KR100572053B1 - QoS scheme for the video telephony service over 1xEV-DO - Google Patents

Abstract

The present invention relates to a video phone traffic classification method through statistical characteristics analysis of forward link / reverse link traffic and a video phone QoS guarantee method using the same.

In the present invention, statistical characteristics of the forward link / reverse link traffic of mobile terminals using a 1xEV-DO network are analyzed to classify other 1xEV-DO traffic and video telephony traffic in a sector, and the forward link scheduling is performed using the same. As a result, even if 1xEV-DO traffic increases in the sector, the QoS of the videophone service can be guaranteed by providing sufficient bandwidth for the videophone traffic.

In the present invention, since the statistical characteristics of the forward link / reverse link traffic used for videophone traffic classification are information used by the channel card controller or the RLP (Radio Link Protocol) processor, the H / W of the network configuration is not changed. QoS guarantee for video telephony service is possible with minimum S / W change.

1xEV-DO, videophone, QoS guarantee, traffic statistical analysis, symmetry

Description

Video telephony traffic classification method through statistical characteristics analysis of forward link / reverse link traffic and video telephony guarantee method using the same {QoS scheme for the video telephony service over 1xEV-DO}

1 is a diagram illustrating a forward link of a 1xEV-DO network.

2 is a flowchart of the PF scheduler of the 1xEV-DO network.

3A to 3D are diagrams illustrating characteristics of a forward link / reverse link traffic for each service of a 1xEV-DO network.

4 is a flowchart of a method for guaranteeing video telephone service QoS according to the present invention.

FIG. 5 is a detailed view of the parameter update subroutine in the step shown in FIG.

The present invention relates to a video telephony traffic classification method through statistical characteristics analysis of forward link / reverse link traffic and a video telephony QoS guarantee method using the same. More specifically, the forward link / reverse direction of mobile terminals using a 1xEV-DO network is provided. Analyze the statistical characteristics of the link traffic to distinguish other 1xEV-DO traffic from video telephony traffic in the sector, and use it to improve forward link scheduling so that even if 1xEV-DO traffic increases in the sector, A method for guaranteeing QoS of a video telephony service by providing sufficient bandwidth for traffic.

Existing 1x CDMA2000 systems are designed to support voice services in circuit switched mode and medium to low speed data services.

In addition, as the desire for services such as wireless Internet has increased, a system for high-speed packet data communication has been proposed, excluding voice service, which is called 1x-EV DO (1x-Evolution Data Only).

Video telephony service is a core multimedia service in the 3G market, and it is essential to apply QoS guarantee technique for stable video / audio quality due to the characteristics of real-time two-way communication.

However, in the 1xEV-DO network, since there is no parameter to classify the service type for 1xEV-DO traffic, it is impossible to guarantee guaranteed QoS for the video telephony service. Therefore, 1xEV-DO traffic in the sector increases. Therefore, there is a high possibility of serious quality deterioration of the videophone service.

More specifically, as shown in FIG. 1, the forward link (FWD Link) of the 1xEV-DO network is a time division multiple access (TDMA) scheme in each slot (1.67 msec) within the current sector. Select one mobile terminal among the mobile stations receiving the service and transmit the data with the maximum output to the mobile terminal.

In this case, the scheduler performs a function of distributing one shared channel to multiple users.

In order to determine a mobile terminal to receive service in every slot, a channel card controller currently uses a PF scheduler (Proportionally Fair Scheduler).

As shown in FIG. 2, in the PF scheduler, a DRC (Data Rate Control) value transmitted by MSs in each slot and an average data throughput provided by the MSs through a forward link for a predetermined time period are used. The mobile terminal to be serviced in the slot is determined.

The decision variable of the PF scheduler is given by Equation 1.

은 n번째 슬롯 타임에 k번째 이동단말기가 올리는 DRC값이며,

은 k번째 이동단말기가 이전

슬롯 타임 동안 평균적으로 제공받은 순방향링크 데이터 처리량(throughput)으로

의 관계식을 만족한다.here

Is the DRC value raised by the kth mobile terminal at the nth slot time.

Is the kth mobile terminal

Forward link data throughput received on average during slot time

Satisfies the relation

은 n번째 슬롯 타임에 k번째 이동단말기로 보내기 시작하려는 데이터가 있을 때, 해당 데이터의 크기(단위:bits)를 의미한다. 1xEV-DO 네트워크에서는 여러 이동단말기가 하나의 순방향링크를 공유하므로, 한 섹터(sector) 내에 1xEV-DO 네트워크를 사용하는 이동단말기의 수가 증가하면, 전체적으로 각각의 이동단말기가 제공받는 대역폭은 점차 줄어든다.here

Is the size (bits) of the data when there is data to be sent to the k-th mobile terminal at n-th slot time. In a 1xEV-DO network, since multiple mobile terminals share a single forward link, as the number of mobile terminals using a 1xEV-DO network increases in a sector, the bandwidth provided by each mobile terminal gradually decreases.

Due to the characteristics of real-time two-way communication, the video telephone service is significantly degraded in quality of service (voice / video quality and delay) if sufficient bandwidth is not guaranteed.

Therefore, in order to guarantee the quality of video telephony service, even if the number of mobile terminals using other 1xEV-DO network-based services in the sector increases in addition to the mobile terminal using the video telephone service, slots are allocated more frequently for the video telephone traffic, thereby providing sufficient bandwidth. Must be secured.

However, in the 1xEV-DO Network, there is no parameter that can distinguish the service type (video phone, VOD (Video On Demand), MMS (Multimedia Messaging Service, etc.) of mobile terminals using packet data service. Since it is not possible, it is difficult to guarantee QoS of the videophone service.

Therefore, in the current 1xEV-DO network where video telephony traffic cannot be distinguished based on parameters, video telephony traffic is classified and based on this, sufficient bandwidth is allocated to video telephony traffic to guarantee QoS of video telephony service. This is desperately required.

The present invention has been made by the above-described request. In the present situation where it is not possible to determine whether video telephony service is a parameter in the 1xEV-DO network, the forward link / reverse link traffic of mobile terminals using the 1xEV-DO network is present. The purpose of this study is to classify video telephony traffic by analyzing the statistical characteristics and to improve the scheduling algorithm.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

Packet data services currently provided through the 1xEV-DO network include VOD streaming, Multimedia Messaging Center (MMC), MMS, and video telephony.

Unlike services such as VOD streaming, MMC, MMS, etc., which have asymmetrical forward link / reverse link traffic characteristics that downloads (forward links) or only uploads (reverse links) content from the mobile terminal, as shown in FIG. Reverse link), which is a real-time bidirectional communication, has a symmetrical forward link / reverse link traffic characteristic in which each mobile terminal in a call transmits and receives a large amount of data at the same time.

Therefore, in the present invention, first, the video phone traffic by measuring the symmetry of the forward / reverse link traffic for a predetermined time for all mobile terminals using the 1xEV-DO network with reference to Figure 4 or 5 We will describe the technique of classifying.

The symmetry measurement of the forward link / reverse link traffic in the present invention considers both the measurement using a channel card controller or a RLP processor.

The DRC value and RRI (reverse rate indicator) values transmitted by the MSs are used to measure the forward link / reverse link symmetry in the channel card controller.

슬롯 타임(=1.67 msec ×

) 동안의 순방향링크 및 역방향링크 평균 데이터 처리량(throughput)은 수학식 2 및 수학식 3과 같이 계산한다(S452).From nth slot time of kth mobile terminal

Slot time (= 1.67 msec ×

The average data throughput of the forward link and the reverse link during () is calculated as in Equations 2 and 3 (S452).

이고(S454),

와

은 각각 n번째 슬롯 타임에서 k번째 이동단말기가 요청하는 패킷의 크기와 전송률이다.here

And (S454),

Wow

Are the size and transmission rate of the packet requested by the k-th mobile terminal at the n-th slot time, respectively.

이고

와

은 각각 n번째 슬롯타임에서 k번째 이동단말기가 전송하는 패킷의 크기와 전송률이다. here

ego

Wow

Are the size and transmission rate of the packet transmitted by the k-th mobile terminal at n-th slot time, respectively.

The size of the reverse link packet is currently fixed at 26.67 msec in the 1xEV-DO network.

은 n번째 슬롯 타임에서 k번째 이동단말기로 새롭게 보낼 데이터가 없는 경우에는 0으로 설정된다.In Equations 2 and 3

Is set to 0 when there is no data to be sent to the k-th mobile terminal at n-th slot time.

)는 순방향링크/역방향링크 데이터 처리량

의 함수로 표현된다.In the case of classifying video telephony traffic with the symmetry measured using the channel card controller, the symmetry of the forward link / reverse link traffic of the k-th mobile terminal at the n-th slot time (

) Is the forward link / reverse link data throughput.

It is expressed as a function of.

The following Equation shows several usable function types and is expressed by Equation 4, which is the mean of the difference, and Equation 5, which is the difference of the mean (S458).

을 기준값 λ와 비교하여 각각의 1xEV-DO 트래픽의 화상전화 트래픽 여부를 판단한다.The channel card controller may be represented by Equation 4 or 5

Is compared with the reference value [lambda] to determine whether each 1xEV-DO traffic is videophone traffic.

At this time, the service showing the symmetrical forward link / reverse link traffic characteristics has a mobile game in addition to the video call, but the video call traffic is significantly higher than the average data throughput of the mobile game as the average data throughput of the forward link / reverse link is more than 40kbps. Because of the characteristics, considering whether the calculated symmetry and the forward link / reverse link average data throughput together, it is determined whether the video call traffic as follows.

값과 L값은 충분한 평균화 효과를 얻을 수 있도록 실험적으로 결정하고,

값은 실험을 통하여 다음 조건을 만족하도록 결정 한다.Of Equations 2 to 5

Values and L values are determined experimentally to achieve sufficient averaging effect,

The value is determined by experiment to satisfy the following conditions.

는 상기 화상전화 트래픽 판단 기법의 오차 허용수준이다.here

Is an error tolerance level of the video telephone traffic determination technique.

The forward link / reverse link symmetry measurement using the RLP processor uses the size of an RLP packet transmitted / received by each mobile station every slot time.

슬롯 타임(=1.67msec×

) 이전부터 n번째 슬롯 타임까지의 순방향링크 및 역방향링크 평균 데이터 처리량은 수학식 6 및 수학식 7과 같이 계산한다(S452).of the kth mobile terminal

Slot time (= 1.67 msec ×

The average data throughput of the forward link and the reverse link from the previous time to the nth slot time is calculated as in Equations 6 and 7 (S452).

은 n번째 슬롯 타임에 k번째 이동단말기의 순간(instantaneous) 순방향 RLP 패킷 크기이다.here

Is the instantaneous forward RLP packet size of the k-th mobile terminal at n-th slot time.

은 n번째 슬롯 타임에 k번째 이동단말기의 순간 역방향 RLP 패킷 크기이다.here

Is the instantaneous reverse RLP packet size of the k-th mobile terminal at n-th slot time.

)는 순방향링크/역방향링크 데이터 처리량

의 함수로

와 같이 표현된다.In case of classifying video call traffic through symmetry measurement using RLP processor, the symmetry of forward link / reverse link traffic of k-th mobile terminal at n-th slot time (

) Is the forward link / reverse link data throughput.

As a function of

It is expressed as

The following equations show some usable function types, expressed as Equation 8, which is the mean of the differences, and as Equation 9, which is the difference between the means (S458).

는 상기 채널카드 컨트롤러를 이용한 대칭도 측정과 동일한 방식으로 설정한다.Parameters related to video phone traffic classification based on Equation 8 or Equation 9

Is set in the same manner as the symmetry measurement using the channel card controller.

Next, a technique for guaranteeing video telephony QoS using forward link / reverse link traffic statistical characteristic analysis obtained as described above will be described.

In the video telephony QoS guarantee scheme according to the present invention, the QoS of the video telephony service is assigned by assigning a high priority to video telephony traffic using the symmetry calculated through the channel card controller or the RLP processor and the forward link / reverse link data throughput. More specifically, the g-fair scheduler or symmetry and forward link / reverse link data throughput, which adjusts the weighting for each mobile station periodically using symmetry and forward link / reverse link average data throughput values. Use the PF scheduler biased by the function of.

The decision variable used to determine the mobile terminal to which the slot is allocated at the nth slot time in the g-fair scheduler is expressed by Equation 10 (S420a).

는 임의의 함수,

는 k번째 이동단말기의 가중치이다.here

Is a random function,

Is the weight of the k-th mobile terminal.

와 순방향링크/역방향링크 평균 데이터 처리량 값을 이용하여 각 이동단말기의 가중치에 해당하는

값을 주기적으로 변경하여 화상전화 서비스 중인 이동단말기에 대하여 더 높은 결정변수 값이 나오도록 조절한다.When the g-fair scheduler is used to guarantee video telephony QoS, the forward link / reverse link symmetry of each mobile station calculated by the channel card controller or the RLP processor

Corresponding to the weight of each mobile station by using the average data throughput value

The value is changed periodically so that a higher decision variable value is obtained for the mobile terminal in the video call service.

는

와 같이 대칭도와 순방향링크/역방향링크 데이터 처리량의 함수로 설정된다.Weight by actual mobile terminal

Is

It is set as a function of symmetry and forward link / reverse link data throughput.

The following equations show several types of functions that can be applied. The hard decision weight is represented by Equation 11, the multi-step weight is represented by Equation 12, and the soft decision weight is represented by Equation 11. Expressed in Equation 13, other function types may also be considered.

는 순방향링크/역방향링크 각각의 데이터 처리량을 고려한 가중치 값으로, 순방향링크/역방향링크 데이터 처리량 값이 크면 클수록 높은 가중치가 주어지도록 구성된다.here

Is a weight value considering the data throughput of each of the forward link and the reverse link, and the larger the forward / reverse link data throughput value is configured to give a higher weight.

개의 값을 가지는

함수의 예를 보 인다.The following is applicable,

With values

An example of a function is shown.

를 제외한 함수 유형이나 기타 변수들은

의 양자화 레벨 등을 고려하여 향후 모의실험이나 필드테스트 등을 통하여 최적화한다.here

Function types and other variables except

In order to optimize the quantization level, the simulations and field tests will be performed in the future.

와 상술한 바와 같이 계산된 대칭도와 순방향링크/역방향링크 데이터 처리량의 함수

로 표현되는 바이어스값과의 적절한 가중치를 통하여 슬롯 할당을 위한 새로운 결정변수를 계산한다.QoS guarantee method of video telephony service using biased PF scheduler is used as determinant of PF scheduler.

And a function of symmetry and forward link / reverse link data throughput calculated as described above.

The new determinant for slot allocation is computed by appropriate weighting with the bias value

That is, the determinant of the biased PF scheduler is given by Equation 13 (S420b).

를 0으로 설정하면, 바이어스된 PF 스케줄러는 종래의 PF 스케줄러와 동일하게 동작하며, 1로 설정하면 매우 높은 확률로 화상전화 서비스를 이용하는 이동단말기들에게만 순방향링크 슬롯을 할당한다.Weight value

If set to 0, the biased PF scheduler operates in the same manner as the conventional PF scheduler. If set to 1, forward link slots are allocated only to mobile terminals using a video telephony service with a very high probability.

는 g-fair 스케줄러의 경우와 마찬가지로 강성결정, 다중스텝, 연성결정 등의 다양한 함수 유형을 가질 수 있다.remind

Like the g-fair scheduler, can have various function types such as stiffness, multistep, and soft decision.

As described above, since the statistical characteristics of the forward link / reverse link traffic used to determine whether to use the videophone service in the present invention is information previously used by the channel card controller or the RLP processor, the H / It is possible to guarantee QoS for video telephony service with minimal S / W change without W change.

Claims (15)

Calculating an average data throughput of the forward link and the reverse link by using a DRC (Data Rate Control) value and a RRI (Reverse Rate Indicator) value transmitted from each MS in a channel card controller; Symmetry of Forward and Reverse Link Traffics of Mobile Terminals (

) And the forward link and reverse link data throughput

As a function of, In the channel card controller

Is compared with the reference value [lambda], and the average data traffic value of the forward link and the reverse link

Reference value

In comparison with

together with A video telephony traffic classification method using statistical characteristics analysis of forward link / reverse link traffic comprising determining whether each 1xEV-DO traffic is video call traffic. The method of claim 1, wherein the n th slot time of the k th mobile terminal is transferred from

The forward link average data throughput during slot time is calculated by Equation (15).

(here

,

Wow

Are the size and rate of packets requested by the kth mobile station at the nth slot time, respectively.) The method of claim 1 or 2, wherein the n-th slot time of the k-th mobile terminal is transferred from

The reverse link average data throughput during the slot time is calculated by Equation 16, characterized in that the video call traffic classification method through the statistical characteristics analysis of the forward link / reverse link traffic.

(here

,

Wow

Are the size and rate of packets transmitted by the kth mobile station at nth slot time, respectively. The method of claim 3, wherein the symmetry of the k-th mobile terminal at the n-th slot time

Is a function of forward link / reverse link data throughput. The video telephony traffic classification method using statistical characteristics analysis of the forward link / reverse link traffic. The method of claim 4, wherein the symmetry

A video telephone traffic classification method using statistical characteristics analysis of the forward link / reverse link traffic, characterized in that expressed as either the equation (17) of the average of the difference in the forward link / reverse link data throughput.

Calculating an average data throughput of a forward link and a reverse link by using a size of an RLP packet transmitted / received at each slot time by a radio link protocol (RLP) processor; Symmetry of Forward and Reverse Link Traffics of Mobile Terminals (

) And the forward link and reverse link data throughput

As a function of, In the RLP processor

Is compared with the reference value [lambda], and the average value of the forward and reverse link data traffic values

Reference value

In comparison with

together with A video telephony traffic classification method using statistical characteristics analysis of forward link / reverse link traffic comprising determining whether each 1xEV-DO traffic is video call traffic. The method of claim 6, wherein the n-th slot time of the k-th mobile terminal is transferred from

The forward link average data throughput during the slot time is calculated by Equation 19, characterized in that the video call traffic classification method through the statistical characteristics analysis of the forward link / reverse link traffic.

(here

Is the instantaneous forward link RLP packet size of the k-th mobile terminal at n-th slot time). The method of claim 6 or 7, wherein the n-th slot time of the k-th mobile terminal is transferred from

The reverse link average data throughput during the slot time is calculated by Equation 20, characterized in that the video telephony traffic classification method through the statistical characteristics analysis of the forward link / reverse link traffic.

(here

Is the instantaneous reverse link RLP packet size of the kth mobile station at nth slot time) The method of claim 8, wherein the symmetry of the k-th mobile terminal at the n-th slot time

Is represented by Equation 21, which is the mean of the difference, or Equation 22, which is the difference between the means.

The method according to claim 1 or 6, Forward link / reverse link symmetry of the mobile terminal

And forward link / reverse link data throughput

Determining variable used to determine the mobile station to be allocated the slot at the nth slot time using

Like this

Is the size and rate of packets requested by the kth mobile station at each nth slot time. Weight of each mobile terminal

The value corresponding to the forward link / reverse link symmetry

And forward link / reverse link data throughput

Function

And periodically changing the value to determine a higher decision variable value for the mobile terminal in the video call service. And assigning a forward link slot to the corresponding mobile terminal by selecting the mobile terminal having the largest value of the decision variable, and using the statistical characteristic analysis of the forward link / reverse link traffic. The method of claim 10, wherein the weight of each mobile terminal

Function used to calculate

The video telephony QoS guarantee method using statistical characteristics analysis of the forward link / reverse link traffic, characterized in that expressed as Equation 23, 24 or 25.

12. The method of claim 11, wherein the forward link / reverse link traffic appears to be a symmetrical feature and a high weight is assigned if the forward link / reverse link data throughput is higher than a reference value.

A video telephony QoS guarantee method using statistical characteristics analysis of forward link / reverse link traffic, wherein the function is expressed as Equation 26.

In a biased Proportionally Fair Scheduler, Forward / reverse link symmetry obtained by and 1 as used as parameters of the PF scheduler.

And forward / reverse link data throughput

Function

Determining a new decision variable value for slot allocation through an appropriate weight with a bias value represented by And assigning a forward link slot to the corresponding mobile terminal by selecting the mobile terminal having the largest value of the decision variable, and using the statistical characteristic analysis of the forward link / reverse link traffic. The method of claim 13, wherein the function is used to calculate a bias value of each mobile terminal.

The video telephony QoS guarantee method using statistical characteristics analysis of the forward link / reverse link traffic, characterized in that expressed as Equation 27, 28 or 29.

15. The method of claim 13, wherein the forward link / reverse link traffic is seen as a symmetrical feature, and is assigned a high weight if the forward link / reverse link data throughput is higher than a reference value.

A video telephony QoS guarantee method using statistical characteristics analysis of the forward link / reverse link traffic, wherein the function is expressed as Equation 30.

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