KR20040065518A - Apparatus and method for power consumption reduction using power saving polling list - Google Patents

Abstract

PURPOSE: A device for reducing power consumption by using a power-saving polling list and a method therefor are provided to convert a station into an active state when a poll frame is received from a coordinator, to receive the poll frame, and to enable the station to be in the active state only when data is transmitted, thereby remarkably reducing power consumption. CONSTITUTION: If a senior station having a higher polling priority than a predetermined station exists, an accumulated lead time frame transmitter(314) generates an accumulated lead time frame including an accumulated lead time value of the senior station, and transmits the generated accumulated lead time frame to the station. A self lead time frame receiver(315) receives a self lead time frame including a self lead time value consumed for transmitting data of the station. A power-saving polling list generator(316) accumulates the self lead time value included in the self lead time frame to the accumulated lead time value, and generates a power-saving polling list including the accumulated lead time value and the self lead time value.

Description

Apparatus and method for power consumption reduction using power saving polling list}

The present invention relates to an apparatus and method for reducing power consumption in a station on a wireless LAN according to the IEEE 802.11 standard.

According to the IEEE 802.11 standard, a basic service set (BSS) including an access point (AP) is called an infrastructure mode, and a basic service set without an AP is an ad-hoc mode. mode). The set of stations in ad-hoc mode is called an Independent Basic Service Set (IBSS). Among the functions in the MAC (Media Access Control) protocol, only the ad-hoc mode works with the Extended Distributed Coordination Function (EDCF), which provides Distributed Coordination Function (DCF) and Quality Of Service (QOS). There is an enhanced distributed coordination function, which is a MAC protocol data unit (MPDU) transmitted through contention, and this period is called a contention period (CP). In infrastructure mode, there is a hybrid coordination function (HCF) that includes all the functions in ad-hoc mode, provides point coordination function (PCF) and QOS. The period in which all MAC protocol data units are transmitted through the poll is called a contention free period (CFP).

1 is a view showing a conventional DTIM.

The point coordinator may select a CF-Pollable subfield and a CF-Poll Request subfield in an association request frame or a reassociation request frame. Based on this, create a polling list. Each station initiates a point coordination function upon receiving a beacon frame according to the illustrated Delivery Traffic Indication Map (DTIM).

2 is a diagram showing a mechanism of a conventional point adjustment function.

During the de-competition period, stations registered to the polling list wait for polling from the point coordinator. The point coordinator polls the stations on the polling list in increasing AID order. The contention release period may be shortened when a beacon frame arrives delayed due to channel busy. The polled station sends data to the point coordinator. Other stations that are not polled wait for their order to remain active and full powered to receive poll frames. Therefore, in the conventional case, even a station not currently transmitting data consumes a lot of power unnecessarily because it is always in an active state in order to receive a poll frame only once. Here, the station is generally a mobile station, and in this case, power consumption is a serious problem because the station has to be miniaturized and lightweight.

The present invention provides an apparatus and method for reducing power at a station by providing an apparatus and method for generating a power saving polling list.

1 is a view showing a conventional DTIM.

2 is a diagram showing a mechanism of a conventional point adjustment function.

3 is a block diagram of an apparatus for reducing power consumption according to an embodiment of the present invention.

4 is a detailed block diagram of the self time frame generation transmitter 334 of FIG. 3.

FIG. 5 is a detailed configuration diagram of the inactive cumulative time counter 335 of FIG. 3.

FIG. 6 is a detailed configuration diagram of the inactive state total time required counting unit 339 of FIG. 3.

7 illustrates a format of a cumulative time frame according to an embodiment of the present invention.

8 is a diagram illustrating a format of a self time frame according to an embodiment of the present invention.

9 is a diagram illustrating a format of a power saving poll list according to an embodiment of the present invention.

10 is a diagram illustrating a format of a power saving poll frame according to an embodiment of the present invention.

11 is a diagram illustrating a process of transmitting and receiving several frames according to the present invention.

12 is a flowchart of a power saving poll list generation method according to an embodiment of the present invention.

13 is a flowchart of a method for reducing station power consumption according to an embodiment of the present invention.

The apparatus for generating a power saving polling list according to the present invention for solving the technical problem includes a cumulative time value that is a time value for data transmission of the priority station when a priority station having a higher polling rank than a predetermined station exists. A cumulative time frame transmitter for generating a cumulative time frame and transmitting the accumulated time frame to the station; A self time frame receiving unit which receives from the station a self time frame including a self time value which is a time value for data transmission of the station; And a self consuming time value included in the self consuming time frame received by the self consuming time frame receiving unit on the accumulated consuming time value, and including the self consuming time value and the accumulated consuming time value. It includes a power saving polling list generating unit for generating a.

An apparatus for reducing station power consumption according to the present invention for solving the another technical problem is an accumulation state including a cumulative time value, which is a time value for data transmission of a priority station having a higher polling rank than a predetermined station in an active state. A cumulative time frame receiver for receiving a time frame from the coordinator; A self time frame generation transmitter configured to generate a self time frame including a self time frame that is a time value for data transmission of the station, and to transmit the generated self time frame to the coordinator; When the cumulative time value included in the cumulative time frame received by the cumulative time frame receiver is valid, the active state is converted into an inactive state, and in the converted inactive state, a count is calculated for the cumulative time value. An inactive accumulated time counting unit; And a first active state converting unit converting the inactive state into the active state when the count is completed by the inactive state accumulation time counting unit.

According to another aspect of the present invention, there is provided a power consumption reducing apparatus according to an embodiment of the present invention. When a priority station having a higher polling rank than a predetermined station exists, A cumulative time frame including a cumulative time frame is transmitted, the accumulated time frame is transmitted to the station, and a self time frame including a self time value, which is a time value for data transmission of the station, is received from the station. And accumulating self-spent time values included in the received self-spent time frame on the accumulated time value, and generating a power saving polling list including the self-spent time value and the accumulated accumulated time value. Consumption reduction unit; And in the active state, receive the accumulated time frame from the coordinator, and in the active state, generate the self time frame, send the generated self time frame to the coordinator, and receive the received accumulated time frame When the cumulative time value included in the frame is valid, the active state is converted into an inactive state, and in the converted inactive state, the cumulative time value is counted, and when the count ends, the inactive state It includes a station power consumption reduction unit for converting to the active state.

According to another aspect of the present invention, there is provided a method for generating a power saving polling list according to an embodiment of the present invention. When a priority station having a higher polling rank than a predetermined station exists, a cumulative time value for data transmission of the priority station is accumulated. Generating a cumulative time frame including a time value and transmitting the generated time frame to the station; (e) receiving from the station a self time frame comprising a self time value, which is a time value for the data transmission of the station; And (f) accumulating a self expenditure time value included in the received self expiration time frame to the cumulative time required value, and generating a power saving polling list including the self expenditure time value and the accumulated cumulative time value. Steps.

According to another aspect of the present invention, there is provided a method for reducing station power consumption according to an embodiment of the present invention. Receiving a cumulative time frame, including from the coordinator; (d) in the active state, generating a self time frame comprising a self time value, which is a time value for data transmission of the station, and transmitting the generated self time frame to the coordinator; (e) converting the active state into an inactive state when the cumulative time value included in the received cumulative time frame is valid, and counting the cumulative time value in the converted inactive state; And (f) converting the inactive state to the active state when the count ends in the step (e).

According to another aspect of the present invention, there is provided a method for reducing power consumption. (A) When a priority station having a higher polling rank than a predetermined station exists, a cumulative requirement that is a time value for data transmission of the priority station is present. Generating a cumulative time frame including a time value, transmitting the generated cumulative time frame to the station, and generating a self time frame including a self time value which is a time value required for data transmission of the station; Receiving from a station, accumulating a self time value included in the received self time frame in the accumulated time value, and generating a power saving polling list including the self time value and the accumulated time value Making; And (b) in the active state, receive the cumulative time frame from the coordinator, and in the active state, generate the self time frame, send the generated self time frame to the coordinator, and receive the received When the cumulative time value included in the cumulative time frame is valid, the active state is converted into an inactive state, and in the converted inactive state, the cumulative time value is counted and the count is terminated. Converting the inactive state to the active state.

The cumulative time frame according to the present invention for solving the above technical problem is that when there is a priority station having a higher polling rank than a predetermined station, a cumulative time value that is a time value for data transmission of the priority station is set. Includes a recorded cumulative time spent field.

According to the present invention for solving the above technical problem, when a priority station having a higher polling rank than a predetermined station exists, a self-time value, which is a time value for data transmission of the station, is recorded. Characterized in that it comprises a self-spend time field.

In the power saving polling list according to the present invention for solving the above technical problem, when there is a priority station having a higher polling rank than a predetermined station, a cumulative time value, which is a time value for data transmission of the priority station, is recorded. The accumulated time field and the self time field, which is a time value for data transmission of the station, is recorded.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram of an apparatus for reducing power consumption according to an embodiment of the present invention.

The power consumption reducing device is composed of a power saving polling list generating device and a station power consumption reducing device. Since the present invention is mainly applied to the infrastructure mode, the power saving polling list generating apparatus is mounted in the AP (Access Point) 31, and the station power consumption reducing apparatus is a basic service set in which the AP serves as a coordinator. Is mounted on any station 33. Strictly speaking, since the polling list is required for a point coordination function (PCF) or a hybrid coordination function (HCF) with a contention free period (CFP), the AP is a point coordinator in the present invention. (PC, Point Coordinator) or Hybrid Coordinator (HC). Therefore, hereinafter, the AP will be referred to as the coordinator 31.

Since the infrastructure mode is a wireless LAN, the communication path between the coordinator 31 and the station 33 will be a channel 32 using a specific frequency. Thus, if the coordinator 31 or station 33 transmits a frame, all other stations will receive this frame at the same time, and the station that needs this frame will store this frame, and the station that does not need this frame Discard this frame. In other words, the transmission on the WLAN is a kind of broadcast transmission.

The power saving polling list generating device mounted on the coordinator 31 includes a combining request frame receiving unit 311, a polling list generating unit 312, a beacon frame transmitting unit 313, a cumulative time frame transmitting unit 314, and a self-consuming time frame receiving unit. 315, a power saving poll list generating unit 316, a total time required determining unit 317, a power saving poll frame transmitting unit 318, and a data frame receiving storage unit 318.

The association request frame receiver 311 receives an association request frame or a reassociation request frame from arbitrary stations. During the de-competition period, stations that may receive poll frames (also called CF-pol frames in the sense of poll frames used during the de-competition period) and want to be registered in the polling list are CF-polled subfields (CF). Set the Pollable subfield to 1 and the CF-Poll Request subfield to 0. The polling list generating unit 312 generates a polling list from the CF-poll enabled subfield and the CF-polle request subfield which are field values included in the combining request frame or recombination request frame received by the combining request frame receiving unit 311. That is, a station that transmits a combine request frame or a recombination request frame in which the CF-poll enable subfield is set to 1 and the CF-poll request subfield is set to 0 is registered in the polling list. At this time, the first registered station has the highest rank in the polling list and receives the poll frame first. The transmission and reception of the association request frame or reassociation request frame occurs when the station enters the basic service set.

The beacon frame transmitter 313 generates a beacon frame including a period value according to a delivery traffic indication map (DTIM), and transmits the generated beacon frame to the station at a period corresponding to the period value. In accordance with the IEEE 802.11 standard, the coordinator 31 initiates the point coordination function by transmitting a beacon frame at intervals according to the DTIM to stations in the basic service set it manages. In the infrastructure basic service set, the power management mechanism is concentrated in the coordinator 31, or AP. Stations may be inactive for a long time because the AP is burdened with storing the data and delivers the stored data when the station requests. When a station is in a power saving mode, i.e., inactive, it must receive a beacon frame to see if the data frame it is the destination is waiting for or to complete a successful frame handshake with the AP. In this case, the inactive state refers to a state in which the minimum power required for the conversion to the active state is supplied, and the active state refers to a state in which all power is supplied.

In infrastructure mode where an AP coordinates a station, the AP does not need to wake up every time it receives a beacon frame, and because it is not required to stay awake for a certain length of time after receiving a beacon frame, it is an independent basic without an AP. You can save even more power than a service set. However, the station should be awake at the time determined by the AP when multicast frames are delivered. This time is shown in the beacon frame according to the DTIM.

The cumulative time frame transmitter 314 includes a cumulative time value, which is a time value for data transmission of the senior station, when there is a priority station having a higher polling rank than the station 33 equipped with the station power consumption reducing device. A cumulative time frame is generated, and the accumulated time frame is transmitted to the station 33. If there is no priority station having a higher polling rank than the station, the cumulative time value is set to an invalid value, that is, 0, and a cumulative time frame including the set cumulative time value is generated. The generated cumulative time frame is transmitted to the station. That is, the cumulative time frame transmitter 314 is generated by the polling list generator 315 after a period corresponding to the Short InterFrame Space (SIFS) elapses from when the beacon frame transmitted from the beacon frame transmitter is transmitted. Generate a cumulative time frame including a cumulative time value, which is a time value for data transmission of a priority station having a predetermined rank ID, that is, an association ID (AID), on the polling list, and generates the accumulated time frame. The polling list generating unit transmits to the station having the AID of the next rank in the ranking on the polling list generated.

In the first polling list, stations with the CF-Poll Enabled subfield set to 1 and the CF-Poll Request field set to 0 are registered, and the cumulative time field of the station with the highest AID among those stations is registered. Is set to 0. As described above, since there is no priority station having a higher polling rank than the station, there is no cumulative time required for data transmission of the priority station. Here, since the ranking is assigned a series of numbers within the base service set, the lowest number AID will be the highest ranking. The coordinator 31 sends a cumulative time frame to the station with the highest AID among the stations on the polling list. At this time, the station receiving the cumulative time frame stores the cumulative time value included in the cumulative time frame. The station that has stored the cumulative time value is in an inactive state, which is a power saving mode, while the senior station is processing data transmission to the coordinator 31, i.e., for a period corresponding to the stored cumulative time value, which has elapsed. After waking up for data transmission to the coordinator 31 by itself, power can be saved.

The self time frame receiving unit 315 receives from the station 33 a self time frame including a self time value which is a time value for data transmission of the station 33. The station 33 receiving the cumulative time frame transmits its own time frame to the coordinator 31 so as to inform the coordinator 31 of the time it takes to transmit data, and the coordinator 31 takes the self time. Receive a time frame.

The power saving polling list generator 316 accumulates the self time value included in the self time frame received by the self time frame receiving unit 315 in the accumulated time value, and the self time value and the accumulated time required. Create a sleep polling list that contains the values. The coordinator 31, which has received its own time frame, updates the polling list. That is, in the polling list, the self time value included in the self time frame is recorded in the self time field of the station that has transmitted the self time frame, and the AID of the next rank of the rank of the station that has transmitted the self time frame. The cumulative time value of the self-spent time value is accumulated in the cumulative time required field of the station having the time. For example, if the station that sent its own time frame had the highest priority AID, such as 1, 0 would be recorded in the accumulated time field of station 1 in the polling list, and the self time of the station with AID 1 The field will record the time value required for data transmission, such as 10us. Subsequently, if the station sending its own time frame has a second highest rank AID, such as 2, 10us will be recorded in the cumulative time field of the station with AID 2 in the polling list, In the Duration field, the time value required for data transmission, for example 5us, will be recorded. By repeating this process for all stations on the polling list, we complete a sleep polling list with information about when each station will wake up.

The total time spent determining unit 317 accumulates the self-spent time value of the station having the lowest rank ID on the power saving poll list generated by the power saving poll list generation unit 316 for the station having the lowest rank ID. The value accumulated in the time value is determined as the total time required. For example, suppose that a station with AID 1 and a station with AID 2 are registered on a sleep polling list. At this time, as in the above example, it is assumed that 10us is recorded in the self-requirement time field of the station having AID 1 and 5us is recorded in the self-retention time field of the station having AID 2. 10us is recorded in the accumulated time field of the station with AID 2, so the total time value is 5us with the lowest rank ID of the station with the lowest ID. The cumulative time value 10us of the station (the station having AID 2) is 15us, which is a value accumulated. In other words, the total time required value refers to the total time required for data transmission of all stations managed by the coordinator 31 equipped with the power saving polling list generating device, that is, all stations registered in the polling list of the coordinator 31. .

The power saving poll frame transmitter 318 generates and transmits a power saving poll frame including the total time required to the priority station and the station 33 according to the polling order of the power saving poll list generated by the power saving poll list generator 316. do. The data frame reception storage unit 318 receives and stores a data frame from the station 33. For example, the coordinator 31 transmits a power saving poll frame to the station having the highest ranking AID, such as 1, among the stations registered in the polling list. Since the station with AID 1 has been polled, it starts transmitting data, and all other stations go into sleep mode. At this time, among the stations registered in the polling list, the station having the second highest rank AID, for example, 2, inputs a cumulative time value stored in its local timer and starts the timer. When the count for the cumulative time duration value is completed, the transition from the power saving mode inactive state to the active state is performed. The AID 2 station, which is in the active state, starts receiving data when it receives a sleep poll frame from the coordinator 31. Repeat this process for all stations registered in the polling list. However, stations whose self time field on the polling list is set to 0, that is, stations which do not have data to transmit, are excluded from polling and remain in an inactive state. Since these stations remain inactive, power savings are maximized.

Subsequent procedures follow the standard. That is, if the AP has buffered multicast frames, they should be sent immediately after the beacon announces the DTIM. If there is one or more multicast frames to be transmitted, the AP may indicate this by setting more data bits in the frame control field of each multicast frame except the last to be transmitted. The station requests delivery of buffered frames by sending power save poll frames to the AP. The AP will respond to each sleep poll frame with a frame with more data bits set. When the station receives a data frame with more set data bits, for each of these received data frames, it is required to send a power saving poll frame to the AP. The AP, which is the coordinator operating the contention release period, uses the contention release period to deliver buffered frames to CF-pollable stations.

The station power consumption reduction apparatus mounted in the station 33 includes a periodic active state conversion unit 331, a beacon frame receiver 332, a cumulative time frame receiver 333, a self time frame generation transmitter 334, and an inactive state. Accumulated time counting unit 335, first active state converting unit 336, power saving poll frame receiving unit 337, data frame transmitting unit 338, inactive state total time required counting unit 339, and second active state The conversion unit 3310 is configured.

The periodic active state conversion unit 331 converts the inactive state converted by the inactive state cumulative time counting unit 335 into an active state for each cycle according to the DTIM. As described above, the active state refers to a state in which full power is being supplied, and the inactive state refers to a state in which the minimum power required for conversion to the active state is supplied. The period value according to DTIM is recorded in the beacon frame received immediately before, and each station enters this value into its local timer, counts it, and when the count ends, each station becomes active. Beacon frames can be received.

The beacon frame receiving unit 332 receives a beacon frame including a period value according to the DTIM from the coordinator 31 in the active state converted by the periodic active state conversion unit 333. As noted above, this period value tells when to wake up to receive the next beacon frame.

In the active state, the cumulative time frame receiving unit 333 receives, from the coordinator 31, a cumulative time frame including a cumulative time value, which is a time value for data transmission of a priority station having a higher polling rank than the 33. Receive. For example, if the station 33 receiving the cumulative time frame has the second highest rank, for example if the AID is two, then the AID of the priority station is one. At this time, the cumulative time frame receiving unit 333 receives a time value required for data transmission of a station having an AID of 1, for example, a cumulative time frame in which 10us is recorded.

The self-running time frame generation transmitter 334 generates a self-running time frame including a self-running time value which is a time value for the data transmission of the self 33 in an active state, and adjusts the generated self-running time frame. 31). For example, if the time required for the station 33 with the AID 2 to transmit data to the coordinator 31 is 5 us, the self-used time frame recorded with 5 us is transmitted to the coordinator 31.

When the cumulative time value included in the cumulative time frame received by the cumulative time frame receiver 333 is valid, the cumulative time counting unit 335 of the inactive state converts the active state into an inactive state and converts the converted inactive state. In the above, the accumulated time value is counted. If the accumulated cumulative time value is invalid, it remains active. Here, the inactive state cumulative time counter 335 counts the cumulative time by repeatedly decrementing a predetermined unit value for each count period, for example, 1us.

The first active state converting unit 336 converts the inactive state into the active state when the count is completed by the inactive state accumulation time counting unit 335. For example, if the cumulative time value is 10 us and counts by repeatedly decrementing by 1 us, after counting ten times, the inactive state is converted into the active state. The power saving poll frame receiving unit 337 includes a total power time value including a total time value that is a total time value for data transmission of all stations managed by the operator 31 in the active state converted by the first active state conversion unit 336. Receive a poll frame. The data frame transmitter 338 generates and transmits a data frame to the coordinator 31 after a time corresponding to SIFS has elapsed from when the poll frame received by the power saving poll frame receiver 337 is received.

For example, if the station 33 receiving the cumulative time frame is the station having the highest rank, for example, if the station has an AID of 1, since there is no priority station, the cumulative time is zero. At this time, the coordinator 31 first transmits a power saving poll frame to a station having an AID of 1, and the station which transmits the power saving poll frame starts data transmission. Subsequently, if the station 33 receiving the cumulative time frame is the second highest ranking station, for example, if the station has an AID of 2, the station having the AID of 1, which is a priority station, is accumulated. The time required is 10us. At this time, the coordinator 31 transmits the poll frame to the station having the AID of 2 at the time when 10us has elapsed from the time of transmitting the poll frame to the station having the AID of 1, and the station having transmitted the poll frame starts data transmission. do. Thus, the station storing the cumulative time value 10us is in an inactive state, which is a power saving mode, while the senior station is processing data transmission to the coordinator 31, i.e., during the 10us period during the period corresponding to the stored cumulative time value. After 10us has elapsed, it is converted into an active state for data transmission to the coordinator 31. When 10us, the time when the coordinator 31 finishes receiving data from the station with the AID of 1, elapses, the poll frame transmits the power saving poll frame to the station with the AID of 2. The AID 2 station, which is in the active state, starts receiving data when it receives a sleep poll frame from the coordinator 31. Repeat this process for all stations registered in the polling list. However, stations whose self time field on the polling list is set to 0, that is, stations which do not have data to transmit, are excluded from polling and remain in an inactive state. Since these stations remain inactive, power savings are maximized.

When the data frame transmitting unit 338 transmits a data frame, the inactive state total duration time counting unit 339 converts the active state converted by the first active state conversion unit 336 into an inactive state, and a total time required value. Deducts the accumulated time value and self time, and counts the total time value deducted from the converted inactive state. The second active state converting unit 3310 converts the inactive state into the active state when the count is completed by the inactive state total time required counting unit 339.

When data transmission of all stations managed by the coordinator 31 is completed, the coordinator 31 should transmit the buffered data to the destination station. Thus, at the time when the data transmission of all stations is completed, each station must be in an active state to receive the data transmitted from the coordinator 31. However, the station that has completed the data transmission does not perform an activity requiring an active state such as data transmission / reception until the completion of data transmission of all stations. Therefore, when the data transmission is completed, the station is converted to the inactive state immediately. Then, to find out when to change back to the active state, the total time value deducted from the inactive state is counted. Here, the deducted total time required value is a value obtained by subtracting the cumulative time value and the self time required from the total time required value. The total time required value is the total time required for data transmission of the station managed by the coordinator 31, and the time point at which the data transmission of the station is completed is the time corresponding to the sum of the accumulated time value and the self time required value. Since this time has elapsed, a count should be taken for the total time value deducted. For example, if the total time value is 30us, the cumulative time value received by a station is 15us, and the self-time value of this station is 5us, then this station is inactive at the time it completes data transmission. Since the time to complete the data transmission is the time 15us + 5us = 20us has elapsed, by counting 30us-20us = 10us, it is precisely active when the data transmission of all stations managed by the coordinator 31 is completed. Will be converted to. Similar to the inactive accumulated time counting unit, the inactive total time counting unit 339 counts by repeatedly decrementing a predetermined unit value for each count period from the deducted total required time value. However, the counting method may be implemented in other forms without departing from the essential characteristics of the present invention. For example, instead of counting in the downward manner as described above, the counting may be performed in the upward manner. That is, starting from 0us, it can be implemented by increasing by 1us for each count. Applying the method to the above example (when the total time value is 30us, the cumulative time value received by a station is 15us, and the self-time value of this station is 5us), the station uses an up-counter counter. For reference, at 15us, it transitions from inactive state to active state, transmits data for 5us, and goes back into inactive state. The station then references the up-counter counter and transitions from inactive to active again at 30us.

4 is a detailed block diagram of the self time frame generation transmitter 334 of FIG. 3.

The self time frame generation transmitter 334 includes a self time frame generator 41 and a self time frame transmitter 42.

The self time frame generation transmitter 41 calculates a self time value, which is a time value required to transmit a data frame from the station that receives the cumulative time frame to the coordinator, and includes a calculated self time value. Create a frame. The self-running time frame transmitter 42 transmits the self-running time frame generated by the self-running time value generator 41 to the coordinator.

FIG. 5 is a detailed configuration diagram of the inactive cumulative time counter 335 of FIG. 3.

The inactive state cumulative time counting unit 335 includes a first inactive state converting unit 51 and a cumulative time counting unit 52.

The first inactive state converting unit 51 converts the active state into an inactive state when the received cumulative time value is valid in the case where the self-time frame generation transmitter 334 transmits the self-time frame. The cumulative time counting unit 52 counts the cumulative time required in the inactive state converted by the first inactive state converting unit 51. As described above, counting is performed by repeatedly decrementing a predetermined unit value, for example, 1us, for each count period from the accumulated time value.

FIG. 6 is a detailed configuration diagram of the inactive state total time required counting unit 339 of FIG. 3.

The inactive state total time required counting unit 339 includes a second inactive state converting unit 61, a total time required deduction unit 62, and a total time required time counting unit 63.

When the data frame transmitter transmits the data frame, the second inactive state converter 61 converts the active state converted by the first active state converter into an inactive state. When the data frame transmission unit transmits the data frame, the total time deduction unit 62 deducts the accumulated time value and the self time required from the total time value. The total time spent counting unit 63 counts the total time spent value deducted by the total time spent deduction unit 62 in the inactive state converted by the second inactive state converting unit 61.

7 illustrates a format of a cumulative time frame according to an embodiment of the present invention.

The cumulative time frame is the frame transmitted from the coordinator to each station. The coordinator transmits the cumulative time frame to each station in the order registered in the polling list, i.e., in increasing order of AID. The station receiving the cumulative time frame from the coordinator may use the 2-octet AID field of the cumulative time frame to know the destination of the received frame. If it is not the destination, it will discard the received frame. In the cumulative lead time field having a size of one octet of the received cumulative time frame, a cumulative time value required for data transmission of stations having a higher priority AID than that is recorded. Using the value of the cumulative duration field, each station knows when to transition from inactive to active to transmit data. In addition, the fields shown in FIG. 6 are basically required, and a frame control field having a size of 2 octets indicates a type of a frame such as a data frame, a control frame, or a management frame, and a basic service set having a size of 6 octets. The ID (BSS ID) field indicates the ID of the basic service set, and the frame check sequence field of 4 octets indicates the frame check order according to the IEEE 802 LAN standard.

8 is a diagram illustrating a format of a self time frame according to an embodiment of the present invention.

The self time frame is a frame transmitted from each station to the coordinator. The station receiving the cumulative time frame from the coordinator transmits its self time frame to the coordinator in an acknowledgment (ACK). At this time, the time required for data transmission from the station to the coordinator is calculated, and the calculated value is recorded in the self lead time field of 1 octet size of the self time frame. In addition, the field shown in FIG. 6 is basically required, and a frame control field having a size of 2 octets indicates a type of a frame such as a data frame, a control frame, a management frame, and a receiver address having a size of 6 octets. The Address field indicates the recipient address to receive the response frame, the 2-octet AID field indicates the ID of the station in the basic service set, and the 4-octet Frame Check Sequence field indicates the IEEE 802 LAN standard. Frame inspection procedure according to the present invention.

9 is a diagram illustrating a format of a power saving poll list according to an embodiment of the present invention.

The power saving poll list is a cumulative lead time field and a self lead time field added to an existing poll list. The coordinator sends a cumulative time frame to each station to indicate the time each station should transition from the inactive state to the active state. In addition, each station transmits its own time frame to the coordinator to inform the coordinator of the time it takes to transmit data. The coordinator receiving the self time frame completes the accumulated time field and the self time field of the polling list by using the self time field of the received self time frame. Looking at the polling list shown, it can be seen that the stations participating in the contention control period are stations with AIDs of 2, 5, 14, 28, and 29, respectively.

The value of the cumulative time field of the station having the AID of 2 is 0, and the value of the self time field is 10us. Since the station with the AID of 2 is the highest station, and there is no priority station, the value of the accumulated time field is zero. Since the value of the self time field is 10 us, it can be seen that in the case of a station having an AID of 2, the time required for transmitting data to the AP is calculated as 10 us. The value of the accumulated time field of the station having an AID of 5 is 10us, and the value of the self time field is 0. Since the self-retention time of the station having a priority station AID of 2 is 10 us, the value of the accumulated time field is 10 us. Since the value of the self time field is 0, it can be seen that there is no data to transmit in the case of the station having an AID of 5. Later, stations with AID 5 are excluded from polling and remain inactive. The value of the accumulated time field of the station having an AID of 14 is 10 us, and the value of the self time field is 8 us. Since the self-required time of the station having the priority station AID 2 and the station AID 5 is 10us and 0, respectively, the value of the accumulated time field is 10us. Since the value of the self-required time field is 8 us, it can be seen that for the station having an AID of 14, the time required for transmitting data to the AP is calculated as 8 us. The value of the cumulative time field of the station with an AID of 28 is 18 us, and the value of the self time field is zero. Since the self-required time of the station of the priority station AID 2, the station AID 5, and the station AID 14 is 10us, 0, 8us, the value of the accumulated time field is 18us. Since the value of the self time field is 0, in the case of the station having an AID of 28, it can be seen that there is no data to transmit. Later, the station with AID 28 is excluded from polling and remains inactive. The value of the accumulated time field of the station having the AID of 29 is 18 us and the value of the self time field is 17 us. The stations in the priority station AID 2, station AID 5, station AID 14, and station AID 28 are 10us, 0, 8us, and 0, respectively. do. Since the value of the self time field is 17 us, it can be seen that in the case of a station having an AID of 29, the time required to transmit data to the AP is calculated to be 17 us. In this case, the total time required value is 17us of the self time value of the station having the lowest rank ID (the station with AID 29) to the cumulative time value 18us of the station having the lowest rank ID (the station with AID 29). The accumulated value is 35us. This total time duration value is then recorded in the power saving poll frame shown in FIG. 10 so that each station can know when it should transition to an active state in order to receive data.

10 is a diagram illustrating a format of a power saving poll frame according to an embodiment of the present invention.

The sleep poll frame is a poll frame sent from the coordinator to each station. The coordinator transmits power saving full frames to each station in the order registered in the polling list, i.e., in increasing order of AID. The station receiving the sleep poll frame from the coordinator can use the two octet AID field of the sleep poll frame to know the destination of the received frame. If it is not the destination, it will discard the received frame. In the received power saving poll frame, the total lead time field of 1 octet size records the total time value for data transmission of all stations managed by the coordinator. Using the value of the Total Time Spent field, each station can know when it must transition from inactive to active to receive data. In addition, the field shown in FIG. 6 is basically required, and a frame control field having a size of 2 octets indicates a type of a frame such as a data frame, a control frame, or a management frame, and a basic service set having a size of 6 octets. The ID (BSS ID) field indicates the ID of the basic service set, and the 6 octet Transmitter Address (TA) field indicates the MAC address of the station that transmitted the frame. Check Sequence) field indicates a frame check order according to the IEEE 802 LAN standard.

11 is a diagram illustrating a process of transmitting and receiving several frames according to the present invention.

9 is shown based on a network allocation vector (NAV). During the period corresponding to the Priority InterFrame Space (PIFS), when the channel is idle, the coordinator transmits a beacon frame, and all stations in the basic service set receive it. After a period corresponding to the Short InterFrame Space (SIFS), the coordinator sends a cumulative time frame 1 to the station with the highest rank, and the station with the highest rank receives it. After a period corresponding to SIFS, the station with the highest rank transmits its own time frame 1 to the coordinator, which receives it. This means that the coordinator sends a cumulative time frame N to the station with the lowest rank, the station with the lowest rank receives it, and then after a period corresponding to SIFS, the station with the lowest rank takes itself to the coordinator. Send time frame N, and the coordinator continues until it receives it. When the transmission and reception of all cumulative time frames and self time frames is complete, and the sleep poll list is complete, the coordinator sends a sleep poll frame to the station, and the station wakes up to the cumulative time and wakes up to the sleep poll frame. On receipt of the data frame, the data frame is sent to the coordinator. When the transmission of the data frame is completed, it is converted back to the inactive state, and the cumulative time required and the self time required are counted from the total time duration value included in the power saving poll frame. When the count is complete, it transitions back to the active state and receives a data frame from the coordinator.

12 is a flowchart of a power saving poll list generation method according to an embodiment of the present invention.

First, a combine request frame or a reassociation request frame is received from a priority station and a predetermined station (121). Subsequently, a polling list is generated from a predetermined field value included in the received combining request frame or reassembly request frame (122). Subsequently, a beacon frame including a predetermined period value is generated, and the generated beacon frame is transmitted to the station for each period corresponding to the period value (123).

Subsequently, when there is a priority station having a higher polling rank than the station (124), a cumulative time frame including a cumulative time value that is a time value for data transmission of the priority station is generated, and the generated cumulative time is required. A time frame is transmitted to the station (125). If there is no priority station having a higher polling rank than the station (124), the cumulative time value is set to an invalid value, and a cumulative time frame including the set cumulative time value is generated and generated. The accumulated cumulative time frame is transmitted to the station (126). That is, after a time corresponding to SIFS from when a beacon frame is transmitted, a cumulative time frame including a cumulative time value that is a time value for transmitting data of a priority station having an ID of a predetermined rank on the generated polling list is generated. And generate the accumulated cumulative time frame to the station with the next rank ID of the rank on the generated polling list.

Subsequently, a self time frame including a self time value, which is a time value for data transmission of the station, is received from the station (127). Subsequently, the self time value included in the received self time frame is accumulated in the accumulated time value, and a power saving polling list including the self time value and the accumulated time value is generated (step 128). Subsequently, a value obtained by accumulating the self-spent time value of the station having the lowest ID on the generated power saving poll list to the accumulated time value of the station having the lowest ID is determined as the total time value (129). . Subsequently, according to the polling order of the generated power saving polling list, a power saving poll frame including a total required time value is generated and transmitted to the priority station and the station (1210). Subsequently, a data frame is received and stored from the station that has received the power saving poll frame (1211).

13 is a flowchart of a method for reducing station power consumption according to an embodiment of the present invention.

First, every predetermined period, the converted inactive state is converted into an active state (131). Subsequently, in the active state, a beacon frame including a period value corresponding to a period is received from the coordinator (132). Here, the active state refers to a state in which full power is being supplied, and the inactive state refers to a state in which the minimum power required for conversion to the active state is supplied.

Subsequently, in an active state, a cumulative time frame including a cumulative time value, which is a time value for data transmission of a priority station having a higher polling rank than the station, is received from the coordinator (133). Subsequently, in the active state, a self time frame including a self time value, which is a time value for data transmission of the station, is generated, and the generated self time frame is transmitted to the coordinator (114). That is, it calculates a self time value, which is a time value for transmitting a data frame from the station to the coordinator, generates a self time frame including the calculated self time value, and converts the generated self time frame into the coordinator. Transmit (134).

If the cumulative time value included in the received cumulative time frame is valid (135), the active state is converted into an inactive state (136), and in the converted inactive state, the cumulative time value is counted. (137). If the received cumulative time required value is not valid (135), it remains active. Here, a count is counted by repeatedly decrementing from a cumulative required time value by a predetermined unit value for each count period. That is, in the case where the self time frame is transmitted, when the received cumulative time value is valid (135), the active state is converted into an inactive state (136). Next, the cumulative time value is counted in the converted inactive state (137).

Next, when the count ends (138), the inactive state is converted to the active state (139). Subsequently, in the converted active state, a power saving poll frame including a total time value, which is a total time value for data transmission of all stations managed by the coordinator, is received (1310). Subsequently, after a predetermined time from when the received power saving poll frame is received, a data frame is generated and transmitted to the coordinator (1311).

Subsequently, when the data frame is transmitted (1312), the active state is converted to the inactive state, the cumulative time value and the self-consuming time are subtracted from the total time value (1313), and the total time deducted from the converted inactive state. The time value is counted (1314). At this time, the count is repeatedly reduced by a predetermined unit value for each count period from the deducted total time value. Next, when the count ends (1315), the inactive state is converted into the active state (1316). Subsequent procedures follow the standard.

Meanwhile, the above-described embodiments of the present invention can be written as a program that can be executed in a computer, and can be implemented in a general-purpose digital computer that operates the program using a computer-readable recording medium.

In addition, the structure of the data used in the above-described embodiment of the present invention can be recorded on the computer-readable recording medium through various means.

The computer-readable recording medium may include a magnetic storage medium (eg, ROM, floppy disk, hard disk, etc.), an optical reading medium (eg, CD-ROM, DVD, etc.) and a carrier wave (eg, the Internet). Storage medium).

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

According to the present invention, the station remains in the power saving mode in an inactive state, and then becomes active at the time of receiving the sleep poll frame from the coordinator, so that the station remains active only while receiving the sleep poll frame and transmitting data. There is an effect that greatly reduces the power consumption. Furthermore, the station without data to transmit does not need to receive the poll frame, and thus keeps it inactive, thereby minimizing power consumption.

Claims (44)

If there is a priority station having a polling rank higher than a predetermined station, a cumulative time frame including a cumulative time value, which is a time value for data transmission of the first station, is generated, and the accumulated time frame is generated. A cumulative time frame transmitter for transmitting to the station; A self time frame receiving unit which receives from the station a self time frame including a self time value which is a time value for data transmission of the station; And A power saving polling list including the self time value included in the self time frame received by the self time frame receiving unit in the accumulated time value, and including the self time value and the accumulated time value; And a power saving polling list generating unit to generate the power saving polling list generating unit. The method according to claim 1, wherein the cumulative time frame generation transmitter sets the cumulative time value to an invalid value when there is no priority station having a higher polling rank than the station, and sets the accumulated time duration value. And generating a cumulative time frame including a signal, and transmitting the generated cumulative time frame to the station. The method of claim 1, And a beacon frame transmitter configured to generate a beacon frame including a predetermined period value and to transmit the generated beacon frame to the station at a period corresponding to the period value. The method of claim 3, wherein A combining request frame receiving unit which receives a combining request frame or a reassembly request frame from the priority station and the station; And And a polling list generator configured to generate a polling list from a predetermined field value included in a join request frame or a recombination request frame received by the join request frame receiving unit. The polling time frame transmitter of claim 4, wherein the cumulative time frame transmitter has an ID of a predetermined rank on the polling list generated by the polling list generator after a predetermined time from when the beacon frame transmitted by the beacon frame transmitter is transmitted. Generate a cumulative time frame including a cumulative time value, which is a time value for data transmission of a senior station, and generate the accumulated time frame as the next rank of the rank on the polling list generated by the polling list generator. Device for generating a power saving polling list, characterized by transmitting to a station having an ID. The method of claim 1, The total time required is a value obtained by accumulating a self time required value of a station having the lowest ID on the power saving poll list generated by the power saving poll list generator to a cumulative time value of the station having the lowest ID. Characterized in that the total time required to determine the determination portion The method of claim 6, A power saving poll frame transmitter configured to generate and transmit a power saving poll frame including the total required time value to the priority station and the station according to a polling order of the power saving poll list generated by the power saving poll list generator; And And a data frame reception storage unit configured to receive and store a data frame from a station that receives the power saving poll frame transmitted by the power saving poll frame transmitter. A cumulative time frame receiving unit for receiving from the coordinator a cumulative time frame including a cumulative time value, which is a time value for data transmission of a priority station having a higher polling rank than a predetermined station, in an active state; A self time frame generation transmitter configured to generate a self time frame including a self time frame that is a time value for data transmission of the station, and to transmit the generated self time frame to the coordinator; When the cumulative time value included in the cumulative time frame received by the cumulative time frame receiver is valid, the active state is converted into an inactive state in which power consumption is less than that of the active state. An inactive cumulative time counter for counting the cumulative time required; And And a first active state converting unit for converting the inactive state into the active state when the count is completed by the inactive state accumulation time counting unit. 10. The apparatus of claim 8, wherein the active state is a state in which full power is being supplied, and the inactive state is a state in which a minimum power required for conversion to the active state is supplied. The method of claim 8, wherein the self time frame generation transmission unit A self time frame generator for calculating a self time value, which is a time value for transmitting a data frame from the station to the coordinator, and generating a self time frame including the calculated self time value; And And a self time frame transmitter for transmitting the self time frame generated by the self time value generator to a coordinator. The apparatus of claim 8, wherein the inactive state cumulative time counting unit maintains the active state when the received cumulative time required value is not valid. 10. The apparatus of claim 8, wherein the inactive cumulative time counting unit counts by repeatedly decrementing the cumulative time value by a predetermined unit value every count period. The method of claim 8, wherein the cumulative time counting period of the inactive state A first inactive state converting unit converting the active state into the inactive state when the received cumulative time value is valid in the case of transmitting the self time frame by the self time frame generation transmitter; And And a cumulative time counting unit for counting the cumulative time value in the inactive state converted by the first inactive state converting unit. The method of claim 8, A periodic active state conversion unit converting the inactive state converted by the inactive state accumulation time counting unit into an active state every predetermined period; And And a beacon frame receiving unit which receives a beacon frame including a period value corresponding to the period from the coordinator in the active state converted by the periodic active state conversion unit. The method of claim 8, A power saving poll frame receiving unit which receives a power saving poll frame including a total time value which is a total time required for data transmission of all stations managed by the coordinator in an active state converted by the first active state converting unit; And And a data frame transmitter configured to generate and transmit a data frame to the coordinator after a predetermined time from when the power saving poll frame received at the power saving poll frame receiver is received. The method of claim 15, When the data frame is transmitted from the data frame transmitter, the active state converted by the first active state converter is converted into an inactive state, and the cumulative time value and the self time are deducted from the total time required. An inactive total time counting unit for counting the deducted total time required value in the converted inactive state; And And a second active state converting unit converting the inactive state into the active state when the count is completed by the inactive state total time required counting unit. 17. The apparatus of claim 16, wherein the inactive total time counting unit counts by repeatedly decrementing a predetermined unit value for each count period from the deducted total time required value. The method of claim 16, wherein the total amount of time spent counting the inactive state A second inactive state converting unit converting the active state converted by the first active state converting unit into the inactive state when the data frame transmitting unit transmits the data frame; A total time deduction unit for subtracting the cumulative time value and the self time required from the total time value when the data frame is transmitted by the data frame transmitter; And And a total required time counting unit for counting the total required time value deducted from the total required time subtracting unit in the inactive state converted by the second inactive state converting unit. If there is a priority station having a polling rank higher than a predetermined station, a cumulative time frame including a cumulative time value, which is a time value for data transmission of the first station, is generated, and the accumulated time frame is generated. Receiving a self time frame from the station, the self time frame including a self time value, which is a time value for data transmission of the station, from the station; An adjuster power consumption reduction unit accumulating on a cumulative time value and generating a power saving polling list including the self time value and the accumulated time value; And In an active state, receiving the cumulative time frame from the coordinator, in the active state, generating the self time frame, sending the generated self time frame to the coordinator, and receiving the received cumulative time frame When the cumulative time value included in is valid, the active state is converted into an inactive state, and in the converted inactive state, the cumulative time value is counted, and when the count is completed, the inactive state is determined. And a station power consumption reduction unit for converting to the active state. (d) if there is a priority station having a higher polling rank than a predetermined station, generating a cumulative time frame including a cumulative time value, which is a time value for data transmission of the priority station, and generating the accumulated time Transmitting a time frame to the station; (e) receiving from the station a self time frame comprising a self time value, which is a time value for the data transmission of the station; And (f) accumulating a self expenditure time value included in the received self expenditure time frame on the accumulated time value and generating a power saving polling list including the self time value and the accumulated time value; Power saving polling list generation method comprising a. 21. The method of claim 20, wherein the step (d) sets the cumulative time value to an invalid value when the priority station having a higher polling rank than the station does not exist and includes the set cumulative time value. Generating a cumulative time frame, and transmitting the generated cumulative time frame to the station. The method of claim 20, (c) generating a beacon frame including a predetermined period value, and transmitting the generated beacon frame to the station at intervals corresponding to the period value. The method of claim 22, (a) receiving a join request frame or a rejoin request frame from the priority station and the station; And (b) generating a polling list from predetermined field values included in the received combining request frame or recombination request frame. 24. The method of claim 23, wherein step (d) has a predetermined rank ID on the polling list generated in step (b) after a predetermined time from when the beacon frame transmitted in step (c) is transmitted. Generate a cumulative time frame including a cumulative time value, which is a time value for data transmission of a senior station, and generate the accumulated time frame as the next rank of the rank on the polling list generated in step (b). Method for generating a power saving polling list, characterized in that for transmitting to the station having the ID. The method of claim 20, (g) Accumulating the self-spent time value of the station having the lowest rank ID on the power saving polling list generated in step (f) to the accumulated time value of the station having the lowest rank ID. And determining a time value. The method of claim 20, (h) generating and transmitting a power saving poll frame including the total required time value to the priority station and the station according to the polling order of the power saving poll list generated in step (f); And (i) receiving and storing a data frame from a station that has received the power saving poll frame transmitted in step (h). (c) receiving, from the coordinator, a cumulative time frame that includes a cumulative time value that is a time value for data transmission of a priority station having a polling rank higher than a predetermined station in an active state; (d) in the active state, generating a self time frame comprising a self time value, which is a time value for data transmission of the station, and transmitting the generated self time frame to the coordinator; (e) if the cumulative time value included in the received cumulative time frame is valid, converts the active state to an inactive state with less power consumption than the active state; and in the converted inactive state, the cumulative time required Counting the values; And and (f) converting the inactive state to the active state when the count ends in the step (e). 28. The method of claim 27, wherein the active state is a state in which full power is being supplied, and the inactive state is a state in which a minimum power required for conversion to the active state is supplied. The method of claim 27, wherein step (d) (d1) calculating a self time value, which is a time value for transmitting a data frame from the station to the coordinator, and generating a self time frame including the calculated self time value; And (d2) transmitting the self-time frame generated in step (d1) to the coordinator. 28. The method of claim 27, wherein step (e) maintains the active state when the received cumulative time duration value is invalid. 28. The method of claim 27, wherein the step (e) repeats a count by a predetermined unit value every count period from the accumulated time value. The method of claim 27, wherein step (e) (e1) converting the active state to the inactive state when the received cumulative time value is valid in the case of transmitting the self time frame in step (d); And and (e2) counting the accumulated time value in the inactive state converted in the step (e1). The method of claim 27, (a) converting the inactive state converted in the step (e) into an active state at predetermined intervals; And (b) receiving a beacon frame including a period value corresponding to the period from the coordinator in the active state converted in step (a). The method of claim 27, (g) receiving a power saving poll frame including a total required time value which is a total time required for data transmission of all stations managed by the coordinator in the active state converted in the step (f); And and (h) generating and transmitting a data frame with the coordinator after a predetermined time from when the power saving poll frame received in step (g) is received. The method of claim 34, wherein (i) when the data frame is transmitted in step (h), converts the active state converted in step (f) to an inactive state, and calculates the cumulative time value and the self time required from the total time value. Subtracting and counting the deducted total time required value in the converted inactive state; And (j) when the count ends in step (i), converting the inactive state into the active state. 36. The method of claim 35, wherein step (i) counts by repeatedly decrementing a predetermined unit value for each count period from the deducted total time value. 36. The method of claim 35, wherein step (i) (i1) converting the active state converted in the step (f) to the inactive state when the data frame is transmitted in the step (h); (i2) if the data frame is transmitted in step (i1), subtracting the cumulative time value and the self time from the total time value; And and (i3) counting the total time value deducted in step (i2) in the inactive state converted in step (i1). (a) when there is a priority station having a higher polling rank than a predetermined station, generating a cumulative time frame including a cumulative time value, which is a time value for data transmission of the priority station, and generating the accumulated time Transmitting a time frame to the station, receiving a self time frame including a self time value which is a time value for data transmission of the station from the station, and a self time required in the received self time frame Accumulating a value in the accumulated time value and generating a power saving polling list including the self time value and the accumulated time value; And (b) in the active state, receive the cumulative time frame from the coordinator, in the active state, generate the self-use time frame, send the generated self-consuming time frame to the coordinator, and receive the received cumulative When the cumulative time value included in the time frame is valid, the active state is converted into an inactive state, in the converted inactive state, the cumulative time value is counted, and when the count is terminated, the Converting an inactive state to the active state. A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 20 to 38. And a cumulative time field in which a cumulative time value, which is a time value for data transmission of the first station, is recorded when there is a priority station having a higher polling rank than a predetermined station. And a self-requirement time field in which a self-requirement time value, which is a time value for data transmission of the station, is recorded when there is a priority station having a polling rank higher than a predetermined station. If there is a priority station having a higher polling rank than a predetermined station, a cumulative time field, in which a cumulative time value, which is a time value for data transmission of the priority station, is recorded, and a self-time, which is a time value for data transmission of the station, is recorded. And a self polling time field in which a time value is recorded. Power saving poll frame, characterized in that it comprises a total time field recorded in the total time value, which is the total time value for data transmission of all stations managed by the coordinator. A computer-readable recording medium having recorded thereon a data structure comprising the data field of any one of claims 40-43.