KR101094994B1 - Admission control method based on priority access for wireless LANs - Google Patents

Abstract

High priority access categories (ACs) block transmission of low priority ACs when there are packets to send, ensuring that the highest AC always accesses the channel first, adjust the amount of network traffic, and Admission control method based on priority access for WLAN that protects from QoS impact is provided. In the WLAN, each access category flow transmits busy tones having a time length shorter than the random interframe interval in the last slot of the random interframe interval period, and at least one flow that receives the busy tones The packet is transmitted while controlling the priority access by stopping the back off counting operation and blocking the transmission of the packet of the low priority access category flow when the high priority access category flow is new. As the new flow transmits the packet transmission acceptance request data including the traffic information to the access point, based on the traffic information and the measured channel state information, an acceptance request is made according to whether the packet to be transmitted satisfies the acceptance decision condition. Accept or reject

WiFi, Priority Access, Admission Control

Description

Admission control method based on priority access for wireless LANs

The present invention relates to a wireless LAN, and more particularly, to an admission control method based on priority access for a wireless LAN.

IEEE 802.11 WLANs are widely used in wireless approaches because of their ease of deployment and low cost. The IEEE 802.11 standard has defined a MAC (Media Access Control) protocol for channel sharing between terminals. The MAC protocol provides a distributed coordination function (DCF) scheme for contention-based channel access. Unlike conventional wired LANs (in IEEE 802.3 standard), MAC protocols in wireless LANs (in IEEE 802.11 standard) do not detect collisions during transmission. For this reason, the WLAN is controlled by polling each station at an access point to control whether or not it is used, and a DCF based on a point coordinator function (PCF) method that prevents collisions and collision avoidance using random numbers. (Distributed Coordinator Function) method is used. PCF is implemented on DCF, although DCF is mandatory in the IEEE 802.11 standard, PCF is specified as optional.

DCF basically operates with Carrier Sense Multi Access / Collision Avoidance (CSMA / CA). This allows each station to detect a carrier at a normal time to determine channel idle, thereby avoiding urges when transmitting data through a channel shared between multiple stations. To this end, in IEE802.11, there are two waiting times, a distributed inter-frame space (hereinafter referred to as 'DIFS') and a back off as shown in FIG. Inter-Frame Space (hereinafter, referred to as 'IFS') is a time taken to determine that a channel is idle, and control and data packets use different interframe spaces. However, if all stations confirm that the channel is idle during the same DIFS and then immediately send a data packet, frequent collisions may occur. A back off counter may be used for this purpose. In other words, the DCF uses DIFS as a criterion for determining whether the channel is used through the minimum channel idle time, and uses an arbitrary back off time to avoid collision when the channel is accessed. The back off counter is selected at any one of (0 to the number of contention windows-1) every time data is transmitted by the station.If an idle time longer than DIFS occurs, the back off counter is decremented by one every slot time while the channel is idle. do. When the back off counter becomes 0, data may be transmitted. If a transmission failure such as a collision occurs after data transmission by the station, the content of the contention window (the range that the back-off value can take) is twice the existing value, and a new delay counter is set based on this value. The contention window value may be defined as a minimum value and a maximum value. The initial contention window value is set to a minimum value, and the contention window value increased due to transmission failure is limited to the maximum value or less.

Meanwhile, as multimedia applications are widely used, new requirements such as high bandwidth and low average delay in wireless LANs have to be satisfied. In this wireless network environment (IEE802.11), since the DIFS and the contention window are defined identically for all traffic, it is not possible to provide differentiated network services according to the type of traffic.

If you can meet all of these network service needs, there will be no problem, but if not, the solution is to differentiate the services and provide equal satisfaction for all services as possible. It is called (Quality of Service).

However, the IEEE 802.11 MAC protocol does not meet QoS requirements. IEEE 802.11e has been standardized to support multimedia applications with stringent QoS requirements in the IEEE 802.11 MAC protocol. In the IEEE 802.11e standard, traffic is classified into one or more Access Categories (hereinafter, referred to as' AC's) and is defined to have independent DIFS and contention windows for each AC. The IEEE 802.11e standard provides enhanced distributed channel access (EDCA) for this new contention-based channel approach. EDCA supports QoS through four ACs. To differentiate between ACs, EDCA uses parameters such as a minimum contention window, a maximum contention window, and an arbitration inter-frame space (hereinafter referred to as 'AIFS'). EDCA, on the other hand, represents existing DIFS as AIFS.

The types of EDCA access in the IEEE 802.11e standard are classified into voice, video, background, and best effort. The EDCA parameters are referenced to determine the traffic transmission policy. Access types can be further classified into real-time access (voice, video) and non-real-time access (background, best effort).

Previously, the methods of the present invention focused only on the study of service differentiation. However, service differentiation alone is not enough to provide QoS for multimedia applications without a way to efficiently control the amount of network traffic. The present invention focuses on the admission control method for IEEE 802.11e EDCA.

Many admission control methods for IEEE 802.11e EDCA have been proposed. Existing methods are largely divided into model based control method and measurement based control method. The model-based control method uses a mathematical analysis model to determine whether to accept a new flow. Measurement-based methods use measurable information, such as the efficiency of traffic present in the network or the probability of collision, delay to determine acceptance.

Conventional methods of the present invention have several problems. First, mathematical analysis models make some impractical assumptions to calculate the QoS performance of flows present on the network. Therefore, these models do not reflect the characteristics of the actual traffic. Therefore, model-based methods are not always accurate and are difficult to apply in real environments. Second, it is difficult to perform accurate admission control because measurement based methods cannot accurately predict the channel time used after a new flow is accepted into the network. For example, the conventional method allocates bandwidth to the flow and performs admission control based on the success transmission time and the constant parameter SurplusFactor. The SurplusFactor parameter is used to compensate for bandwidth due to expected transmission failure. This is because the conventional method cannot distinguish which AC flow transmits a packet when a collision occurs. Inaccuracy of this parameter leads to poor admission control. Third, the existing methods do not solve the priority reversal problem in which the low priority flow has access to the channel with a smaller backoff counter value than the high priority flow. Since each flow decrements its back off counter value when the channel state is idle, it will have a small value later even though the initial value is large. Since the back off counter value is chosen randomly according to the Uniform distribution, there is no guarantee that a high priority flow always has a smaller back off counter value. Therefore, a low priority flow may send a packet faster than a high priority flow. As a result, high priority traffic may wait longer for channel competition. Fourth, although the admission control method works well, high priority traffic is affected by low priority traffic because low priority traffic can cause collisions with high priority traffic. Finally, since most conventional methods control general data traffic first to guarantee QoS for real-time traffic, performance starvation of data traffic may occur in a high traffic volume environment. However, the conventional IEEE 802.11e EDCA as described above does not meet the real-time requirements of multimedia applications such as voice and video without a way to efficiently control the amount of network traffic.

The present invention is to solve the above-described problems, the high priority access category (AC) is to block the transmission of low priority AC when there is a packet to transmit the highest AC always access the channel first The purpose of the present invention is to provide an admission control method based on a priority access for WLAN that adjusts the amount of network traffic and protects the accepted flow from being affected by QoS from a new flow.

In order to achieve the above object, the admission control method based on the priority access for wireless LAN according to the present invention is that (i) each access category flow in the wireless LAN is shorter than the random interframe space in the last slot of the random interframe space period. Transmit a busy tone having a length of time, the at least one flow receiving the busy tone stops busy tone transmission and back off counting operations, and the high priority access category flow has a lower priority if there is a new flow. Transmitting a packet while controlling priority access in a manner that blocks packet transmission of the access category flow; And (ii) whether the packet to be transmitted satisfies the acceptance decision condition based on the traffic information and the measured channel state information as the new flow transmits the packet transmission acceptance request data including the traffic information to the access point. And accordingly, accepting or rejecting the acceptance request.

The present invention proposes a measurement-based admission control method consisting of two parts, priority access and admission control. First, the performance of the method of the present invention is evaluated through simulation. As a result of the performance evaluation, it is confirmed that the method of the present invention is very effective for guaranteeing QoS of multimedia applications and preventing performance starvation of low priority traffic. Referring to the effects of the present invention as described above in detail. (1) The priority approach blocks the transmission of low priority AC when there is a packet to be transmitted by the high priority AC. This ensures that the highest AC always accesses the channel first. Therefore, the method of the present invention can solve the priority reversal problem. (2) The priority approach ensures channel contention only for AC flows with the same priority. Therefore, the AP can accurately measure channel state information for each priority AC. And it can accurately predict the channel time used after the new flow is accepted. (3) In the conventional method of the present invention, bandwidth allocation for each priority AC has been considerably difficult due to packet collisions between different priority ACs. However, in the method of the present invention, since there is no collision between different priority ACs, bandwidth allocation for each priority AC is possible. In addition, the method of the present invention can prevent starvation of data traffic.

Hereinafter, an admission control method based on priority access for a wireless LAN according to an embodiment of the present invention will be described with reference to the accompanying example drawings. 3 is a flowchart illustrating a priority approach method according to an embodiment of the present invention.

The present invention proposes a measurement-based admission control method consisting of two parts, a priority access process and an admission control process.

IEEE 802.11e has been standardized to support QoS in IEEE 802.11 WLAN. The new standard proposed the concept of a competitive-based enhanced distributed access mechanism (EDCA). EDCA is an enhanced version of DCF. In the DCF, all terminals have the same priority and channel contention. EDCA, however, introduces the concept of an access category (AC) to support several priority levels. The terminal has up to four ACs to support eight user priorities. Each AC is implemented as a separate queue. Each packet has priority information and is passed from the upper layer to the MAC layer and mapped to each AC according to the priority. AC 3, AC 2, AC 1, and AC 0 are used for voice, video, best data, and background traffic, respectively. For traffic differentiation, EDCA uses parameters CWmin [i] (Minimum contention window), CWmax [i] (Maximum contention window), and AIFS [i] (Arbitration inter-frame space) for each AC i (i = 0,…, 3). ). AIFS should be at least DIFS (Distributed inter-frame space) or more and is calculated using AIFSN [i] (Arbitration inter-frame space number). AIFS [i] is SIFS + AIFSN [i] * aSlotTime. SIFS is the length of time in short inter-frame space (SIFS) and aSlotTime is the length of time in one slot. EDCA should have CWmin [i] ≧ Cwmin [j], CWmax [i] ≧ Cwmax [j], AIFSN [i] ≧ AIFSN [j] for 0 ≦ i <j ≦ 3. At least one of these expressions must be ">". EDCA assigns small CWmin, CWmax, and AIFSN values to give higher priority AC higher opportunities in channel competition. Therefore, QoS support in EDCA is achieved by differentiating channel access probability between different priority ACs.

Admission control method based on priority access for wireless LAN according to the present invention requires some modification to EDCA, but the basic operation process is the same as EDCA.

The method of the present invention blocks the transmission of low priority AC when there is a packet for the high priority AC to transmit. That is, low priority ACs do not transmit packets until the high priority AC no longer competes in a channel.

In a conventional EDCA, the flow of some AC first senses the radio channel medium. After detecting the idle of the AIFS period, the flow waits for a random back off time before sending the packet. Unlike the EDCA, the high priority AC should always have a small AIFSN value compared to the low priority AC for the correct operation of the method of the present invention. That is, the relationship AIFSN [i]> AIFSN [j] for 0 ≦ i <j ≦ 3.

The transmission time of busy tone varies depending on packet arrival time and channel condition. In order to determine the busy tone transmission time, the method of the present invention provides the following three parameters: MAC layer packet arrival time (PAT), and last channel busy time (LCBT) due to the last packet transmission. For example, use AIFS of the lowest priority AC (LAIFS). LCBT is set to the time at which the transmission of one packet is completed. However, if a packet collision is detected, the end time of (EIFS-DIFS) is set. This is because the back off operation of EDCA starts after channel idle during (EIFS-DIFS + AIFS). EIFS means extended inter-frame space (EIFS) time.

Two cases should be considered to determine busy tone transmission timing (see FIGS. 1 and 2). In the priority approach process, it is determined whether a new flow has received a busy tone between the LCBT and the PAT (step S303), so that when the flow receives the busy tone between the LCBT and the PAT, that is, the last busy tone reception time is If it is greater than the last channel busy time (LCBT) due to the recent packet transmission, the operation is stopped until the channel busy due to the packet transmission is detected. If not, it works in two cases:

It is determined whether the flow has received a new packet from the upper layer before or after the LCBT, that is, PAT> LCBT (step S304).

As a result of the determination of step S304, when the flow receives a new packet from the upper layer before LCBT (PAT ≤ LCBT), the radio channel medium (hereinafter, referred to as 'channel') for (AIFS-aSlotTime) time with reference to FIG. Detects whether is idle (step S305).

이다.

는 x 이상의 정수 중에서 최소값을 의미한다. 플로우가 전송할 패킷이 없어도 본 발명의 방법에서는 LAIFS 단위로 매체의 번잡 이후에 얼마나 많은 시간이 지났는지 측정해야 한다. 그래서 플로우의 AIFS 감지 시작을 언제 할지 알 수 있다. 이러한 정렬은 같은 우선 순위 AC를 갖는 플로우들간 채널 경쟁이 이루어지는 것을 보장하기 위해 필요하다. 이와 같은 정렬 없이 플로우가 (AIFS - aSlotTime) 동안의 채널 유휴를 감지한 후에 비지 톤을 전송하게 되면 다른 우선 순위 AC의 플로우들과 비지 톤 충돌을 야기할 수 있다. 충돌된 비지 톤을 전송한 플로우들은 동시에 채널 경쟁을 수행하게 되어 다른 우선 순위 AC들간 영향이 존재하게 된다. On the other hand, if the flow receives the packet after LCBT (PAT> LCBT), the flow waits for (LCBT + LAIFS * N + AIFS-aSlotTime) time with reference to FIG. 2 (step S306). N is used to sort the starting point of AIFS by an integer multiple of LAIFS, with the value

to be.

Is the minimum value among integers of x or greater. Even if there is no packet to be transmitted by the flow, the method of the present invention should measure how much time has passed since the media has been crowded in units of LAIFS. So you know when to start the AIFS detection of the flow. This alignment is necessary to ensure channel competition between flows having the same priority AC. Without this sort, if a flow detects channel idle during (AIFS-aSlotTime) and transmits busy tones, it can cause busy tone collisions with flows of other priority ACs. Flows that send collided busy tones perform channel contention at the same time, so that there is an impact between different priority ACs.

While detecting channel idle for (AIFS-aSlotTime) time, it is determined whether a busy tone transmitted by another flow is received before the busy tone transmission time (step S307).

As a result of the determination in step S307, when busy tone is received at any time within its (AIFS-aSlotTime) period, busy tone transmission and backoff are performed by storing the LBT, stopping current channel competition and waiting for packet transmission to occur. The counting process is stopped (step S308). This process ensures that each priority traffic performs its own packet transmission process in order of priority. As long as there is a higher priority AC, the flows of the lower priority AC will detect busy tone within the (AIFS-aSlotTime) period.

If no busy tone is received at any time within its (AIFS-aSlotTime) period, the flow sends a busy tone with a time length shorter than aSlotTime in the last slot of its AIFS period. (Step S309), the back off counter value is decremented until it becomes 0 in slot time units (step S310). In this case, the back off counting process works in the same way as the IEEE 802.11 EDCA.

The flow determines whether the channel is in an idle state (S311).

As a result of the determination in step S311, when the channel is not in the idle state, the flow stores the LCBT (step S312). In contrast, when the channel is in the idle state, a packet (data) is transmitted to the AP (step S313).

In step S314, the flow determines whether the transmission of the packet was successful.

As a result of the determination in step S314, when the transmission of the packet is not successful, the contention window CW indicating the range that the back off counter value can take is increased (step S315).

If the transmission of the packet is successful, the flow stores the LCBT and sets the CW to the minimum CW (step S316).

It is very important to distinguish busy tone from packet transmission to ensure the correct operation of the priority approach. In the present invention, the transmission time is used for classification. The transmission time of one packet requires at least three slots or more due to the physical layer header having a value of 20us. Busy Tones use values smaller than one time slot. Measuring the transmission time can be simple without any additional overhead or cost. This is because all terminals operate in the CSMA / CA method. Each terminal detects a channel state and measures a troublesome time through a channel detection method. Therefore, when the terminal receives a signal, it is possible to distinguish between busy tone and packet transmission.

Ping proposed a fixed priority approach similar to the proposed one. However, this method has the following differences. The main purpose is to ensure only the priority of voice traffic over data traffic. Channel competing voice flows transmit busy tones instead of performing a back off counting operation after confirming channel idle for AIFS time. The busy tone length is equal to the back off counter value. After completing busy tone transmission, the terminal detects a channel. If the channel is still busy, it will stop the current race and if it is idle, send a packet. This allows the flow with the longest busy tone to send a packet. If at least one voice flow is present, all data flows detect busy tones within the AIFS period and stop the channel contention process.

Distributed admission control (DAC) method

Xiao proposed a two-step DAC method. The first step is to protect the voice and video flows that are accepted and operated by the network from being affected by new voice and video flows. The AP measures the channel time (TxTime [i]) used for successful transmission for each AC i during the Beacon period. Then, the channel time TXOPBudget [i] additionally available for AC i flows during the next beacon interval is calculated by the following equation.

TXOPBudget [i] = max (ATL [i] -TxTime [i] * SurplusFactor [i], 0),

Where ATL [i] is the maximum assignable channel time for AC i during the beacon interval and SurplusFactor [i] is used to compensate for possible transmission failures due to collisions. The calculated budget information is delivered to each terminal through a beacon frame.

Each terminal maintains the following variables for each AC i: TxUsed [i], TxSuccess [i], TxLimit [i], TxRemainder [i], and TxMemory [i]. TxUsed [i] is the channel time used by the UE to transmit traffic of AC i (regardless of success or failure). TxSuccess [i] is the channel time used due to successful transmission. The terminal does not transmit a data packet when TxUsed [i] exceeds TxLimit [i]. TxLimit [i] is described below. If packet transmission is blocked for the above reason, the value of TxRemainder [i] is TxLimit [i]-TxUsed [i]. If the packet is sent without blocking, TxRemainder [i] is zero. TxMemory [i] records the channel time used by the terminal's AC i during the beacon interval, which is equal to ∝ * TxMemory [i] + (1-∝) * (TxSuccess [i] * SurplusFactor [i] + TXOPBudget [i]) to be. ∝ is a smoothing factor. TxLimit [i] is TxMemory [i] + TxRemainder [i]. The condition for the acceptance decision is shown in Equation 2 below.

TXOPBudget [i] ≥ Φ * ReqBudget [i]

Where ReqBudget [i] is the budget required for the new flow of AC i and Φ represents the ratio. If Equation 2 is satisfied, the new flow is accepted.

The second step is to protect voice and video flows from the effects of best data traffic. In order to control data transmission according to traffic conditions, the DAC method dynamically adjusts EDCA parameters for data traffic. The standard uses a competing window increase factor 2 when a collision occurs, but the DAC method uses a larger competing window increase factor σ _i for the back off phase i to increase the competing window size faster than the standard. Σ _i <σ _j (σ ₁ ≧ 2) for 1 ≦ _i < _j ≦ L _retries . L _retry indicates the retry limit. When the data frame reaches the retry limit, CWmin and AIFS increase (ie, CWmin = θ * CWmin (θ> 1), AIFS = * AIFS (ψ> 1)). Each time the UE successfully transmits m consecutive packets, CWmin and AIFS decrease (ie, CWmin = CWmin / θ, AIFS = AIFS / ψ).

Admission control, the second process of the present invention, regulates the amount of network traffic and protects the accepted flows from being affected by QoS from new flows. The priority approach is used to make admission control work well. The access point (AP) measures channel state information for each traffic type and performs admission control.

An admission control method for measuring elements representing characteristics of a radio channel and determining whether to accept a new flow based on a priority approach method according to an embodiment of the present invention is described. The method of the present invention is called priority access-based admission control (PAAC). Consider an IEEE 802.11e Basic Service Set (BSS) environment with an infrastructure. The admission control module is located at the AP of the BSS and operates according to the procedure described in the IEEE 802.11e standard. In order to request acceptance before the new flow starts packet transmission, an ADDTS request frame including traffic information as data for packet transmission acceptance request is transmitted to the AP. The admission control module determines whether to accept the new flow by using the channel state information measured by the AP and the traffic information transmitted by the flow. If it does not affect the performance of existing flows existing on the network, the AP sends an ADDTS response frame that accepts the accept request and, if so, sends a reject response to the flow.

In order to make the correct accept decision, the AP must be able to accurately predict the channel time to be used after the new flow is accepted. Accepted new flows result in more collisions and back off times as well as additional transmission time. Hereinafter, a method of calculating channel time required for a new flow will be described.

The AP measures three channel state information for each AC i (i = 0, ..., 3), that is, average channel time utilization U _i , average collision probability P _i , and average back off time B _i per transmission attempt. Channel time utilization is the percentage of time used to transmit each priority traffic. It can be seen that it is not difficult to measure the necessary information in the method of the present invention for the following two reasons. First, in the method of the present invention, since the flows are separated for each AC to perform packet transmission, unlike the conventional measurement-based admission control methods, the admission control method according to the present invention can know which AC is caused when a collision occurs. . Second, the AP can perform channel sensing without additional overhead or cost.

In an embodiment of the present invention, the collision probability is used to calculate the channel time of packets that must be retransmitted due to transmission failure. The priority approach allows us to measure the probability of collision for each AC. The inventors of the DAC method allocate channel time based on successful transmission time and SurplusFactor. This is because it is not known which AC flow caused the collision. Therefore, the DAC method may make a false acceptance decision.

In the present invention, the channel state information is updated at the end of each beacon interval. The AP examines the channel status and measures the total transmission interval time TI _i , the total back off time BP _i , the number of transmissions NT _i , and the number of collisions NC _i for each AC i during the beacon interval BI. The transmission interval is the time required to transmit a packet and is the sum of AIFS, back off, and packet transmission times. The channel time utilization U _i ^measurement , the collision probability P _i ^measurement , and the average backoff time B _i ^measurement measured at the end of the beacon interval are calculated as in Equations 3 to 5 below.

U _i , P _i , and B _i from Equations 3 to 5 are calculated as in Equations 6 to 8 below.

U _i = αU _i + (1-α) U _i ^measurement

P _i = αP _i + (1-α) P _i ^measurement

B _i = αB _i + (1-α) B _i ^measurement

Where α is a smoothing factor with a range of [0, 1]. In the prior art, the influence of α on the performance was studied. Values close to 1 require a long time to reflect the changed network state, and when the value is close to 0, continuous changes in the network state will greatly affect performance. Therefore, the prior art concluded that it is appropriate to select a value of 0.9 as a smoothing factor in an environment in which network state changes occur. Therefore, the smoothing factor 0.9 is used in the present invention.

The new flow k belonging to AC i sends an ADDTS request frame containing the following traffic information to the AP to make an accept request: average packet size L _{i , k} , average data rate ρ _{i, k} , physical layer transmission Rate R _{i , k} . After receiving the ADDTS request frame, the AP calculates the channel time utilization for which flow k is required. N _{i , k} is the number of packets arriving in a new flow k during one beacon interval and is calculated as in Equation 9 below.

Since flows are retransmitted for collided packets, the channel time that requires a new flow must include the packet to be retransmitted. Therefore, the total number of packets to be transmitted is as shown in Equation 10 below.

The channel time required to transmit N _{i, k, total} packets is expressed by Equation 11 below.

ChTime _{i , k} = N _{i , k} T _s + (N _{i , k, total} -N _{i , k} ) T _c + N _{i , k, total} (B _i + AIFS [i]) where T _c And T _s represent the average time when the channel is detected as troublesome due to collisions and successful transmissions, respectively. T _c and T _s for the Basic approach and the RTS / CTS approach, respectively, are given by Equations 12 and 13.

Where H (= PHYhdr + MAChdr) is the packet header transmission time, δ is the propagation delay, and SIFS is the SIFS time. RTS, CTS, and ACK are times for transmitting RTS, CTS, and ACK frames, respectively. L is the packet transmission time and is the ratio of L _{i , k} and R _{i , k} . The channel time usage rate required by the new flow k is expressed by Equation 14 below.

In the priority approach, each priority traffic is separated and performs its own packet transmission process. Channel time is allocated to each traffic type as shown in FIG. 4 to determine acceptance according to the traffic type. C is the total channel time, f ₁ C is the channel time allocated for voice traffic, f ₃ C is the channel time allocated for video traffic, f ₂ C is the channel time allocated for both voice and video traffic, f ₄ C is the channel time allocated for data traffic (f ₁ + f ₂ + f ₃ + f ₄ = 1). These rates can change depending on the state of voice, video and data traffic. Previously proposed methods could not allocate channel time correctly to each traffic type due to collision between different AC traffics. However, since the method of the present invention eliminates collisions between other AC traffics through a priority approach, channel time allocation is possible according to traffic type. Dividing the channel time prevents voice and video traffic from monopolizing the channel time and prevents performance starvation of the data traffic. Data traffic can use channel times not used by voice and video traffic for high channel utilization.

When the AP receives a new ADDTS request frame, the AP determines whether to accept the new flow. The flow k belonging to AC i has an acceptance decision condition as shown in Equation 15 below.

U _i + U _{i , k, requirement} ≤ CT _i

Where CT _i is the channel time utilization that can be used for AC i when a new request is received. This value changes dynamically over time because voice and video traffic share f ₂ C of channel time, and data traffic uses channel time that voice and video traffic do not use. Therefore, CT _i for voice traffic is (f ₁ + f ₂ + f ₃ -maximum (U _video , f ₃ )) video traffic is (f ₁ + f ₂ + f ₃ -Maximum (U _voice , f ₁ )), data traffic is (1-U _voice -U _video ).

If Equation 15 is satisfied then the new flow is accepted and otherwise rejected.

Performance evaluation

Hereinafter, the performance of the method of the present invention will be analyzed. The method of the present invention was implemented using an NS-2 simulator. The system parameters used in the simulations are listed in Table 1. Simulation was performed in an IEEE 802.11a network environment with a data rate of 54 Mbps and a control packet of 6 Mbps. Traffic types consist of three types: voice, video, and data. The parameters related to the traffic are listed in Table 2. The CBR (Constant Bit Rate) model was used for traffic generation. 65% of channel time is allocated for real-time traffic (i.e. f ₁ = ATL [3] = 0.25, f ₂ = 0.0, f ₃ = ATL [2] = 0.4, f ₄ = ATL [1] = 0.35). f ₂ is not allocated for performance comparison with the DAC method. Data traffic may use channel times not used by real-time traffic.

In the method of the present invention, since each priority traffic is separated and performs channel contention separately, the number of flows simultaneously channel contention is smaller than that of the standard MAC. Thus, CWmin and CWmax can be set smaller than the standard. The (CWmin, CWmax) values of the method of the present invention are set to (3, 7), (7, 15) and (15, 511) for voice, video and data traffic respectively.

, θ=1.5, σ_i+1 = 2σ_i(i = 1, 2,...L_재시도 -1)이다.The parameter settings of the DAC method are SurplusFactor = 1.2, Φ = 1, m = 1,

, θ = 1.5, σ _{i + 1} = 2 σ _i (i = 1, 2, ... L _retry -1).

In the simulation, we consider the basic approach and single-hop WLAN network environment with uplink traffic. The terminal has one flow for each of voice, video, and data traffic. The simulation time is 120 seconds. Table 1 lists the system parameters and Table 2 lists the traffic parameters.

parameter value Data bit rate 54 Mbps Control bit rate 6 Mbps Slot time 9 us SIFS 16 us Retry limit 7 Transmission delay 1 us MAC header 26 Octets FCS 4 Octets PHY PLCP Preamble Length 16 us PHY PLCP header length 5 Octets ACK 14 Octets Beacon spacing 200 ms

parameter voice video data AIFSN 2 4 7 CWmin 7 15 31 CWmax 15 31 1023 Packet Size (Octets) 120 1000 1500 Inter arrival time (ms) 10 12.5 12.5 Bit rate (Kbps) 96 640 960 Channel time (%) 25 40 35

The main performance factors are efficiency, delay, and channel time utilization. The delay is the time that elapses from the moment the packet arrives in the MAC layer queue to the successful transmission to the destination.

5 shows the channel time utilization obtained from equation (14) for the new flow. In this figure, the network accepts all new flows because no admission control method is used. Voice, video and data New flows for each traffic arrive at the network periodically, every 10 seconds. In Figure 4, the estimated ratio is the sum of the channel time utilization measured when k-1 flows compete with the channel and the channel time utilization obtained from Equation 14 when the new kth flow requests acceptance. Allocated ratio is the channel time utilization measured after the new kth flow is accepted. This figure shows that the channel time utilization increases almost linearly, and shows good agreement at steady state. When there is a lot of traffic, the rates do not match well. This is because the channel time of the low priority traffic is reduced by using the channel time of the low priority traffic for the high priority traffic. However, if there is no available channel time, the new flow is blocked by the admission control method of the present invention, so it is not necessary to consider the mismatch. This figure shows that the channel time utilization obtained from Equation 14 for the new flow is justified and that the method of the present invention can make a correct acceptance decision.

6-10 show the performance when the admission control method is used. The arrival pattern of each traffic type is as follows. At first there is no flow running on the network. Voice starts at 2 seconds, video starts at 4 seconds, data starts at 6 seconds, and one flow arrives at the network periodically every 6 seconds. In other words, the voice is 2 seconds, 8 seconds, 14 seconds,... And video is 4 seconds, 10 seconds, 16 seconds,... , Data is 6 seconds, 12 seconds, 18 seconds,... To arrive. In addition, the start time of each flow is delayed by a randomly selected time according to the uniform distribution in the range of [0s, 0.5s].

6 shows the channel time utilization of the method of the present invention. When the traffic is low, high data rate data traffic uses more channel time than other traffic types. However, as the number of flows increases, the channel time used by data traffic decreases. This is because, in the method of the present invention, high priority traffic has priority over channel access over low priority traffic. That is, in order to satisfy the QoS requirements of high priority traffic, the method of the present invention differentiates low priority traffic and allocates channel time to high priority traffic. From this figure, real-time traffic uses the channel time allocated in Table 2. This means that performance starvation of data traffic can be avoided.

7 shows the change of TxLimit and TxUsed values according to the simulation time of the first accepted flow of voice and video traffic in the DAC method. In this figure, the unit of the Y axis is the channel time ratio, not the channel time. For readability, two plots with different proportions of the Y-axis are shown. When TXOPBudget is used up, TxLimit converges to TxSuccess * SurplusFactor. This ensures that the terminal uses the same amount of channel time even during the next beacon interval. TxUsed is limited by TxLimit because the packet transmission is blocked when the TxUsed value exceeds TxLimit. This can lead to reduced performance. As the number of flows increases, the probability of collision increases, so traffic requires more channel time to provide QoS. However, because the network is calculated based on SurplusFactor with a constant TxLimit value, it cannot provide enough channel time for real-time traffic. In order to provide more channel time, SurplusFactor must be large and the number of flows accepted will be smaller. From this figure, it can be seen that it is difficult to determine the optimal SurplusFactor value throughout the network.

8 and 9 show the efficiency according to the simulation time, FIG. 8 shows the change of voice and video traffic efficiency, and FIG. 9 shows the efficiency of data traffic. The result of the method of the present invention has a pattern almost similar to that of FIG. When the traffic is low, there is little difference in performance between the method of the present invention and the DAC method. The efficiency of voice and video traffic of the PAAC method is stable and always meets the requirements regardless of the amount of network traffic. However, data traffic changes when traffic is heavy. This is because voice and video traffic use more channel time to retransmit collided packets. In the DAC method, the efficiency of video traffic is not stable. When there is heavy traffic, video traffic requires more channel time due to collisions, but as shown in Figures 8 and 9, TxLimit cannot use more channel time. Therefore, the DAC method does not satisfy the efficiency requirement from the point where TxLimit and TxUsed cross in FIGS. 8 and 9.

 10 shows the delay performance over the simulation time. It can be seen that the delay is kept low when the traffic is low. However, as the traffic volume increases, it can be seen that the method of the present invention performs better than the DAC method for all priority traffics. The delay of the PAAC method does not increase because of low priority traffic. The main reason for voice traffic is due to the increase in channel contention of voice flows. However, in the case of video traffic, the performance is affected by the number of voice flows and the number of video flows. The delay of the DAC method increases rapidly. This is because all flows attempt to access the channel and cause conflicts with each other.

As shown in Figs. 6 to 10, the method of the present invention accepted a total of 15 voice flows, 15 video flows, and 12 data flows. However, the DAC method accepted 15 voice flows and 14 video flows. Although both methods have the same traffic pattern and maximum channel time for each traffic type, the PAAC method of the present invention accepts one more video flow than the DAC method. This means that the PAAC method is efficient to accommodate more traffic. No more flows are accepted after 92 seconds in the PAAC method. When the thirteenth new data flow arrives at 78 seconds, about 98% of the channel time is already used by the accepted flow (ie, about 20% voice, about 34% video, about 44% data). Therefore, the new data flow is rejected. Similarly, at 92 and 94 seconds, voice and video traffic use about 24% and 39% of channel time, respectively, and the network cannot allow 16th new voice and video traffic. In the DAC method, video and voice flows arrive at 88 and 92 seconds, respectively, and are not accepted because the required budget value is larger than the TXOPBudeget value.

11 shows the delay performance of one voice flow according to the amount of traffic. In order to confirm that the method of the present invention can solve the priority reversal problem, there is only one voice flow and the arrival pattern of the remaining traffic was simulated in the above-mentioned environment. Channel time for video traffic was increased to allow 20 video flows. The delay of the DAC method worsens as the amount of traffic increases. This is because all priority flows attempt to access the channel and collide with each other. However, the PAAC method remains almost the same regardless of the amount of traffic and always meets the requirements of voice traffic. This is because the method of the present invention ensures that the highest AC flow performs the channel access first. However, at moderate traffic volume, it increases slightly compared to low. This is because voice flows with new packets arriving during the transmission interval of the video or data flow have to wait until packet transmission is detected.

IEEE 802.11e EDCA does not meet the QoS requirements of multimedia applications and causes high performance, resulting in performance starvation of low priority traffic. The present invention proposes a measurement based admission control method to improve QoS performance. The method of the present invention consists of two parts. The first part is a priority approach that uses busy tone. Each priority traffic is separated and performed separately for channel competition. Therefore, the AP can accurately measure the channel state of each priority traffic. The measured information is then used in the second part, the admission control method. Simulation results show that the method of the present invention is very effective, guarantees QoS requirements of multimedia applications such as voice and video traffic, and prevents performance starvation of data traffic.

Although the present invention has been described as a specific preferred embodiment, the present invention is not limited to the above-described embodiments, and the present invention is not limited to the above-described embodiments without departing from the gist of the present invention as claimed in the claims. Anyone with a variety of variations will be possible.

The admission control method based on the priority access for WLAN according to the present invention can be used for channel access and data admission control in WLAN.

1 and 2 illustrate a criterion for determining a busy tone transmission time according to an embodiment of the present invention.

3 is a flowchart illustrating a priority access control process according to an embodiment of the present invention.

4 is a diagram illustrating channel time allocated to each traffic type.

5 is a graph showing channel time usage rates that require a new flow.

6 to 10 are diagrams showing the performance when the admission control method is used.

11 is a diagram illustrating delay performance of one voice flow according to the amount of traffic.

Claims (5)

(i) In the WLAN, each access category flow transmits a busy tone having a length of time shorter than the random interframe space in the last slot of the random interframe space period, and at least one flow that receives the busy tone is busy Tone transmission and back-off counting operations are stopped, and high priority and low priority are relative ranks, and high priority access category flows block packet transmission of low priority access category flows when there is a new flow. Transmitting a packet while controlling priority access to the network; And (ii) as the new flow transmits the packet transmission acceptance request data including the traffic information to the access point according to whether the packet to be transmitted satisfies the acceptance decision condition based on the traffic information and the measured channel state information. Admission control method based on priority access for WLAN, including accepting or rejecting an accept request. The method of claim 1, wherein step (i) (i-1) determining whether a new flow has received busy tone between the last channel busy time and the packet arrival time; (i-2) if the new flow receives a busy tone between the last channel busy time and the packet arrival time, stopping operation until a channel busy due to packet transmission is detected; (i-3) determining whether the new flow has received a new packet before the last channel busy time or after the last channel busy time; (i-4) if the new flow receives a new packet before the last channel busy time, detecting whether the wireless channel medium is in a first idle state for any random interframe interval-one slot time; (i-5) if the new flow receives the new packet after the last channel busy time, waiting for (LCBT + LAIFS * N + AIFS-aSlotTime) time, wherein the last channel busy time (LCBT) Is the last channel busy time, the arbitration inter-frame space (AIFS) is an arbitrary inter-frame interval, the AIFS of the lowest priority AC (LAIFS) is the lowest priority access category, and N is the LAIFS start time of the AIFS. Used to sort by an integer multiple of

ego,

Is a minimum value among integers equal to or greater than x, the packet arrival time (PAT) is the MAC layer packet arrival time, and aSlotTime is the time of one slot; (i-6) detecting whether the channel is idle for (random interframe interval-one slot time) and determining whether a busy tone transmitted by another flow is received by the new flow before the busy tone transmission time point; (i-7) When receiving busy tone at any time within the (random interframe interval-one slot time) period of the new flow, storing the last channel busy time, stopping current channel competition and waiting for packet transmission to occur In a manner, stopping busy busy transmission and back off counting processes; (i-8) If no busy tone is received at any time within the (random interframe space minus one slot time) period of the new flow, the new flow is less than one slot time in the last slot of its random interframe interval. After transmitting busy tone with a short length of time, decreasing the back off counter value until zero in slot time units; (i-9) the new flow includes determining whether a currently operating channel is in a second idle state; (i-10) storing the last channel busy time or transmitting the packet to an access point depending on whether the channel is in the second idle state; And (i-11) The new flow increases a contention window indicating a range that the back off counter value can take or stores the last channel busy time and sets the contention window to a minimum contention window according to whether the new packet has been completed. Admission control method based on the priority access for WLAN comprising the step of setting to. The method of claim 1, wherein step (ii) (ii-1) a new flow generates an Add Traffic Stream (ADDTS) request frame for a packet transfer acceptance request including traffic information having an average packet size, an average data rate, and a physical layer transfer rate as data for the packet transfer acceptance request; Transmitting to the access point; (ii-2) measuring, by the access point, channel state information with average channel time utilization, average collision probability, and average back off time per transmission attempt; (ii-3) Using the channel state information measured by the access point and the traffic information transmitted by the new flow, transmit an ADDTS response frame that accepts an accept request according to whether a packet to be transmitted satisfies an acceptance decision condition. Or sending a rejection response to the new flow. 4. The method of claim 3, wherein the channel state information is channel state information for each access category i (where i = 0, 1, 2, 3), wherein the access category i (where i = 0, 1, 2, 3). said average channel time usage included in the channel state information (U _i), the average collision probability (P _i), and the average back-off time (B _i) per transmission attempt equation s U _i = αU _i + (1 -α) U _i ^measurement , P _i = αP _i + (1-α) P _i ^measurement , B _i = αB _i + (1-α) B _i ^measurement , where α is [0, 1] The channel time utilization (U _i ^measurement ), the collision probability (P _i ^measurement ), and the average back off time (B _i ^measurement ) measured at the end of the beacon interval, are smoothing factors with a range

,

, And

Wherein the channel state information is updated at the end of each beacon interval, wherein the TI _i , BP _i , NT _i , and NC _i are each access category during the beacon interval BI in the channel state, respectively. A total transmission interval time, total back off time, the number of transmissions, and the number of collisions by i, the transmission time is the admission control method based on the priority access for the wireless LAN, which is the sum of the random inter-frame interval, back off, packet transmission time. delete

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