JP2014236374A - Repeater device and repeater sleep control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce failures in data transmission and reception between an access point device and a terminal involved in sleep control while performing sleep control without increasing the number of radio devices.SOLUTION: A repeater device comprises a power management managing unit for terminals 15 and a power management managing unit for access point devices 16. The power management managing unit for terminals 15 keeps a repeater 1 in an active state until first data communication is completed if it is determined that the first data communication with a terminal 3 will occur within a certain period from the time of determination. Also, the power management managing unit for access point devices 16 keeps the repeater 1 in the active state until second data communication is completed if it is determined that the second data communication with an access point device 2 will occur within a certain period from the time of determination.

Description

  The present invention relates to a repeater device that performs a relay process between an access point device and a terminal device in a wireless communication system, and a sleep control method for the repeater.

  In recent years, wireless local area networks (LANs) have become widespread in homes and offices, and wireless LAN functions are installed in many information devices and widely used as a means of Internet access. The specification of a wireless LAN that is generally used is standardized as IEEE (The Institute of Electrical and Electronics Engineers, Inc.) 802.11 standard.

  Generally, in a wireless LAN operating in the infrastructure mode, a wireless LAN access point device (hereinafter referred to as “access point device”) and a wireless LAN terminal (hereinafter referred to as “terminal”) communicate with each other. However, when the access point device and the terminal are remotely located, there arises a problem that the other device cannot receive a radio signal emitted from one device. In order to improve this problem, radio wave signals can be relayed using a wireless LAN repeater (hereinafter referred to as “repeater”). The repeater behaves like a terminal and communicates with an access point. In addition, the repeater behaves like an access point to connect to a terminal and communicates. The repeater communicates with the terminal using information such as SSID (Service Set IDentifier) received from the access point device. As a communication method of the repeater, there are two methods for processing both the communication of the access point device partner and the communication of the terminal partner with a single wireless device, and the two different wireless communication methods of the access point device partner communication and the terminal partner communication There is a method of processing with a machine. In the latter case, both communications use different frequencies. In the former case, both communications generally use the same frequency in a time-sharing manner.

  A power saving technique for the wireless LAN device will be described. Generally, power saving is required for communication devices. Also in the IEEE 802.11 standard, operation of a power save mode based on switching between an active state and a sleep state is defined as a power saving function of a terminal. An active terminal can perform all functions of transmission, reception, and listening. On the other hand, in a terminal in the sleep state, execution of some functions of transmission, reception, and listening is restricted by cutting off power supply to some circuits. In the sleep state, the power consumption of the terminal is smaller than in the active state.

  The terminal uses a TIM (Traffic Indication Map) element on the beacon frame transmitted by the access point to check whether it is necessary to receive data, and when it is necessary to receive data, until all data reception is completed Operates in an active state. When there is no need to receive data, it is operated in an active state only when a beacon frame having a DTIM (Delivery Traffic Indication Message) count of 0 is received. The terminal achieves power saving by shifting to the sleep state at times other than when receiving a beacon frame in which the DTIM count is 0. The terminal can be a device driven by a battery, and power saving is more important in battery driving. For this reason, the power saving function of the terminal is defined by the IEEE 802.11 standard (for example, Non-Patent Document 1).

  On the other hand, the access point device is designed on the assumption that power is always supplied. Therefore, the IEEE 802.11 standard does not specify the power saving function of the access point device. NAV (Network Allocation Vector), which is a reservation signal that sets the channel reservation period of the used channel, is used as a power saving function of the access point device that is realized in accordance with the IEEE 802.11 standard without changing the function on the terminal side. A utilized power save mode has been proposed (for example, Non-Patent Document 2).

IEEE Std 802.11TM-2007 Feng Zhang, et al, “Power saving Access Points for IEEE 802.11 Wireless Network Infrastructure”, WCNC, 2004.

  As described above, the repeater plays two roles as a terminal for the access point device and as an access point device for the terminal. If each of the two roles is implemented by two radios, that is, if two radios are installed in one repeater, the power save mode of the terminal and the power of the access point device are also used in the repeater. Both functions of the save mode can be applied. However, by installing two wireless devices, the power consumption of the wireless device is doubled, so the purpose of suppressing power consumption by the power save mode cannot be achieved.

  FIG. 9 is a diagram illustrating a configuration example in a case where the repeater plays two roles of a role as a terminal for the access point device and a role as the access point device for the terminal with one radio. As shown in FIG. 9, the repeater 100 and the access point device 200, and the repeater 100 and the terminal 300 are connected in the infrastructure mode. The repeater 100 includes an antenna 101, a wireless communication processing unit 102, a power management management unit 103 for an access point device, and a power management management unit 104 for a terminal.

  The repeater 100 communicates with the access point device 200 from the wireless communication processing unit 102 via the antenna 101. The repeater 1 serves as a terminal to the access point device 2 and connects in the infrastructure mode. In relation to the access point device 2, sleep control is executed by the power management management unit 103 for the access point device. The repeater 1 communicates with the terminal 300 from the wireless communication processing unit 102 via the antenna 101. The repeater 1 serves as an access point device to the terminal 3 and connects in the infrastructure mode. In relation to the terminal 3, sleep control is executed by the power management management unit 104 for the terminal.

FIG. 10 is a diagram illustrating an example of frame transmission / reception when the repeater 100 plays a role as a terminal with respect to the access point device 200 and executes sleep control of the terminal. Here, the repeater 100 performs sleep control by the power management management unit 103 for the access point device.
In a TBTT _AP (Target Beacon Transmit Time) 801 of the access point device 200, the access point device 200 transmits a beacon frame 8101. The repeater 100 that has received the beacon frame 8101 uses the TIM element on the beacon frame 8101 to check whether data reception is necessary. When there is no need for data reception and no frame is held in the transmission buffer, the repeater 1 (wireless communication processing unit 102) up to TBTT _RS 802 is controlled by the power management management unit 103 for the access point device. , Go to sleep. Since the sleep state is not notified from the repeater 100 to the terminal 300, when the data frame 1102 occurs in the terminal 300, the terminal 300 transmits the data frame 1102 according to the CSMA (Carrier Sense Multiple Access) / CS procedure. . However, since the relay device 100 in the sleep state cannot receive the data frame 1102, there arises a problem that data transmission / reception fails.

FIG. 11 is a diagram illustrating an example of frame transmission / reception when the repeater 100 serves as an access point device for the terminal 3 and executes sleep control of the access point device. Here, the repeater 100 performs sleep control by the power management management unit 104 for terminal.
When the frame is not held in the transmission buffer at the time of TBTT _RS 901 of the repeater 100 and the frame is not received from the terminal 300 in a certain period immediately before the TBTT _RS 901, the repeater 100 transmits the beacon frame 9101. Through this, the terminal 300 is notified of the channel reservation period. The repeater 100 (wireless communication processing unit 102) shifts to the sleep state by the power management management unit for terminal 104 after transmitting the beacon frame 2101 and maintains the sleep state until the channel reservation period ends. The terminal 300 notified of the channel reservation period does not transmit the data frame even if a data frame occurs in the channel reservation period. When the repeater 100 is in the sleep state, even if the access point device 200 transmits the beacon frame 9102 at the time of TBTT _AP 902, the repeater 100 cannot receive the beacon frame 9102. Therefore, even if the access point device 200 notifies the presence of the transmission data frame 9103 using the TIM element of the beacon frame 9102, the repeater 200 cannot recognize and cannot receive the transmission data frame 9103. . As a result, there arises a problem that data transmission / reception fails.

  In view of the above circumstances, the present invention provides a repeater device and a repeater for reducing failure in data transmission / reception between an access point device and a terminal associated with sleep control while performing sleep control without increasing the number of wireless devices. To provide a sleep control method.

  One aspect of the present invention is a repeater device that includes a wireless device and wirelessly communicates between the terminal device and the access point device using the wireless device in a time-sharing manner, depending on the communication status with the terminal device, A first management unit that controls switching between the active state and the sleep state of the repeater device, and between the active state and the sleep state of the repeater device according to a communication state with the access point device A second management unit that controls switching, and when the first management unit determines that the first data communication with the terminal device occurs within a certain period from the determination time, The repeater device is activated until the first data communication is completed, and the second management unit performs the second data communication with the access point device within a certain period from the determination time. And If it is, the said repeater device to the active state until the second data communication is completed.

  Also, in one aspect of the present invention, the first management unit should receive data from the terminal device within a certain period retroactive from the determination time, or transmit the data to the terminal device in a buffer memory When the data exists, it is determined that the first data communication occurs.

  In one aspect of the present invention, the second management unit determines whether the second data communication occurs based on a TIM (Traffic Indication Map) element of a beacon received from the access point device. judge.

  One embodiment of the present invention includes a wireless device, and switches between an active state and a sleep state of a repeater that wirelessly communicates with the terminal device and the access point device using the wireless device in a time-sharing manner. In the sleep control method of the repeater to be controlled, when it is determined that the first data communication with the terminal device occurs within a certain period from the determination, the relay is performed until the first data communication is completed. And when the second management unit determines that the second data communication with the access point device occurs within a certain period from the determination time, the second management unit Until the data communication is completed, the repeater device is activated.

  ADVANTAGE OF THE INVENTION According to this invention, the failure of the data transmission / reception between the access point apparatus and terminal accompanying sleep control can be reduced, performing sleep control, without increasing the number of radio | wireless machines.

It is a functional block diagram which shows the structure of the repeater by one Embodiment of this invention. It is a flowchart which shows the procedure of the state switching operation | movement of the active state / sleep state by the power management management part for terminals. It is a flowchart which shows the procedure of the state switching operation | movement of the active state / sleep state by the power management management part for terminals. It is a flowchart which shows the procedure of the state switching operation | movement of an active state / sleep state by the power management management part for access point apparatuses. It is a flowchart which shows the procedure of the state switching operation | movement of an active state / sleep state by the power management management part for access point apparatuses. It is a figure which shows an example of the frame transmission / reception operation | movement by a repeater. It is a figure which shows the example of the frame transmission / reception operation | movement by a repeater when there exists transmission of the data frame from an access point apparatus. It is a figure which shows the example of the frame transmission / reception operation | movement by a repeater when there exists transmission of the data frame from a terminal. It is a figure which shows the structural example in case a repeater plays two roles with one radio | wireless machine. It is a figure which shows an example of the frame transmission / reception when the repeater plays a role as a terminal with respect to the access point device and executes sleep control of the terminal. It is a figure which shows an example of frame transmission / reception when the repeater plays a role as an access point device for a terminal and executes sleep control of the access point device.

  Hereinafter, a wireless LAN repeater device (hereinafter referred to as a “repeater”) according to an embodiment of the present invention will be described with reference to the drawings. In this description, as an embodiment, communication between a wireless LAN access point device and a repeater and between a repeater and a wireless LAN terminal (hereinafter referred to as “terminal”) is performed in accordance with the IEEE 802.11 standard. I will write about.

  FIG. 1 is a functional block diagram showing the configuration of a repeater 1 (repeater device) according to an embodiment of the present invention. In FIG. 1, a repeater 1 is connected in an infrastructure mode between an access point device 2 and a terminal 3 (terminal device). The repeater 1 includes an antenna 11, a wireless communication processing unit 12, a power management management unit 13, and an information storage unit 14.

The wireless communication processing unit 12 communicates with the access point device 2 via the antenna 11. The repeater 1 serves as a terminal to the access point device 2 and connects in the infrastructure mode. Further, the wireless communication processing unit 12 communicates with the terminal 3 via the antenna 11. The repeater 1 serves as an access point device to the terminal 3 and connects in the infrastructure mode.
In the repeater 1, the antenna 11 and the wireless communication processing unit 12 are used in common for both communication with the access point device 2 and communication with the terminal 3. In general, time division is used.
The wireless communication processing unit 12 includes a buffer 12a that temporarily stores transmission schedule data.
The power management management unit 13 includes a power management management unit for terminal 15 (first management unit) and a power management management unit for access point device 16 (second management unit), and each function performs wireless communication. Management of switching between the active state and the sleep state in the processing unit 12 is performed.

  A procedure for performing state switching determination in the power management manager 13 will be described. First, in accordance with the IEEE 802.11 standard, the power management management unit 13 notifies that the terminal is in the power save mode when belonging to the access point apparatus 2. Therefore, a frame transmitted from the access point device 2 to the repeater 1 is not necessarily transmitted until the access point device 2 receives the PS_POLL frame.

  FIG. 2 is a flowchart illustrating the procedure of the state switching operation between the active state and the sleep state by the power management management unit 15 for the terminal of the repeater 1.

The flow in FIG. 2 starts with the timing of TBTT _RS- T _Awake as a trigger. TBTT _RS is the TBTT of repeater 1. T _Awake is a time determined so as to be always in an active state for the purpose of reliably receiving the attribution signal of the new terminal and the data frame held in the buffer 12a addressed to the terminal 3. When T _Awake is set to a small value, the power saving effect is increased.

The terminal power management management unit 15 sets F _STA to 1 (S1). F _STA is a variable indicating whether or not the repeater 1 makes a channel reservation so that a frame from the terminal 3 is not accepted. When F _STA is 0, repeater 1 performs channel reservation and indicates a state in which frames are not accepted. When F _STA is 1, repeater 1 does not perform channel reservation and indicates a state in which frames can be accepted. ing.
Next, the power management management unit for terminal 15 determines whether or not the wireless communication processing unit 12 is in a sleep state (S2).
When the wireless communication processing unit 12 is in the sleep state (S2-Yes), the power management management unit for terminal 15 shifts the wireless communication processing unit 12 to the active state and changes to a state in which a frame can be received (S3). On the other hand, when the wireless communication processing unit 12 is in the active state (S2-No), the power management management unit for terminal 15 causes the wireless communication processing unit 12 to wait in the active state.
The wireless communication processing unit 12 in the active state freely performs transmission / reception up to TBTT _RS (S4).

Subsequent to FIG. 3, the power management management unit for terminal 15 determines whether or not the variable F _AP is 1 at the timing of the TBTT _RS (S5). F _AP is a variable indicating whether or not the access point device 2 permits the repeater 1 to enter the sleep state. When _FAP is 0, the access point apparatus 2 has permitted the repeater 1 to enter the sleep state. When _FAP is 1, it indicates a state where the access point device 2 does not permit the repeater 1 to enter the sleep state. The _FAP is stored in the information storage unit 14. To query F _AP values from terminal-Power management manager 15, information storage unit 14 to answer. It will be described later procedure for changing the value of F _AP.

When the variable F _AP is 1 (S5-Yes), that is, when the access point device 2 does not permit the repeater 1 to enter the sleep state, the wireless communication processing unit 12 sets the TBTT _RS . The channel reservation period is not set in the beacon transmitted at the timing (S9), and the active state is continued (S11).
On the other hand, when the variable F _AP is 0 (S5-No), that is, when the access point device 2 permits the repeater 1 to enter the sleep state, the time from the terminal 3 is within the time of T _Awake . It is determined whether the wireless communication processing unit 12 has received the data frame (S6).
When the repeater 1 receives the data frame from the terminal 3 within the time of T _Awake (S6-Yes), the wireless communication processing unit 12 does not set the channel reservation period in the beacon transmitted at the timing of TBTT _RS ( S9) The active state is maintained (S11).

If the repeater 1 does not receive a data frame from the terminal 3 during T _Awake (S6-No), does the data frame addressed to the terminal 3 exist in the buffer 12a of the wireless communication processing unit 12 at the timing of TBTT _RS ? It is determined whether or not (S7).

When the data frame addressed to the terminal 3 is present in the buffer 12a of the wireless communication processing unit 12 (S7-Yes), the wireless communication processing unit 12 does not set the channel reservation period in the beacon transmitted at the timing of TBTT _RS (S9). ), The active state is continued (S11). In S6 and S7, a prediction is made as to whether or not there is transmission data from the terminal 3 until the next TBTT _RS . When the result of S6 or S7 is Yes, it is predicted that there is data to be transmitted from the terminal 3, and the standby in the active state is selected.

数式（１）において、ＢＩはＴＢＴＴとＴＢＴＴとの間隔を示すビーコンインターバル、Ｂはビーコンの送信に要する時間である。Ｔ_{Ｒｅｓｅｒｖｅ}とＴ_{Ａｗａｋｅ}との値によって、スリープ効率が定まる。前述の通り、Ｔ_{Ａｗａｋｅ}の時間内は、無線通信処理部１２は、必ずアクティブ状態となる。また、Ｔ_{Ｒｅｓｅｒｖｅ}の値は、端末３からのフレーム送信を禁止する期間である。Ｔ_{Ｒｅｓｅｒｖｅ}の値は、必ず無線通信処理部１２がスリープ状態となる期間ではない。
次に、対端末用パワーマネジメント管理部１５は、無線通信処理部１２をスリープ状態に移行させ（Ｓ１０）、情報保管部１４に保存されている変数Ｆ_ＳＴＡに０を代入する（Ｓ１２）。 When there is no data frame addressed to the terminal 3 in the buffer 12a of the wireless communication processing unit 12 (S7-No), the channel reservation period T _Reserve is set in the beacon transmitted at the timing of TBTT _RS (S8). Note that the value of T _Reserve can be expressed by the following mathematical formula (1).

In Equation (1), BI is a beacon interval indicating an interval between TBTT and TBTT, and B is a time required for transmitting a beacon. The sleep efficiency is determined by the values of T _Reserve and T _Awake . As described above, the wireless communication processing unit 12 is always in an active state during the time of T _Awake . The value of T _Reserve is a period during which frame transmission from the terminal 3 is prohibited. The value of T _Reserve is not necessarily a period during which the wireless communication processing unit 12 is in the sleep state.
Next, the terminal-use power management management unit 15 shifts the wireless communication processing unit 12 to the sleep state (S10), and substitutes 0 for the variable F _STA stored in the information storage unit 14 (S12).

FIG. 4 is a flowchart showing a procedure of the state switching operation between the active state / sleep state by the power management management unit 16 for the access point device of the repeater 1.
The flow in FIG. 4 starts with the timing of TBTT _AP as a trigger. The TBTT _AP is a TBTT of the access point device 2.

The power management manager 16 for the access point device determines whether or not the wireless communication processing unit 12 is in a sleep state (S14).
When the wireless communication processing unit 12 is in the sleep state (S14-Yes), the power management managing unit 16 for the access point device shifts the wireless communication processing unit 12 to the active state and changes it to a state in which a frame can be received ( S15). S15 occurs when S9 is executed in the immediately preceding TBTT _RS .
On the other hand, when the wireless communication processing unit 12 is in the active state (S14-No), the power management managing unit 16 for the access point device makes the wireless communication processing unit 12 stand by in the active state.

  The wireless communication processing unit 12 in the active state receives a beacon from the access point device 2 (S16). In the TIM element of the received beacon frame, information indicating whether or not the access point device 2 holds a data frame addressed to the repeater 1 or a broadcast data frame is described.

Moving to FIG. 5, the access point device power management management unit 16 determines that the access point device 2 transmits the data frame addressed to the repeater 1 based on the TIM element information of the beacon frame received by the wireless communication processing unit 12. It is determined whether or not it is held (S17).
When the access point 1 does not hold the data frame addressed to the repeater 1 (S17-No), the power management management unit 16 for the access point device uses the TIM element information of the beacon frame received by the wireless communication processing unit 12. Based on the above, it is determined whether or not the access point 1 holds a broadcast data frame (S18).

When the access point 1 holds a data frame addressed to the repeater 1 (S17-Yes), or when the access point 1 holds a broadcast data frame (S18-Yes), the access point 1 The device power management management unit 16 assigns 1 to the variable _FAP stored in the information storage unit 14 while maintaining the active state of the wireless communication processing unit 12 (S19).

  The power management management unit 16 for the access point device causes the wireless communication processing unit 12 to transmit a PS-Poll frame to the access point device 2 (S20). Then, the wireless communication processing unit 12 receives the data frame transmitted from the access point device 2 (S21). The wireless communication processing unit 12 confirms the received data frame and confirms whether the MoreData field is 1 (S22).

If the MoreData field of the received data frame is 1 (S22-Yes), that is, if there is still a frame to be transmitted from the access point apparatus 2 to the repeater 1, the process returns to step 21 and is repeated.
On the other hand, when the MoreData field of the received data frame is 0 (S22-No), that is, when there is no frame to be transmitted from the access point device 2 to the repeater 1, the variable F _AP stored in the information storage unit 14 is stored. 0 is substituted into (S23). Then, it is determined whether or not the variable F _STA is 1 (S24).
If it is determined in S18 that the access point 2 does not hold a broadcast data frame, it is similarly determined whether or not the variable F _STA is 1 (S24).
When F _STA is 0 (S24-No), the wireless communication processing unit 12 is shifted to the sleep state (S25). Conversely, when F _STA is 1 (S24-Yes), the active state of the wireless communication processing unit 12 is maintained (S26).

FIG. 6 is a diagram illustrating an example of a frame transmission / reception operation by the repeater 1. FIG. 6 shows an example in which there is no transmission / reception of frames other than beacon frames. The relay device 1 shifts to the active state at a timing before T _Judge from the TBTT _RS 101 by the power management management unit 15 for terminal. _{F AP} stored in the information storage unit 14 _{0, F STA} is 1. Since there was no transmission / reception of a data frame with the terminal 3 during T _Judge , after transmitting the beacon frame 1101 using TBTT _RS 101, the wireless communication processing unit 12 shifts to a sleep state. _{F AP} stored in the information storage unit 14 _{0, F STA} is zero.

Next, at the timing of TBTT _AP 102, the wireless communication processing unit 12 shifts to the active state by the power management management unit 16 for the access point device, and receives the beacon frame 1102 at the timing of TBTT _AP 102. The wireless communication processing unit 12 shifts to the sleep state again because there is no frame received from the access point 2. The _{F AP} stored in the information storage unit 14 _{0, F STA} remains 0. Then, the wireless communication processing unit 12 again shifts to the active state at the timing before T _Judge from the TBTT _RS 103 by the terminal power management management unit 15. _{F AP} stored in the information storage unit 14 _{0, F STA} is 1.

FIG. 7 is a diagram illustrating an example of a frame transmission / reception operation by the repeater 1 when there is a data frame transmission from the access point device 2. The wireless communication processing unit 12 shifts to an active state at a timing before T _Judge from TBTT _RS 201 by the power management management unit 15 for terminal. _{F AP} stored in the information storage unit 14 _{0, F STA} is 1. Since no data frame was transmitted / received to / from the terminal 3 within the time of T _Judge , the wireless communication processing unit 12 transmits a beacon frame 2101 using TBTT _RS 201 and then shifts to a sleep state. _{F AP} stored in the information storage unit 14 _{0, F STA} is zero.

Next, at the timing of TBTT _AP 202, the wireless communication processing unit 12 shifts to the active state by the power management management unit 16 for access point device, and receives the beacon frame 2102 at the timing of TBTT _AP 202. From the information described in the TIM element of the beacon frame 2102, the repeater 1 can determine that there is a frame that the access point device 2 wants to transmit. Therefore, the wireless communication processing unit 12 maintains the active state and transmits the PS_POLL frame 2201 to the access point apparatus 2. _{F AP} stored in the information storage unit 14 becomes _{1, F STA} is 0. The access point device 2 that has received the PS_POLL frame 2201 transmits a data frame 2301 to the repeater 1. The repeater 1 that has received the data frame 2301 transmits an ACK frame 2401 to the access point apparatus 2. MoreData field of the data frame 2301 has a 0, _and since _{the F STA} is 0, the wireless communication processing unit 12 shifts to the sleep state. Thereafter, the wireless communication processing unit 12 again shifts to the active state at the timing before T _Judge from TBTT _RS 103 by the power management management unit 15 for terminal. _{F AP} stored in the information storage unit 14 _{0, F STA} is 1.

FIG. 8 is a diagram illustrating an example of a frame transmission / reception operation by the repeater 1 when there is a data frame transmission from the terminal 3. The wireless communication processing unit 12 shifts to an active state at a timing before T _Judge from TBTT _RS 201 by the power management management unit 15 for terminal. _{F AP} stored in the information storage unit 14 _{0, F STA} is 1. Since transmission / reception of the data frame 3201 and the ACK frame 3301 has occurred with the terminal 3 within the time of T _Judge , the wireless communication processing unit 12 is in the active state even after transmitting the beacon frame 3101 with the TBTT _RS 201. To maintain. The F _AP stored in the information storage unit 14 maintains 0, and the F _STA maintains 1. The active state is continued until the next TBTT _RS 303, so that the repeater 1 can freely transmit and receive frames.

  According to the repeater 1 described above, failure in data transmission / reception between the access point device and the terminal associated with sleep control can be reduced while performing sleep control without increasing the number of wireless devices.

  In the above description, the upper connection target of the repeater 1 is described as the access point device 2. However, the upper connection target of the repeater 1 is not limited to the access point device 2. For example, the upper connection target of the repeater 1 may be a repeater having an access point function. In this case, a plurality of repeaters are connected continuously.

  In the above description, the case where the wireless communication between the repeater 1 and the access point device 2 and between the repeater 1 and the terminal 3 is performed according to the IEEE802.11 standard is shown. However, the wireless communication standard for these wireless communication is not limited to the IEEE 802.11 standard.

  1 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed to perform communication processing. Also good. The “computer system” here includes an OS (Operating System) and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible disk, a magneto-optical disk, a portable medium such as a ROM (Read Only Memory) and a CD-ROM, and a hard disk incorporated in a computer system. Say. Furthermore, “computer-readable recording medium” refers to a fixed volatile memory such as a volatile memory inside a computer system serving as a server or client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. Including those holding time programs.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes a design that does not depart from the gist of the present invention. Needless to say, the above-described embodiment and a plurality of modifications can be combined within a range in which the contents do not conflict with each other. In the above-described embodiments and modifications, the structure of each part has been specifically described. However, the structure and the like can be changed in various ways within the scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Repeater (repeater device), 2 ... Access point device, 3 ... Terminal (terminal device), 11 ... Antenna, 12 ... Wireless communication processing part, 12a ... Buffer, 13 ... Power management management part, 14 ... Information storage , 15... Power management management unit for terminal (first management unit), 16... Power management management unit for access point device (second management unit)

Claims (4)

In a repeater device that includes a wireless device and wirelessly communicates between the terminal device and the access point device using the wireless device in a time-sharing manner,
A first management unit that controls switching between an active state and a sleep state of the repeater device according to a communication status with the terminal device;
A second management unit that controls switching between an active state and a sleep state of the repeater device according to a communication status with the access point device;
When it is determined that the first data communication with the terminal device occurs within a certain period from the determination time, the first management unit performs the repeater device until the first data communication is completed. Is activated and
When it is determined that the second data communication with the access point device occurs within a certain period from the determination time, the second management unit performs the relay until the second data communication is completed. A repeater device that activates the device.   The first management unit receives the data from the terminal device within a certain period retroactive from the determination time, or when there is data to be transmitted to the terminal device in the buffer memory. The repeater apparatus according to claim 1, wherein it is determined that the data communication is performed.   The second management unit according to claim 1 or 2, wherein the second management unit determines whether or not the second data communication occurs based on a TIM (Traffic Indication Map) element of a beacon received from the access point device. Repeater device. In a sleep control method for a repeater that includes a wireless device and controls switching between an active state and a sleep state of a repeater that wirelessly communicates between the terminal device and the access point device using the wireless device in a time-sharing manner ,
When it is determined that the first data communication with the terminal device occurs within a certain period from the determination time, the step of making the repeater device active until the first data communication is completed;
When it is determined that the second data communication with the access point device occurs within a certain period from the determination time, the second management unit performs the relay until the second data communication is completed. A sleep control method for a repeater, comprising: bringing a device into an active state.

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