KR20150049232A - A method and an apparatus for scheduling of an access point on the Wireless Local Area Network - Google Patents

Abstract

Embodiments of the present invention provide a method and a device for scheduling an access point in wireless local area network (WLAN). According to an embodiment of the present invention, the method for scheduling an access in WLAN comprises the steps of: calculating actual transmission time according to data transmission to a terminal selected by a transmission ranking and basic transmission time ensuring a minimum transmission speed; and setting schedule index information showing a data transmission ranking about the terminal related to other terminals according to a result of a comparison between the calculated actual transmission time and basic transmission time.

Description

[0001] The present invention relates to a method and an apparatus for scheduling an access point in a WLAN,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to data transmission in a wireless local area network (WLAN) environment, and more particularly, to allocating transmission resources while guaranteeing a minimum throughput at an access point.

In an IEEE 802.11 wireless local area network (WLAN) environment, there may be a plurality of terminals to receive services through an access point. Therefore, it is important to distribute the resources equally to a plurality of terminals. It is a resource allocation policy that is contrary to fairness that other terminals are affected by using a resource by a specific terminal.

There are many fair queuing algorithms for implementing this resource allocation policy, among which throughput fairness and airtime fairness are typical.

In WLAN, resources can be allocated fairly to each terminal based on the length of transmission data. This is called throughput fairness. In addition, in WLAN, there are various data rates, and there is a time difference in transmitting data of the same size for each data rate. Airtime fairness is the fairness of resource allocation to each terminal based on transmission time.

1 is a graph showing a relationship between a data transmission rate (throughput) and an actual transmission time (airtime) according to data transmission from an access point to a terminal. As shown in FIG. 1, the higher the data throughput, the smaller the actual transmission time required to transmit data. On the contrary, the lower the throughput, the more the actual transmission time required to transmit data .

Therefore, in the case of throughput fairness, the transmission length of data is made equal to that of a plurality of UEs, so that a large amount of radio resources are allocated in data transmission of a UE having a low data rate. Therefore, a UE having a low data rate allocates a relatively small amount of radio resources to a UE having a high data rate, so that an unreasonable radio resource is allocated to the UE as compared with the performance of the UE. Meanwhile, since the airtime fairness allocates the radio resources based on the data transmission time, the radio resources are fairly allocated according to the transmission rate of the terminal, but the terminal having a low transmission rate guarantees the minimum transmission rate due to the relatively long transmission time Can not.

A problem to be solved by the present invention is to provide a WLAN in which a minimum transmission rate for data transmission to a station with a low transmission rate is given and a resource is allocated fairly to other terminals for the remaining radio resources, To a scheduling method and apparatus.

According to an aspect of the present invention, there is provided a method of scheduling an access point in a wireless local area network (WLAN), the method comprising: Calculating a basic transmission time for ensuring a speed; And setting schedule index information indicating a data transmission order for the terminal related to the other terminals according to a result of the comparison between the calculated actual transmission time and the basic transmission time.

According to another aspect of the present invention, there is provided an apparatus for scheduling an access point in a wireless local area network (WLAN), the apparatus comprising: A transmission time calculating unit for calculating a basic transmission time for ensuring a speed; And a scheduling setting unit for setting schedule index information for determining a data transmission order of the UE in relation to the other UEs according to the result of the comparison between the calculated actual transmission time and the basic transmission time.

According to the present invention, it is possible to provide a minimum transmission rate for a terminal having a low transmission rate in airtime fairness. In addition, since the remaining radio resources are equally distributed to other terminals, it is possible to prevent the transmission time from being delayed to another terminal due to the terminal having a low transmission rate.

BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, wherein like reference numerals designate identical parts.
1 is a graph showing a relationship between a data transmission rate (throughput) and an actual transmission time (airtime) according to data transmission from an access point to a terminal.
2 is a reference diagram illustrating a network system for illustrating the scheduling of an access point in a WLAN in accordance with the present invention.
3 is a flowchart illustrating a scheduling method according to the present invention.
FIG. 4 is a graph showing a relationship between a data transmission rate (throughput) and an actual transmission time (Airtime) according to data transmission to a terminal according to the scheduling method of an access point according to the present invention.
5 is a flowchart of an embodiment for explaining a method of scheduling an access point in a WLAN according to the present invention.
FIG. 6 is a flowchart of an exemplary process for setting the schedule index information shown in FIG.
7 is a block diagram of one embodiment for illustrating an apparatus for scheduling an access point in a WLAN according to the present invention.
8 is a block diagram of an embodiment for explaining the scheduling setting unit shown in FIG.

1 to 8 used to describe the principles of the present invention in this patent disclosure are for illustrative purposes only and are not to be construed as limiting the scope of the invention. Those skilled in the art will appreciate that the principles of the present invention may be implemented in any wireless communication system in which it is properly arranged.

Embodiments of the present invention to be described below are intended to equally distribute transmission resources while ensuring a minimum throughput at an access point.

Figure 2 is a reference diagram illustrating a network system for illustrating the scheduling of an access point in a WLAN according to the present invention, including a network 10, an access point 20 and terminals 1 to n 30, 50). Referring to FIG. 2, the network 10 to which the present invention is applied includes one or more access points 10, one or more terminals 1 to n (30, 40, ...) that can be connected to the access point 10, And 50 connected to the network. Here, the network 10 transmits and receives data to and from the access point 20 and the terminals 1 to n (30, 40, ..., 50) and exchanges data with corresponding destinations through a router (not shown) And may be an Internet network or a mobile communication network.

The access point 20 is connected to the network 10 and wirelessly communicates with the terminals 1 to n (30, 40, ..., 50) existing within a certain distance, and transmits the data received from the terminals 1 to n (30, 40, ..., 50) to the corresponding destination via the network 10 (30, 40, ..., 50).

To this end, the access point 20 includes an antenna (not shown), a receiver (not shown), a transmitter (not shown), a demodulator (not shown), a modulator (not shown), a network interface module (not shown) A memory (not shown), a processor (not shown), and the like.

Signals transmitted from the terminals 1 to n (30, 40, ..., 50) are received via an antenna and the receiver performs various processes including radio frequency to baseband conversion, amplification, analog to digital conversion, . The signals received at the receiver are demodulated in the demodulator according to one or more communication designs or standards. The demodulator performs rate reception, equalization, combining, deinterleaving, decoding, and various other functions required by the received signal format. And the demodulated signal is transmitted to the network 10 through the network interface module.

On the other hand, the data transmitted from the network 10 is received through the network interface module, and the received data is modulated by the modulator and provided to the transmitter. The transmitter formats the received data according to the wireless system standard and transmits the data to the antenna. The antenna wirelessly transmits the formatted data to the terminals 1 to n (30, 40, ..., 50). At this time, the scheduler generates a transmission schedule index corresponding to the sequence number for data transmission according to the scheduling algorithm, with respect to the data to be transmitted to the terminals 1 to n (30, 40, ..., 50) Data is sequentially transmitted to each of the terminals 1 to n (30, 40, ..., 50). Details of the scheduler will be described later.

The memory stores various information for data transmission / reception and, in particular, stores schedule index information related to the present invention.

The processor controls the overall operation of each of the components of the access point 10 described above.

The terminals 1 to n (30, 40, ..., 50) are terminals capable of performing short-range communication wirelessly with an access point 20 existing within a certain distance. For example, a smartphone, a tablet personal computer, a mobile phone, a videophone, an e-book reader, a desktop personal computer, a laptop personal computer, netbook computer, personal digital assistant, portable multimedia player (PMP), MP3 player, mobile medical device, electronic bracelet, electronic necklace, electronic apps, camera, Wearable devices, electronic clocks, wrist watches, smart white appliances such as refrigerators, air conditioners, vacuum cleaners, artificial intelligence robots, TVs, digital video disk (Eg, magnetic resonance angiography (MRA), magnetic resonance imaging (MRI), computed tomography (CT), a photographic machine, an ultrasonic machine, etc.) Navigation device, GPS reception such as a global positioning system receiver, an event data recorder (EDR), a flight data recorder (FDR), a set-top box, a TV box (e.g., Samsung HomeSyncTM, Apple TVTM, or Google TVTM) , Automotive infotainment devices, electronic equipment for ships (eg marine navigation devices, gyro compasses, etc.), avionics, security devices, electronic apparel, electronic keys, camcorders, A game console, a head-mounted display (HMD), a flat panel display device, an electronic album, a piece of furniture or a building / structure including communication functions, an electronic board, , An electronic signature receiving device or a projector, and the like. The terminals according to the embodiment of the present invention are not limited to the above-mentioned devices.

3 is a flowchart for explaining a method of scheduling an access point according to the present invention.

In the present invention, the term for describing the description of the technology in the WLAN over the scheduling of the access point is defined as follows. AP denotes an access point, STA denotes a terminal, SQ denotes a STA transmission service queue, ASQ denotes an active service queue, which means an STA queue in which data to be transmitted by the AP exists, GMT is Guaranteed Minimum Throughput, which means minimum transmission rate, Schedule Index means index of each STA referenced when scheduler selects SQ, T _Airtime means actual transmission time of data to be transmitted, T _BaseAirtime Means a basic transmission time for ensuring a minimum transmission rate of data to be transmitted.

First, a service time (T _Airtime ) at the time of data transmission for a selected STA is calculated (S100). The actual transmission time (T _Airtime ) is calculated using the current transmission rate of the STA selected by the scheduler and the length of data to be transmitted. The following equation (1) represents the actual transmission time (T _Airtime ). ≪ / RTI >

Here, T (k) _Airtime denotes an actual transmission time for any terminal k among terminals 1 to n (30, 40, ..., 50), Length (k) And the PHY Rate (k) denotes a current transmission rate of data to be transmitted to the terminal k.

After step S100, base time (T _BaseAirtime ) for ensuring a minimum throughput at the time of data transmission is calculated (step S102). The base transmission time (T _BaseAirtime ) is calculated using the current transmission rate, the length of the data to be transmitted, and the transmission rate that ensures minimum throughput. The following equation (2) is a formula for calculating the base transmission time (T _BaseAirtime ).

Here, T (k) is _BaseAirtime terminal 1 ~ n (30, 40, ..., 50) sense the primary delivery time on any one of the terminal k, and Min are _GTP terminal 1 ~ n (30, 40, ..., 50) and TP (k) means the current transmission rate for data transmission to terminal k.

After step S102, the time value of the actual transmission time T (k) _Airtime is compared with the time value of the base transmission time T (k) _{BaseAirtime in} step S104.

If the size of the actual transmission time T (k) _Airtime is larger than the size of the base transmission time T (k) _BaseAirtime , the Schedule Index is set as the base transmission time T (k) ) _BaseAirtime ) (step S106). If the size of the actual transmission time (T (k) _Airtime ) is larger than the base transmission time (T (k) _BaseAirtime ), the minimum transmission rate for data transmission to the STA can not be guaranteed. On the other hand, the schedule index is information for determining the data transmission order for the terminals 1 to n (30, 40, ..., 50) receiving data from the access point 10. Therefore, if a minimum transmission rate can not be guaranteed at the time of data transmission to the terminal k, a schedule index is set to a base transmission time (Base time: T (k) _BaseAirtime ). The following equation (3) is a formula for adding a schedule index.

Here, SI (k) + means a schedule index in which the basic transmission time for terminal k among terminal 1 to n (30, 40, ..., 50) is added.

After step S106, the difference value between the actual transmission time and the basic transmission time is added to the shortage time sum value (step S108). The difference between the actual transmission time and the basic transmission time for terminal k corresponds to a short transmission time during which the minimum transmission rate is not guaranteed at the time of data transmission to terminal k. Equation (4) is a formula for calculating the difference between the actual transmission time and the basic transmission time.

Here, T (k) _Insufficient means a difference between the actual transmission time and the basic transmission time for the terminal k. Therefore, T (k) _Insufficient means insufficient transmission time because the minimum transmission rate is not guaranteed in data transmission to terminal k.

The insufficient transmission time for the terminal k is added to the insufficient time sum value. The insufficient time sum value is a value obtained by adding the insufficient transmission time to all the terminals 1 to n (30, 40, ..., 50) Which is the sum of these short transmission times of terminals with insufficient transmission time due to data transmission. The following equation (5) is a formula for calculating the shortage time sum value.

T (Sum) _Insufficient corresponds to the lack of time the integrated _{value, T (1) Insufficient, T} (2) Insufficient, .., T (K) Insufficient value of the difference between the actual transmission time and the transmission time base that is, the primary transfer time And a shortage of data transmission time for each of the corresponding terminals.

After step S108, terminal k is added to the number N (Sum) _Insufficient number of terminals for terminals with insufficient transmission time (step S110). A mobile station whose actual transmission time is larger than the base transmission time is a mobile station whose guaranteed transmission rate is not guaranteed. The terminal k is added to the number of terminals that are not guaranteed the minimum transmission rate according to the data transmission.

On the other hand, if it is determined in step S104 that the size of the actual transmission time is not larger than the size of the base transmission time, the schedule index is increased by the actual transmission time (step S112). Equation (6) is a formula for adding a schedule index.

Here, SI (k) + means a schedule index in which the actual transmission time for terminal k among terminals 1 to n (30, 40, ..., 50) is added.

After step S112, a distribution allocation time for allocating time to the terminal having a short transmission time is added to the schedule index (step S114). Herein, when there are terminals having a short transmission time due to data transmission among terminals other than the terminal k whose transmission rate is lower than the minimum transmission rate, the allocation allocation time is distributed evenly to terminals having a short transmission time . Equation (7) is a formula for calculating the allocation allocation time.

Here, T (k), _distribution means, and, N (Sum) _asq the access point 20 for distribution to delay for assigning to the other terminal transmission rate that the transmission rate in the fast UE k than the minimum transmission rate of the high The number of terminals to which the data to be transmitted exists. Therefore, the meaning of (N (Sum) _asq - N (Sum) _Insufficient ) means that a terminal having data to be transmitted at the access point 20 subtracts terminals whose data rates do not satisfy the minimum transmission rate The total number of terminals satisfying the minimum transmission rate in terms of the transmission rate.

By adding the allocation allocation time calculated in Equation (7) to the time value of the Schedule Index, the transmission order for the terminal k that is faster than the minimum transmission rate is pushed backward by the allocation allocation time added to the schedule index, , The UEs that do not satisfy the minimum transmission rate can prioritize the data transmission order by the allocation allocation time relatively.

[0064] With respect to performing steps S112 and S114 described above, one expression is expressed by the following equation (8).

FIG. 4 is a graph showing a relationship between a data transmission rate (throughput) and an actual transmission time (Airtime) according to data transmission to a terminal according to the scheduling method of an access point according to the present invention. As shown in FIG. 4, the scheduling is performed such that the transmission priority is given to a terminal having a lower transmission rate (Low) than the minimum guarantee transmission speed (Throughput), so that data is transmitted so as to satisfy the minimum guaranteed transmission rate . On the other hand, for a terminal having a transmission rate (Very High) higher than a minimum guaranteed transmission rate, scheduling is performed such that the transmission order is relatively rearranged, so that the transmission rate is reduced within a range that satisfies the minimum guaranteed transmission rate.

5 is a flowchart of an embodiment for explaining a method of scheduling an access point in a WLAN according to the present invention.

A basic transmission time for ensuring an actual transmission time and a minimum transmission throughput according to data transmission to a terminal selected by the transmission order is calculated in operation S200.

For example, if data transmission to one of the terminals 1 to n (30, 40, ..., 50) is determined according to a predetermined transmission order, the actual transmission time for data transmission for the selected terminal k And the basic transmission time. The actual transmission time for terminal k is calculated using Equation (1). Also, a basic transmission time is calculated by using a current transmission rate for the terminal k, a length of data to be transmitted, and a transmission rate to guarantee minimum throughput. The basic transmission time for terminal k is calculated using Equation (2).

After step S200, schedule index information indicating a data transmission order for the corresponding mobile station with respect to the other mobile stations is set according to a result of comparison between the calculated actual transmission time and the basic transmission time (S202). The schedule index information corresponds to a time value for determining the data transmission order of the UE, and the lower the time value, the higher the data transmission order to the UE.

FIG. 6 is a flowchart of an exemplary process for setting the schedule index information shown in FIG.

First, the actual transmission time calculated in step S200 is compared with the basic transmission time (S300).

If the actual transmission time is larger than the value of the basic transmission time, the basic transmission time is added to the time value of the schedule index information and set (S302). For example, if the actual transmission time for data transmission to terminal k is greater than the value of basic transmission time, it means that it takes more time than the time required for data transmission to terminal k. Therefore, it means that the minimum transmission rate for data transmission to the terminal k is not guaranteed. Therefore, when transmitting data to the terminal k, more data transmission time should be allocated than other terminals. As described above, since the schedule index information is information for determining the order for transmitting data to each terminal, the schedule index information for the terminal k has a minimum time value The scheduling index information is added by adding only the basic transmission time. The scheduling index information for the terminal k is set by adding the basic transmission time to the schedule index information using Equation (3).

After the step S302, it is assumed that the difference between the actual transmission time and the basic transmission time is regarded as a short transmission time that is not guaranteed at the minimum transmission rate at the time of data transmission to the corresponding terminal, (Step S304). In step S304, the difference value is added to the shortage time sum value obtained by adding the short transmission times of the terminals having the shortage time. For example, the difference between the actual transmission time and the basic transmission time for terminal k means a short transmission time at which the minimum transmission rate is not guaranteed at the time of data transmission. The difference between the actual transmission time and the basic transmission time for terminal k is calculated using Equation (4). The difference value calculated using Equation (4) is added to the shortage time sum value as a short transmission time for the terminal k. The insufficient time sum value is a value obtained by adding the insufficient transmission times of terminals having insufficient transmission times according to data transmission among all the terminals 1 to n (30, 40, ..., 50) to which the access point 20 transmits data to be. Therefore, as described above, the insufficient transmission time for terminal k is summed with the insufficient transmission time of other terminals using Equation (5) to calculate the insufficient time sum (T (Sum) _Insufficient ).

In addition, in step S304, the terminal is regarded as a terminal whose guaranteed minimum transmission rate is not guaranteed to the terminal, and the corresponding terminal is added to the terminal number value of the terminal having the insufficient transmission time according to the data transmission among the other terminals. A mobile station whose actual transmission time is larger than the value of the basic transmission time corresponds to a mobile station whose guaranteed minimum transmission rate is not guaranteed. For example, when the terminal k is a terminal whose guaranteed minimum transmission rate is not guaranteed, the access point 20 transmits data to all of the terminals 1 to n (30, 40, ..., 50) So that the terminal k is included in the number of terminals that are not guaranteed the minimum transmission rate.

On the other hand, if it is determined in step S300 that the actual transmission time is not larger than the value of the basic transmission time, an actual transmission time is added to the time value of the schedule index information, and for the terminals having an insufficient transmission time The allocation allocation time for allocating the sub allocation is added to the time value of the schedule index information (step S306).

For example, the fact that the actual transmission time for data transmission to terminal k is not greater than the value of basic transmission time means that it takes less time to transmit data to terminal k than to other terminals. Therefore, it means that a minimum transmission rate for data transmission to the terminal k is already secured. Therefore, an extra time during the transmission time allocated to the terminal k can be allocated as a time for data transmission to the other terminals. As described above, since the schedule index information is information for determining a rank for transmitting data to each terminal, the schedule index information for the terminal k is made to be slower than that of the other terminals. To this end, the actual allocation time is added to the schedule index information for the terminal k, and the distribution allocation time for allocation to the other terminals having the short transmission time is added to the schedule index information. Accordingly, since the schedule index information for the terminal k is added by the allocation allocation time allocated to the other terminals, the order for data transmission is delayed compared to other terminals. The schedule index information for terminal k is calculated and set using Equation (8). As shown in Equation (8), by adding the calculated allocation allocation time to the time value of the schedule index information, the transmission order for the terminal k that is faster than the minimum transmission rate is pushed backward by the summed allocation allocation time, On the other hand, the terminals that do not satisfy the minimum transmission rate take precedence over the data transmission order by the allocation allocation time relatively.

FIG. 7 is a block diagram of an embodiment for explaining an access point scheduling apparatus in a WLAN according to the present invention, and includes a transmission time calculating unit 300 and a scheduling setting unit 310. FIG. Here, the scheduling device of the access point is a component corresponding to the scheduler (not shown) among the components of the access point 20 of FIG. 2 described above.

The transmission time calculating unit 300 calculates a basic transmission time for ensuring an actual transmission time and a minimum transmission throughput according to data transmission to a terminal selected by the transmission order.

For example, when data transmission to any terminal k of the terminals 1 to n (30, 40, ..., 50) is determined according to a preset transmission order, the transmission time calculator 300 calculates The actual transmission time according to the data transmission is calculated using Equation (1). The transmission time calculating unit 300 calculates a basic transmission time using Equation 2 based on the current transmission rate for the terminal k, the length of the data to be transmitted, and the transmission rate for ensuring minimum throughput . The transmission time calculating unit 300 transmits the calculated actual transmission time and the basic transmission time to the scheduling setting unit 310.

The scheduling setting unit 310 sets up schedule index information for determining a data transmission order of a corresponding terminal related to other terminals according to a result of comparison between the actual transmission time calculated by the transmission time calculator 300 and the basic transmission time .

FIG. 8 is a block diagram of an embodiment for explaining the scheduling configuration unit 310 shown in FIG. 7, and includes a time comparison module 400 and a schedule setting module 410. FIG.

The time comparison module 400 compares the value of the actual transmission time with the value of the basic transmission time, and transmits the comparison result signal to the schedule setting module 410. The time comparison module 400 outputs a comparison signal indicating whether the actual transmission time is greater than the value of the basic transmission time.

When the comparison module 400 receives a comparison signal indicating that the actual transmission time is larger than the value of the basic transmission time, the schedule setting module 410 adds the basic transmission time to the time value of the schedule index information to set the schedule index information do.

For example, if the actual transmission time for data transmission to the terminal k is greater than the value of the basic transmission time, the scheduling module 410 Adds only the basic transmission time to the schedule index information to set the schedule index information. The schedule setting module 410 adds the schedule index information for the terminal k by adding the basic transmission time using Equation (3). The schedule setting module 410 stores the set schedule index information in a predetermined memory (not shown). Here, the predetermined memory may be a storage space provided in the schedule setting module 410, or may correspond to a memory space that is one of the components of the access point 20 described above.

If the actual transmission time for data transmission to the terminal k is larger than the value of the basic transmission time, the schedule setting module 410 sets the difference between the actual transmission time and the basic transmission time as a minimum value at the time of data transmission to the terminal k And the difference value is added to the shortage time sum value obtained by summing the short transmission times of the other terminals having the short transmission time due to the data transmission. To this end, the schedule setting module 410 calculates the difference between the actual transmission time and the basic transmission time for the terminal k using Equation (4). Then, the difference value calculated using Equation (4) is added to the shortage time sum value as the short transmission time for the terminal k, and the shortage time sum value is calculated by summing the short transmission time of the terminals having the short transmission time due to the data transmission Value. Therefore, the schedule setting module 410 calculates the shortage time sum value by adding the insufficient transmission time for the terminal k to the insufficient transmission time of the other terminals using Equation (5).

If the actual transmission time for data transmission to the terminal k is larger than the value of the basic transmission time, the schedule setting module 410 regards the terminal k as a terminal that is not guaranteed the minimum transmission rate for the terminal k, The terminal k is added to the number of terminals for terminals having an insufficient transmission time according to the number of terminals.

On the other hand, when the comparison module 400 receives a comparison signal indicating that the actual transmission time is not greater than the value of the basic transmission time, the schedule setting module 410 adds the actual transmission time to the time value of the schedule index information, To the time value of the schedule index information, the allocation allocation time for allocating to the terminals having the insufficient transmission time due to the data transmission.

For example, if the actual transmission time for data transmission to the terminal k is not greater than the value of the basic transmission time, an extra time in the transmission time allocated to the terminal k is allocated as a time for data transmission to other terminals can do. Accordingly, the schedule setting module 410 sets the schedule index information for the terminal k to be slower than the other terminals. To this end, the schedule setting module 410 adds the actual transmission time to the schedule index information for the terminal k, and adds the allocation allocation time for allocating to the other terminals having the short transmission time to the schedule index information. The schedule setting module 410 calculates and sets the schedule index information for the terminal k using Equation (8). The schedule setting module 410 stores the set schedule index information in a predetermined memory (not shown) as described above.

As described above, a minimum guaranteed transmission rate can be satisfied by scheduling a terminal having a transmission rate lower than a minimum guaranteed transmission rate so that the transmission order takes precedence over other terminals. On the other hand, For a terminal having a transmission rate higher than the rate, data is transmitted within a limit that satisfies the minimum guaranteed transmission rate by scheduling the transmission order to be relatively rearranged by the allocation allocation time.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Do.

Operations according to embodiments of the present invention may be implemented by a single controller. In this case, program instructions for performing various computer-implemented operations may be recorded on a computer-readable medium. The computer-determinable medium may include program instructions, data files, data structures, etc., alone or in combination. The program instructions may be those specially designed and constructed for the present invention or may be available to those skilled in the art. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs or DVDs, magneto-optical media such as floppy disks and ROMs, , Random access memory (RAM), flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. When all or a part of the base station or relay described in the present invention is implemented as a computer program, the computer readable recording medium storing the computer program is also included in the present invention. The scope of the present invention should, therefore, be determined not only by the details of the embodiments described, but also by the appended claims and their equivalents.

20: access point
300: Transmission time calculating section
310: Scheduling setting unit
400: time comparison module
410: schedule setting module

Claims (17)

A scheduling method of an access point in a wireless local area network (WLAN)
Calculating a basic transmission time for ensuring an actual transmission time and a minimum transmission rate according to data transmission to a terminal selected by the transmission order; And
And setting schedule index information indicating a data transmission order for the MS with respect to the other MSs according to a result of comparison between the calculated actual transmission time and the basic transmission time.
The method of claim 1, wherein the calculating of the basic transmission time comprises:
Using the current transmission rate to the terminal for the data, the minimum transmission rate, and the actual transmission time.
3. The method of claim 2,
Wherein the basic transmission time is calculated using the following equation.

Here, the T (k) _BaseAirtime refers to the basic transmission time for data transmission to the user terminal k, and the Min _GTP refers to the minimum transmission rate for the data transmission to the user terminal k, and the TP (k ) _Denotes a current transmission rate for data transmission to the terminal k, and T (k) _Airtime denotes the actual transmission time for data transmission to the terminal k.
The method according to claim 1,
Wherein the schedule index information corresponds to a time value for determining a data transmission order of the UE, and the lower the time value, the higher the data transmission order to the UE.
The method of claim 1, wherein the step of setting the schedule index information comprises:
Comparing the actual transmission time with a value of the basic transmission time; And
Wherein the basic transmission time is added to the time value of the schedule index information if the actual transmission time is larger than the value of the basic transmission time.
6. The method of claim 5, wherein the step of setting the schedule index information comprises:
The mobile station regards the difference between the actual transmission time and the basic transmission time as a short transmission time at which the minimum transmission rate is not guaranteed at the time of data transmission to the terminal, And adding the difference value to the shortage time summed value obtained by summing the time.
6. The method of claim 5, wherein the step of setting the schedule index information comprises:
Further comprising the step of considering the terminal as a terminal not guaranteed the minimum transmission rate and adding the terminal to the terminal number value for other terminals having an insufficient transmission time.
6. The method of claim 5, wherein the step of setting the schedule index information comprises:
If the actual transmission time is not larger than the value of the basic transmission time, adds the actual transmission time to the time value of the schedule index information, and allocates a distribution allocation time for allocating to other terminals having a short transmission time To the time value of the schedule index information.
9. The method of claim 8,
Wherein the schedule index information is set using the following equation.

Here, SI (k) + refers to the schedule index information and, T (k) _Airtime; refers to the actual transmission time for a data transmission to the user terminal k, and, T (Sum) _Insufficient means enough time integrated value , N (Sum) _asq means the number of terminals for the UEs in which data to be transmitted exists in the access point, and N (Sum) _Insufficient means the number of UEs for UEs with a short transmission time.
An access point scheduling apparatus in a wireless local area network (WLAN)
A transmission time calculating unit for calculating a basic transmission time for ensuring an actual transmission time and a minimum transmission rate according to data transmission to a terminal selected by the transmission order; And
And a scheduling setting unit configured to set schedule index information for determining a data transmission order of the terminal related to the other terminals according to a result of comparison between the calculated actual transmission time and the basic transmission time.
11. The apparatus of claim 10, wherein the transmission time calculation unit
Using the current transmission rate to the terminal with respect to the data, the minimum transmission rate, and the actual transmission time.
12. The apparatus of claim 11, wherein the transmission time calculation unit
Wherein the basic transmission time is calculated using the following equation.

Here, the T (k) _BaseAirtime refers to the basic transmission time for data transmission to the user terminal k, and the Min _GTP refers to the minimum transmission rate for the data transmission to the user terminal k, and the TP (k ) _Denotes a current transmission rate for data transmission to the terminal k, and T (k) _Airtime denotes the actual transmission time for data transmission to the terminal k.
The apparatus of claim 10, wherein the scheduling setting unit
A time comparison module for comparing the actual transmission time with the value of the basic transmission time; And
And a schedule setting module to add and set the basic transmission time to a time value of the schedule index information if the actual transmission time is larger than the value of the basic transmission time.
14. The method of claim 13, wherein the schedule setting module
The mobile station regards the difference between the actual transmission time and the basic transmission time as a short transmission time at which the minimum transmission rate is not guaranteed at the time of data transmission to the terminal, And adding the difference value to the shortage time summed value obtained by adding the time.
14. The method of claim 13, wherein the schedule setting module
The terminal is regarded as a terminal not guaranteed the minimum transmission rate for the terminal, and the terminal is added to the terminal number value for other terminals having an insufficient transmission time.
14. The method of claim 13, wherein the schedule setting module
If the actual transmission time is not larger than the value of the basic transmission time, adds the actual transmission time to the time value of the schedule index information, and allocates a distribution allocation time for allocating to other terminals having a short transmission time To the time value of the schedule index information.
17. The method of claim 16, wherein the schedule setting module
And the schedule index information is set using the following equation.

Here, SI (k) + refers to the schedule index information and, T (k) _Airtime; refers to the actual transmission time for a data transmission to the user terminal k, and, T (Sum) _Insufficient means enough time integrated value , N (Sum) _asq means the number of terminals for the UEs in which data to be transmitted exists in the access point, and N (Sum) _Insufficient means the number of UEs for UEs with a short transmission time.

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