JP2016213556A - Wireless communication method and wireless communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless communication method capable of achieving synchronization establishment between a data transfer source and a data transfer destination, that is required at the time of data transfer, while reducing power consumption in a wireless system performing intermittent action repeating dormant state and operational state.SOLUTION: A wireless communication method in a wireless communication system receiving a synchronization signal, for synchronizing a first wireless device and a second wireless device, at a predetermined time interval, has a synchronization signal transmission step where the first wireless device transmits the synchronization signal with a period of longer time than the time interval of intermittent reception, and a synchronization step where the second wireless device maintains synchronization with the first wireless device by receiving the synchronization signal. In the synchronization signal transmission step, the synchronization signal is transmitted while leading or lagging by a previously notified offset time for the second wireless device.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a wireless communication method and a wireless communication system.

  In many wireless systems, in order to reduce power consumption, a wireless terminal performs an intermittent operation that repeats a sleep state in which power consumption is very low and an operation state in which transmission and reception can be performed. For example, when data is transmitted from another wireless terminal 1 to the wireless terminal 2 that is intermittently receiving data, the wireless terminal 2 is synchronized with the timing of intermittently receiving data for reception. When the wireless terminal 1 transmits data, the wireless terminal 2 can receive the data.

  Two methods are applicable as a method of maintaining timing synchronization between two wireless terminals. The first method will be described with reference to FIG. FIG. 13 is a sequence diagram illustrating a processing procedure of a method for maintaining timing synchronization between two wireless terminals. As shown in FIG. 13, the first method is a method in which the wireless terminal 1 receives a synchronization signal that the wireless terminal 2 periodically transmits. [R] illustrated in FIG. 13 indicates an intermittent reception operation. In the processing procedure shown in FIG. 13, the wireless terminal 2 transmits a synchronization signal to the wireless terminal 1 at an interval of the synchronization signal interval (Tsync) (steps S1 and S2). The wireless terminal 1 receives the transmitted synchronization signal and calculates and obtains the timing at which the wireless terminal 2 transmits. Then, the wireless terminal 1 performs data transmission based on the calculated timing (step S3). The wireless terminal 2 receives this data by an intermittent reception operation.

  Next, the second method will be described with reference to FIG. FIG. 14 is a sequence diagram illustrating a processing procedure of a method for maintaining timing synchronization between two wireless terminals. The second method is a method in which the wireless terminal 2 receives a synchronization signal that the wireless terminal 1 periodically transmits. [R] shown in FIG. 14 indicates an intermittent reception operation. In the processing procedure illustrated in FIG. 14, the wireless terminal 1 transmits a synchronization signal to the wireless terminal 2 at a synchronization signal interval (Tsync) (steps S <b> 11 and S <b> 12). The wireless terminal 2 receives the transmitted synchronization signal and calculates and obtains the timing at which the wireless terminal 1 transmits. Then, the wireless terminal 1 performs data transmission (step S13). The wireless terminal 2 receives this data by the intermittent reception operation based on the calculated timing.

  In this way, the two wireless terminals can maintain synchronization by executing the two methods described above.

Uchida, Matsumura, Kuwano, Cloth, Mochizuki, Odabe, Suzuki, Fujita, Kamiya, “Technological Development Effort to Realize Wide Area Ubiquitous Network”, NTT Technical Journal, Vol. 22, no. 3, PP. 12-16, 2010

  As described above, in one wireless communication system, the period for transmitting a synchronization signal is generally operated at the same time interval. For this reason, when the timings of transmitting the synchronization signals of the two wireless terminals coincide with each other, the synchronization signal is always transmitted at the same timing, so that there is a problem that a collision occurs every time. Since each wireless terminal has a relative error in its reference oscillator, it is resolved over time, but when the relative error is small, it takes time to resolve the collision. In order to avoid this, there is a means of transmitting with a time offset randomly every time a signal is transmitted at the timing of transmitting a synchronization signal, that is, transmitting with a short time timing.

  On the other hand, since there is a reference oscillator error between two wireless terminals to be synchronized, for example, in order to transfer data from the wireless terminal 1 within the intermittent reception time of the wireless terminal 2, In consideration of the timing shift corresponding to the error, it is necessary to receive the radio terminal 2 intermittently for a long time with a margin for the timing shift. In order to reduce the power consumption of the wireless terminal, it is necessary to shorten the intermittent reception time. For this purpose, it is necessary to increase the accuracy of synchronization between the two wireless terminals as much as possible. As a method for this, by adding a correction value corresponding to the error of both reference oscillators from the timing of the received synchronization signal, the timing deviation of intermittent reception is reduced, and the reception time of intermittent reception is shortened, resulting in lower consumption. There is a means of using electricity.

  By applying both, it is possible to avoid synchronization signal collisions and reduce power consumption. However, if a random time offset is applied to the transmission of the synchronization signal, the transmission interval of the synchronization signal is random each time. Therefore, there is a problem that the timing does not match even if the correction value is calculated on the receiving side.

  The present invention has been made in view of such circumstances, and establishes synchronization between a data transfer source and a data transfer destination that are required at the time of data transfer in a wireless system that performs intermittent operation that repeats a pause state and an operation state. It is an object of the present invention to provide a wireless communication method and a wireless communication system that can be realized while reducing power consumption.

  One aspect of the present invention is a wireless communication method performed by a wireless communication system that intermittently receives a synchronization signal for synchronizing a first wireless device and a second wireless device at a predetermined time interval. A synchronization signal transmitting step in which one wireless device transmits a synchronization signal at a period longer than the intermittent reception time interval; and the second wireless device receives the synchronization signal, thereby causing the first A synchronization step for maintaining synchronization with the wireless device, and in the synchronization signal transmitting step, when transmitting the synchronization signal, the second wireless device is advanced or delayed by an offset time previously notified to the second wireless device. A wireless communication method for transmitting the synchronization signal.

  One aspect of the present invention is the wireless communication method, wherein, in the synchronization step, the reception for receiving the synchronization signal at a timing of receiving the next synchronization signal when the reception of the synchronization signal fails. The time is increased by the time width during which the synchronization signal may be transmitted.

  One aspect of the present invention is the wireless communication method, wherein in the synchronization signal transmission step, the synchronization signal is transmitted by superimposing the offset time information, and the second wireless device transmits the synchronization signal. A reply transmission step for transmitting to the first wireless device a notification notifying that the synchronization signal has been received when received, and in the synchronization signal transmission step, when the reply is received, the offset time Then, the next synchronization signal is transmitted, and when the reply is not received, the next synchronization signal is transmitted at a predetermined timing.

  One aspect of the present invention is the wireless communication method, wherein in the reply transmission step, the reply is transmitted at a time interval longer than a transmission interval of the synchronization signal, and in the synchronization signal transmission step, the reply is transmitted. The next synchronization signal is transmitted based on the offset time when not transmitted, and the next synchronization signal is transmitted at a predetermined timing when the reply is not received when the reply is transmitted.

  One aspect of the present invention is the wireless communication method, wherein in the synchronization signal transmission step, transmission of the synchronization signal is stopped irregularly at a certain rate, and in the synchronization step, the reply is transmitted at a timing. When the synchronization signal is not received, the reply is transmitted. In the synchronization signal transmission step, when the reply is received, the synchronization signal is transmitted at a timing at which the next synchronization signal is to be transmitted.

  One aspect of the present invention is a wireless communication system that intermittently receives a synchronization signal for synchronizing a first wireless device and a second wireless device at predetermined time intervals, wherein the first wireless device includes: A synchronization signal transmitting means for transmitting a synchronization signal at a period of time longer than the intermittent reception time interval, wherein the second wireless device receives the synchronization signal and thereby communicates with the first wireless device. Synchronization means for maintaining synchronization is provided, and the first wireless device transmits the synchronization signal by advancing or delaying the offset time previously notified to the second wireless device when transmitting the synchronization signal. A wireless communication system.

  According to the present invention, establishment of synchronization between a data transfer source and a data transfer destination, which is necessary at the time of data transfer, is realized while reducing power consumption in a wireless system that performs intermittent operation that repeats a sleep state and an operation state. The effect that it can be obtained.

It is a block diagram which shows the structure of the radio | wireless communications system by 1st Embodiment of this invention. 3 is a flowchart illustrating an operation of the wireless communication system according to the first embodiment. It is a sequence diagram which shows operation | movement of a radio | wireless communications system. It is a flowchart which shows operation | movement of the radio | wireless communications system by 2nd Embodiment. It is a sequence diagram which shows operation | movement of a radio | wireless communications system. 10 is a flowchart illustrating an operation of the wireless communication system according to the third embodiment. It is a sequence diagram which shows operation | movement of a radio | wireless communications system. It is a flowchart which shows operation | movement of the radio | wireless communications system by 4th Embodiment. It is a sequence diagram which shows operation | movement of a radio | wireless communications system. It is a flowchart which shows operation | movement of the radio | wireless communications system by 5th Embodiment. It is a sequence diagram which shows operation | movement of a radio | wireless communications system. It is a block diagram which shows the structure of the radio | wireless communications system by 6th Embodiment. It is a sequence diagram which shows the process sequence of the method of maintaining the timing synchronization between two radio | wireless terminals. It is a sequence diagram which shows the process sequence of the method of maintaining the timing synchronization between two radio | wireless terminals.

<First Embodiment>
Hereinafter, a wireless communication system according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a device configuration of the first embodiment. In this figure, reference numeral 1 denotes a wireless terminal on the side that receives a synchronization signal by wireless communication. Reference numeral 2 denotes a wireless terminal that transmits a synchronization signal to the wireless terminal 1.

  In the first embodiment, when there is a wireless terminal 2 that transmits a synchronization signal and a wireless terminal 1 that synchronizes with the wireless terminal 2 by receiving the synchronization signal transmitted by the wireless terminal 2, the wireless terminal 2 Is transmitted by adding a random offset time to a predetermined transmission interval. At this time, the wireless terminal 2 superimposes and transmits the information of the offset time added at the transmission timing of the subsequent synchronization signal in addition to the terminal ID as information to the synchronization signal to be transmitted. Then, the wireless terminal 1 that receives the synchronization signal knows the timing of the next synchronization signal transmitted using the offset time information of the next and subsequent synchronization signals superimposed on the synchronization signal, and synchronizes accordingly. Set the signal reception timing.

  This operation will be described with reference to FIG. FIG. 2 is a flowchart showing the operation of the wireless communication system according to the first embodiment. First, the wireless terminal 2 sets a reference synchronization signal transmission interval (Tsync) (step S21). The wireless terminal 1 also sets a reference synchronization signal transmission interval (Tsync) (step S31).

  Next, the wireless terminal 2 sets a random offset time (ΔT (n)) (step S22). And the radio | wireless terminal 2 transmits the synchronous signal which superimposed the information of (DELTA) T (n) by the space | interval of Tsync + (DELTA) T (n-1) (step S23). The wireless terminal 2 repeatedly executes the processing operations of steps S22 and S23.

  The synchronization signal is received by the wireless terminal 1 (step S32), and ΔT (n) superimposed on the synchronization signal is read to calculate the next synchronization signal reception timing (step S33). The wireless terminal 1 repeatedly executes the processing operations of steps S32 and S33.

  Next, the operation of the wireless communication system according to the first embodiment will be described with reference to FIG. FIG. 3 is a sequence diagram showing the operation of the wireless communication system. First, the wireless terminals 1 and 2 each set a reference synchronization signal transmission interval (Tsync). Then, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S41). Information of ΔT (n) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S51). In FIG. 3, [R] indicates an intermittent reception operation. The wireless terminal 1 reads ΔT (n) superimposed on the synchronization signal and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n) from the start time of the reference synchronization signal transmission interval (Tsync) (step S42). Information of ΔT (n + 1) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S52). The wireless terminal 1 reads ΔT (n + 1) superimposed on the synchronization signal and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n + 1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S43). Information of ΔT (n + 2) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S53). The wireless terminal 1 reads ΔT (n + 2) superimposed on the synchronization signal and calculates the next synchronization signal reception timing. The wireless terminals 1 and 2 repeatedly execute such processing operations.

  Note that the offset time information to be superimposed is the offset time itself or information by which the offset time can be known by calculation on the receiving side. The information on the offset time to be superimposed is not only the offset time of the next synchronization signal but also the offset time of the synchronization signal for a plurality of times.

  The wireless terminal 1 uses the offset time information added to the transmission timing of the next synchronization signal superimposed as information on the received synchronization signal to match the reception timing of the next synchronization signal and multiple times more than once. The correct correction value is calculated by using it when calculating the correction value from the received synchronization signal.

  According to this method, since a plurality of wireless terminals each add a random offset and transmit a synchronization signal, the possibility that the synchronization signals from each wireless terminal collide continuously is greatly reduced, and the synchronization is corrected accurately. Can be applied.

Second Embodiment
Next, a radio communication system according to the second embodiment of the present invention will be described. When the method of the first embodiment is used, if the wireless terminal 1 cannot receive the synchronization signal from the wireless terminal 2 due to some influence, the wireless terminal 1 adds to the transmission of the next synchronization signal from the wireless terminal 2. There is a possibility that the offset time is not known and the timing is shifted. Therefore, when the wireless terminal 1 cannot receive the synchronization signal, the reception time for receiving the synchronization signal at the reception timing of the next synchronization signal is a long time reflecting the variation due to the offset time and the variation due to the relative error. Change to

  This operation will be described with reference to FIG. FIG. 4 is a flowchart showing the operation of the wireless communication system according to the second embodiment. In FIG. 4, the same processing operations as those shown in FIG.

  First, the wireless terminal 2 sets a reference synchronization signal transmission interval (Tsync) (step S21). The wireless terminal 1 also sets a reference synchronization signal transmission interval (Tsync) (step S31).

  Next, the wireless terminal 2 sets a random offset time (ΔT (n)) (step S22). And the radio | wireless terminal 2 transmits the synchronous signal which superimposed the information of (DELTA) T (n) by the space | interval of Tsync + (DELTA) T (n-1) (step S23). The wireless terminal 2 repeatedly executes the processing operations of steps S22 and S23.

  This synchronization signal is received by the wireless terminal 1 (step S32). Then, the wireless terminal 1 determines whether or not the synchronization signal has been successfully received (step S34). If the result of this determination is that the synchronization signal has been successfully received, the wireless terminal 1 reads ΔT (n) superimposed on the synchronization signal and calculates the next synchronization signal reception timing (step S33). On the other hand, when the reception of the synchronization signal fails, the wireless terminal 1 extends the reception time of the synchronization signal reception (step S35). The wireless terminal 1 repeatedly executes the processing operations of steps S32 to S35.

  Next, the operation of the wireless communication system according to the second embodiment will be described with reference to FIG. FIG. 5 is a sequence diagram showing the operation of the wireless communication system. First, the wireless terminals 1 and 2 each set a reference synchronization signal transmission interval (Tsync). Then, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−2) from the start time of the reference synchronization signal transmission interval (Tsync) (step S41). Information of ΔT (n−1) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S54). The wireless terminal 1 reads ΔT (n−1) superimposed on the synchronization signal and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S41). Information of ΔT (n) is superimposed on this synchronization signal. At this time, the wireless terminal 1 fails to receive the synchronization signal (step S51). In response, the wireless terminal 1 extends the next reception time.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n) from the start time of the reference synchronization signal transmission interval (Tsync) (step S42). Information of ΔT (n + 1) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S52). At this time, the wireless terminal 1 starts the reception operation before the start time of the reference synchronization signal transmission interval (Tsync) and extends the reception time. When the synchronization signal is successfully received, the wireless terminal 1 reads ΔT (n + 1) superimposed on the synchronization signal and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n + 1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S43). Information of ΔT (n + 2) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S53). The wireless terminal 1 reads ΔT (n + 2) superimposed on the synchronization signal and calculates the next synchronization signal reception timing. The wireless terminals 1 and 2 repeatedly execute such processing operations.

  By doing so, the next synchronization signal can be received even if reception of the synchronization signal fails. In the case of a wireless communication system in which synchronization is maintained by receiving a synchronization signal on the data receiving side, similarly, regarding the reception time of intermittent reception between the synchronization signal and the synchronization signal, when the synchronization signal cannot be received. By extending the reception time, data transmission that occurs after the synchronization signal cannot be received can be received.

<Third Embodiment>
Next, a radio communication system according to a third embodiment of the present invention is described. When the method of the first embodiment or the second embodiment is used, if the wireless terminal 1 cannot receive the synchronization signal from the wireless terminal 2 due to some influence, the wireless terminal 1 performs the next synchronization from the wireless terminal 2. There is a possibility that the offset time added to the signal transmission cannot be known and the timing is shifted. Therefore, when the wireless terminal 1 receives the synchronization signal from the wireless terminal 2, it transmits a reply (ACK) for notifying that the synchronization signal has been received, and the wireless terminal 2 receives this to transmit the next transmission. Update the offset value added to. By returning ACK, the wireless terminal 2 that transmits the synchronization signal can recognize whether the wireless terminal 2 that receives the synchronization signal is in a synchronized state or out of synchronization.

  The wireless terminal 1 updates the offset value added to the reception timing of the synchronization signal when the synchronization signal from the wireless terminal 2 cannot be received at the timing of receiving the synchronization signal or when ACK cannot be transmitted due to carrier sense or the like Or set the offset value to 0 to prepare for the reception of the next synchronization signal. When the wireless terminal 2 does not receive the ACK from the wireless terminal 1, the same offset value or offset value as the previous time is transmitted as 0 when the next synchronization signal is transmitted.

  This operation will be described with reference to FIG. FIG. 6 is a flowchart showing the operation of the wireless communication system according to the third embodiment. In FIG. 6, the same processing operations as those shown in FIG.

  First, the wireless terminal 2 sets a reference synchronization signal transmission interval (Tsync) (step S21). The wireless terminal 1 also sets a reference synchronization signal transmission interval (Tsync) (step S31).

  Next, the wireless terminal 2 sets a random offset time (ΔT (n)) (step S22). And the radio | wireless terminal 2 transmits the synchronous signal which superimposed the information of (DELTA) T (n) by the space | interval of Tsync + (DELTA) T (n-1) (step S23).

  This synchronization signal is received by the wireless terminal 1 (step S32). Then, the wireless terminal 1 determines whether or not the synchronization signal has been successfully received (step S34). If the result of this determination is that the synchronization signal has been successfully received, the wireless terminal 1 returns ACK (step S36), reads ΔT (n) superimposed on the synchronization signal, and calculates the next synchronization signal reception timing ( Step S33).

  On the other hand, when the reception of the synchronization signal fails, the wireless terminal 1 calculates the next synchronization signal reception timing using the same ΔT (n−1) as this time (step S37). The wireless terminal 1 repeatedly executes the processing operations of steps S32 to S37.

  When ACK is returned from the wireless terminal 1, the wireless terminal 2 receives this ACK (step S24) and determines whether or not the ACK has been successfully received (step S25). If the result of this determination is that reception of ACK has failed, the wireless terminal 2 returns to step S23 and repeats the processing. On the other hand, when the reception of the ACK is successful, the wireless terminal 2 returns to step S22 and repeats the process.

  Next, the operation of the wireless communication system according to the second embodiment will be described with reference to FIG. FIG. 7 is a sequence diagram showing the operation of the wireless communication system. First, the wireless terminals 1 and 2 each set a reference synchronization signal transmission interval (Tsync). Then, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−2) from the start time of the reference synchronization signal transmission interval (Tsync) (step S41). Information of ΔT (n−1) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S54). The wireless terminal 1 returns an ACK to the wireless terminal 2 (step S55), reads ΔT (n) superimposed on the synchronization signal, and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S41). Information of ΔT (n) is superimposed on this synchronization signal. At this time, the wireless terminal 1 fails to receive the synchronization signal (step S51).

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n−1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S45). Information of ΔT (n) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S52). Receiving this, the wireless terminal 1 receives this synchronization signal (step S52). The wireless terminal 1 returns an ACK to the wireless terminal 2 (step S56), reads ΔT (n) superimposed on the synchronization signal, and calculates the next synchronization signal reception timing.

  Next, the wireless terminal 2 transmits a synchronization signal at a time delayed by ΔT (n + 1) from the start time of the reference synchronization signal transmission interval (Tsync) (step S46). Information of ΔT (n) is superimposed on this synchronization signal. Receiving this, the wireless terminal 1 receives this synchronization signal (step S53). The wireless terminal 1 returns an ACK to the wireless terminal 2 (step S57), reads ΔT (n) superimposed on the synchronization signal, and calculates the next synchronization signal reception timing. The wireless terminals 1 and 2 repeatedly execute such processing operations.

  By doing so, it is possible to reduce a timing shift due to a failure in receiving the synchronization signal.

<Fourth embodiment>
Next, a radio communication system according to a fourth embodiment of the present invention is described. In the fourth embodiment, the power consumption can be reduced by setting the ACK return interval for the synchronization signal to a sufficiently long time with respect to the interval for transmitting the synchronization signal. The wireless terminal 1 updates the offset value of the synchronization signal regardless of whether or not an ACK is received. When the wireless terminal 1 has not received ACK for a time longer than the ACK reply interval, the wireless terminal 1 determines that the synchronization with the wireless terminal 2 has been lost, and supplements the synchronization at the first time determined separately. Go to step. Before proceeding to the procedure for supplementing synchronization first, at the next synchronization signal transmission timing, the synchronization signal is transmitted with the offset value set to 0, and the synchronization signal receiving side also receives the synchronization signal with the offset value set to 0. Try. In addition, by returning ACK for the synchronization signal at this time, it is possible to avoid long-time synchronization signal reception failures.

  This operation will be described with reference to FIG. FIG. 8 is a flowchart showing the operation of the wireless communication system according to the fourth embodiment. In FIG. 8, the same processing operations as those shown in FIG.

  First, the wireless terminal 2 sets a reference synchronization signal transmission interval (Tsync) and an ACK transmission interval (Tack) (step S26). The wireless terminal 1 also sets a reference synchronization signal transmission interval (Tsync) and an ACK transmission interval (Tack) (step S38).

  Next, the wireless terminal 2 sets a random offset time (ΔT (n)) (step S22). And the radio | wireless terminal 2 transmits the synchronous signal which superimposed the information of (DELTA) T (n) by the space | interval of Tsync + (DELTA) T (n-1) (step S23).

  This synchronization signal is received by the wireless terminal 1 (step S32). Then, the wireless terminal 1 determines whether or not the synchronization signal has been successfully received (step S34). If reception of the synchronization signal fails as a result of this determination, the wireless terminal 1 calculates the next synchronization signal reception timing with the offset set to 0 (step S40), and returns to step S32.

  On the other hand, when the reception of the synchronization signal is successful, the wireless terminal 1 determines whether or not it is time to transmit an ACK (step S39). If the result of this determination is that it is time to transmit ACK, the wireless terminal 1 transmits ACK (step S36). On the other hand, ACK transmission is not performed unless it is the timing to transmit ACK.

  Next, the wireless terminal 1 reads ΔT (n) superimposed on the synchronization signal, calculates the next synchronization signal reception timing (step S33), and returns to step S32.

  When ACK is returned from the wireless terminal 1, the wireless terminal 2 determines whether it is time to receive ACK (step S27). If the result of this determination is that it is not time to receive ACK, the process returns to step S22. On the other hand, if it is time to receive ACK, the wireless terminal 2 receives ACK (step S24), and determines whether or not the ACK has been successfully received (step S25). If reception of ACK fails as a result of this determination, the radio terminal 2 transmits a synchronization signal on which the offset is set to 0 and information on ΔT (n) is superimposed (step S27). On the other hand, when the reception of the ACK is successful, the wireless terminal 2 returns to step S22 and repeats the process.

  Next, the operation of the wireless communication system according to the fourth embodiment will be described with reference to FIG. FIG. 9 is a sequence diagram illustrating an operation of the wireless communication system. The wireless terminal 2 transmits a synchronization signal to the wireless terminal 1 based on the transmission offset of the synchronization signal according to the procedure described above (steps S61 to S69). In response to this, the wireless terminal 1 receives the synchronization signal based on the reception offset of the synchronization signal superimposed on the received synchronization signal (steps S71 to S79). Then, the wireless terminal 1 transmits ACK to the wireless terminal 2 based on the ACK transmission interval (Tack) (steps S80 and S81). In response to this, the wireless terminal 2 receives this ACK. The wireless terminal 2 determines whether or not to receive ACK depending on whether or not ACK has been received after Tack since the previous ACK reception.

  At this time, the interval at which the wireless terminal 1 transmits ACK may be shorter than the time interval at which the wireless terminal 1 determines that it has not received ACK, and does not necessarily have to be a constant cycle. As shown in FIG. 13, since the wireless terminal 2 repeats short reception (reception window) intermittently in preparation for data transmission from the wireless terminal 1 between the synchronization signals, any one of the reception windows By returning ACK in accordance with the timing, it is possible to notify the wireless terminal 2 of reception of the synchronization signal (see the right diagram (enlarged diagram) in FIG. 9).

  Further, the reliability of the correction value may be improved by performing the synchronization signal reception timing used for calculating the correction value only by using the signal that has received the ACK of the synchronization signal at the timing of returning the ACK.

<Fifth Embodiment>
Next, a radio communication system according to a fifth embodiment of the present invention is described. In the fifth embodiment, continuous synchronization signal collisions are avoided by randomly canceling transmission of synchronization signals at a constant rate. Even when the wireless terminal 1 that receives the synchronization signal does not receive the synchronization signal, the wireless terminal 1 continues to receive the synchronization signal at a predetermined synchronization signal transmission interval, and is longer than the synchronization signal transmission interval as in the fourth embodiment. Reply with ACK.

  This operation will be described with reference to FIG. FIG. 10 is a flowchart showing the operation of the wireless communication system according to the fifth embodiment. First, the wireless terminal 2 sets a reference synchronization signal transmission interval (Tsync) (step S111). The wireless terminal 1 also sets a reference synchronization signal transmission interval (Tsync) (step S101).

  Next, the wireless terminal 2 waits until the timing for transmitting the synchronization signal while determining whether it is the timing for transmitting the synchronization signal (step S112). Then, when it is time to transmit the synchronization signal, the wireless terminal 2 determines whether or not to thin out the synchronization signal (step S113). If the synchronization signal is not thinned out as a result of this determination, the wireless terminal 2 transmits a synchronization signal to the wireless terminal 1 (step S114).

  On the other hand, the wireless terminal 1 waits until the timing for receiving the synchronization signal while determining whether it is the timing for receiving the synchronization signal (step S102). And reception is started at the timing which receives a synchronous signal (step S103), and it is determined whether the reception of the synchronous signal was successful (step S104). Subsequently, the wireless terminal 1 determines whether it is time to transmit ACK (step S105), and returns to step S102 if it is not time to transmit ACK. On the other hand, if it is time to transmit ACK, the wireless terminal 1 transmits ACK (step S106), returns to step S102, and repeats the process.

  In response to this, the wireless terminal 2 determines whether or not an ACK has been received (step S115), and returns to step S113.

  On the other hand, if the synchronization signal is thinned out in step S113, the wireless terminal 2 stops the synchronization signal transmission (step S116). Then, the wireless terminal 2 determines whether or not an ACK has been received (step S117). If the result of this determination is that ACK is not received, the wireless terminal 2 returns to step S113. When receiving the ACK, the wireless terminal 2 transmits a synchronization signal at the next synchronization signal transmission timing (step S118), and returns to step S113.

  Next, the operation of the wireless communication system according to the fifth embodiment will be described with reference to FIG. FIG. 11 is a sequence diagram showing the operation of the wireless communication system. First, the wireless terminal 2 transmits a synchronization signal to the wireless terminal 1 at a reference synchronization signal transmission interval (Tsync) (steps S120 to S125). In response to this, the wireless terminal 1 receives the synchronization signal at the reference synchronization signal transmission interval (Tsync) (steps S131 to S139). However, since the predetermined synchronization signal is thinned out and not transmitted, the wireless terminal 1 cannot receive the synchronization signal. In the example shown in FIG. 11, the synchronization signals between steps S120 and S121, between steps S122 and S123, and between steps S123 and S124 are thinned out and not transmitted. On the other hand, the wireless terminal 1 transmits ACK to the wireless terminal 2 at an ACK transmission interval (Tack) (steps S141 to S143).

  Thus, by thinning out the synchronization signal transmitted from the wireless terminal 2, the number of transmissions of the synchronization signal can be reduced, so that the power consumption of the wireless terminal 2 that transmits the synchronization signal can be reduced.

<Sixth Embodiment>
Next, a radio communication system according to a sixth embodiment of the present invention is described. FIG. 12 is a block diagram showing a configuration of a wireless communication system according to the sixth embodiment. The sixth embodiment is a star-type wireless communication system in which one wireless base station 4 and a plurality of wireless terminals 1, 2, and 3 communicate. The wireless terminals 1, 2, and 3 transmit synchronization signals at their own timings, and intermittent reception function units 11 and 21 that perform reception by setting a short reception time (reception window) between the synchronization signals and the synchronization signals. , 31 are provided. The wireless base station 4 receives the synchronization signal of each of the wireless terminals 1, 2, and 3 to manage the reception time timing of each of the wireless terminals 1, 2, and 3 by the intermittent reception timing management function unit 41. When data is transmitted from the base station 4 to the wireless terminals 1, 2, and 3, data is transmitted in accordance with the reception timing.

  At this time, in order to make the transmission opportunities of data toward the wireless terminals 1, 2, and 3 constant, the reception time intervals of the wireless terminals 1, 2, and 3 and the synchronization signal transmission time intervals are the same. It is common. Therefore, in the case where there are a large number of wireless terminals, if the transmission timings of the synchronization signals between the wireless terminals once match, the timing will continue to match for a while, so in this embodiment, each wireless terminal 1, 2, When 3 transmits a synchronization signal, a random offset time is added and the synchronization signal is transmitted. On the other hand, in order for the radio base station 4 to manage the reception timings of the radio terminals 1, 2, and 3, it is necessary to know the offset time added when transmitting the synchronization signal. Before transmission, the radio base station is notified in advance of the offset time added to the next synchronization signal. As in the first embodiment, this notification may be superimposed on the previous synchronization signal.

  The radio base station 4 notifies each radio terminal 1, 2 and 3 of the confirmation signal (ACK) for notifying that the synchronization signal has been received, thereby notifying that the synchronization signal has been obtained. Since it is unlikely that the synchronization signal cannot be received when the communication quality in the wireless section is relatively good, each of the confirmation signals has a sufficiently long time interval with respect to the transmission interval of the synchronization signal as in the fourth embodiment. The wireless terminals 1, 2, and 3 transmit in accordance with a reception window waiting for data reception from the wireless base station 4. If the wireless terminals 1, 2, and 3 are unable to receive the ACK transmission interval or longer, the wireless terminals 1, 3 shift to a process of re-synchronizing with the wireless base station 4.

  In this way, in a star-type wireless network, the wireless terminal's intermittent reception time is extremely shortened, and the number of synchronization signal transmissions is reduced, thereby significantly reducing the power consumption of the wireless terminal. It becomes possible to do.

  In the above description, an example in which the random offset time is delayed from the start time of the reference synchronization signal transmission interval has been described. However, the offset time may be advanced from the start time of the reference synchronization signal transmission interval.

  As described above, a wireless terminal that transmits a synchronization signal adds a random offset time to the synchronization signal for transmission, and notifies the receiver in advance of the offset time before transmission, thereby reducing synchronization establishment. This can be realized while achieving electric power. In this method, since the offset time is random, collision can be avoided, and since the offset time added by the synchronization signal transmitting side radio terminal and the synchronization signal receiving side radio terminal is shared, It is also possible to make corrections at the wireless terminal.

  In addition, in the method of notifying the offset time in advance, if the notification is not received, there is a mismatch in the offset time between the wireless terminal on the synchronization signal transmitting side and the wireless terminal on the synchronization signal receiving side. To solve this problem, when the synchronization signal receiving wireless terminal receives the synchronization signal, it notifies the transmitting wireless terminal of the reception (ACK), and the synchronization signal transmitting wireless terminal receives the ACK. The occurrence of discrepancy can be reduced by taking a procedure for updating the offset time only when the error occurs. Also, if there is a concern that the power consumption will increase by returning an ACK, it is possible to thin out the ACK responses at a certain rate.

  Furthermore, in order to reduce the power consumption on the synchronization signal transmission side, the synchronization signal transmission itself is randomly thinned out at a constant rate. In this case, if the wireless terminal that receives the synchronization signal cannot receive the synchronization signal for a certain period of time, the wireless terminal on the synchronization signal transmitting side is notified that the synchronization signal has not been received in order to request transmission of the synchronization signal. Send a signal. Thus, by avoiding a state in which the synchronization signal cannot be received for a certain time or longer, the synchronization state can be maintained with low power consumption while avoiding the collision of the synchronization signals.

  According to this configuration, it is possible to reduce the power consumption of the wireless terminal while avoiding the occurrence of continuous collision particularly when there are a large number of wireless terminals and each transmitting a synchronization signal. It becomes. In particular, in a radio system having a star-type network configuration in which radio communication is performed between one radio base station and a plurality of radio terminals, radio when the radio base station and the radio terminals transmit synchronization signals autonomously and distributedly, respectively. When the synchronization signals of the terminals collide, it is possible to avoid the occurrence of continuous collisions and reduce the power consumption of the wireless terminal.

  You may make it implement | achieve all or one part of the wireless base station or wireless terminal in embodiment mentioned above with a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be a program for realizing a part of the above-described functions, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system. It may be realized using hardware such as PLD (Programmable Logic Device) or FPGA (Field Programmable Gate Array).

  As mentioned above, although embodiment of this invention has been described with reference to drawings, the said embodiment is only the illustration of this invention, and it is clear that this invention is not limited to the said embodiment. is there. Therefore, additions, omissions, substitutions, and other modifications of the components may be made without departing from the technical idea and scope of the present invention.

  For wireless systems that perform intermittent operation that repeats the sleep state and the operation state, it is essential to achieve synchronization establishment between the data transfer source and the data transfer destination, which is necessary during data transfer, while reducing power consumption Applicable.

  1, 2, 3, ... wireless terminals, 11, 21, 31 ... intermittent reception function unit, 4 ... wireless base station, 41 ... intermittent reception timing management function unit

Claims (6)

A wireless communication method performed by a wireless communication system that intermittently receives a synchronization signal for synchronizing a first wireless device and a second wireless device at predetermined time intervals,
A synchronization signal transmitting step in which the first wireless device transmits a synchronization signal at a period of time longer than the time interval of the intermittent reception;
The second wireless device has a synchronization step of maintaining synchronization with the first wireless device by receiving the synchronization signal;
In the synchronization signal transmitting step, when transmitting the synchronization signal, the synchronization signal is transmitted by being advanced or delayed by an offset time notified in advance to the second wireless device.   In the synchronization step, when the reception of the synchronization signal fails, the reception time for receiving the synchronization signal is the time width at which the synchronization signal may be transmitted at the timing of receiving the next synchronization signal. The wireless communication method according to claim 1, wherein the wireless communication method is lengthened. In the synchronization signal transmission step, the information on the offset time is superimposed and transmitted on the synchronization signal,
When the second wireless device receives the synchronization signal, it further includes a reply transmission step of transmitting a reply notifying that the synchronization signal has been received to the first wireless device;
3. The synchronization signal transmission step according to claim 1, wherein when the reply is received, a next synchronization signal is transmitted according to the offset time, and when the reply is not received, the next synchronization signal is transmitted at a predetermined timing. The wireless communication method described. In the reply transmission step, the reply is transmitted at a time interval longer than the transmission interval of the synchronization signal,
In the synchronization signal transmission step, a synchronization signal from the next time is transmitted based on the offset time at a timing when the reply is not transmitted, and when the reply is not received at a timing when the reply is transmitted, the next is performed at a predetermined timing. The wireless communication method according to claim 3, wherein the synchronization signal is transmitted. In the synchronization signal transmission step, the transmission of the synchronization signal is stopped irregularly at a certain rate,
In the synchronization step, if the synchronization signal is not received at the timing of transmitting the reply, the reply is transmitted.
5. The wireless communication method according to claim 4, wherein, in the synchronization signal transmitting step, when the reply is received, the synchronization signal is transmitted at a timing at which the next synchronization signal is to be transmitted. A wireless communication system that intermittently receives a synchronization signal for synchronizing a first wireless device and a second wireless device at predetermined time intervals,
The first wireless device is:
Synchronization signal transmitting means for transmitting a synchronization signal with a period of time longer than the time interval of intermittent reception;
The second wireless device is
Synchronization means for maintaining synchronization with the first wireless device by receiving the synchronization signal;
When transmitting the synchronization signal, the first wireless device is a wireless communication system that transmits the synchronization signal after being advanced or delayed by an offset time notified in advance to the second wireless device.

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