JP6283574B2 - Radio control apparatus and radio control method - Google Patents

Description

  The present invention relates to a wireless control device and a wireless control method.

  Conventionally, IEEE Std 802.11 (Non-Patent Document 1) is known as a standard group of wireless LANs. Non-Patent Document 1 describes a procedure for signals between a transmitter and a receiver in WiFi (registered trademark). Is described.

  An example of wireless communication using IEEE 802.11 is shown in FIG. As shown in FIG. 7A, for example, when a data frame is transmitted from the WiFi device A (A terminal) to the WiFi device B (B terminal), the B terminal performs carrier sense after receiving the data frame normally, During SIFS (Short InterFrame Space) time, it is determined whether or not there is another terminal that performs communication using the same frequency channel. Thereafter, when it is confirmed that the frequency channel is free (idle), the B terminal sends back an ACK (acknowledgment) frame to the A terminal.

  On the other hand, FIG. 7B shows an operation example when data frame transmission from the A terminal to the B terminal fails. As shown in FIG. 7B, the terminal A waits for the return of the ACK frame from the terminal B during ACKTimeout after the completion of data frame transmission (for example, after receiving PHY-TXEND.confirm). In the case where the A terminal cannot receive the ACK frame from the B terminal even after the ACKTimeout has elapsed (for example, when PHY-RXSTART.indication is not started), the A terminal tries to retransmit the data frame. That is, the terminal A confirms whether or not the same frequency channel is used during a DIFS (Distributed InterFrame Space) time and a BO (Back Off) time, and retransmits the data frame when it is not used.

IEEE Std 802.11-2012 “IEEE Standard for Information technology-Telecommunications and information exchange between systems-Local and metropolitan area networks-Specific requirements, Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications”

  By the way, in the wireless LAN, there is a so-called hidden terminal problem in which a frame collision occurs in a state where wireless communication signals do not reach each other due to an influence of a distance between devices or an obstacle that does not transmit radio waves. Specifically, as illustrated in FIG. 7C, the wireless communication signals reach between the A terminal and the C terminal, but the wireless communication signals reach between the B terminal and the C terminal. Consider C. In such a case, the A terminal and the C terminal cannot see each other, and communication from the A terminal to the B terminal and communication from the C terminal to the other WiFi device X may occur simultaneously.

  As shown in FIG. 7C, the terminal B transmits the data frame transmitted from the terminal A normally, but the terminal C transmits to the terminal X while waiting for the SIFS time to elapse. Received data frames. In such a case, since the same frequency channel is used by other terminals (busy), the B terminal waits until the frequency channel becomes free without returning an ACK frame to the A terminal. At this time, if the waiting time at terminal B is long, ACKTimeout will elapse at terminal A, and the data frame will be retransmitted.

  In this way, in an environment where the hidden terminal problem occurs, the data frame may be retransmitted from the transmitter even though the data frame can be normally received on the receiver side. May not be available.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a radio control apparatus and a radio control method that can efficiently use radio resources.

  In the first aspect of the present invention, a transmission determination unit that outputs transmission notification information notifying that a transmission frame has been transmitted to another terminal, and a reception notification notifying that a response frame has been received from the other terminal Based on the reception determination unit that outputs information and the transmission notification information and the reception notification information, a specific transmission frame is transmitted to the other terminal, and then a response frame corresponding to the specific transmission frame is received. A time information calculation unit that calculates time information until the time information calculation unit, and a parameter adjustment unit that adjusts a frame retransmission interval from transmission of a transmission frame to retransmission based on the calculated time information. Provided is a wireless control device.

  In addition, when the parameter adjustment unit receives a transmission frame from the other terminal based on the calculated time information, the parameter adjustment unit receives a response frame corresponding to the transmission frame after receiving the transmission frame. It is good also as adjusting the response interval until it transmits.

  In the second aspect of the present invention, a reception determination unit that outputs reception notification information for notifying that a transmission frame has been received from another terminal, and a transmission notification for notifying that a response frame has been transmitted to the other terminal From receiving a specific transmission frame from the other terminal based on the transmission determination unit that outputs information, and the transmission notification information and the reception notification information, until a response frame corresponding to the specific transmission frame is transmitted A time information calculation unit for calculating the time information of the transmission, and a response from the time when the transmission frame is received from the other terminal to the time when the response frame corresponding to the transmission frame is transmitted to the other terminal based on the calculated time information Provided is a wireless control device comprising a parameter adjustment unit for adjusting an interval.

  Further, the parameter adjustment unit adjusts a frame retransmission interval from when the transmission frame is transmitted to when the transmission frame is retransmitted when the transmission frame is transmitted to the other terminal based on the calculated time information. It is good.

  In addition, the parameter adjustment unit increases the frame retransmission interval when the calculated time information is equal to or greater than the first threshold, and adjusts the frame retransmission interval to be shorter when the time information is equal to or less than the second threshold. It is good as well.

  Further, the parameter adjusting unit shortens the response interval when the calculated time information is greater than or equal to a third threshold, and adjusts the response interval longer when the time information is equal to or less than a fourth threshold. Also good.

  The transmission frame may be a data frame, and the response frame may be an ACK frame.

  The transmission frame may be an RTS frame, and the response frame may be a CTS frame.

  In the third aspect of the present invention, a step of outputting transmission notification information notifying that a transmission frame has been transmitted to another terminal, and reception notification information notifying that a response frame has been received from the other terminal are provided. And a time from when a specific transmission frame is transmitted to the other terminal based on the transmission notification information and the reception notification information until a response frame corresponding to the specific transmission frame is received. There is provided a radio control method including a step of calculating information and a step of adjusting a frame retransmission interval from transmission of a transmission frame to retransmission based on the calculated time information.

  In the fourth aspect of the present invention, the step of outputting reception notification information notifying that a transmission frame has been received from another terminal, and transmission notification information notifying that the response frame has been transmitted to the other terminal are provided. A step of outputting, and based on the transmission notification information and the reception notification information, time information from when a specific transmission frame is received from the other terminal until a response frame corresponding to the specific transmission frame is transmitted. Calculating a response interval from receiving a transmission frame from the other terminal to transmitting a response frame corresponding to the transmission frame to the other terminal based on the calculated time information; A wireless control method is provided.

  According to the present invention, radio resources can be used efficiently.

It is a figure which shows the outline | summary of a radio | wireless control apparatus. It is a block diagram which shows the function structure of a radio | wireless control apparatus. It is a figure which shows the operation example in case a radio | wireless control apparatus is a terminal device of the transmission side. It is a figure which shows the operation example in case a radio | wireless control apparatus is a terminal device of the receiving side. It is a flowchart which shows the flow of a process of a radio | wireless control apparatus. It is a figure which shows the outline | summary of the radio | wireless control apparatus in another embodiment. 1 is a diagram illustrating an example of wireless communication using IEEE 802.11.

[Outline of wireless control device]
First, the outline of the wireless control device of the present invention will be described with reference to FIG. In an environment where the hidden terminal problem occurs, even if the data frame can be normally received on the receiver side, the reply of the ACK frame is delayed and the data frame is retransmitted from the transmitter. is there. The radio control apparatus of the present invention can reduce the probability that such unnecessary transmission of data frames will occur.

Specifically, on the transmitter side (terminal A in the figure), time information TA from when a data frame is transmitted until when an ACK frame is received (hereinafter sometimes referred to as “ACK response time TA”). Based on this, the time required for ACKTimeout is adjusted. On the receiver side (B terminal in the figure), based on time information TB from receiving a data frame to transmitting an ACK frame (hereinafter sometimes referred to as “ACK transmission time TB”), Adjust SIFS time etc.
Hereinafter, the wireless control device of the present invention will be specifically described with reference to the drawings.

[Configuration of Radio Control Device 1]
FIG. 2 is a block diagram showing a functional configuration of the wireless control device 1 of the present invention. The wireless control device 1 is a terminal device that can wirelessly communicate with other terminal devices in a wireless LAN environment. For example, a terminal device compatible with WiFi, such as a smartphone or a tablet PC, or these terminal devices are connected to each other or another network. A WiFi device such as an access point to be connected. Note that the radio network controller 1 according to the present invention can be applied to both a transmission-side terminal device (A terminal) and a reception-side terminal device (B terminal).
As shown in FIG. 2, the radio network controller 1 includes a transmission determination unit 2, a reception determination unit 3, a time information calculation unit 4, and a parameter adjustment unit 5.

[Configuration of radio control apparatus 1 (transmission side)]
When the wireless control device 1 is a transmission-side terminal device, the transmission determination unit 2 acquires transmission notification information for notifying other terminals that a “transmission frame” has been transmitted, and outputs it to the time information calculation unit 4 To do. In the present embodiment, the transmission frame is a data frame transmitted to another terminal, and the transmission notification information is information including the time when the data frame is transmitted. The transmission notification information may include information (for example, a sequence number) that can identify the transmitted data frame.

  The reception determination unit 3 acquires reception notification information for notifying that the “response frame” has been received from another terminal, and outputs the reception notification information to the time information calculation unit 4. In the present embodiment, the response frame is an ACK frame received from another terminal, and the reception notification information is information including the time when the ACK frame is received. Note that the reception notification information may include information that can identify the received ACK frame (for example, a sequence number of a data frame that performs an ACK response).

  Based on the transmission notification information and the reception notification information, the time information calculation unit 4 transmits time information from a specific transmission frame to another terminal until receiving a response frame corresponding to the specific transmission frame. Is calculated. That is, the time information calculation unit 4 transmits the data frame to the terminal device on the receiving side from the difference between the transmission time of the latest data frame and the reception time of the latest ACK frame, and then receives the ACK from the terminal device. Time information (ACK response time) until frame reception is calculated. When the transmission notification information and the reception notification information include a sequence number, the time information calculation unit 4 calculates the ACK response from the difference between the transmission time of the data frame having the same sequence number and the reception time of the ACK frame. Calculate time.

By using the ACK response time calculated by the time information calculation unit 4, the surrounding wireless LAN environment can be evaluated. At this time, it is preferable to perform the evaluation based on the tendency of the ACK response time within a certain period. Therefore, the time information calculation unit 4 calculates the average, variance, and the like of the ACK response time calculated during a certain period. Of course, the time information calculation unit 4 is not limited to the average and the variance, and may calculate a CDF-X% value of the ACK response time in a certain period, a forgetting average, and the like.
The ACK response time calculated by the time information calculation unit 4 is output to the parameter adjustment unit 5.

The parameter adjustment unit 5 evaluates the wireless LAN environment around the wireless control device 1 based on the calculated ACK response time, and transmits a frame retransmission interval from transmission of a transmission frame to retransmission (in this embodiment, ACKTimeout). Time).
For example, the situation where the ACK response time is equal to or greater than a predetermined value is a situation where the reply of the ACK frame from the receiver is delayed, so the parameter adjustment unit 5 lengthens the ACKTimeout time and suppresses retransmission of the data frame. . Note that the situation in which the ACK response time is equal to or less than the predetermined value is a situation in which the ACK frame is returned from the receiver early, so that the ACK Timeout time may be adjusted to be short. On the other hand, when the ACK response time falls within the predetermined range, the parameter adjustment unit 5 maintains the ACK Timeout time without adjusting it.

  The parameter adjustment unit 5 compares the previously calculated average, variance, CDF-X% value, forgetting average, and the like, and adjusts the ACK Timeout time based on whether it is increasing or decreasing. It is good as well. That is, the parameter adjustment unit 5 may adjust the ACKTimeout time short when it is increasing and adjust the ACKTimeout time long when it is decreasing.

  In addition, the calculation of the ACK response time by the time information calculation unit 4 and / or the adjustment of the ACK timeout time based on the ACK response time by the parameter adjustment unit 5 are based on the wireless LAN scheme (802.11a / b / g / n / ac). ) May be performed every time.

[Operation of radio control apparatus 1 (transmission side)]
Next, with reference to FIGS. 3A and 3B, an operation example when the radio network controller 1 is a terminal device on the transmission side will be described. Note that FIG. 3C will be described later.

As shown in FIG. 3A, the time trend (average, variance, etc.) until the A terminal (transmitting side) that transmitted the data frame receives the ACK frame from the B terminal (receiving side) is the ACK response. Consider the case of time TA0, ACK response time TA1, and ACK response time TA2.
The ACK response time TA0 is a standard ACK response time, the ACK response time TA1 is an ACK response time longer than the standard ACK response time, and the ACK response time TA2 is shorter than the standard ACK response time. ACK response time. In FIG. 3B, ACKTimeout_TA0, TA1, and TA2 are ACKTimeout times that are adjusted corresponding to the ACK response times TA0, TA1, and TA2, respectively.

Since the situation in which the ACK response time becomes the ACK response time TA1 is a situation in which the reply of the ACK frame from the B terminal is delayed, as shown in FIG. 3B, the parameter adjusting unit 5 extends the ACK Timeout time. , ACKTimeout_TA1.
As described above, since the radio control apparatus 1 (transmission side) dynamically changes the ACK Timeout time according to the surrounding wireless LAN environment, the ACK frame is received from the reception side terminal apparatus even in a situation where a hidden terminal is generated. Can be received, and it is possible to suppress unnecessary transmission of data frames from the terminal device on the transmission side.

  Note that the situation in which the ACK response time TA2 is reached is a situation in which an ACK frame is returned from the B terminal early. In such a case, by shortening the ACKTimeout time and adjusting it to ACKTimeout_TA2, it is possible to detect early that the data frame cannot be received at the B terminal when the data frame transmission fails, which is preferable.

[Configuration of Radio Control Device 1 (Reception Side)]
Returning to FIG. 2, when the radio network controller 1 is a terminal device on the receiving side, the reception determination unit 3 acquires reception notification information for notifying that “transmission frame” has been received from another terminal, and calculates a time information calculation unit. 4 is output. In the present embodiment, the transmission frame is a data frame, and the reception notification information is information including the time when the data frame is received. In addition, it is good also as information (for example, sequence number) which can identify the received data frame as reception notification information.

  The transmission determination unit 2 acquires transmission notification information for notifying other terminals that a “response frame” has been transmitted, and outputs the transmission notification information to the time information calculation unit 4. In the present embodiment, the response frame is an ACK frame, and the transmission notification information is information including the time when the ACK frame is transmitted. The transmission notification information may include information that can identify the transmitted ACK frame (for example, the sequence number of the data frame that makes an ACK response).

  Based on the transmission notification information and the reception notification information, the time information calculation unit 4 calculates time information from when a specific transmission frame is received from another terminal until a response frame corresponding to the specific transmission frame is transmitted. To do. That is, the time information calculation unit 4 calculates time information (ACK transmission time) until the ACK frame is returned to the terminal device from the difference between the reception time of the latest data frame and the transmission time of the latest ACK frame. To do. Of course, the time information calculation unit 4 may calculate the ACK transmission time from the difference between the reception time of the data frame having the same sequence number and the transmission time of the ACK frame.

  The calculation method of the ACK transmission time by the time information calculation unit 4 is arbitrary, and the time information calculation unit 4 may calculate, for example, the average, variance, etc. of the ACK transmission time calculated during a certain period. Also, the CDF-X% value of the ACK transmission time in a certain period, the forgetting average, and the like may be calculated.

The parameter adjustment unit 5 evaluates the wireless LAN environment around the wireless control device 1 based on the calculated ACK transmission time, receives a transmission frame from another terminal, and then receives a response frame corresponding to the transmission frame. The response interval (SIFS time in this embodiment) until transmission to the terminal is adjusted.
For example, the situation where the ACK transmission time is equal to or greater than a predetermined value is a situation where the reply of the ACK frame to the transmitter is delayed. An example of a situation in which the reply of the ACK frame is delayed is a case where it is detected that the same frequency channel is used during carrier sense, as shown in FIG. 7C. In such a case, if the SIFS time is lengthened, the possibility that the frequency channel is used by another terminal and transmission of the ACK frame is further delayed increases. Therefore, in a situation where the ACK transmission time is equal to or greater than a predetermined value, the parameter adjustment unit 5 adjusts the SIFS time to be short so that other terminals can transmit the ACK frame before using the frequency channel. Thereby, it can suppress that a data frame is resent from a transmitter.

  Since the situation where the ACK transmission time is equal to or less than the predetermined value is a situation where the ACK frame is returned to the transmitter early, the SIFS time may be adjusted to be long and a sufficient carrier sense period may be secured. When the ACK transmission time is within the predetermined range, the parameter adjustment unit 5 maintains the SIFS time without adjusting it.

  Further, the parameter adjustment unit 5 performs comparison with the previously calculated average, variance, CDF-X% value, forgetting average, or the like, and adjusts the SIFS time based on whether it is increasing or decreasing. It is good as well. That is, the parameter adjustment unit 5 may adjust the SIFS time short when the trend is increasing, and may adjust the SIFS time long when the trend is decreasing.

  In addition, the calculation of the ACK transmission time by the time information calculation unit 4 and / or the adjustment of the SIFS time based on the ACK transmission time by the parameter adjustment unit 5 are based on the wireless LAN scheme (802.11a / b / g / n / ac). ) May be performed every time.

[Operation of radio control apparatus 1 (reception side)]
Next, with reference to FIGS. 4A and 4B, an operation example when the radio network controller 1 is a receiving-side terminal device will be described. Note that FIG. 4C will be described later.

As shown in FIG. 4 (A), the B terminal (receiving side) that received the data frame has a time trend (average, variance, etc.) until it returns an ACK frame to the A terminal (transmitting side). Consider the case of ACK transmission time TB0, ACK transmission time TB1, and ACK transmission time TB2.
The ACK transmission time TB0 is a standard ACK transmission time, the ACK transmission time TB1 is an ACK transmission time longer than the standard ACK transmission time, and the ACK transmission time TB2 is shorter than the standard ACK transmission time. ACK transmission time. In FIG. 4B, SIFS_TB0, TB1, and TB2 are SIFS times adjusted to correspond to the ACK transmission times TB0, TB1, and TB2, respectively.

The situation in which the ACK transmission time becomes the ACK transmission time TB1 is a situation in which the reply of the ACK frame to the terminal A is delayed, for example, when it is detected that the same frequency channel is used during carrier sense There are things to do. Therefore, as shown in FIG. 3B, the parameter adjustment unit 5 reduces the SIFS time and adjusts to SIFS_TB1, thereby detecting the timing when the frequency channel is not used and transmitting the ACK frame. To do.
Thus, since the SIFS time is dynamically changed according to the surrounding wireless LAN environment, the wireless control device 1 (reception side) increases the probability of returning an ACK frame even in a situation where a hidden terminal is generated. Thus, unnecessary transmission of data frames from the terminal device on the transmission side can be suppressed.

  Note that the situation in which the ACK transmission time TB2 is reached is a situation in which the ACK frame is returned to the A terminal early. In such a case, by extending the SIFS time and adjusting it to SIFS_TB2, a sufficient carrier sense period can be secured, and communication collision can be avoided appropriately.

[Operation 2 of Wireless Control Device 1]
By the way, in wireless communication, a terminal device that is a transmission side at a certain timing may become a reception side terminal device at another timing. For example, in a situation where a data frame is transmitted from the A terminal to the B terminal at the first timing and a data frame is transmitted from the B terminal to the A terminal at another second timing, the A terminal It is a terminal device, and is a terminal device on the receiving side at the second timing.

In the radio network controller 1 according to the present invention, the transmission side terminal device (A terminal) adjusts the ACK Timeout time, and the reception side terminal device (B terminal) adjusts the SIFS time, thereby eliminating the need for a data frame. Retransmission is suppressed and efficient use of radio resources is realized.
In this regard, when the terminal device on the transmission side and the terminal device on the reception side are switched depending on the timing, the SIFS time may be adjusted for the A terminal, and similarly, the ACK Timeout time may be adjusted for the B terminal. Good.

  Specifically, the terminal A calculates “ACK response time TA” from the transmission of the data frame to the reception of the ACK frame during the period of the terminal device on the transmission side. When the terminal A becomes a terminal device on the receiving side, the terminal A adjusts the SIFS time based on the tendency (average, variance, etc.) of the “ACK response time TA” calculated during the period on the transmitting side. That is, the terminal A adjusts the SIFS time to be shorter when the “ACK response time TA” is longer than the standard. Note that the terminal A may adjust the SIFS time to be longer when the “ACK response time TA” is shorter than the standard.

  Similarly, the B terminal calculates “ACK transmission time TB” from the reception of the data frame to the transmission of the ACK frame during the period of the terminal device on the receiving side. When the terminal B becomes a terminal device on the transmission side, the terminal B adjusts the ACK Timeout time based on the tendency (average, variance, etc.) of the “ACK transmission time TB” calculated during the period of the reception side. That is, the B terminal adjusts the ACK timeout time to be longer when the “ACK transmission time TB” is longer than the standard. Note that the B terminal may adjust the ACK Timeout time to be shorter when the “ACK transmission time TB” is shorter than the standard.

Here, FIG. 3C is an operation example in the case where the terminal A that was the transmission-side terminal device at a certain timing becomes the reception-side terminal device at another timing.
In FIG. 3C, SIFS_TA0, TA1, and TA2 are SIFS times that are adjusted in accordance with the ACK response times TA0, TA1, and TA2, respectively.

The situation in which the ACK response time becomes the ACK response time TA1 is a situation in which the reply of the ACK frame from the terminal B is delayed, so it is assumed that the surrounding wireless LAN environment is crowded. Therefore, when the transmission side / reception side is switched, the A terminal shortens the SIFS time and adjusts to SIFS_TA1. As a result, the A terminal can adjust the SIFS time when it becomes the data receiving side based on the “ACK response time TA” calculated during the period that was the data transmitting side. Unnecessary retransmission of data frames can be suppressed.
The situation in which the ACK response time becomes the ACK response time TA2 is a situation in which the ACK frame is quickly returned from the B terminal. In such a case, the terminal A may extend the SIFS time and adjust it to SIFS_TA2. Thereby, a sufficient carrier sense period can be ensured, and communication collisions can be appropriately avoided.

FIG. 4C shows an operation example in the case where the B terminal which is the receiving terminal device at a certain timing becomes the transmitting terminal device at another timing.
In FIG. 4C, ACKTimeout_TB0, TB1, and TB2 are ACKTimeout times that are adjusted corresponding to the ACK transmission times TB0, TB1, and TB2, respectively.

Since the situation in which the ACK transmission time becomes the ACK transmission time TB1 is a situation in which the reply of the ACK frame to the terminal A is delayed, it is assumed that the surrounding wireless LAN environment is crowded. Therefore, when the transmission side / reception side is switched, the terminal B extends the ACKTimeout time and adjusts it to ACKTimeout_TB1. As a result, the B terminal can adjust the ACK Timeout time when it becomes the data transmission side based on the “ACK transmission time TB” calculated during the period of the data reception side. Unnecessary retransmission of data frames can be suppressed.
The situation where the ACK transmission time becomes the ACK transmission time TB2 is a situation where the ACK frame is returned to the A terminal early. In such a case, the B terminal may shorten the ACKTimeout time and adjust it to ACKTimeout_TB2. Thereby, when transmission of the data frame fails, it can be detected early that the data frame cannot be received at the terminal A, which is preferable.

[Processing flow of wireless control device 1]
Subsequently, processing of the radio network controller 1 will be described with reference to FIG. FIG. 5 is a flowchart showing a processing flow of the wireless control device 1.

  As shown in FIG. 5, in step S <b> 1, the transmitting terminal device transmits a data frame to the receiving terminal device. Subsequently, in step S2, the transmission-side terminal device starts timing. As shown in steps S3, S4, S5, and S6, this time is measured until the ACKTimeout time elapses or until an ACK frame is received from the terminal device on the receiving side. When ACKTimeout time has passed without receiving an ACK frame, the terminal device on the transmitting side checks whether or not the frequency channel is used during the DIFS time and BO time, and the same frequency channel is not used. The data frame is retransmitted at step S1.

  On the other hand, when an ACK frame is received from the receiving terminal device, the transmitting terminal device calculates an ACK response time from the transmission of the data frame to the reception of the ACK frame. The terminal device on the transmission side adjusts a parameter (ACK Timeout time or SIFS time) at an arbitrary timing based on the trend (average, variance, etc.) of the ACK response time (step S7).

  In addition, when receiving the data frame from the transmitting terminal device, the receiving terminal device starts timing and carrier sense (steps S11 and S12). At this time, when the receiving side terminal device confirms that the same frequency channel is free during the SIFS time (steps S13 and S14), in step S15, an ACK frame is transmitted to the transmitting side terminal device. At the same time, the timing is terminated, and the ACK transmission time from the reception of the data frame to the transmission of the ACK frame is calculated.

  Subsequently, in step S <b> 16, the receiving-side terminal device adjusts a parameter (ACK Timeout time or SIFS time) at an arbitrary timing based on the tendency (average, variance, etc.) of the ACK transmission time.

[Effect of wireless control device 1]
In the wireless control device 1 of the present invention described above, the ACK Timeout time and the SIFS time are adjusted according to the surrounding wireless LAN environment. Accordingly, it is possible to prevent the transmitter from retransmitting the data frame even though the receiver can normally receive the data frame, and it is possible to efficiently use radio resources.

[Another embodiment]
Next, another embodiment of the wireless control device 1 of the present invention will be described. In the embodiment described above, an example in which the transmission frame transmitted from the terminal device on the transmission side is a “data frame” and the response frame transmitted from the terminal device on the reception side according to the transmission frame is an “ACK frame”. explained.
In this regard, the radio control apparatus 1 of the present invention may use an “RTS frame” as a transmission frame and a “CTS frame” as a response frame.

As a method for preventing the occurrence of a hidden terminal problem, an access control method called RTS / CTS (request to send / clear to send) is known.
In RTS / CTS, as shown in FIG. 6, the A terminal on the transmission side transmits an RTS (request to send) frame to the B terminal that is the transmission partner before transmitting the data frame. When terminal B that has received the RTS frame is ready to receive a data frame, it returns a CTS (clear to send) frame to terminal A, and terminal A waits for the CTS frame from terminal B to Send.

  In such a case, the A terminal in another embodiment adjusts the ACK Timeout time and the SIFS time based on time information from when the RTS frame is transmitted until the CTS frame is received. Similarly, the B terminal in another embodiment adjusts the ACK Timeout time and the SIFS time based on time information from the reception of the RTS frame to the transmission of the CTS frame.

  Even in the wireless control device 1 as described above, the ACK Timeout time and the SIFS time can be adjusted according to the surrounding wireless LAN environment, so that wireless resources can be used efficiently.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

That is, the radio network controller 1 according to the present invention uses the ACKTimeout based on the time information from when the transmission frame is transmitted until the response frame is received and the time information after the transmission frame is received until the response frame is transmitted. Adjust time and SIFS time. In this respect, the transmission frame and the response frame need only have a transmission / response relationship, and are not limited to the above-described embodiment.
As an example, the radio control apparatus 1 of the present invention can be applied with a transmission frame as a “CTS frame” and a response frame as a “data frame” (see FIG. 6).

DESCRIPTION OF SYMBOLS 1 ... Radio control apparatus, 2 ... Transmission determination part, 3 ... Reception determination part, 4 ... Time information calculation part, 5 ... Parameter adjustment part

Claims (6)

A transmission determination unit that outputs transmission notification information notifying that a transmission frame has been transmitted to another terminal;
A reception determination unit that outputs reception notification information notifying that a response frame has been received from the other terminal;
Time for calculating time information from when a specific transmission frame is transmitted to the other terminal until a response frame corresponding to the specific transmission frame is received based on the transmission notification information and the reception notification information An information calculation unit;
Based on the calculated time information, a frame retransmission interval from transmission of a transmission frame to retransmission is adjusted , and when a transmission frame is received from the other terminal based on the calculated time information, the transmission A parameter adjustment unit that adjusts a response interval from when a frame is received until a response frame corresponding to the transmission frame is transmitted to the other terminal ;
A wireless control device comprising: The parameter adjustment unit increases the frame retransmission interval when the calculated time information is equal to or greater than a first threshold, and adjusts the frame retransmission interval to be shorter when the time information is equal to or less than a second threshold.
The radio control apparatus according to claim 1. The parameter adjustment unit shortens the response interval when the calculated time information is equal to or greater than a third threshold, and adjusts the response interval to be longer when the time information is equal to or less than a fourth threshold.
The radio control apparatus according to claim 1 or 2 . The transmission frame is a data frame;
The response frame is an ACK frame;
Radio controller according to any one of claims 1 to 3. The transmission frame is an RTS frame;
The response frame is a CTS frame.
Radio controller according to any one of claims 1 to 4. Outputting transmission notification information notifying that a transmission frame has been transmitted to another terminal;
Outputting reception notification information notifying that a response frame has been received from the other terminal;
A step of calculating time information from when a specific transmission frame is transmitted to the other terminal until a response frame corresponding to the specific transmission frame is received based on the transmission notification information and the reception notification information When,
Adjusting a frame retransmission interval from transmitting a transmission frame to retransmitting based on the calculated time information;
Based on the calculated time information, when a transmission frame is received from the other terminal, a response interval from when the transmission frame is received until a response frame corresponding to the transmission frame is transmitted to the other terminal is adjusted. And steps to
A wireless control method including:

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