JP2011101276A - Radio communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio communication device that solves a problem, wherein a slave radio terminal has a large power consumption because the terminal continues to be in a receiving state, in a method that the slave terminal continues to be in the receiving state and joins a communication system of a master radio terminal, to which a detected beacon signal is transmitted. <P>SOLUTION: The radio communication device shifts to an intermittent reception operation during a period shorter than a time length of a start signal when receiving a replacement signal, and intermittently detects the start signal. The device discontinues the intermittent reception operation and continues to receive the start signal, and captures the beacon signal. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention is a wireless communication apparatus that can be used in a wireless system that includes a parent wireless terminal that transmits a beacon signal and one or more child wireless terminals that receive the beacon signal and synchronize with the parent wireless terminal. The present invention relates to a wireless communication device when a parent wireless terminal is exchanged.

  A communication system including a parent wireless terminal that transmits a beacon is used in a wireless network system provided by a wireless LAN or a fixed wireless access (FWA) provider. In general, in most communication systems, a child wireless terminal is installed after a parent wireless terminal corresponding to infrastructure is installed. For example, there are Patent Document 1 and Patent Document 2 as a method in which a child wireless terminal enters the communication system and assigns or exchanges an ID with the parent wireless terminal.

  According to Patent Document 1, a child wireless terminal receives the beacon signal transmitted from a plurality of parent wireless terminals, transmits an entry request to the wireless communication system to a parent wireless terminal in an optimal communication quality state, and Negotiation is performed with the machine, and an IP address is given from the parent machine to enter the communication system.

  Further, according to Patent Document 2, when the child wireless terminal determines that the beacon signal from the parent wireless terminal has not been received within a certain time, the parent wireless terminal is cut off from the power supplied to the wireless communication unit. When it becomes impossible to confirm the presence of the wireless communication, the wireless communication is stopped to save power.

  In addition, in a public mobile communication system or the like, when it becomes impossible to receive a beacon signal from a parent wireless terminal, the child wireless terminal maintains a continuous reception state until a beacon signal from any parent wireless terminal is detected, There is a case where a method of entering the communication system of the parent wireless terminal that has transmitted the detected beacon signal may be taken.

JP 2007-181231 A JP 2009-135708 A

  However, Patent Document 1 does not describe the case where the parent wireless terminal is exchanged, and the child wireless terminal maintains a continuous reception state until the beacon signal is detected, and the parent wireless terminal that has transmitted the detected beacon signal. In the method of entering the communication system, there is a problem that the power consumption of the child wireless terminal increases because the child wireless terminal is in a continuous reception state.

  Further, Patent Document 2 describes that wireless communication is stopped when the beacon signal of the parent wireless terminal can no longer be received, but there is no description about the case where the parent wireless terminal is replaced, and the replaced parent wireless terminal There was a problem with the method of entering the communication system.

The present invention solves the above-described conventional problems, and even when a parent wireless terminal is exchanged by a simple configuration and method, it can immediately enter the communication system of the parent wireless terminal, and a child wireless It aims at providing the radio | wireless communication apparatus which can reduce the power consumption until a terminal enters the said communication system.

  A beacon generating means for generating a beacon signal notifying the presence of the own station, a slot control means for controlling the timing for periodically transmitting a beacon by activating the beacon generating means, and one digit compared to the length of the beacon signal The wireless communication apparatus is constituted by an activation signal transmitting unit that transmits an activation signal that is long in time and that notifies the presence of the own station, and an exchange signal transmitting unit that transmits an exchange signal when the exchange is performed.

  In order to save power, the child wireless terminal in the intermittent reception state can be notified of the presence of the replaced parent wireless terminal, so that the child wireless terminal can enter the communication system of the parent wireless terminal. .

  By using the wireless communication device of the present invention, even if the parent wireless terminal is exchanged, the child wireless terminal immediately after the parent wireless terminal is installed without increasing the power consumption of the child wireless terminal. The communication system of the parent wireless terminal can be entered.

The block diagram of the radio | wireless system in 1st embodiment of this invention Sequence diagram of beacon signal transmission / reception in the first embodiment of the present invention The figure which shows the slot structure in 1st embodiment of this invention. The figure which shows the terminal call transmission or polling signal format in 1st embodiment of this invention. 1 is a configuration diagram of a wireless communication apparatus related to activation signal transmission according to a first embodiment of the present invention. 1 is a configuration diagram of a wireless communication apparatus related to activation signal reception in the first embodiment of the present invention. Sequence diagram of activation signal transmission / reception in the first embodiment of the present invention The figure which shows the starting signal format in 1st embodiment of this invention Sequence diagram of activation signal transmission in the first embodiment of the present invention Processing flow diagram of wireless communication apparatus in first embodiment of the present invention Processing flow diagram of wireless communication apparatus in first embodiment of the present invention

  The first invention comprises a beacon generating means for generating a beacon signal notifying the presence of the own station, a slot control means for controlling the timing for activating the beacon generating means and periodically transmitting a beacon, A radio comprised of an activation signal transmitting means for transmitting an activation signal that is a signal that is one digit or more longer than the length and that notifies the presence of the own station, and an exchange signal transmitting means for transmitting an exchange signal when the exchange is performed. It is a communication device.

  And even if the parent wireless terminal is removed and is in an intermittent reception state for power saving, and the parent wireless terminal is replaced and installed later, the child wireless terminal can be notified of the presence of the parent wireless terminal. The child radio terminal can enter the communication system of the parent radio terminal.

  According to a second aspect of the present invention, the activation signal transmitting means is activated when the power is turned on and transmits the activation signal.

  As soon as the parent wireless terminal is installed and starts operating, an activation signal can be transmitted, and the child wireless terminal can enter the system without delay.

  According to a third aspect of the present invention, the activation signal transmitting means is periodically activated and transmits the activation signal.

  Even if the child radio terminal misses the reception of the activation signal, the activation signal transmitted at the next timing can be received, and the child radio terminal can enter the system.

  According to a fourth aspect of the present invention, the activation signal transmitting means is activated based on an instruction from the outside and transmits the activation signal.

  And an activation signal can be transmitted by the instruction | indication from the center server connected with a parent | wireless radio | wireless terminal, and a child radio | wireless terminal can be entered into a system.

  A fifth aspect of the present invention is a wireless communication apparatus configured to perform a reception operation of a beacon signal by continuing a reception operation for a time longer than the intermittent period when an activation signal cannot be received during an integral multiple of the intermittent reception operation period. is there.

  If the activation signal cannot be received for a long time, the beacon signal can be supplemented temporarily in a continuous reception state, and the child radio terminal can enter the system even if the reception of the activation signal is missed.

  According to a sixth aspect of the present invention, the activation signal is a wireless communication apparatus configured such that a block including a preamble signal and an identification signal indicating the activation signal is a unit block, and the unit block is repeated a plurality of times.

  In supplementing the activation signal, it is possible to identify whether the signal is a signal other than noise or the activation signal or the activation signal in a short time, which can contribute to power saving of the child radio terminal.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
First, an operation in which a parent wireless terminal has already been installed and a child wireless terminal has entered or has entered the communication system of the parent wireless terminal will be described.

  FIG. 1 shows an example of a system using the wireless communication apparatus of the present invention. In the figure, 101 is a parent wireless terminal, 102 to 104 are child wireless terminals belonging to the parent wireless terminal 101, 201 is a relay wireless terminal belonging to the parent wireless terminal 101, 202 to 204 are child wireless terminals belonging to the relay wireless terminal 201, Reference numeral 301 denotes a relay radio terminal belonging to the relay radio terminal 201, 302 to 304 are child radio terminals belonging to the relay radio terminal 301, and 401 is a relay radio terminal belonging to the relay radio terminal 301.

  The parent wireless terminal 101 and the relay wireless terminals 201, 301, 401 periodically transmit a beacon signal, and each child wireless terminal belonging to each of the parent wireless terminal 101, the relay wireless terminals 201, 301, 401 receives the beacon signal. By doing so, each wireless terminal can synchronize with the clock of the parent wireless terminal 101 and the relay wireless terminals 201, 301, 401. Each child wireless terminal performs intermittent reception at the timing transmitted by the parent wireless terminal 101 and relay wireless terminals 201, 301, and 401 to which the child wireless terminal belongs, and the terminal at the timing received by the parent wireless terminal 101 and relay wireless terminals 201, 301, and 401 to which it belongs. Call communication can be performed.

  The operation of the wireless communication apparatus of the present invention will be described below with reference to FIGS. FIG. 2A is a diagram illustrating a state of a beacon signal that the parent wireless terminal 101 periodically transmits. As shown in FIG. 2A, the parent wireless terminal 101 alternately transmits the beacon signal 1 and the beacon signal 2 every time T1 seconds.

  The beacon signal 1 is immediately transmitted at a timing of 2 × T1 seconds. On the other hand, the beacon signal 2 is transmitted after waiting for a random time T3 seconds (where T3 seconds <T2 seconds <T1 seconds) with the timing after T1 seconds from the transmission timing of the beacon signal 1 as a base point. For example, T1 is 4 seconds, T2 is 100 milliseconds, T3 is 10 milliseconds × n, and n is an integer between 0 and 9 and is randomly selected. The transmission time of the beacon signals 1 and 2 is set to 10 ms or less.

  The child radio terminals 102 to 104 and the relay radio terminal 201 receive the beacon signal shown in FIG. The first child radio terminals 102 to 104 and the relay radio terminal 201 do not know at which timing the beacon signal is transmitted, and thus continue the reception operation for a time of T1 seconds or more. Beacon signal 1 or beacon signal 2 can be received without fail if the receiving operation is continued for a time of T1 seconds or longer. In addition to receiving a beacon signal from the parent wireless terminal 101 if the reception operation is continued for a time of T1 seconds or longer, a case where a beacon signal from the relay wireless terminals 201, 301, 401 is received may be considered. When a plurality of beacon signals are received, the clock is set to the beacon signal of the wireless terminal having the beacon signal level equal to or higher than the predetermined level and the smallest number of relay stages. For example, the number of relay stages decreases in the order of relay wireless terminal 401 ⇒ relay wireless terminal 301 ⇒ relay wireless terminal 201 ⇒ parent wireless terminal 101. The parent wireless terminal 101 has 0 relay stages and the smallest number of relay stages.

  When the beacon signal 2 is received, there is a random delay of T3 seconds. If the slave wireless terminals 102 to 104 that receive the beacon signal 2 and synchronize with the transmission timing of the beacon signal 1 of the parent wireless terminal 101 do not know the random time T3, the beacon signal 1 or beacon signal 2 for each T1 I do not know the base point of the transmission timing. Therefore, the parent wireless terminal 101 that transmits the beacon signal 2 transmits the beacon signal 2 by inserting information indicating how many random delay times T3 are in the signal format of the beacon signal 2. Then, the child wireless terminals 102 to 104 that receive the beacon signal 2 correct T3 seconds using the information of the random delay time T3 included in the signal format of the beacon signal 2, and calculate the base point of the timing of T1 seconds. Can do. Through the above operation, the child wireless terminals 102 to 104 can synchronize with the beacon transmission timing T1 seconds of the parent wireless terminal 101. And intermittent reception operation | movement is performed at the timing which the beacon signal 1 is transmitted, and the beacon signal 1 is received.

  FIG. 2B shows the operation of the beacon signal transmitted by the parent wireless terminal 101 and the timing at which the child wireless terminals 102 to 104 receive the beacon signal. As shown in FIGS. 2B and 2A, the parent wireless terminal 101 transmits beacon signal 1 and beacon signal 2 alternately. The slave radio terminals 102 to 104 and the relay radio terminal 201 receive intermittently at a cycle that is an integral multiple of the timing of the beacon signal 1 as shown in FIGS. When the beacon signal 1 is detected, the detection operation of the beacon signal 1 is performed at the next intermittent reception timing. If the beacon signal 1 cannot be detected, it rises at the timing of the next beacon signal 2 and receives the beacon signal 2 to regain synchronization.

Here, consider a case where there are a plurality of systems shown in FIG. Each system is not synchronized, and the beacon signal transmitted from each system is in an asynchronous state. If the beacon signal transmission interval T1 is 4 seconds and the beacon transmission time is 10 milliseconds, the duty ratio of beacon transmission is 1/400, and even if the beacon signals transmitted from each system are asynchronous, the probability of collision is low. However, since there is a slight clock error in the beacon transmission interval T1 of each system, the timing of the beacon signal transmitted from each system gradually shifts with the passage of time, and the timing of beacon signal transmission sometimes coincides. Conceivable.

  Once the timing matches, the beacon signal 1 is in a collision state for a long time until the timing shifts due to a clock error. However, since the beacon signal 2 is transmitted with a random delay time T3, the probability that the beacon signal 2 collides will be low even if the beacon transmission timings of the systems coincide. And the probability that the beacon signal 2 collides continuously becomes lower. That is, even if the beacon transmission timings of the respective systems coincide with each other and the state in which the beacon signal 1 collides and cannot be detected continues, the beacon signal 2 does not collide and therefore the child wireless terminals 102 to 102 belonging to each parent wireless terminal 101. 104 and the relay wireless terminal 201 can detect the beacon signal 2 of the parent wireless terminal 101 and synchronize with the clock of the parent wireless terminal 101.

  FIG. 2C is a diagram for explaining a signal format of a beacon signal and a beacon receiving method. (C) in FIG. 2 is a signal format of the beacon signal, and (2) in FIG. 2C is a beacon receiving method. The beacon signal format of (1) in FIG. 2C is the signal format of beacon signals 1 and 2 transmitted every T1 seconds shown in FIG. The reception method shown in (2) of FIG. 2C is a reception method when the beacon signal 1 or the beacon signal 2 is received at the timing (1) of FIG.

  The signal format of the beacon signal includes a redundant bit consisting of repetition of “1010...” And a beacon signal 1 or a beacon signal 2. The signal format of beacon signal 1 or beacon signal 2 is not shown in the figure, but a bit synchronization signal consisting of repetition of “1010...”, A frame synchronization signal for finding the head of data, a clock And a control signal for synchronization. The redundant bit length is T4 seconds.

  Even if the slave wireless terminals 102 to 104 and the relay wireless terminal 201 detect the beacon signal 1 of the parent wireless terminal 101 and synchronize the clock, they are built in the parent wireless terminal 101 until the next beacon signal 1 is received. There is a slight clock error between the clock and the clock built in each of the slave radio terminals 102 to 104 and the relay radio terminal 201.

  Generally, a crystal oscillation signal generated using a crystal resonator is used as a reference oscillation source of a watch built in a wireless terminal. An oscillation frequency error oscillated by the crystal resonator is a maximum of ± 100 ppm in consideration of a temperature change or the like. Further, assuming that the oscillation frequency error of the wireless terminal that transmits the beacon signal is ± 100 ppm at the maximum and the oscillation frequency error of the wireless terminal that receives the beacon signal is also the maximum ± 100 ppm, the beacon signal transmission side and the beacon signal reception side The relative oscillation frequency error is ± 200 ppm at the maximum.

  For example, suppose T1 = 4 seconds, beacon signal 1 is transmitted every 2 × T1 = 8 seconds, and the child wireless terminals 102 to 104 and the relay wireless terminal 201 receive the beacon signal 1 every 8 × T1 = 32 seconds. The maximum clock error between the parent wireless terminal 101 and the child wireless terminals 102 to 104 and the relay wireless terminal 201 in 32 seconds is 32 seconds × ± 200 ppm = ± 6.4 ms. Therefore, even if a maximum clock error of ± 6.4 msec occurs, the child radio terminals 102 to 104 and the relay radio terminal 201 are 6.4 msec earlier than the transmission timing of the beacon signal 1 so that the beacon signal 1 can be reliably received. The power source of the transmission / reception means 12 is turned on and the timeout time T6 is set. Then, the intermittent reception operation is repeated for T6 seconds at intervals of T5 seconds.

When the maximum clock error is X, X is the child radio terminals 102 to 104 and the relay radio terminal 201.
Varies depending on the reception cycle of receiving the beacon signal 1. The reception period is 2 × T1 × N (N is an arbitrary integer), and the maximum clock error ± X is calculated as X = 2 × T1 × N × 200 ppm. Therefore, in consideration of the reception cycle for receiving the beacon signal 1, the child radio terminals 102 to 104 and the relay radio terminal 201 transmit / receive the transmission / reception unit 12 earlier than the transmission timing of the beacon signal 1 by the maximum clock error X calculated by the above formula. Is set to be turned on, and the timeout time is set to T6. Then, the intermittent reception operation is repeated for T6 seconds at intervals of T5 seconds. T5 <T4 is set.

  T6 is set to 2 × X <T6 in consideration of the maximum clock error ± X. The slave radio terminals 102 to 104 and the relay radio terminal 201 can always detect the redundant bit having the length T4 and receive the beacon signal 1 during T6 seconds. When the child wireless terminals 102 to 104 and the relay wireless terminal 201 detect the redundant bit of T4, the child wireless terminals 102 to 104 cancel the timeout time T6 and continue reception. The beacon signal 1 is about 10 milliseconds, and the maximum clock error ± X is generally set smaller than the length of the beacon signal 1 in consideration of current consumption. Therefore, the timeout time of T6 is at most twice as long as the length of the beacon signal 1 is 10 milliseconds.

  Next, consider a case where the beacon signal 1 cannot be received and the beacon signal 2 is received. The redundant bit of beacon signal 2 is also T4 long. Then, the child radio terminals 102 to 104 and the relay radio terminal 201 transmit the beacon signal 1 in order to absorb the maximum clock error ± X, as in the case of receiving the beacon signal 1. The power of the transmission / reception means 12 is turned on and the timeout time T7 is set earlier than the timing by the maximum clock error X. The intermittent reception operation is repeated for T7 seconds at intervals of T5 seconds. T5 <T4 is set. T7 is set to (2 × X + T2) <T7 in consideration of the maximum clock error ± X + the maximum value T2 of the random delay time. The slave radio terminals 102 to 104 and the relay radio terminal 201 can always detect the redundant bit having the length T4 and receive the beacon signal 2 during T7 seconds. In this example, T2 is a maximum of 90 milliseconds and X is about 10 milliseconds, so T7 is set to a value slightly larger than 110 milliseconds.

  Note that the beacon transmission timing and the beacon reception timing shown in FIG. 2C are relative clocks between the parent wireless terminal 101 on the beacon signal transmitting side and the child wireless terminals 102 to 104 and the relay wireless terminal 201 on the beacon receiving side. When the error is zero, and the relative error is not zero, the beacon transmission timing is shifted back and forth between the maximum clock error ± X with respect to the beacon reception timing.

  As described above, T6 is a timeout time when receiving the beacon signal 1, and T7 is a timeout time when receiving the beacon signal 2.

  As described above, the slave radio terminals 102 to 104 and the relay radio terminal 201 perform beacon reception every T5 seconds for T6 seconds slightly longer than the clock error ± X, as long as there is no collision between the beacon signals 1. 1 can be detected with certainty, so that the time taken up for receiving the beacon signal 1 can be shortened and the power consumption can be suppressed.

  Only when the beacon signal 1 cannot be detected due to a collision for a certain period, intermittent reception is performed every T5 seconds for T7 seconds slightly longer than the maximum clock error ± X + the maximum value T2 of the random delay time. The number of times that the beacon signal 2 is received is much smaller than the number of times that the beacon signal 1 is received. Furthermore, since the beacon signal 2 is received intermittently every T5 seconds, the influence of the reception of the beacon signal 2 on the overall power consumption is insignificant.

As described above, even if a plurality of asynchronous systems exist in the vicinity of the parent wireless terminal 101 and the beacon transmission timings coincide with each other, they belong to the parent wireless terminal 101 due to the presence of the beacon signal 2. The slave radio terminals 102 to 104 and the relay radio terminal 201 can synchronize with the parent radio terminal 101 in time. And since it is comprised so that a clock synchronization may be normally acquired by the beacon signal 1 transmitted with the fixed period T2, power consumption can be suppressed. That is, it is possible to achieve both resistance to interference and suppression of power consumption.

  Next, the relay wireless terminal 201 synchronizes the clock with the parent wireless terminal 101 and transmits a beacon signal in the same manner as the parent wireless terminal 101. FIG. 3 is a diagram illustrating the relationship of beacon transmission between the parent wireless terminal 101 and the relay wireless terminals 201, 301, and 401.

  Each wireless terminal has two types of slots, an upper slot and a lower slot. Since the parent wireless terminal 101 does not have a higher rank, only the lower slot is provided. The upper slot is a slot for communication with an upper radio terminal, and the lower slot is a slot for communication with a lower radio terminal. Wireless terminals that communicate in the lower slot of the parent wireless terminal 101 are the child wireless terminals 102 to 104 and the relay wireless terminal 201. The upper slots of the slave radio terminals 102 to 104 and the relay radio terminal 201 are synchronized with the position of the lower slot of the parent radio terminal 101. Similarly, the relationship shown in FIG.

  The configuration of the upper (or lower) slot is shown in FIG. The slot length is, for example, 2 seconds. The slots are further composed of three slots: a beacon slot, a slave unit call slot, and a polling slot. For example, the beacon slot is 100 milliseconds, the slave unit call slot is 900 milliseconds, and the polling slot is 1000 milliseconds. The beacon signal 1 and the beacon signal 2 are transmitted from the beacon slot in the lower slot and received in the beacon slot in the upper slot. The beacon signal 1 is transmitted at the head of the beacon slot, and the beacon signal 2 is transmitted at random timing in the beacon slot 100 msec.

  The timing at which the beacon signal 1 and the beacon signal 2 are transmitted is shown in FIG. For example, when the parent wireless terminal 101 transmits the beacon signal 1 and the relay wireless terminal 201 receives the transmitted beacon signal 1, the clock synchronization is aligned with the parent wireless terminal 101 to correct the slot timing. Then, the relay wireless terminal 201 transmits the beacon signal 1 in the next lower slot. Beacon signal 1 and beacon signal 2 are transmitted alternately using lower slots. Thereafter, the lower relay radio terminal receives the beacon signal from the upper relay radio terminal, performs clock synchronization, corrects the slot timing, and transmits the beacon signal to the lower level by the same operation.

  When a call originates in the child radio terminal and data is to be sent to the upper radio terminal, transmission of the child machine call signal is started at the head of the child machine call slot. The upper parent wireless terminal 101 or the relay wireless terminals 201, 301, 401 can receive the child device call signal from the lower wireless terminal so that the child device call at the head of the child device call slot in the lower slot can be received. Intermittent reception is performed at the timing when the signal is transmitted, and if it is determined that there is no slave unit call signal, reception is immediately stopped. When the relay radio terminals 201, 301, 401 receive the slave unit call signal from the lower radio terminal, the slave unit in the next higher slot for the upper parent radio terminal 101 or the upper relay radio terminal The received slave unit call signal is transmitted to the host at the head of the call slot. Thus, for example, the slave unit call signal generated in the slave radio terminal 401 is sent to the relay radio terminal 301, and the relay radio terminal 301 further transmits the slave unit call signal via the relay radio terminal 201. Can be sent to.

A case where it is desired to send a polling signal from the parent wireless terminal 101 to the child wireless terminal 301 will be described. The parent wireless terminal 101 starts transmitting a polling signal at the head of the polling slot in the lower slot. The slave wireless terminals 102 to 104 and the relay wireless terminal 201 perform intermittent reception at the timing when the first polling signal of the polling slot in the upper slot is transmitted so that the polling signal from the parent wireless terminal 101 can be received, and polling is performed. If it is determined that there is no signal, reception is immediately stopped. The relay wireless terminal 201 that has received the polling signal starts transmission of the polling signal at the head of the polling slot in the lower slot. Thereafter, a polling signal is sent to the child radio terminal 301 via the relay radio terminal 301 by the same operation.

  FIG. 4A is a format diagram of the slave unit call signal or polling signal. FIG. 4B is a diagram showing the components of the repetitive header in the signal format of FIG.

  The slave unit call signal or polling signal is composed of a repeated header followed by a bit synchronization signal, a frame synchronization signal, and data. The data includes a control signal, an identification code (hereinafter referred to as ID) indicating a transmission source and a transmission destination, and the like.

  As shown in FIG. 4B, the repetitive header has a bit sync signal, a frame sync signal, and a simple ID as constituent elements, and the constituent elements are repeatedly transmitted a plurality of times. A simple ID is a shortened version of an ID. For example, the ID is 48 bits, and the simple ID is 8 bits obtained by taking the lower byte of the ID.

  For the child radio terminals 102 to 104, 202 to 204, and 302 to 304, reception of the beacon signal 1 is reception every time a plurality of times the beacon signal 1 is transmitted. Since the reception of the beacon signal 1 is for clock synchronization, it is not necessary to receive the beacon signal so frequently. For example, when the beacon signal 1 is received every time the beacon signal 1 is transmitted 100 times with a beacon signal 1 transmission period of 8 seconds, reception is performed every 800 seconds. On the other hand, when receiving a polling signal, it is desirable to shorten the intermittent reception cycle as much as possible in consideration of real-time characteristics. That is, the intermittent reception operation is performed at a cycle of 4 seconds, which is the timing for each upper slot. The child radio terminals 102 to 104, 202 to 204, and 302 to 304 may be driven by a battery, and it is important to suppress power consumption. Therefore, it is desired to perform a carrier detection operation in intermittent reception with a period of 4 seconds and immediately stop reception when there is no carrier. However, if there is a clock error between the parent wireless terminal 101 and a higher-order relay wireless terminal, the timing at which the carrier detection operation is performed may deviate from the polling signal transmission timing. Fails. It is the role of repeated headers to avoid that. The length of the repetitive header is set to be longer than the maximum clock error X during a period of 800 seconds for clock synchronization by receiving a beacon. The reception timing is set so that the carrier is repeatedly detected in the middle of the header when there is no clock error. By setting in this way, even if the maximum clock error ± X occurs, carrier detection is repeatedly performed somewhere in the header, and it can be determined whether or not the signal is to be received roughly by the simple ID.

  The relay wireless terminals 201, 301, and 401 and the parent wireless terminal 101 are generally AC power sources, and need not be concerned with power consumption, but are repeated in the same manner as the child wireless terminals 102 to 104, 202 to 204, and 302 to 304. At this point, the carrier is detected.

  Next, the case where the child wireless terminal is installed first, which is the point of the present invention, and the parent or relay wireless terminal is installed later will be described with reference to FIG. As a specific example, consider a case where the child wireless terminal 302 is installed in FIG. 1 but the relay wireless terminal 301 is not installed. 7A is a sequence diagram for explaining the operation of the child radio terminal 302, and FIG. 7B is a sequence diagram for explaining the operation of the relay radio terminal 301.

The child radio terminal 302 is installed in a place where the beacon signal transmitted from the parent radio terminal 101 and the relay radio terminal 201 cannot be received. Since the child radio terminal 302 cannot receive the beacon signal, the intermittent reception operation is performed at the intermittent reception cycle T10 by the clock built in the child radio terminal 302 independently of the clock of the parent radio terminal 101 or the relay radio terminal 201. In FIG. 7A, (1) shows intermittent reception performed at the intermittent reception cycle T10. The intermittent reception period T10 is set to a time that is at least one digit longer than the signal length of the beacon signal in order to reduce power consumption. For example, while the beacon signal length is about 10 milliseconds, the intermittent reception cycle T10 is set to 1 second. T10 may be the same as the beacon transmission interval T1, or may be an integer multiple of T1.

  A case where the relay wireless terminal 301 is installed in the above state will be described. When the relay wireless terminal 301 is installed and the relay wireless terminal 301 is turned on and starts operating, the relay wireless terminal 301 first transmits an activation signal. In FIG. 7B, (5) shows the timing when the relay wireless terminal 301 is turned on, and (6) shows the transmission of the activation signal. The signal length of the activation signal (6) is T11, and T11> T10 is set. Therefore, the slave radio terminal 302 can always receive the activation signal (6) at the timing of the intermittent reception operation. (2) indicates that the child radio terminal 302 has received the activation signal (6). Even if the slave wireless terminal 302 has received the activation signal (6), the slave wireless terminal 302 continues reception and supplements the beacon signal (7) transmitted from the relay wireless terminal 301 following the activation signal (6). When the beacon signal (7) is supplemented, the child radio terminal 302 transmits an entry request signal (3) to the relay radio terminal 301. When the relay wireless terminal 301 receives the entry request signal (3) from the child wireless terminal 302 (8), it transmits a response signal (9) such as entry permission and ID assignment to the child wireless terminal 302. The child wireless terminal 302 can enter the system of FIG. 1 in a form connected to the relay wireless terminal 301 by receiving (4) the response signal (9).

  The entry request signal (3) is transmitted in the slave unit call slot in FIG. The response signal (9) may be transmitted in the slave unit call slot or in the polling slot.

  FIG. 8A shows the signal format of the activation signal (6). The start signal (6) is composed of repeating unit blocks. As shown in FIG. 8B, the unit block is distinguished from a preamble signal called a bit synchronization signal composed of repetition of “0” and “1” such as “101010...” And a frame synchronization signal indicating the head of data. It consists of signals. The identification signal is a signal indicating that it is an activation signal.

  Note that the identification signal may be a signal including information that can be recognized as a start signal by the received child radio terminal, such as device type information indicating a relay radio terminal or a parent radio terminal.

  Further, if the code pattern of the frame synchronization signal is devised and the code pattern is detected on the receiving side as a code pattern unique to the activation signal, it can be recognized as the activation signal. If the code pattern of the frame synchronization signal can be recognized as an activation signal, the identification signal following the frame synchronization signal can be omitted.

  Although the example in which the activation signal is transmitted at the timing when the power of the relay wireless terminal 301 is turned on has been described, the activation signal can also be transmitted at another timing. FIG. 9 is a sequence diagram in the case where the relay wireless terminal 301 periodically transmits an activation signal after the operation starts. In the figure, (7) is a beacon signal transmitted every T1, and (6) is an activation signal. The activation signal (6) is transmitted every T12. T12 is set to an integer multiple of T1. For example, T12 is a long time of one day.

The timing at which the activation signal (6) is transmitted is the parent wireless terminal 101 or the parent wireless terminal 1
When the relay wireless terminal 301 receives an instruction from a center server (not shown in FIG. 1) to which 01 is connected, it may be transmitted.

  Further, the child radio terminal 302 performs the intermittent reception operation (1) at the intermittent reception cycle T10 until the activation signal (6) can be received as shown in FIG. In the example of FIG. 7A, the child radio terminal 302 receives the activation signal (6), but when the activation signal (6) cannot be received even after waiting for an integral multiple of the intermittent reception period T10, the beacon signal transmission interval. A reception operation is performed for a time longer than T1, and acquisition of a beacon signal is attempted. That is, if the activation signal (6) cannot be received, an operation of performing a reception operation for a time longer than the beacon signal transmission interval T1 in a time period T11 (not shown) that is an integral multiple of the intermittent reception period T10 and attempting to capture a beacon signal. I do.

  5 and 6 are examples of block diagrams for realizing the operation of the wireless communication apparatus of the present invention described above. The master wireless terminal 101 or the relay wireless terminals 201, 301, and 401 that transmit the activation signal have the block configuration shown in FIG. The child wireless terminals 102 to 104, 202 to 204, 302 to 304, and the relay wireless terminals 201, 301, and 401 that receive the activation signal have the block configuration shown in FIG.

  Each means and operation of the wireless communication apparatus shown in FIG. 5 will be described. 1 is an antenna, 2 is a transmission / reception means, 3 is a beacon generation means, 4 is a slot control means, 5 is an activation signal transmission means, and 6 is a control means. The control means 7 performs time management of the entire wireless communication apparatus and control of each means. The slot control means performs transmission slot control such as the transmission timing of the beacon signal 1 and the beacon signal 2 shown in FIG. The beacon generation unit 3 generates a beacon signal 1 and a beacon signal 2 under the control of the slot control unit 4 and transmits the beacon signal 1 through the transmission / reception unit 2. The activation signal transmission means 5 transmits the activation signal shown in FIG. 8 via the transmission / reception means 2 in response to an instruction from the control means 6. The activation signal transmitted from the activation signal transmission means 5 in response to an instruction from the control means 6 is (6) shown in FIGS.

  Next, each unit and operation of the wireless communication apparatus shown in FIG. 6 will be described. 11 is an antenna, 12 is a transmission / reception means, 13 is a beacon reception means, 14 is a beacon reception means, 15 is an intermittent reception control means, 16 is an activation signal reception means, and 17 is a control means. The control means 17 performs time management of the entire wireless communication apparatus and control of each means. Until the start signal can be received, the intermittent reception operation (1) shown in FIG. 7 or FIG. The activation signal receiving means detects whether there is an activation signal (6) when the intermittent reception operation (1) is performed by the operation of the intermittent reception means 15, and performs an operation of receiving the activation signal (6). When the activation signal (6) is received, the operation of the intermittent receiving means 15 is stopped via the control means 17 and the beacon reception control means 14 and the beacon receiving means 13 are operated to perform a beacon signal supplementing operation.

  FIG. 10 is an example of a flowchart showing the operation of the wireless communication apparatus of the present invention shown in FIG. The operation will be described again with reference to FIG.

  First, the power is turned on (step 110). Next, the activation signal transmission means 5 transmits the activation signal (6) shown in FIG. 7 (step 111), and transmits the beacon signal (7) (step 112).

  If a beacon signal (7) is transmitted in step 112, it will change to a reception state and reception operation (8) of whether there is an entry request signal (3) will be performed (step 113).

  When the entry request signal (3) is received in step 113, the process proceeds to step 114. If the entry request signal (3) could not be received, the process proceeds to step 115.

  In step 114, a response signal (9) is transmitted. In Step 115, the mode shifts to the beacon regular transmission mode. The beacon periodic transmission mode is a mode in which the beacon signal shown in FIG. 2 is periodically transmitted at a period T1.

  FIG. 11 is an example of a flowchart showing the operation of the wireless communication apparatus of the present invention shown in FIG. The operation will be described again with reference to FIG.

  First, the power is turned on (step 120). Next, in order to receive the beacon signal periodically transmitted as shown in FIG. 2, the reception operation is continued for a time of T1 seconds or longer to supplement the beacon signal (step 121). In step 121, it is detected whether there is a beacon signal during the period during which the beacon capturing operation is performed (step 122).

  If a beacon signal is detected in step 122, the process proceeds to step 123. If no beacon signal is detected in step 122, the process proceeds to step 126.

  In step 123, an entry request signal (3) is transmitted. And it shifts to the reception state, performs the reception operation (4) for the response signal (9) (step 124), and shifts to the beacon regular reception mode (step 125). The beacon periodic reception mode is a mode for periodically receiving a beacon signal in synchronization with the beacon signal shown in FIG.

  In step 126, an intermittent reception operation is performed at a cycle T10 as shown in FIG. Thereafter, the determination at step 122 is performed in the intermittent reception operation.

  The wireless communication device and the wireless communication method of the present invention can be used for a gas automatic meter reading system and the like. A gas meter is connected to each of the child wireless terminals 102 to 104, 202 to 204, and 302 to 304, and the gas meters connected to the child wireless terminals 102 to 104, 202 to 204, and 302 to 304 by polling communication from the parent wireless terminal 101 are connected. Gas meter reading data can be collected in the parent wireless terminal 101. The collected gas meter reading data can be sent to the center apparatus using a public line connected to the parent wireless terminal 101. The relay wireless terminals 201, 301, and 401 also have a function as a slave wireless terminal and may be connected to a gas meter.

  Gas meters are replaced periodically every 10 years. A procedure has been considered in which child wireless terminals are installed in accordance with the replacement of the gas meter, and infrastructure such as the parent wireless terminal is established when the child wireless terminal to the gas meter has advanced to some extent. In such an installation procedure, the wireless communication apparatus, wireless communication method, and program of the present invention are very useful.

  As described above, the wireless communication apparatus according to the present invention allows the parent wireless terminal to be replaced by the parent wireless terminal without increasing the power consumption of the child wireless terminal even when the parent wireless terminal is removed for the purpose of replacement. A radio communication system that can enter the communication system of the parent radio terminal as soon as it is installed can be constructed.

DESCRIPTION OF SYMBOLS 1 Antenna 2 Transmission / reception means 3 Beacon generation means 4 Slot control means 5 Activation signal transmission means 6 Slave unit call communication means 7 Control means 11 Antenna 12 Transmission / reception means 13 Beacon reception means 14 Beacon reception control means 15 Intermittent reception means 16 Activation signal reception Means 17 Control means 101 Parent wireless terminal 102-104, 202-204, 302-304 Child wireless terminal

Claims (6)

A beacon generating means for generating a beacon signal notifying the presence of the own station, a slot control means for controlling the timing for periodically transmitting a beacon by activating the beacon generating means, and one digit compared to the length of the beacon signal Transmitted from a wireless communication apparatus composed of an activation signal transmitting means for transmitting an activation signal that is long in time and notifying the presence of the own station and an exchange signal transmitting means for transmitting an exchange signal when performing the exchange. A wireless communication device that receives the beacon signal or the activation signal; when the replacement signal is received, the wireless communication device shifts to an intermittent reception operation having a period shorter than the time length of the activation signal and intermittently receives the activation signal. A detection operation, and when receiving the activation signal, the intermittent reception operation is interrupted and the reception is continued and the beacon signal is captured. Wireless communication device. 2. The wireless communication apparatus according to claim 1, wherein the activation signal transmitting unit is activated when the power is turned on and transmits the activation signal. 2. The wireless communication apparatus according to claim 1, wherein the activation signal transmitting means is periodically activated to transmit the activation signal. 2. The wireless communication apparatus according to claim 1, wherein the activation signal transmitting means is activated based on an instruction from the outside and transmits the activation signal. The wireless communication device according to claim 1 is configured such that when the activation signal cannot be received during an integral multiple of the intermittent reception operation cycle, the reception operation is continued for a time longer than the intermittent cycle and the beacon signal is captured. The wireless communication apparatus according to claim 1. 6. The wireless communication apparatus according to claim 1, wherein the activation signal is configured such that a block including a preamble signal and an identification signal indicating the activation signal is a unit block and the unit block is repeated a plurality of times.

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