JP5366061B2 - TERMINAL DEVICE, WIRELESS BASE STATION FOR WIRELESS COMMUNICATION WITH THE SAME AND WIRELESS COMMUNICATION SYSTEM USING THE SAME - Google Patents

Description

  The present invention relates to a terminal device, a radio base station that performs radio communication with the terminal device, and a radio communication system using them.

  Wireless LAN (Local Area Network) is widely used in homes and offices. Along with the widespread use of wireless LANs, many access points (APs) are installed, but these APs are normally used with the power turned on even if no communication data is generated.

  Since such an “already-on” AP has not been used for a majority of the time, power is wasted.

  In the sensor network, a method of waking up a data transmission destination only when communication using a wake-up receiver is necessary is being studied.

  In Non-Patent Document 1, when a wireless LAN channel having the same frequency is observed using 802.15.4 sensor motes that consume lower power than a wireless LAN card and radio waves from the transmission source are detected, A method for waking up a card has been proposed.

  Patent Documents 1 to 3 and Non-Patent Document 2 propose a method of waking up a data communication wireless interface using a wakeup receiver that consumes lower power.

  Further, in Patent Documents 1 and 2 and Non-Patent Document 2, the frequency of the wake-up signal is different from the frequency of the wireless LAN, so two antennas are required.

Special table 2007-526655 gazette International Publication No. 04/100503 Pamphlet US Patent Application Publication No. 2007/0253468

Nilesh Mishra, Kameswari Chebrolu, Bhaskaran Raman, Abhinav Pathak, Wakeon WLAN, WWW 2006. Shigeki Ishida, Makoto Suzuki, Takashi Morito, Hiroyuki Morikawa, Multistage Wakeup Mechanism for Low Receiving Standby Power Wireless Communication, IEICE technical report, information networks 107 (525), 355-360, 2008-02-28.

  However, in the prior art, it is assumed that ESSID is used as an identification ID for identifying an access point. The ESSID has a length of 32 bytes at the maximum, but the 32-byte wakeup ID is redundant in consideration of the number of access points existing around the terminal device attempting to wake up. Since the data transfer rate of the wakeup signal is low, there is a problem that a long wakeup ID leads to an increase in band occupation time.

  In addition, when an error occurs in a bit in the wakeup ID, there is a problem that an access point to be woken up cannot be woken up. In order to solve this problem, it is assumed that an error correction process is performed in the receiver, but the error correction process cannot be performed in the receiver in order to save power in the receiver of the wakeup ID.

  Furthermore, if a bit error occurs when a wakeup signal including an ID different from the ID of the access point itself is transmitted, there arises a problem that an access point that is not intended to be woken up is erroneously woken up.

  Therefore, the present invention has been made to solve such a problem, and an object of the present invention is to provide a terminal device that can reduce the band occupation time of a wake-up signal and can accurately start a radio base station. It is to be.

  Another object of the present invention is to provide a radio base station that can be activated even when the wakeup ID has a bit error of a certain value or less.

  Furthermore, another object of the present invention is to provide a radio communication system including a terminal device that can reduce the band occupation time of a wake-up signal and can accurately activate a radio base station.

  According to the embodiment of the present invention, the terminal device includes a bit number reduction unit, an encoding unit, and a transmission unit. The bit number reduction means reduces the number of bits of identification information of the radio base station to be shifted from the sleep state to the activated state. The encoding means includes a bit so that a hamming distance between a wake-up ID indicating a radio base station to be shifted from a sleep state to an activated state and an ID of another radio base station different from the radio base station is a certain value or more. The identification information of the radio base station reduced by the number reduction means is encoded. The transmission means transmits the identification information of the radio base station encoded by the encoding means to the radio base station as a wake-up ID. The sleep state is a state in which the radio base station cannot perform radio communication with the terminal device. The activated state is a state in which the wireless base station performs wireless communication with the terminal device.

  According to the embodiment of the present invention, the radio base station includes a main device, a reception unit, a bit determination unit, and an activation unit. The main device periodically transmits a management frame for managing the terminal device, and has a startup state in which wireless communication with the terminal device is performed and a sleep state in which wireless communication with the terminal device cannot be performed, and is constant. When wireless communication with the terminal device is not performed during this period, or when there is no terminal device belonging to the wireless base station, the state shifts from the activated state to the sleep state. The receiving unit receives the radio wave transmitted from the terminal device according to claim 1 or claim 2. The bit determining means performs bit determination based on the radio wave received by the receiving means to obtain a received bit string. The activation means provides an activation signal for shifting the main device from the sleep state to the activation state when the Hamming distance between the received bit string bit-determined by the bit determination means and the ID of the radio base station is equal to or less than a threshold value. Generate and output to the main device. Then, the main device shifts from the sleep state to the start state in response to the start signal.

  Further, according to the embodiment of the present invention, the radio communication system includes a terminal device and a radio base station. The radio base station performs radio communication with the terminal device. And a terminal device consists of a terminal device of Claim 1 or Claim 2, and a wireless base station consists of a wireless base station of Claim 3.

  A terminal apparatus according to an embodiment of the present invention reduces the number of bits of identification information of a radio base station that is to be shifted from a sleep state to an active state, and a wakeup ID that indicates a radio base station that is to be shifted from the sleep state to the active state; The identification information of the radio base station with a reduced number of bits is encoded so that the Hamming distance between the IDs of the other radio base stations is a certain value or more. Then, the terminal device transmits the encoded identification information as a wakeup ID to the radio base station.

  Therefore, the bandwidth occupation time of the wake-up signal can be reduced, and the radio base station can be activated accurately.

  Also, the radio base station according to the embodiment of the present invention activates the main device when the hamming distance between the wakeup ID and the radio base station ID is equal to or less than a threshold value. That is, the radio base station allows the bit error of the wakeup ID and activates the main device.

  Therefore, the radio base station can be activated even when the wakeup ID has a bit error below a certain value. And since the wake-up ID is encoded so that the hamming distance between the radio base station to be woken up and the ID of another radio base station different from the radio base station is not less than a certain value, the radio that you do not want to wake up accidentally The probability of wakeup of the base station can be reduced. In addition, this processing is realized only by a simple process of calculating the hamming distance between the wakeup ID and the ID of the radio base station and determining the threshold value, so that a processing load as in the case of error correction is required. The processing load can be reduced.

  Furthermore, a radio communication system according to an embodiment of the present invention includes the above-described terminal device and a radio base station.

  Therefore, the bandwidth occupation time of the wake-up signal can be reduced, and the radio base station can be activated accurately. In addition, the radio base station can be activated even when the wake-up ID has a bit error below a certain value.

1 is a schematic diagram of a radio communication system according to an embodiment of the present invention. It is a block diagram of the radio base station shown in FIG. It is a block diagram of the wake-up signal receiver shown in FIG. It is a block diagram of the terminal device shown in FIG. FIG. 5 is a configuration diagram of a wakeup signal generation unit shown in FIG. 4. 3 is a flowchart for explaining an operation in the wireless communication system shown in FIG. 1. It is a figure which shows the simulation result regarding the probability of making a radio base station wake up.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

  FIG. 1 is a schematic diagram of a radio communication system according to an embodiment of the present invention. Referring to FIG. 1, a radio communication system 10 according to an embodiment of the present invention includes a radio base station 1 and a terminal device 2.

  The radio base station 1 has a communication range REG. The radio base station 1 is connected to the network 30 via the wired cable 20.

  The radio base station 1 periodically transmits a beacon frame Beacon (= management frame) for managing the terminal device 2, an activation state in which wireless communication with the terminal device 2 is performed, and wireless communication with the terminal device 2 (= And a sleep state in which data transmission / reception cannot be performed.

  The wireless base station 1 is activated when it does not perform wireless communication with the terminal device 2 for a certain period of time or when there is no terminal device belonging to itself (that is, when there is no terminal device within the communication range REG). Transition from state to sleep state.

  In addition, when the radio base station 1 receives a wake-up signal for activating itself from the terminal device 2 in the sleep state, the radio base station 1 shifts from the sleep state to the activation state. The wireless base station 1 performs wireless communication with the terminal device 2 and also communicates with other communication devices via the wired cable 20 and the network 30. In this case, the radio base station 1 performs radio communication with the terminal device 2 in the 2.45 GHz band, for example.

  The terminal device 2 exists within the communication range REG of the radio base station 1. When the terminal device 2 does not receive the beacon frame Beacon from the radio base station 1, the terminal device 2 determines that the radio base station 1 is in the sleep state. Then, the terminal device 2 generates a wake-up signal for activating the wireless base station 1 when starting wireless communication with the wireless base station 1 when the wireless base station 1 is in the sleep state, The generated wakeup signal is transmitted to the radio base station 1 by radio communication in the 2.45 GHz band. That is, the terminal device 2 transmits a wake-up signal to the radio base station 1 using the same frequency band as that used for radio communication with the radio base station 1.

  Further, the terminal device 2 performs normal wireless communication with the wireless base station 1 in the 2.45 GHz band when the wireless base station 1 is in the activated state.

  FIG. 2 is a configuration diagram of the radio base station 1 shown in FIG. Referring to FIG. 2, radio base station 1 includes an antenna 11, a switch 12, a wake-up signal receiver 13, a main device 14, and a power supply 15.

  The antenna 11 is connected to the wake-up signal receiver 13 or the main device 14 via the switch 12.

  The switch 12 is connected between the antenna 11 and the wakeup signal receiver 13 and the main device 14.

  The antenna 11 receives a radio frame from the terminal device 2 by radio communication, and outputs the received radio frame to the wakeup signal receiver 13 or the main device 14 via the switch 12. Further, the antenna 11 transmits the radio frame received from the main device 14 to the terminal device 2 by radio communication.

  The switch 12 connects the antenna 11 to the wake-up signal receiver 13 or the main device 14 according to the control signal CTL from the main device 14.

  The wake-up signal receiver 13 receives, for example, 100 μW of power from the power supply 15 and is driven by the received power. The wakeup signal receiver 13 is connected to the antenna 11 via the switch 12 when the main device 14 is in the sleep state. When the wake-up signal receiver 13 receives a radio frame from the terminal device 2 via the antenna 11, the wake-up signal receiver 13 performs bit determination using the received radio frame, and between the received bit string and the ID of the radio base station 1. It is determined whether or not the Hamming distance is less than or equal to a threshold value. When the wake-up signal receiver 13 determines that the hamming distance between the wake-up ID and the ID of the radio base station 1 is equal to or less than the threshold value, the wake-up signal receiver 13 generates an activation signal and sends the generated activation signal to the main device 14. Output.

  On the other hand, the wakeup signal receiver 13 discards the wakeup ID when the hamming distance between the wakeup ID and the ID of the radio base station 1 is not less than the threshold value. Then, the wakeup signal receiver 13 waits for reception of a radio frame.

  Note that the wake-up signal receiver 13 has only a function of receiving a radio frame for wake-up of the radio base station 1, and does not have a function of transmitting a radio frame.

  The main device 14 receives, for example, 7 W of power from the power supply 15 and is driven by the received power.

  When the main device 14 is in the activated state, the main device 14 performs wireless communication with the terminal device 2 via the antenna 11 and communicates with other communication devices via the wired cable 20.

  The main device 14 shifts from the activated state to the sleep state when the wireless communication with the terminal device 2 is not performed for a certain period T1, or when there is no terminal device belonging to the wireless base station 1. Note that the certain period T1 is set to several tens of seconds, for example.

  Further, when the main device 14 is in the sleep state and receives an activation signal from the wakeup signal receiver 13, the main device 14 shifts from the sleep state to the activation state.

  The power supply 15 supplies 100 μW of power to the wake-up signal receiver 13 and supplies 7 W of power to the main device 14.

  The switch 12 includes a switch 121 and terminals 122 and 123. The main device 14 includes a wireless communication module 141, a wired communication module 142, and a host system 143.

  The switch 121 is connected to the antenna 11. The terminal 122 is connected to the wakeup signal receiver 13. The terminal 123 is connected to the wireless communication module 141.

  The switch 121 receives a control signal CTL from the host system 143 of the main device 14. The switch 121 connects the antenna 11 to the terminal 122 or the terminal 123 by the control signal CTL.

  In this case, the control signal CTL is an L (logic low) level signal or an H (logic high) level signal. The switch 121 connects the antenna 11 to the terminal 122 when the control signal CTL is an L level signal, and connects the antenna 11 to the terminal 123 when the control signal CTL is an H level signal.

  When receiving the command signal COM1 from the host system 143, the wireless communication module 141 shifts from the activated state to the sleep state, and when receiving the command signal COM2 from the host system 143, the wireless communication module 141 shifts from the sleep state to the activated state. This sleep state is a state in which the wireless communication module 141 has stopped operating.

  Then, when the wireless communication module 141 shifts to the activated state, the wireless communication module 141 generates a wireless frame (activation notification) for notifying the terminal device 2 that the wireless base station 1 has been activated, and the generated wireless frame (activation notification). Is transmitted to the terminal device 2.

  Thereafter, the wireless communication module 141 periodically transmits a beacon frame Beacon via the antenna 11 to establish a wireless communication link with the terminal device 2. The wireless communication module 141 performs wireless communication with the terminal device 2. In this case, the wireless communication module 141 extracts data from the wireless frame received from the terminal device 2, outputs the data to the host system 143, generates a wireless frame including the data received from the host system 143, and transmits the wireless frame to the terminal device 2. .

  The wired communication module 142 receives data from other communication devices via the wired cable 20 and outputs the received data to the host system 143.

  The wired communication module 142 receives data from the host system 143 and transmits the received data to another communication device via the wired cable 20.

  Further, when the wired communication module 142 receives the command signal COM1 from the host system 143, the wired communication module 142 shifts from the activated state to the sleep state, and upon receiving the command signal COM2 from the host system 143, the wired communication module 142 shifts from the sleep state to the activated state. This sleep state is a state in which the wired communication module 142 has stopped operating.

  When the host system 143 does not receive the packet from the terminal device 2 via the wireless communication module 141 for a certain period T1, or when the terminal device does not exist within the communication range REG, the host system 143 generates the command signal COM1. The command signal COM1 is output to the wireless communication module 141, and an L level control signal CTL is generated and output to the switch 12. Then, the host system 143 shifts to a sleep state (= stopped state). In this case, the host system 143 may output the command COM1 also to the wired communication module 142.

  Further, when the host system 143 receives the activation signal from the wakeup signal receiver 13, the host system 143 shifts from the sleep state to the activation state. Then, the host system 143 generates a command signal COM2, outputs the generated command signal COM2 to the wireless communication module 141 and the wired communication module 142, generates an H level control signal CTL, and outputs it to the switcher 12. To do.

  Further, when receiving data from the wireless communication module 141, the host system 143 outputs the received data to the wired communication module 142.

  Further, when receiving data from the wired communication module 142, the host system 143 outputs the received data to the wireless communication module 141.

  Furthermore, the host system 143 manages terminal devices that exist within the communication range REG.

  FIG. 3 is a block diagram of the wake-up signal receiver 13 shown in FIG. Referring to FIG. 3, wakeup signal receiver 13 includes a BPF (Band Pass Filter) 131, a bit determination unit 132, and an ID identification unit 133.

  The BPF 131 receives a radio wave via the antenna 11 and the switch 12 and extracts a signal having a radio frame frequency from the received radio wave. Then, the BPF 131 outputs the extracted signal to the bit determiner 132.

  The bit determination unit 132 performs bit determination using the radio frame received from the BPF 131. Then, the bit determiner 132 outputs the acquired received bit string to the ID identifier 133.

  The ID identifier 133 receives the received bit string from the bit determiner 132. Then, the ID identifier 133 calculates a Hamming distance between the received bit string and the ID of the radio base station 1. Then, the ID identifier 133 determines whether or not the calculated Hamming distance is equal to or less than a threshold value. The threshold is set to k (k is a positive integer) bits.

  When it is determined that the Hamming distance is equal to or less than the threshold value k, the ID identifier 133 generates an activation signal and outputs it to the main device 14.

  On the other hand, when it is determined that the Hamming distance is not equal to or less than the threshold value k, the ID identifier 133 discards the wakeup ID.

  FIG. 4 is a configuration diagram of the terminal device 2 shown in FIG. With reference to FIG. 4, the terminal device 2 includes an antenna 21, a wireless communication module 22, and a host system 23. The host system 23 includes a wakeup signal generation unit 231.

  When receiving the activation notification from the radio base station 1 via the antenna 21, the radio communication module 22 establishes a radio communication link with the radio base station 1 and performs radio communication with the radio base station 1.

  In this case, the radio communication module 22 receives a radio frame from the radio base station 1 via the antenna 21, demodulates the received radio frame, extracts data, and outputs the extracted data to the host system 23. The wireless communication module 22 receives data from the host system 23, generates a wireless frame including the received data, and transmits the generated wireless frame.

  Upon receiving the wakeup ID indicating the wireless base station 1 to be woken up from the wakeup signal generation unit 231 of the host system 23, the wireless communication module 22 generates a wireless frame including the wakeup ID, and the generated wireless frame is It transmits to the radio base station 1 via the antenna 21.

  The host system 23 receives the beacon frame Beacon received by the wireless communication module 22 via the antenna 21 from the wireless communication module 22. Then, the host system 23 extracts and manages the ESSID included in the received beacon frame Beacon, and manages the radio base station 1 to which the terminal device 2 belongs based on the ESSID.

  Further, when the host system 23 does not receive the beacon frame Beacon from the radio base station 1, the host system 23 determines that the radio base station 1 is in the sleep state, and outputs the command signal COM 3 and ESSID to the wakeup signal generation unit 231.

  Further, the host system 23 receives data from the wireless communication module 22, generates data, and outputs the data to the wireless communication module 22.

  When the wakeup signal generation unit 231 receives the command signals COM3 and ESSID from the host system 23, the wakeup signal generation unit 231 generates a wakeup ID by a method described later based on the ESSID, and outputs the generated wakeup ID to the wireless communication module 22. . The wakeup ID is information indicating a radio base station that is activated by the terminal device 2.

  FIG. 5 is a configuration diagram of the wake-up signal generation unit 231 shown in FIG. Referring to FIG. 5, wakeup signal generation unit 231 includes a hash calculator 2311, a thinning calculator 2312, and an encoding unit 2313.

  The hash calculator 2311 receives the ESSID from the host system 23. This ESSID has a maximum length of 32 bytes (256 bits).

  Upon receiving the ESSID, the hash calculator 2311 calculates the hash value of the ESSID and generates a bit string of n (n is, for example, 15) bits. Then, the hash calculator 2311 outputs the calculated n-bit bit string to the thinning calculator 2312.

  The thinning calculator 2312 receives an n-bit bit string from the hash calculator 2311 and generates a bit string of p (p is an integer satisfying n> p) by arbitrarily thinning bits from the received n-bit bit string. To do. Then, the thinning-out calculator 2312 outputs the generated p-bit bit string to the encoding unit 2313.

  The encoding unit 2313 receives a p-bit bit string from the thinning-out calculator 2312 and encodes the received p-bit bit string by BCH (Bose Chaudhuri Hocquechem). This BCH encoding encodes a p-bit bit string so that the hamming distance between the wake-up ID of the radio base station 1 and the ID assigned to another radio base station is a certain value or more. is there.

  Then, the encoding unit 2313 outputs the encoded bit string of m (m is a positive integer, for example, 30) to the wireless communication module 22 as a wakeup ID.

  FIG. 6 is a flowchart for explaining the operation in the wireless communication system 10 shown in FIG.

  Referring to FIG. 6, when a series of operations is started, the host system 143 of the radio base station 1 determines whether or not to shift to the sleep state (step S1). More specifically, the host system 143 of the radio base station 1 is not performing radio communication with the terminal device 2 for a certain period T1, or there is no terminal device belonging to the radio base station 1. When it is determined that the sleep state is to be entered. In addition, the host system 143 of the radio base station 1 performs radio communication with the terminal device 2 within a certain period T1, or when a terminal device belonging to the radio base station 1 exists. It determines with not shifting to a sleep state.

  In step S1, when it is determined to shift to the sleep state, the host system 143 of the radio base station 1 generates a command signal COM1 and outputs the command signal COM1 to the radio communication module 141, and also outputs a control signal CTL composed of an L level signal. It generates and outputs to the switcher 12, and stops its own operation. Here, the host system 143 may also output the command COM1 to the wired communication module 142 to stop the operation of the wired communication module 142. Then, the switch 12 of the radio base station 1 connects the antenna 11 to the terminal 122 according to the L level control signal CTL. In addition, the wireless communication module 141 and the wired communication module 142 of the wireless base station 1 stop operating in response to the command signal COM1. That is, when it is determined in step S1 that the sleep state is to be entered, the main device 14 is stopped (step S2).

  Then, the wakeup signal receiver 13 waits for a wakeup signal (step S3).

  Thereafter, the host system 23 of the terminal device 2 detects that the beacon frame Beacon is not received from the radio base station 1 (step S4). That is, the host system 23 of the terminal device 2 detects that the wireless base station 1 is in the sleep state. Then, the host system 23 of the terminal device 2 determines whether or not to start wireless communication (step S5).

  When it is determined in step S5 that the wireless communication is started, the host system 23 of the terminal device 2 outputs the ESSID of the wireless base station 1 to be activated and the command signal COM3 to the wakeup signal generation unit 231. Then, when receiving the command signal COM3, the wakeup signal generation unit 231 of the terminal device 2 generates a wakeup ID by the above-described method based on the ESSID. That is, the terminal device 2 generates a wakeup ID indicating the radio base station 1 to be activated (step S6).

  More specifically, in the wake-up signal generation unit 231 of the terminal device 2, the hash calculator 2311 receives the ESSID from the host system 23, calculates the hash value of the received ESSID, and generates an n-bit bit string. . Then, the hash calculator 2311 outputs the calculated n-bit bit string to the thinning calculator 2312. The thinning calculator 2312 receives an n-bit bit string from the hash calculator 2311, and arbitrarily thins bits from the received n-bit bit string to generate a p-bit bit string. Thereafter, the thinning-out calculator 2312 outputs the generated p-bit bit string to the encoding unit 2313. The encoding unit 2313 receives a p-bit bit string from the thinning-out calculator 2312 and BCH-encodes the received p-bit bit string to generate a wakeup ID.

  Then, the wakeup signal generation unit 231 of the terminal device 2 outputs the generated wakeup ID to the wireless communication module 22.

  Upon receiving the wakeup ID from the wakeup signal generation unit 231, the wireless communication module 22 of the terminal device 2 generates a wireless frame including the wakeup ID, and the generated wireless frame is transmitted to the wireless base station 1 via the antenna 21. (Step S7).

  In the wake-up signal receiver 13 of the radio base station 1, the BPF 131 receives a radio wave via the antenna 11, detects a signal having a radio frame frequency based on the received radio wave, and converts the detected signal into a bit. The data is output to the determiner 132. Then, the bit determination unit 132 performs bit determination using the signal received from the BPF 131, and acquires a received bit string. That is, the wake-up signal receiver 13 of the radio base station 1 receives a radio frame via the antenna 11, and acquires a received bit string from the received radio frame by bit determination (step S8).

  Then, in the wake-up signal receiver 13 of the radio base station 1, the ID identifier 133 calculates the Hamming distance between the received bit string and the ID of the radio base station 1 (step S9).

  Then, in the wake-up signal receiver 13 of the radio base station 1, the ID identifier 133 determines whether or not the hamming distance is equal to or less than the threshold value k (step S10).

  When it is determined in step S10 that the Hamming distance is not less than or equal to the threshold value k, the series of operations returns to step S3.

  On the other hand, when it is determined in step S10 that the hamming distance is equal to or less than the threshold value k, the ID identifier 133 generates an activation signal and outputs it to the host system 143 in the wakeup signal receiver 13 of the radio base station 1. To do. Then, the host system 143 of the wireless base station 1 shifts from the sleep state to the activated state according to the activation signal from the wakeup signal receiver 13, generates the command signal COM <b> 2, and outputs it to the wireless communication module 141. When the wired communication module 142 is sleeping, the host system 143 also outputs a command COM2 to the wired communication module 142. Then, the wireless communication module 141 of the wireless base station 1 shifts from the sleep state to the activated state according to the command COM2. When the wired communication module 142 is sleeping, the wired communication module 142 shifts from the sleep state to the activated state according to the command COM2. As described above, the main device 14 of the radio base station 1 shifts from the sleep state to the activated state in response to the activation signal from the wakeup signal receiver 13 (step S11).

  Then, the wireless communication module 141 of the wireless base station 1 generates an activation notification and transmits the generated activation notification to the terminal device 2 via the antenna 11 (step S12).

  Then, the wireless communication module 22 of the terminal device 2 receives the activation notification via the antenna 21 (step S13), and outputs the received activation notification to the host system 23. Thereafter, the host system 23 of the terminal device 2 detects that the wireless base station 1 has shifted from the sleep state to the activated state in response to the activation notification from the wireless communication module 22.

  Then, the wireless communication module 141 of the wireless base station 1 starts wireless communication for establishing a wireless communication link with the terminal device 2, establishes a wireless communication link with the terminal device 2, and performs wireless communication. Is performed (step S14).

  When it is determined in step S1 that the sleep state is not shifted, the series of operations shifts to step S14.

  Then, after step S14 or when it is determined in step S5 that the wireless communication is not started, the series of operations ends.

  As described above, when generating the wakeup ID, the wakeup signal generation unit 231 of the terminal device 2 calculates a 32-byte (= 256 bits) ESSID hash value to obtain an n = 15-bit bit string. In addition, a bit string of p (<n) bits is generated by thinning-out calculation, and a bit string of m = 30 bits is further generated by BCH encoding to generate a wakeup ID (see step S6).

  As a result, redundant bits can be greatly reduced compared to the case where ESSID is used as a wakeup ID. Therefore, it is possible to greatly suppress an increase in the band occupation time due to the transmission of a long wakeup ID.

  Further, the wake-up signal receiver 13 of the radio base station 1 generates an activation signal and sends it to the main device 14 if the Hamming distance between the received received bit string and the ID of the radio base station 1 is equal to or less than the threshold value k. Output (refer to “YES” in step S10, step S11). That is, the wakeup signal receiver 13 matches the wakeup ID and the ID of the radio base station 1 if the bit that does not match between the wakeup ID and the ID of the radio base station 1 is k bits or less. And an activation signal is generated and output to the main device 14. That is, the wake-up signal receiver 13 allows the mismatch between the wake-up ID and the ID of the radio base station 1 up to k bits, and activates the main device 14.

  Therefore, it is possible to solve the problem that a radio base station different from the radio base station 1 to be woken up is caused by a bit error.

  Furthermore, the wakeup signal generation unit 231 of the terminal device 2 performs BCH encoding to generate a wakeup ID (see step S6). This BCH encoding is performed in order to maintain the Hamming distance.

  Accordingly, it is possible to solve the problem that a radio base station that is not desired to be woken up due to a bit error is woken up.

  Thus, the radio base station 1 and the terminal device 2 according to the embodiment of the present invention can solve the three conventional problems.

  In the above description, the wakeup signal generation unit 231 has been described as performing both the first process for calculating the hash value of the ESSID and the second process for performing the thinning calculation. According to the form, the wakeup signal generation unit 231 is not limited to this, and the wakeup signal generation unit 231 may perform at least one of the first and second processes to reduce the number of bits of the ESSID.

  In this case, the wake-up signal generation unit 231 includes at least one of the hash calculator 2311 and the thinning calculator 2312 according to the content of the process to be executed.

  FIG. 7 is a diagram illustrating simulation results regarding the probability of waking up a radio base station.

  In FIG. 7, the vertical axis represents the probability that the radio base station that is desired to wake up cannot be woken up and the probability that the radio base station that is not desired to be woken up is woken up. The horizontal axis represents the number of allowable error bits. Further, a curve k1 indicates a probability that a radio base station that is desired to wake up cannot be woken up when the method according to the present invention and the comparison method are used. Furthermore, the curve k2 shows the probability of wake-up of a radio base station that does not want to wake-up when using the method according to the present invention. Further, a curve k3 indicates the probability of wakeup of a radio base station that does not want to be woken up when using the comparison method.

  In the system according to the present invention, the number of bits p output from the decimation unit 231 is 15 bits, and the encoding means 2313 performs BCH encoding of (15, 31, 7) to wake up 31 bits. The ID is output. This (15, 31, 7) BCH encoding is an encoding capable of correcting a 7-bit error.

Further, in comparison method ^was prepared ^{2 15} wakeup ID. The 2 ¹⁵ wakeup ID is the length of the wake-up ID and 31 bits, are those selected from 2 ³¹ bit patterns arbitrarily. That is, BCH encoding is not performed in the comparison method.

  Referring to FIG. 7, in the method according to the present invention and the comparison method, the probability that the radio base station to be woken up cannot be woken up is the same, and rapidly decreases as the number of allowable error bits increases (curve). k1).

  On the other hand, the probability of waking up a radio base station that does not want to be woken up increases as the number of allowable error bits increases, and is 100% when the number of allowable error bits is 20 bits or more (see curves k2 and k3). .

  In addition, when using the method according to the present invention, the probability of waking up a radio base station that does not want to be woken up is lower than in the comparison method when the number of allowable error bits is 7 bits or less (see curves k2 and k3). ). Therefore, the allowable error bit number k is set to 7 bits or less.

  Thus, by using the system according to the present invention, the radio base station can be accurately woken up.

  In the above description, the encoding unit 2313 performs BCH encoding. However, in the embodiment of the present invention, the hamming distance between the wakeup ID and the radio base station ID is not limited to this. As long as the encoding method can be maintained at a constant value, the bit string may be encoded using any encoding method. The encoding by the encoding means 2313 and the technology for waking up when the Hamming distance is k or less can also be used as a wake-up method in other wireless systems such as a sensor network.

  In the embodiment of the present invention, the antenna 11 and the BPF 131 constitute a “reception unit”, the bit decision unit 132 constitutes a “bit decision unit”, and the ID discriminator 133 constitutes “activation unit”. Configure.

  In the embodiment of the present invention, the wireless communication module 22 constitutes a “transmission unit”.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

  The present invention is applied to a terminal device, a radio base station that performs radio communication with the terminal device, and a radio communication system using them.

  1, 2 terminal device, 10 wireless communication system, 11, 21 antenna, 12 switch, 13 wakeup signal receiver, 14 main device, 15 power supply, 20 wired cable, 22,141 wireless communication module, 23, 143 host system , 30 network, 121 switch, 122, 123 terminal, 131 BPF, 132 bit determiner, 133 ID identifier, 142 wired communication module, 231 wake-up signal generator, 2311 hash calculator, 2312 decimation calculator, 2313 encoding means.

Claims (4)

A bit number reduction means for reducing the number of bits of identification information of a radio base station to be shifted from a sleep state to a startup state;
The bit number reducing means so that a hamming distance between a wakeup ID indicating a radio base station to be shifted from the sleep state to the activated state and an ID of a radio base station different from the radio base station is equal to or greater than a predetermined value. Encoding means for encoding the identification information of the radio base station reduced by
Transmitting means for transmitting the identification information of the radio base station encoded by the encoding means to the radio base station as the wake-up ID,
The sleep state is a state in which the wireless base station cannot perform wireless communication with the terminal device,
The activated state is a terminal device in which the wireless base station performs wireless communication with the terminal device.   The bit number reduction means includes a first process for calculating a hash value of identification information of the radio base station, and a second process for thinning out a predetermined number of bits from a bit string constituting the identification information of the radio base station. The terminal device according to claim 1, wherein at least one is executed to reduce the number of bits of identification information of the radio base station. A management frame for managing the terminal device is periodically transmitted, and has a startup state in which wireless communication with the terminal device is performed and a sleep state in which wireless communication with the terminal device cannot be performed, and for a certain period A main device that shifts from the activated state to the sleep state when no wireless communication is performed with the terminal device or when there is no terminal device belonging to the wireless base station;
Receiving means for receiving radio waves transmitted from the terminal device according to claim 1 or 2,
Bit determination means for determining bits based on radio waves received by the reception means;
When a hamming distance between the received bit string bit-determined by the bit determination means and the ID of the radio base station is equal to or less than a threshold, an activation signal for causing the main device to transition from the sleep state to the activation state Generating means for generating and outputting to the main device,
The main apparatus is a radio base station that shifts from the sleep state to the activation state in response to the activation signal. A terminal device;
A wireless base station that performs wireless communication with the terminal device,
The terminal device comprises the terminal device according to claim 1 or claim 2,
The radio base station is a radio communication system including the radio base station according to claim 3.

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