present invention relates to a communication apparatus capable of avoiding a collision between frames of a sensor network and an IP wireless network in an environment where communication methods coexist, and a control method thereof.

  An environment in which a terminal (ZigBee terminal: for example, ZigBee coordinator or ZigBee end device) connected to the sensor network and a terminal (wireless LAN terminal: for example, wireless LAN access point or wireless LAN station) connected to the IP wireless network are the same In other words, in an environment where two different wireless communication systems coexist, two networks may use the same frequency band. Under such circumstances, when data frames are transmitted simultaneously to the sensor network and the IP wireless network, there is radio wave interference between the radio wave to the sensor network and the radio wave to the IP wireless network. Occur. In order to prevent such radio wave interference, carrier sense is performed in each communication method to confirm that radio waves from other devices or the like are not sent out before sending out the own radio waves.

  FIG. 1 is a diagram showing a state of data transmission / reception of terminals connected to respective networks in an environment in which a plurality of different wireless communication systems of a sensor network and an IP wireless network coexist. In FIG. 1, when a terminal (ZigBee coordinator) connected to the sensor network receives a data frame 101, a control for notifying (responding) that data has been successfully received after a certain period of time since receiving the data frame 101. An (ACK) frame 102 is transmitted.

  The wireless LAN access point connected to the IP wireless network periodically transmits a management frame indicating the presence of the wireless LAN access point to a communicable terminal connected to the IP wireless network including the wireless LAN station. doing. On the other hand, the wireless LAN access point may transmit the data frame 103 separately from the management frame, and the wireless LAN station may also transmit the data frame.

  Here, the ZigBee coordinator does not perform carrier sense when transmitting the control frame 102 indicating a response. On the other hand, a wireless LAN access point connected to an IP wireless network performs carrier sense when transmitting a data frame, and after a certain period of time (frame transmission interval: AIFS: Arbitration Inter-Frame Spacing) has passed. After the tension window (random waiting time) has elapsed, if no other radio wave is transmitted, the data frame 103 is transmitted. Here, the contention window (back-off time) is a waiting time set to avoid collision of data frames after the AIFS has elapsed, and is generally determined at random. The wireless LAN station also transmits a data frame if no other radio wave is transmitted after the AIFS has elapsed and the contention window has elapsed.

  Here, AIFS is a frame transmission interval, and is determined when a management frame transmitted by the wireless LAN access point is created. The management frame includes AIFSN, which is information indicating AIFS, and the wireless LAN station calculates AIFS from the AIFSN of the received management frame and reflects it.

  In this case, if use of radio waves is detected during carrier sense, carrier sense is started again after confirming that radio waves are not being used. Here, the ZigBee coordinator has not transmitted radio waves during the time from when the data frame 101 is received from the sensor network until the control frame 102 indicating the response is transmitted. Accordingly, if the wireless LAN access point (or wireless LAN station) performs carrier sense during that time, it is determined that data transmission is possible. At this time, when the wireless LAN access point (or wireless LAN station) transmits the data frame 103, the data frame 103 transmitted from the wireless LAN access point (or wireless LAN station) and the response transmitted from the ZigBee coordinator are sent. The control frame 102 shown in the figure collides (the transmission times overlap, causing radio wave interference). Then, the wireless LAN access point (or wireless LAN station) must retransmit the data frame 103, causing a reduction in communication speed.

  In response to the problem of collision between data frames, Non-Patent Document 1 discloses a busy tone between a terminal connected to a sensor network and a control frame transmission 102 indicating a response after receiving the data frame 101. It has been proposed to send. By this busy tone, it is detected that the terminal connected to the IP wireless network is in a busy state by carrier sense, and data cannot be transmitted to the IP wireless network, and as a result, collision is avoided.

  As another method, the time when the control frame indicating the response from the ZigBee coordinator and the data frame from the wireless LAN access point (or the wireless LAN station) collide is uniquely predicted, and the data frame does not collide. As described above, a method of setting the transmission interval of frames from the wireless LAN access point is also considered.

X. Zhang and K. G. Shin: “Cooperative Carrier Signaling: Harmonizing Coexisting WPAN and WLAN Devices”, IEEE Trans. Networking, Vol.21, No.2, pp.426-439 (2013)

  However, the data frame collision avoidance method described in Non-Patent Document 1 uses a special frame not defined by the standard. Therefore, there is a problem that data communication cannot be performed using only the standard frame.

  In addition, when the time when the control frame indicating the response from the ZigBee coordinator collides with the data frame from the wireless LAN access point or the wireless LAN station is uniquely predicted, the data frame collision time may be unpredictable. is there. This is because the predicted time at which the ZigBee coordinator receives a data frame and the actual data frame arrival time may differ depending on radio wave propagation characteristics, carrier sense, and the like. If the data frame collision time is unpredictable, useless collision avoidance processing is further performed, resulting in a cause of a decrease in communication speed.

  The present invention has been made in view of such problems, and an object of the present invention is to prevent a decrease in communication speed by controlling a frame transmission interval from a terminal connected to an IP wireless network. It is to provide a wireless communication apparatus for the above.

  In order to achieve the above object, the first aspect of the present invention can communicate with each of the first terminal connected to the sensor network and the second terminal connected to the IP wireless network. And a management frame transmitted to the IP wireless network by the second terminal, and means for predicting the reception time of the data frame from the sensor network by the first terminal. Means for predicting the transmission time of the management frame immediately before the predicted reception time of the data frame, and information on the management frame transmitted from the second terminal at the predicted transmission time of the management frame Means for changing a frame transmission interval and a contention window included in the frame, wherein The total time of the transmission interval and the contention window is the data frame from the radio wave for transmitting the control frame indicating the response to the data frame and the third terminal connected to the second terminal or the IP wireless network. Means for setting so as not to interfere with radio waves for transmitting.

  A second aspect of the present invention is the communication apparatus according to the first aspect, wherein the first terminal is within a management frame transmission interval in which a total time of the frame transmission interval and the contention window is changed. Means for determining whether or not the data frame has been received at the first terminal within the management frame transmission interval in which the total time of the frame transmission interval and the contention window is changed If not, it further includes means for re-predicting the reception time of the data frame from the sensor network and the transmission time of the management frame to be transmitted to the IP wireless network.

  According to a third aspect of the present invention, there is provided the communication device according to the second aspect, wherein a statistical value of a reception interval of a data frame of a sensor network received from a terminal connected to the sensor network is obtained, and a subsequent sensor The apparatus further comprises means for predicting the reception time of the data frame of the network.

  According to a fourth aspect of the present invention, there is provided the communication apparatus according to any one of the first to third aspects, wherein the frame transmission interval and the contention window to be changed include a total time of the data frame. It is characterized in that it is equal to or longer than the interval from the time when the reception of the data frame ends to the time when transmission of a control frame indicating a response to the data frame starts.

  According to a fifth aspect of the present invention, there is provided the communication apparatus according to any one of the first to fourth aspects, further comprising the second terminal.

  According to a sixth aspect of the present invention, there is provided a communication apparatus including a module capable of communicating with each of a first terminal connected to a sensor network and a second terminal connected to an IP wireless network. A method for controlling a frame transmission interval of frames transmitted from two terminals, the step of predicting a reception time of a data frame from the sensor network by the first terminal, and the IP system by the second terminal Of the management frames to be transmitted to the wireless network, the step of predicting the transmission time of the management frame immediately before the predicted reception time of the data frame, and the second terminal at the predicted transmission time of the management frame The frame transmission interval and contention window included in the management frame information to be transmitted A total time of the changed frame transmission interval and contention window is a step of changing a total time, a radio wave for transmitting a control frame indicating a response to the data frame, and the second terminal or And a step of setting so as not to interfere with radio waves for transmitting data frames from a third terminal connected to the IP wireless network.

  According to a seventh aspect of the present invention, there is provided a computer-readable storage medium which stores an instruction for causing a computer to execute the control method of the sixth aspect when executed by the computer.

  According to an eighth aspect of the present invention, there is provided a program for causing a computer to execute the control method according to claim 6 when executed by the computer.

  In the present invention, when a channel (frequency) cannot be changed with respect to a radio wave interference problem occurring in radio systems of different communication systems using the same frequency band, the radio system of different communication systems is controlled by controlling the radio wave transmission time. Interference of radio waves due to frame transmission in can be avoided. As a result, the number of frame retransmissions due to interference can be reduced, and a reduction in communication speed can be prevented.

It is a figure which shows the mode of the transmission / reception of the data of the terminal connected to each network in the environment where several wireless communication systems from which a sensor network and an IP type | system | group wireless network differ coexist. It is a block diagram which shows the structure of the radio | wireless system which concerns on Embodiment 1 of this invention. It is a figure which shows the mode of the frame reception from a sensor network in the case of using the wireless system of FIG. 2, and the management frame transmission to an IP type | system | group wireless network. 3 is a flowchart illustrating a procedure for changing a frame transmission interval to an IP wireless network in the cooperation module of the wireless system in FIG. 2. FIG. 3 is a diagram showing a frequency distribution of reception intervals of data frames of the ZigBee coordinator in the wireless system of FIG. 2. FIG. 3 is a diagram illustrating a method for estimating a data frame reception time of a ZigBee coordinator in the wireless system of FIG. 2. FIG. 3 is a diagram illustrating a state of data transmission / reception between a terminal connected to a sensor network and a terminal connected to an IP wireless network in the wireless system of FIG. 2. It is a block diagram which shows the structure of the radio | wireless system which concerns on Embodiment 2 of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Embodiment 1]
FIG. 2 is a block diagram showing the configuration of the wireless system according to Embodiment 1 of the present invention. The wireless system 200 of FIG. 2 includes a wireless LAN access point 210, a ZigBee coordinator 220, and a communication device 230 including a linkage module 240 that is communicably connected to both the wireless LAN access point 210 and the ZigBee coordinator 220. The wireless LAN access point 210 is a terminal connected to the IP wireless network and can communicate with a plurality of wireless LAN stations in the IP wireless network. The ZigBee coordinator 220 is a terminal connected to the sensor network, and can communicate with a plurality of ZigBee end devices in the sensor network. The cooperation module 240 manages beacon (management frame) transmission from the wireless LAN access point 210 based on information from the wireless LAN access point 210 and the ZigBee coordinator 220.

  When the ZigBee coordinator 220 connected to the sensor network receives a data frame, it transmits a control frame to the ZigBee end device notifying that data has been successfully received after a certain period of time since receiving the data frame.

  A wireless LAN access point connected to the IP wireless network periodically transmits a beacon indicating the presence of the wireless LAN access point to a communicable terminal in the IP wireless network including the wireless LAN station. . On the other hand, a wireless LAN access point may transmit a data frame 103 separately from Beacon, and a wireless LAN station may also transmit a data frame.

  Here, the ZigBee coordinator 220 does not perform carrier sense when transmitting a control frame indicating a response. On the other hand, when the wireless LAN access point 210 or the wireless LAN station transmits a data frame, carrier sense is performed during the AIFS, and if a contention window is set, another radio wave is transmitted after the back-off time has elapsed. If not, a data frame is transmitted.

  The cooperation module 240 includes a wireless LAN management frame transmission time reception unit 241 that receives the Beacon transmission time, a wireless LAN management frame transmission time management unit 242 that accumulates the Beacon transmission time, and a wireless LAN management frame transmission that calculates the Beacon transmission interval. An interval calculation unit 243 and a wireless LAN management frame transmission time estimation unit 244 (management frame transmission estimation means) for estimating the next Beacon transmission time are provided. The cooperation module 240 also includes a ZigBee data frame reception unit 245 that receives the ZigBee data frame reception time, a ZigBee data frame reception time management unit 246 that accumulates the ZigBee data frame reception time, and a ZigBee data frame reception interval. A data frame reception interval calculation unit 247 and a ZigBee data frame reception time estimation unit 248 (data frame reception estimation means) for estimating the next ZigBee data frame reception time are provided. Further, the cooperation module 240 includes a wireless LAN frame transmission interval / contention window changing unit 249 (frame transmission interval / contention window changing means) that changes the frame transmission interval before and after the reception time of the ZigBee data frame, and a Beacon that has changed the AIFS. A ZigBee data frame reception determination unit 250 (data frame reception determination unit) that determines whether a ZigBee data frame has been received at a transmission interval.

  FIG. 3 is a diagram showing a state of data frame reception from the sensor network by the ZigBee coordinator 220 and Beacon transmission from the wireless LAN access point 210 to the IP wireless network when the wireless system 200 of FIG. 2 is used. It is. In this embodiment, in order to avoid collision between data frames using a standard frame, the linkage module 240 links frame management in the sensor network and frame management with the IP wireless network, The frame transmission interval (AIFS) of the IP wireless network before and after the time when the ZigBee coordinator 220 receives the data frame is changed. Here, the sensor network is often used when a ZigBee end device periodically transmits sensing data such as temperature data to the ZigBee coordinator. Therefore, using the fact that the data transmission interval is periodic, the ZigBee data frame reception interval calculation unit 247 and the ZigBee data frame reception time estimation unit 248 predict the time when the data frame is received from the sensor network. be able to. By changing the frame transmission interval (AIFS) from the wireless LAN access point 210 to the IP wireless network before and after the predicted data frame reception time from the sensor network, data frame transmission at the wireless LAN access point and the wireless LAN station can be performed. Control can be performed.

  In addition, when the predicted time of data frame reception in the sensor network deviates from the actual data frame reception time, a mechanism for re-prediction is adopted.

  Next, a flow for changing the frame transmission interval to the IP wireless network in the cooperation module 240 will be described. FIG. 4 is a flowchart showing a procedure for changing the frame transmission interval from the wireless LAN access point 210 to the IP wireless network in the cooperation module 240.

  The flow of FIG. 4 starts in step 400. In step 411, the wireless LAN management frame transmission time reception unit 241 notifies the beacon transmission (creation) time from the wireless LAN access point 210 that the wireless LAN access point is present. Receive notifications. In step 412, the wireless LAN management frame transmission time management unit 242 stores the received Beacon transmission time of the wireless LAN access point. In step 413, the wireless LAN management frame transmission interval calculation unit 243 calculates the Beacon transmission interval from the accumulated Beacon transmission time of the wireless LAN access point. The beacon transmission interval of the wireless LAN access point can be calculated by taking the latest beacon transmission interval as a representative value or by calculating the beacon transmission interval sequentially and taking the nearest several average values.

  In step 414, the wireless LAN management frame transmission time estimation unit 244 estimates the next Beacon transmission time from the calculated Beacon transmission interval. The next Beacon transmission time can be estimated, for example, by adding the calculated Beacon transmission interval to the latest (previous) Beacon transmission time received in step 411.

  On the other hand, in step 421, the ZigBee data frame receiving unit 245 receives a notification of the reception time of the data frame of the ZigBee coordinator 220 from the ZigBee coordinator 220. In step 422, the ZigBee data frame reception time management unit 246 stores the received data frame reception time of the ZigBee coordinator 220. In step 423, the ZigBee data frame reception interval calculation unit 247 calculates the data frame reception interval from the accumulated data frame reception time.

  The calculation of the data frame reception interval of the ZigBee coordinator 220 can be obtained by the following method.

  First, the data frame reception interval can be calculated by taking the latest data frame reception interval as a representative value, or by sequentially calculating the data frame reception interval and taking the nearest several average values.

  Second, using the fact that a sequence number is assigned to a ZigBee data frame, the reception interval (DI) of the data frame of the ZigBee coordinator 220 can also be calculated by the following equation.

Here, NR is the number of data frames received by the ZigBee coordinator 220, T _i is the data frame reception time at the reception number i received by the ZigBee coordinator 220, and S _i is the data frame at the reception number i received by the ZigBee coordinator 220. Represents the sequence number.

  Third, the reception interval of the data frame can be calculated from the frequency distribution of the reception interval of the data frame of the ZigBee coordinator 220. FIG. 5 is a diagram showing the frequency distribution of the reception interval of the data frame of the ZigBee coordinator 220. As shown in FIG. From the frequency distribution of the data frame reception interval in FIG. When multiple ZigBee end devices are connected to the sensor network, a frequency distribution is created for each ZigBee end device by identifying which ZigBee end device the received data frame is from. Can do.

  In step 424, the ZigBee data frame reception time estimation unit 248 estimates the next data frame reception time from the calculated data frame reception interval. FIG. 6 is a diagram illustrating a method of estimating the data frame reception time of the ZigBee coordinator. For example, the reception interval (for example, T1, T2, or T3) of the data frame calculated in step 423 is added to the reception time of the data frame of the latest (immediately) ZigBee coordinator received in step 421. By adding the data frame reception interval to the latest data frame reception time, the reception time of the next data frame to be received can be predicted.

  In step 431, the wireless LAN frame transmission interval changing unit 249 calculates the Beacon transmission time of the wireless LAN access point immediately before the estimated data frame reception time of the next ZigBee coordinator.

  In step 432, the wireless LAN frame transmission interval changing unit 249 notifies the wireless LAN access point of changes in the AIFS and contention window in the AIFSN included in the beacon transmitted at the calculated beacon transmission time. Regarding the total time of the AIFS and contention window to be changed, collision between data frames does not occur. In this case, the following two cases are considered.

  As a first example, when the slot time of the wireless LAN is 20 μs, since the time (aTurroundTime) from the reception of the data frame of the ZigBee coordinator to the transmission of the control frame indicating the response is 192 μs, as the AIFS to be changed, aTurroundTime It is preferable to set the time slightly longer than 192 μs, for example, 210 μs. This is because the AIFS, which is the prediction time, should be set slightly longer than the aTurroundTime so that the collision between the data frames can be avoided without completely matching the aTurroundTime of the ZigBee coordinator.

  When the wireless LAN access point changes the AIFS, the data frame can be transmitted at an interval at which collision between data frames can be avoided in the Beacon interval at this time. Also, a beacon is transmitted from the wireless LAN access point 210 to the wireless LAN station. At this time, the wireless LAN station also transmits data to the wireless LAN station by the changed AIFS and contention window in the AIFSN included in the transmitted beacon. Data frames can be transmitted at intervals that can avoid collisions between frames.

  FIG. 7 is a diagram illustrating a state of data transmission / reception between a terminal (ZigBee coordinator) connected to the sensor network and a terminal (wireless LAN access point) connected to the IP wireless network in the present embodiment. . For example, when AIFS is set to 210 μs, the wireless LAN access point 210 performs carrier sense during the AIFS from the Beacon transmission time calculated in step 431 (210 μs). Here, when sensing the use of radio waves by transmitting data frames to the ZigBee coordinator in the sensor network, the reception of data frames by the ZigBee coordinator 220 is completed, and after confirming that radio waves are not being used, carrier sense is performed again. Start. When carrier sense is performed during AIFS (210 μs), a control frame indicating a response of ZigBee is transmitted after 192 μs. Therefore, the use of radio waves is detected, and the data frame cannot be transmitted from the wireless LAN access point 210. Therefore, collision between the control frame and the data frame is avoided. The AIFS is counted again after transmitting the control frame indicating the ZigBee response, and after 210 μs, after passing through a contention window, the wireless LAN access point 210 data frame is transmitted. At this point, since transmission of the control frame indicating the ZigBee response has been completed, there is no collision between the control frame and the data frame.

  As a second example, when the slot time of the wireless LAN is 9 μs, the AIFS can be set to only 145 μs at the maximum. The ZigBee coordinator's aTurroundTime is 192 μs, but in this case AIFS is smaller than the ZigBee coordinator's aTurroundTime. Therefore, the value of the contention window is increased, and the total of the AIFS and the contention window is set to be longer than the aTurroundTime of the ZigBee coordinator. Since the contention window is an integer multiple of the time slot, the value can be increased by increasing the number applied to the time slot. In the present embodiment, if CWmin, which is one of the parameters for determining the contention window, is changed and the total of the AIFS and the contention window is set to be longer than the aTurnroundTime of the ZigBee coordinator, the control frame And the data frame can be prevented from colliding with each other. The same applies to data frame transmission from the wireless LAN station.

  In step 433, the ZigBee data frame reception determination unit 250 determines whether the ZigBee coordinator 220 actually receives the data frame within the Beacon interval in which the AIFS and contention window are changed. In step 433, if the ZigBee coordinator 220 actually receives a data frame at the Beacon interval in which the AIFS and contention window are changed, it is determined that the estimated reception interval of the data frame received by the ZigBee coordinator 220 is correct (step S43). 433: Yes), the process returns to step 424, and the scheduled reception time of the data frame of the subsequent ZigBee coordinator 220 is estimated. On the other hand, if the ZigBee coordinator 220 does not actually receive a data frame in the Beacon interval in which the AIFS and contention window are changed, it is determined that the estimated reception interval of the data frame received by the ZigBee coordinator 220 is incorrect. (Step 433: No), the process returns to Step 400, and the data frame reception time and Beacon transmission time are received and stored again. By performing again from the reception and accumulation of the reception time of the data frame, it becomes possible to correct immediately even if the prediction is lost.

  The method for changing the frame transmission interval from the wireless LAN access point 210 or the wireless LAN station to the IP wireless network in the cooperation module 240 of the present embodiment is included in the program module. It can be described in the general context of computer-executable instructions executing on a real or virtual processor. Computer-executable instructions for program modules may be executed within a local computing environment or in a distributed computing environment.

  Also, the method for changing the frame transmission interval of this embodiment can be described in the general context of computer-readable media. Computer readable media can be any available media that can be accessed within a computing environment. By way of example, and not limitation, within a computing environment, computer-readable media includes memory, storage, communication media, and any combination of the foregoing.

[Embodiment 2]
FIG. 8 is a block diagram showing a configuration of a wireless system according to Embodiment 2 of the present invention. 8 includes a ZigBee data frame reception unit 811, a ZigBee data frame reception time management unit 812, a ZigBee data frame reception interval calculation unit 813, and a ZigBee data frame reception time estimation unit. 814, a wireless LAN frame transmission interval / contention window changing unit 815, and a ZigBee data frame reception determining unit 816. The Beacon transmission (creation) time and transmission (creation) interval at the wireless LAN access point 800 of this embodiment are collected by the wireless LAN access point 800 itself, and the processing contents of other functions are the same as those of the first embodiment. is there.

101 Data frame 102 Control frame 103 Data frame 200 Wireless system 210, 800 Wireless LAN access point 220 ZigBee coordinator 230 Communication device 240 Cooperation module 241 Wireless LAN management frame creation time reception unit 242 Wireless LAN management frame creation time management unit 243 Wireless LAN management Frame creation interval calculation unit 244 Wireless LAN management frame creation time estimation unit 245, 811 ZigBee data frame reception unit 246, 812 ZigBee data frame reception time management unit 247, 813 ZigBee data frame reception interval calculation unit 248, 814 ZigBee data frame reception time Estimating unit 249, 815 Wireless LAN frame contention window creation interval changing unit 250, 816 ZigBe Data frame reception determining unit

Claims (8)

A communication device including a module capable of communicating with each of a first terminal connected to a sensor network and a second terminal connected to an IP wireless network,
Means for predicting the reception time of a data frame from the sensor network by the first terminal;
Means for predicting a transmission time of a management frame immediately before a predicted reception time of the data frame among management frames transmitted to the IP wireless network by the second terminal;
Means for changing a frame transmission interval and a contention window included in information of a management frame transmitted from the second terminal at the predicted transmission time of the management frame, the frame transmission interval being changed; The total time with the contention window is: a radio frame for transmitting a control frame indicating a response to the data frame and a data frame transmitted from the second terminal or a third terminal connected to the IP wireless network. Means for setting so as not to interfere with radio waves for transmission. Means for determining whether or not the data frame is received at the first terminal within a transmission interval of the management frame in which a total time of the frame transmission interval and a contention window is changed;
The reception time of the data frame from the sensor network when the data frame is not received by the first terminal within the transmission interval of the management frame in which the total time of the frame transmission interval and the contention window is changed The communication apparatus according to claim 1, further comprising: a unit that re-estimates a transmission time of a management frame to be transmitted to the IP wireless network.   3. The apparatus according to claim 2, further comprising means for taking a statistical value of a reception interval of a data frame of the sensor network received from a terminal connected to the sensor network and predicting a reception time of a data frame of the subsequent sensor network. The communication apparatus as described in.   The frame transmission interval to be changed and the contention window are the same as the interval between the time at which reception of the data frame is completed and the time at which transmission of a control frame indicating a response to the data frame is started. The communication apparatus according to any one of claims 1 to 3, wherein the communication apparatus is more than that.   The communication apparatus according to claim 1, further comprising the second terminal. In a communication apparatus equipped with a module capable of communicating with each of a first terminal connected to a sensor network and a second terminal connected to an IP wireless network, a transmission interval of frames transmitted from the second terminal is set. A method of controlling,
Predicting a reception time of a data frame from the sensor network by the first terminal;
Predicting the transmission time of the management frame immediately before the predicted reception time of the data frame among the management frames transmitted to the IP wireless network by the second terminal;
Changing a total time of a frame transmission interval and a contention window included in information of a management frame transmitted from the second terminal at the predicted transmission time of the management frame, the frame being changed The total time of the transmission interval and the contention window is transmitted from a radio wave for transmitting a control frame indicating a response to the data frame and a third terminal connected to the second terminal or the IP wireless network. And a step set so as not to interfere with radio waves for transmitting data frames.   A computer-readable storage medium storing instructions that, when executed by a computer, cause the computer to execute the control method according to claim 6.   A program that, when executed by a computer, causes the computer to execute the method according to claim 6.