KR100414078B1 - Traffic management method for mobile communication system - Google Patents

Abstract

The present invention reduces the signal to interference (S / I) on the wireless channel in the wireless VoIP system of the CDMA method using a leak-bucket, a traffic management method, and the quality of voice of the real-time traffic voice signal (OoS) The present invention relates to a traffic management method of a mobile communication system, which can improve the utilization of radio resources by guaranteeing a service, and in transmitting a voice signal by using a voice of internet protocol (VoIP) technology in a mobile communication system, In the MS, a first step of coding the input analog voice signal into a digital signal; A second step of shaping the digital signal into a packet and then shaping by a leaky bucket method to prevent disconnection of a call even when talk subscribers of all subscribers occur at a specific time at the same time; A third step of spreading the shaped voice traffic and wirelessly outputting the same can be achieved.

Description

Traffic management method in mobile communication system {TRAFFIC MANAGEMENT METHOD FOR MOBILE COMMUNICATION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a traffic management method of a mobile communication system. In particular, by using a leaky bucket, which is a traffic management method, a signal to interference (S / I) on a wireless channel is reduced in a wireless VoIP system of a CDMA method. The present invention relates to a traffic management method of a mobile communication system, by which the OoS (Quality of Service) of a voice signal, which is real-time traffic, can be improved.

1 is a diagram illustrating a configuration of a mobile communication system including a plurality of terminals and a base station. In the case of a forward channel, since the base station controls the traffic, there is no problem of multiple access. That is, by scheduling the radio resources according to the channel characteristics at the base station, collisions can be avoided.

However, in case of the reverse channel, since each terminal cannot know the state of the radio channel, a collision occurs inevitably.

In addition, the capacity of the mobile communication system using the CDMA largely depends on how the power is controlled in the wireless section. In the case of the IS-95, the power is controlled so that the total power of the reverse wireless channel is not exceeded by a predetermined amount or more. Maximizing the capacity of the channel.

Therefore, as the number of subscribers increases, the power used by the corresponding terminal decreases, resulting in poor voice quality.

On the other hand, in the case of transmitting a voice signal using the VoIP technology in the wireless section, as shown in Figure 2 by transmitting data only in the talk spurt (talk spurt), the power on the radio is increased.

However, the wireless section is not used by one terminal, but because a plurality of subscribers communicate with the base station through different services, in order to maximize the overall CDMA capacity, power control must be performed in harmony with other subscribers. In addition, it must be compatible with other types of services in order to use the wireless channel efficiently.

The wireless VoIP technology accommodates 2.5 times as many subscribers as the voice subscriber using one channel exclusively for the statistical multiplexing gain of the wireless section. In other words, the use of VOIP technology for wireless means a 2.5x increase in channel.

However, this problem also occurs. For example, when a talk spurt of all subscribers occurs at the same time in synchronization at a specific time, PAPR (Peak) in Orthogonal Frequency Division Multiplexing (OFDM) occurs. Problems such as Average Power Ratio occur.

In this case, the power of the wireless channel is greatly increased, and almost all calls are disconnected.

Accordingly, the present invention has been created to solve the above-mentioned conventional problems, using a leaky bucket (leak-bucket) traffic management method, to reduce the S / I on the radio channel in a wireless VoIP system of the CDMA method It is an object of the present invention to provide a traffic management method of a mobile communication system that can improve the utilization of radio resources by guaranteeing a quality of service (OoS) of voice signals, which are real-time traffic.

In order to achieve the above object, the present invention provides a method for transmitting a voice signal using a Voice of Internet Protocol (VoIP) technology in a mobile communication system. Step 1; A second step of shaping the digital signal into a packet and then shaping by a leaky bucket method to prevent disconnection of a call even when talk subscribers of all subscribers occur at a specific time at the same time; And spreading the shaped voice traffic to wirelessly output the third step.

1 is an exemplary view showing the configuration of a mobile communication system composed of a plurality of terminals and one base station.

2 is an exemplary view shown to explain the characteristics of a voice signal.

Figure 3 is an exemplary view for explaining the characteristics of the liquid bucket circuit applied to the traffic management method according to the present invention.

4A and 4B are diagrams illustrating a configuration of a wireless VoIP system to which a liquid bucket is applied when a wireless section operates in a circuit-base according to the present invention.

5A and 5B are diagrams illustrating a configuration of a wireless VoIP system to which a liquid bucket is applied when a wireless section operates in a packet-base according to the present invention.

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

First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components have the same reference numerals as much as possible even if displayed on different drawings.

Also, in the following description, numerous specific details, such as specific processing flows, are set forth in order to provide a more general understanding of the invention, and it is to be understood that the invention may be practiced without these specific details. It will be obvious to them.

3 is an exemplary view for explaining the characteristics of the liquid bucket applied to the traffic management method according to the present invention. As shown in FIG. 3, the packet generation is controlled using the liquid bucket for the generated voice traffic.

In general, the amount of packets output by the modem between [0, t] can be expressed by Equation 1 below.

A (0, t) = B + Rt

Here, R is the output rate of the average packet, B is the peak cell rate (peak cell rate), the type of traffic output over the air is determined by B and R.

In other words, the shape of the spectrum on the radio is determined by B (maximum cell rate) and R (average packet output rate). In order to determine B and R, the present invention uses the following information.

(1) Radio channel status (multi-path fading, long-term fading, pilot signal, channel information transmitted from the base station to the terminal).

(2) The number of subscribers occupying the channel (transmitted from the base station to the terminal).

(3) Type of service using a wireless channel (transmitted from base station to terminal).

Next, FIGS. 4A and 4B are schematic diagrams of a wireless VoIP system applying a liquid bucket when a wireless section operates on a circuit-base according to the present invention. First, analog voice is input from a terminal MS. When converted into a digital signal through the codec (11).

The digital signal is made into a packet through the packet generation unit 12, and then shaped by the leaky bucket method in the traffic generation unit 13, spread through the modem 14, and then wirelessly output.

Accordingly, the base station BS receives the signal, despreads it through the modem 21, creates an RTP / RTCP segment using time information, converts it into UDP / IP, and converts it into a public land mobile network (PLMN). Will be sent.

Here, RTP / RTCP is used to guarantee QoS in the network for voice signals requiring real time, and the time information used is used to reproduce voice signals in the receiver.

The procedure for reproducing the voice is as follows.

d _i = (1-u) d _i-1 + u (r _i -t _i )

v _i = (1-u) v _i-1 + u | r _i -t _i -d _i |

p _i = t _i + d _i + Kv _i

Where p _i : playback time, t _i : packet transmission time, r _i : packet reception time, d _i : average delay time, v _i : delay change time, u: motion average weight (generally 0.01), K: delay margin (typically 4).

Equation 2 is an equation for calculating an average value between a packet transmission time and a reception time, and is calculated using a moving average.

Here, the smaller the u value, the smaller the influence of the current delay on the motion average value.

Equation 3 is a formula for calculating the variance of the delay time.

A moving average of the variance is obtained by using the value of d _i (average delay time) obtained in Equation 2 above. Equation 4 shows a process of determining the reproduction time of the voice packet using the average delay time and the variance obtained in Equations 2 and 3 below.

Here, K is a constant used to set a play time margin, but can be changed depending on the state of the radio channel or the traffic of the network.

In order to determine the reproduction time of the voice packet using Equations 2 to 4, time information on which the voice packet is generated is required. This information is in the header of the RTP segment and can be used.

The reason why the voice packet can be reproduced as described above is possible because the human sensory ability is relatively insensitive to the difference between talk spurt and silence.

In other words, even if the interval between talk spurt and silence is changed according to the wireless channel and the network state, the voice stream recognized by human being does not greatly reject.

Next, FIGS. 5A and 5B are diagrams illustrating a configuration of a wireless VoIP system using a repacket bucket when a wireless section operates in a packet-base according to the present invention. System.

In this case, the terminal generates an RTP / RTCP segment and a UDP segment and transmits a voice packet in a wireless section using IP / PPP. As described above, when the wireless section is divided into packet schemes, the channel usage rate in the wireless section is used. Although statistical multiplexing gain can be obtained, the disadvantage is that the overhead is increased while using the RTP / RTCP, UDP, IP, and PPP protocols.

Therefore, when used in a circuit as shown in FIG. 5, although the efficiency of the radio channel is somewhat lowered, the effect of reducing the protocol overhead may be obtained.

In other words, in the current mobile communication system, voice transmission is performed by the PCM method, but the base station manages bursts to block subscriber access beyond capacity, but has a problem in that the utilization efficiency of the wireless channel is low. It is expected to transmit voice using technology.

However, when VoIP is used, the traffic is transmitted only in the idle period due to the characteristics of the voice signal shown in FIG. 2, and thus it is possible to accommodate 2.5 times as many subscribers as the voice subscriber using one channel exclusively. At the same time, if the sound section occurs, the problem that the call can be disconnected.

Therefore, in the present invention, by applying the Ricky Bucket method to the radio channel, it is possible to prevent the disconnection of the call by appropriately controlling even when the traffic is congested.

As described above, the traffic management method of the mobile communication system of the present invention can not only improve the utilization rate of the wireless channel by using the statistical multiplexing concept but also prevent the degradation of voice quality due to the increase in the number of subscribers. There is.

In addition, the present invention has the advantage of statistically controlling the noise level of the wireless channel has the effect that can be harmonized with other services.

Claims (3)

In transmitting a voice signal using the Voice of Internet Protocol (VoIP) technology in a mobile communication system, In the MS, a first step of coding the input analog voice signal into a digital signal; A second step of shaping the digital signal into a packet and then shaping by a leaky bucket method to prevent disconnection of a call even when talk subscribers of all subscribers occur at a specific time at the same time; And spreading the shaped voice traffic to wirelessly output the third step. 2. The mobile station of claim 1, wherein the repacket bucket includes radio channel conditions (multi-path fading, long-term fading, pilot signals, channel information transmitted from the base station to the terminal), and the number of subscribers occupying the channel (base station to terminal). The maximum cell rate (B) and the average packet output rate (R) according to the type of service using the wireless channel (transmitted from the base station to the terminal). How to manage. The base station receiving voice traffic wirelessly output from the terminal, after despreading the voice traffic, creates a RTP / RTCP segment using time information, converts it into UDP / IP, and converts the PLMN (Public). Traffic management method of a mobile communication system characterized in that the transmission to the land mobile network.