KR20010064267A - A scheduling method to enhance system capacity and guarantee quality of service in Multicode-CDMA environment with multi-cell - Google Patents

Abstract

PURPOSE: A scheduling method for securing transmission quality and increasing system capacity, in a CDMA(Code Division Multiple Access) cellular environment having a multi-cell structure, is provided to increase the capacity of wireless blocks using location information of a mobile station, and to improve performance. CONSTITUTION: When allocating packets in priority order, the amount of transmission packets of different mobile station of an identical area in a slot to be allocated is confirmed. A transmittable packet number is decided, to prevent a total interruption amount by the mobile station in the identical area from exceeding a preset boundary value.

Description

A scheduling method to enhance system capacity and guarantee quality of service in multicode-CDMA environment with multi-cell in multi-code divisional cellular environment with multi-cell structure

The present invention relates to a scheduling method for guaranteeing transmission quality and increasing system capacity in a multi-code divisional cellular environment having a multi-cell structure. Particularly, the present invention relates to a WISPER protocol considering only a single cell in a next-generation mobile communication system. A scheduling method designed to be suitable for a cellular system in a multi-cell environment by increasing the capacity of a wireless section and improving its performance by using the location information of a terminal station while supporting the QoS (Quality of Service) quality of multimedia traffic will be.

Mobile communication technology has developed into first generation analog mobile communication and second generation digital mobile communication technology, and recently, IMT-2000 (International Mobile Telecommunication-2000) service providing high quality call service with anyone, anywhere, anytime The 3GPP (3rd Generation Partnership Project) and the 3GPP2 is in progress. The IMT-2000 system supports a time division duplex mode (TDD mode) to accommodate high speed users and provide high quality services.

In addition, many researches on wireless ATM (Asynchronous Transfer Mode) have been conducted to improve channel efficiency in order to support high speed users and multimedia users. The wireless ATM technology considers a dynamic reservation based MAC (Media Access Control) protocol as an access method for efficiently accommodating service traffic having a variable bit rate while satisfying a service quality defined in a wired ATM network. At this time, in order to realize bandwidth-on-demand (BOD) that ATM pursues for traffic requiring various quality of service (QoS) and transmission rate, statistical multiplexing should be implemented in a wireless section.

In the wired ATM network, statistical multiplexing itself is a means of realizing BoD, but in the wireless network, direct statistical multiplexing cannot be performed because the traffic occurrence situation can not be directly recognized from distributed mobile stations. Therefore, in order to realize statistical multiplexing in a target wireless section, a scheduling function capable of performing dynamic slot allocation by a central base station should be provided. That is, the scheduler of the base station must quickly and accurately grasp the bandwidth requirements according to the traffic characteristics of each mobile station, and ensure the quality of the requirements of each mobile station. To this end, dynamic slot allocation must be performed to efficiently allocate available slots among the entire mobile stations as required.

Slot assignment in the wireless ATM method includes DSA / DSA ++ (Dynamic Slot Assignment), Bandwidth-on-Demand Fair-Sharing Round-Robin (BoD-FSRR), and EP-SA (Estimate-based Dynamic Band Assignment). ), Equivalent Capacity-based Dynamic Release Slot Assignment (EC-DRSA), Nonpreemptive Priority Polling, Non-Uniform Fully Gated-Limited Polling: N-FGL Polling) and Dynamic Priorities Fair Resource Auction Multiple Access (D-RAMA).

On the other hand, a protocol called WISPER has been proposed as a method for scheduling in an MC-CDMA (MultiCode-Code Division Multiple Access) environment. In WISPER, the same service class requires the same bit error rate (BER) value, and assumes the same maximum data rate. Therefore, the service class is sufficient for QoS requirements. The scheduling method of the WISPER protocol uses a method of guaranteeing delay time and BER. Also, by collecting packets of the same class in the same packet while improving channel efficiency in consideration of the situation in which the terminal station transmits several packets at the same time, It is designed to minimize packet errors and losses caused by interference. This approach may increase channel efficiency if only considering a channel for one base station, but may not be so for a cellular environment.

1 is a diagram illustrating the position of a terminal station in a cellular environment according to the present invention, in which both terminal stations A at a distance r1 and a terminal station B at r2 (r1 <r2) are equally applicable to both terminal stations. Assume that m codes have been allocated. It does not matter which terminal station is assigned m codes in the cell currently serving. However, in consideration of the effect on the neighboring cells, the scheduling of transmitting the same number of codes to the terminal station B near the cell boundary and transmitting them simultaneously is more likely than the case of assigning the code to the terminal station A. The interference power is so large that the overall system capacity is likely to decrease. In particular, this disadvantage will be more prominent in the CDMA scheme where interference power has a great influence on system performance and capacity.

The present invention has been made to solve the problems of the prior art, while supporting the QoS (Quality of Service, Quality of Service) characteristics of each multimedia traffic based on the WISPER protocol considering only a single cell in the next-generation mobile communication system It is an object of the present invention to provide a scheduling method designed to be suitable for a cellular system which is a multi-cell environment by increasing the capacity of a radio section by using the location information of a terminal station and improving performance.

1 is a diagram showing the position of a terminal station in a cellular environment according to the present invention,

2 is a diagram illustrating a region division of a cell and a position of a terminal according to an embodiment of the present invention;

FIG. 3 is a view showing a part which significantly influences the interference calculation in the six equal cells shown in FIG.

4 is a flowchart illustrating a scheduling method for increasing QoS guarantee and system capacity according to an embodiment of the present invention.

According to the present invention for achieving the above object, a scheduling method for ensuring transmission quality and increasing system capacity in a multi-code division multiple access (MC-CDMA) cellular environment having a multi-cell structure The method comprising: a first step of confirming, when allocating packets in order of priority, how many transmission packets of other terminal stations in the same area are allocated to a slot to be allocated; And a second step of determining the number of packets that can be transmitted so that the total amount of interference by the terminal stations in the same area does not exceed a predetermined boundary value. This is provided.

In addition, in a scheduling method for guaranteeing transmission quality and increasing system capacity in a multi-code divisional cellular environment having a structure of a multi-cell, when a packet is allocated in priority order, another terminal station in an adjacent area is allocated to a slot to be allocated. A first step of confirming how much of the transport packets are allocated; And a second step of determining the number of packets that can be transmitted so as not to exceed the interference tolerance of the immediate neighboring cells of the terminal stations in the neighboring area. 2. A scheduling method for guaranteeing transmission quality and increasing system capacity is provided. do.

In the following, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail.

In a real cellular environment, when scheduling using BER in allocating multiple codes, a scheduling method for reducing interference between cells using location information of a terminal is proposed. This uses that each base station can know the location of the terminal in the cell.

When the base station knows the location of the terminal by area, it first divides each cell into 6 areas and sends a lot of codes to the terminals in the same sector simultaneously by sending terminals of the same class to the same slots based on the existing WISPER protocol. Prevent allocation Accordingly, the efficiency of the channel can be increased while maintaining the interference on the adjacent cells in a cellular environment at a predetermined level or less according to the load of the adjacent cells.

In the method of knowing the load of the neighboring cells, since neighboring base stations are connected by wire, each of the loads in each cell may be notified to each other. Base stations belonging to the RNS can transmit the information only when they reach a certain state, and when the base stations belong to different RNSs, the required interference can be fixed at the initial design. Only when the load is large or when the amount of interference needs to be changed, control information may be transmitted to calculate an allowable interference degree of a neighboring cell.

FIG. 2 is a diagram illustrating a region division of a cell and a position of a terminal according to an embodiment of the present invention, and FIG. 3 is a diagram showing a part which significantly influences the interference calculation in the six equal cells shown in FIG. According to the present invention, as shown in Figs. 2 and 3, the hexagonal shape is divided into six parts, and the distance from the center point of each cell to the vertex is set to R.

The base station of each cell performs power control with the terminal station in the cell to always receive constant power. In this case, when the sum of power is 1 and the number of packets (limited by BER for each class) that can fit in one slot is S, the base station in the cell receives one packet, thereby receiving 1 / S of power. .

Assume that the power attenuation obtained by the terminal station using the pilot strength and the pilot transmission power information received from the base station in its cell is η ₁ , and the power attenuation obtained using the pilot received from the neighbor cell base station is η ₂ .

In order for the base station in the cell to receive 1 / S of power, the terminal transmits a packet at a power of (1 / η ₁ ) * (1 / S) in consideration of attenuation by distance. At this time, the power used by the terminal is attenuated by (1 / S) * η ₂ in the neighbor cell base station to cause interference. Thus, the power used by each terminal station can be obtained by the amount of power controlled by the base station, and the degree of interference on the adjacent cell can be known by the position of the terminal station.

At this time, since the amount of interference received by the base station of the neighboring cell is inversely proportional to the 4th or 6th power of the distance between the base station and the terminal station, when the distance in the cell area is 2R or more, the value is almost zero. Therefore, it can be said that only the three closest regions have a great influence on the amount of adjacent cell interference.

For example, as shown in Figure 2, the amount of interference received by the base station (b) of the cell next to the area B is mainly affected by the power sent by the terminals in the areas A, B and C. In addition, only three adjacent cells are mainly affected by the above-described logic.

The sum of powers of reservation packets of UEs corresponding to three adjacent regions included in slots may be obtained by Equation 1 below.

Here, S _l represents the maximum number of packets that can be sent in one slot of class l, η ₁ represents the attenuation ratio while going to the base station in the cell, and η _2k represents the attenuation ratio while going to the neighbor cell k base station. , α _k represents the amount of interference that the neighbor cell k base station can tolerate.

In addition, by using Equation 1, the number of packets X _i of the terminal i that can enter the slot can be obtained by Equation 2 below.

Here, X _i represents the number of packets of the terminal i can enter the slot, P _j slot is the total power of the reserved packets for transmission of the j area terminal in the slot when the total power received by the base station is 1, Indicates.

As shown in FIG. 2, the terminal to which the packet is to be transmitted increases the amount of interference of the base stations (a, b, c) of the neighbor cell, and the number of slots X _i that one terminal can send in one slot is determined in the region where the terminal is located. The interference received by the base station c by the terminal in the adjacent area (B, D), the interference received by the base station b by the terminal in A, B and C, and the interference received by the base station d by the terminal in the C, D and E It restricts not to exceed (alpha) _k . At this time, the minimum value of the number of packets X _i for the different values of α _{k for} all three adjacent cells becomes the maximum number of transport packets that can be reserved by the terminal.

The priority is higher as the remaining processing time (frame) is smaller and the more packets are left by one terminal. Priority means the number of slots to be sent every frame for the remaining frames. The number of packets to send in the next frame is proportional to the priority, and the number cannot exceed the number of remaining packets. By multiplying this priority by the number of packets the terminal can send, the number of packets to be sent in the next frame can be obtained.

4 is a flowchart illustrating a scheduling method for increasing QoS guarantee and system capacity according to an embodiment of the present invention.

1) Start scheduling with the highest priority.

2) The same priority is chosen arbitrarily regardless of position or interference.

3) From slot 1, check whether the slot is empty or the packet of the same class is to be transmitted. (S401 ~ S408)

4) If there is a slot under the condition 2) above, the packet is distributed so that things in the same sector do not gather in one slot at a time by using the position (sector) information of the terminal so as not to interfere with a predetermined amount or more in an adjacent cell. (S422, S423 )

5) If 15 slots are seen from the front and there are no empty slots or the same slots, the location (area) information of the terminal is used so as not to cause a certain amount of interference to a cell adjacent to a slot containing a packet of a class larger than its BER requirement. To distribute packets so that they are not in one slot at a time (S409 to S413, S420).

6) If there is no slot of 5), a slot containing a packet having a small BER requirement is found and inserted. At this time, the BER requirement of this slot follows the new BER requirement. Packets are distributed so that things in the same area are not gathered in one slot at a time by using the location (area) information of the terminal so as not to interfere with the neighboring cell by a certain amount or more. (S414 to S419)

The present invention as described above is recorded on a computer-readable recording medium, and can be processed by a computer.

As described in detail above, the present invention adjusts the maximum number of transmission packets of a terminal by using the location information of the terminal in the MC-CDMA multimedia environment, and adjusts the packets that can be transmitted according to the load of an adjacent cell, thereby busy time. ) Or even in a hot spot area, it is possible to reduce interference to adjacent cells and increase capacity efficiency of the entire system.

The technical spirit of the present invention has been described above with reference to the accompanying drawings, but this is by way of example only and not by way of limitation to the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (2)

In the scheduling method for guaranteeing transmission quality and increasing system capacity in a multi-code division multiple access (MC-CDMA) cellular environment having a multi-cell structure, When allocating packets in order of priority, a first step of checking how many transmission packets of other terminal stations in the same area are allocated to the slot to be allocated; And And a second step of determining the number of packets that can be transmitted so that the total amount of interference by the terminal stations in the same area does not exceed a predetermined boundary value. In the scheduling method for guaranteeing transmission quality and increasing system capacity in a multi-code division multiple access (MC-CDMA) cellular environment having a multi-cell structure, When allocating packets in priority order, a first step of checking how many transmission packets of other terminal stations in an adjacent area are allocated to the slot to be allocated; And And a second step of determining the number of packets that can be transmitted so as not to exceed an interference allowance value of immediately adjacent cells of the terminal stations in the adjacent area.