KR100825174B1 - Wireless communication system and base station apparatus - Google Patents

Abstract

In a CDMA wireless communication system having a base station and at least one wireless communication terminal for performing packet communication using at least one carrier for the base station, the wireless communication terminal simultaneously performs packet communication using a plurality of carriers for the base station. Perform. When the base station allocates a carrier to a specific terminal of the wireless communication terminal, the base station assigns an allocation information assigning unit to assign allocation information commonly used for a plurality of carriers, and a time for allocating a time slot used in the wireless communication terminal during communication. A slot assignment unit, an allocation information storage unit for storing allocation information, and a time slot distribution determination unit for determining time slot distributions that can be used in a wireless communication terminal using one carrier and a wireless communication terminal using a plurality of carriers at the same time. do.

Description

Wireless communication system and base station device {WIRELESS COMMUNICATION SYSTEM AND BASE STATION APPARATUS}

1 is a schematic diagram showing a communication system according to Embodiment 1 of the present invention;

2 is a schematic diagram showing a MAC index,

3 is a schematic diagram illustrating assignment of carriers to mobile stations;

4 is a sequence diagram illustrating carrier allocation operation between a mobile station and a base station;

5 is a flowchart for explaining a processing operation performed when a base station allocates a carrier to a mobile station;

6 is a sequence diagram illustrating MAC index allocation operation between a mobile station and a base station;

7 is a flowchart for explaining a processing operation performed when a base station assigns a MAC index to a mobile station;

8A is a schematic diagram of a packet used for communication between a base station and a mobile station;

8b is a schematic allocation diagram for allocating a frame to each mobile terminal;

9A is a schematic allocation diagram for allocating a frame to each mobile terminal;

9B is a schematic diagram showing a packet used for communication between a mobile station and a base station;

10 is an allocation diagram illustrating a case where a ratio of a single carrier terminal to a multicarrier terminal is set to 1: 3;

11 is a flowchart for explaining a frame allocation operation based on a ratio of average values of communication quality;

12 is a flowchart for explaining a frame allocation operation based on a ratio of maximum values of communication quality;

13 is a flowchart for explaining a frame allocation operation based on the ratio of the total number of terminals.

Explanation of symbols for the main parts of the drawings

10: mobile station 20: base station

21 ~ 23: Antenna 24 ~ 26: Radio part

27: control unit 28: storage unit

30: exchange office

Mobile terminal A, mobile terminal B: multi-carrier terminal

Mobile terminal C, mobile terminal D, mobile terminal E, mobile terminal F, mobile terminal G: single carrier terminal

The present invention generally relates to a CDMA communication system capable of executing packet communication. More specifically, the present invention relates to a wireless communication system that can utilize both a multicarrier terminal and a single carrier terminal.

A CDMA wireless communication system capable of performing forward-direction communication from a base station in a time division multiple access (TDMA) manner by packet communication, for example, 3GPP2 (http://3gpp2.org/) "HRPD", which is standard defined by C.S0024 as disclosed in, is known. This technical standard "HRPD" corresponds to a radio communication technology of a single carrier terminal capable of performing packet communication over one set of frequency channels (carriers) (i.e., upstream and downstream).

On the other hand, as a technique capable of performing forward directional packet communication from a base station by a code division multiple access (CDMA) scheme, for example, "SpreadRate3" (SR3) defined by C.S0001 to C.S0005 of the 3GPP2 standard. Is known. This technology is a wireless communication technology of a multi-carrier terminal capable of simultaneously performing packet communication using a plurality of frequency channels, that is, a chip rate of 3.6864 MHz by simultaneously using three carriers (frequency channels) having a chip rate of 1.2288 MHz. It corresponds to a wireless communication technology capable of performing packet communication.

In the multi-carrier terminal using the SR3 technique described above, since one carrier generates one spreading code used to execute the CDMA scheme, a plurality of spreading codes are required according to the total number of multi-carrier terminals in the same cell. .

On the other hand, when the conventional wireless communication system using a single carrier is changed to a wireless communication system using a multi-carrier that can be expected to be popularized, the existing equipment can be expanded to extend the single carrier wireless communication technology and the multi-carrier wireless communication technology. Can be used simultaneously and simultaneously, this technology idea becomes very effective in terms of cost and scalability.

According to a first aspect of the invention, a wireless communication system corresponds to a base station and one carrier (e.g., one set of frequency channels (upstream / downstream) for the base station, hereinafter " single carrier " At least one wireless communication terminal performing packet communication using one carrier and one carrier (e.g., one set of frequency channels (one or more upstream and two or more downstream) to a base station Combined, hereinafter referred to as " multi-carrier ", to simultaneously perform packet communication, and the base station is commonly used for a plurality of carriers when allocating carriers to specific terminals among the wireless communication terminals. Allocation information assigning means for assigning the assigned allocation information, and allocation information storing means for storing the allocation information.

In addition, the wireless communication system includes a base station, a first wireless communication terminal performing packet communication using one carrier for a base station, and a second wireless communication using a plurality of carriers for the base station at the same time. And a base station, the base station comprising: allocation information assigning means for assigning allocation information commonly used to the plurality of carriers when allocating a carrier to the first radio communication terminal or the second radio communication terminal; Allocation information storage means for storing allocation information is provided.

Preferably, the wireless communication system includes time slot assignment means for allocating time slots used for packet communication in the first and second wireless communication terminals, and one of the first and second wireless communication terminals for each carrier. And a time slot assignment means for allocating a wireless communication terminal to one unit of time slot distribution used by the first and second wireless communication terminals in packet communication.

Preferably, the wireless communication system includes time slot assignment means for allocating time slots for use in packet communication in the first and second wireless communication terminals, and both the first wireless communication terminal and the second wireless communication terminal. The apparatus further comprises time slot distribution determining means for determining a time slot distribution that can be used in the.

According to a second aspect of the present invention, packet communication is executed for a first wireless communication terminal performing packet communication using one carrier and a second wireless communication terminal performing packet communication using a plurality of carriers at the same time. In the base station apparatus, the base station apparatus, the allocation information assigning means for assigning the allocation information commonly used to the plurality of carriers when allocating a carrier to the first radio communication terminal or the second radio communication terminal; And allocation information storage means for storing the allocation information.

Preferably, the base station apparatus further comprises time slot assignment means for allocating a time slot used in the wireless communication terminal for packet communication, wherein the time slot assignment means is configured for the first and second radio communication for each carrier. Any wireless communication terminal of the terminal is assigned to one unit of time slot distribution used by the first and second wireless communication terminals in packet communication.

Preferably, the base station apparatus includes time slot assignment means for allocating time slots used in the first and second radio communication terminals in packet communication, and in the first radio communication terminal and the second radio communication terminal. Time slot distribution determining means for determining possible time slot distribution.

According to a third aspect of the present invention, a communication is performed with a base station apparatus that performs packet communication for a wireless communication terminal that performs packet communication using one carrier and another wireless communication terminal that performs packet communication using a plurality of carriers at the same time. In the radio communication terminal, the base station apparatus stores allocation information assigning means for assigning allocation information commonly used for the plurality of carriers when allocating a carrier to a specific radio communication terminal, and storing the allocation information. An assignment information storage means, wherein the radio communication terminal determines the destination of the communication packet transmitted from the base station based on the assignment information included in the header of the transmitted packet and communicates with the base station.

Further, a wireless communication terminal that communicates with a base station apparatus that performs packet communication to a wireless communication terminal that performs packet communication using one carrier and another wireless communication terminal that performs packet communication using a plurality of carriers simultaneously. In the base station apparatus, when allocating a carrier to a specific wireless communication terminal, allocation information assigning means for simultaneously assigning allocation information commonly used to a plurality of carriers, and time used by the wireless communication terminal in packet communication. And time slot assignment means for allocating slots, and assignment information storage means for storing the assignment information, wherein the time slot assignment means is for wireless communication of one of the first and second radio communication terminals for every carrier in packet communication. One end of time slot distribution using the terminal in the first and second wireless communication terminals The wireless communication terminals, and is assigned to, the destination of the communication packet transmitted from the BS, it is determined on the basis of the allocation information included in the header of the transmitted packet, the communication with the base station.

A wireless communication terminal which communicates with a base station apparatus that performs packet communication with another wireless communication terminal that performs packet communication using a plurality of carriers at the same time as a wireless communication terminal that performs packet communication using one carrier, wherein The base station apparatus, when allocating a carrier to a specific terminal among the wireless communication terminals, allocation information assigning means for assigning allocation information commonly used for the plurality of carriers, and time used by the wireless communication terminal for packet communication. Time slot allocation means for allocating slots, allocation information storage means for storing the allocation information, and time that can be used in the wireless communication terminal using the plurality of carriers simultaneously with the wireless communication terminal using one carrier; Time slot distribution determining means for determining slot distribution, The communication terminal is the destination of the communication packets transmitted from the base station, up to the determination on the basis of the allocation information included in the header of the transmitted packet, the communication with the base station.

According to the present invention, the allocation information assigning means assigns allocation information commonly used to the plurality of carriers when allocating the plurality of carriers to the radio communication terminal. Therefore, communication between the base station and the wireless communication terminal is controlled based on allocation information (MAC index).

According to the present invention, a wireless communication terminal using a plurality of carriers and a wireless communication terminal using one carrier are controlled by assignment information. This allocation information is stored so that the radio communication terminal using a plurality of carriers and the radio communication terminal using one carrier do not overlap.

According to the present invention, the assignment information assigning means changes the boundary in the arrangement of the assignment information. Therefore, the ratio between the first wireless communication terminal and the second wireless communication terminal is changed according to the traffic state of the communication line.

According to the present invention, the wireless communication terminal determines the destination of the communication packet by assignment information appended to the header of the communication packet transmitted from the base station, and communicates with the base station. Therefore, communication is controlled by assignment information (MAC index).

According to the present invention, time slot distribution is determined at a base station between a wireless communication terminal using one carrier and a wireless communication terminal using a plurality of carriers.

According to the present invention, time slot distribution is determined at a base station between a radio communication terminal using one carrier and a radio communication terminal using a plurality of carriers.

According to the present invention, the time slot assignment means can allocate the time used for packet communication based on an independent algorithm, thereby reducing the workload in the time slot assignment processing operation.

According to the present invention, the amount of traffic in a cell can be managed in advance by the base station.

According to the present invention, the priority order of packet communication can be dynamically determined according to the state of communication quality for each wireless communication terminal in the cell.

According to the present invention, the priority of packet communication can be dynamically determined according to the state of communication quality for each wireless communication terminal in the cell.

According to the present invention, the time slot distribution determining means can allocate a large time slot distribution to a wireless communication terminal having a large communication number, thereby dynamically increasing the priority of packet communication.

According to the present invention, time slot distribution may be determined at a base station between a wireless communication terminal using one carrier and a wireless communication terminal using a plurality of carriers.

According to the present invention, the time slot distribution between the first wireless communication terminal and the second wireless communication terminal can be determined at the base station.

According to the present invention, a time slot distribution between a wireless communication terminal using one carrier and a wireless communication terminal using a plurality of carriers can be determined at the base station.

In addition, packet communication is performed using variable length packets. As a result, it is possible to effectively use a communication line by preventing unnecessary packets from being generated.

Referring now to the drawings, a wireless communication system according to an embodiment of the present invention will be described in detail.

(Example)

1 is a schematic diagram illustrating a wireless communication system according to an embodiment of the present invention.

Reference numeral 10 denotes a mobile station, reference numeral 20 denotes a base station, and reference numeral 30 denotes an exchange station.

The mobile station 10 includes one or more mobile communication terminals. Mobile terminal "A " and mobile terminal " B " correspond to multi-carrier communication terminals, and each multi-carrier terminal uses three carriers simultaneously, and this multi-carrier terminal uses a code division multiple access (CDMA) system as one carrier. Each time, the packet communication from the base station 20 is executed in the forward direction. The mobile terminal "C", the mobile terminal "D", the mobile terminal "E", the mobile terminal "F" and the mobile terminal "G" correspond to a single carrier communication terminal, and this single carrier terminal uses only one carrier, This single carrier terminal executes a code division multiple access system to perform packet communication from the base station 20 along the forward direction.

The base station 20 is composed of antennas 21 to 23, radio units 24 to 26, control unit 27, and storage unit 28. The antennas 21 to 23 are connected to the radio units 24 to 26, respectively, and these antennas 21 to 23 receive electromagnetic waves transmitted from the mobile station 10 and also transmit electromagnetic waves to the mobile station 10. . The radio units 24 to 26 convert the transmission data into high frequency signals transmitted from the antennas 21 to 23, and further convert the high frequency signals received from the antennas 21 to 23 into received data. Antenna 21 and radio section 24, antenna 22 and radio section 25, and antenna 23 and radio section 26 communicate with the mobile station 10 using different carriers. That is, the base station 20 can perform multicarrier communication for the mobile station 10 by simultaneously transmitting and receiving a plurality of carriers. The control unit 27 controls the radio units 24 to 26, and the control unit 27 assigns a MAC index (to be described later) to store the MAC index in the storage unit 28, and stores the mobile station 10. Manage.

The switching center 30 connects the base station 20 to another base station or a broadband line, and relays communication between them.

Next, an outline of a wireless communication system according to an embodiment of the present invention will now be described.

In the wireless communication system of the present embodiment, the base station 20 can transmit and receive three carriers at the same time, and the mobile station 10 and the base station 20 can perform wireless communication using these three carriers at the same time. Of the mobile stations 10, a single carrier terminal can wirelessly communicate with the base station 20 using any one of these three carriers, while a multi-carrier terminal uses these three carriers simultaneously and with the base station 20 Wireless communication is possible. At this time, a time division multiple access (TDMA) system is executed on each of these three carriers, and after a time slot is set in a single carrier, data is divided by time slots to perform wireless communication (packet communication). It should be understood that the size of this time slot may be a fixed length or may be variable length depending on the amount of data and / or data type.

In addition, when the base station 20 and the mobile station 10 communicate with each other, communication data included in each time slot is processed in a CDMA manner to perform CDMA communication.

When the mobile station 10 and the base station 20 are communicating, the base station 20 manages carriers and time slots used by the mobile station 10 based on the "MAC index".

2 is a diagram for explaining this MAC index.

The MAC index of this embodiment is a 6-bit code map composed of 64 types of codes (i.e., 0 to 63 in decimal). For these 64 types of codes (MAC codes), the base station 20 allocates the carrier and available time slots used in each terminal to each terminal included in the mobile station 10.

3 is a schematic diagram schematically showing assignment of carriers and time slots when the mobile station 10 and the base station 20 perform packet communication.

A multi-carrier terminal (wireless terminal "A" or wireless terminal "B") is a plurality of time slots (i.e., three time slots in this embodiment) of a plurality of assigned carriers (i.e., three carriers in this embodiment). Simultaneous use of wireless communication. Since the single carrier terminal (wireless terminal "C" to "G") performs packet communication using only one carrier, the single carrier terminal uses only one time slot of one carrier at the same time, so that three sets of single The carrier terminal may simultaneously execute packet communication at the same time in different carriers.

Next, using the MAX index, the packet communication operation executed by the base station 20 by allocating a carrier and a time slot to the wireless terminal for the base station 20 to perform packet communication will now be described. .

First, with reference to FIG. 4, an operation performed when the base station 20 allocates a carrier to the mobile station 10 (wireless terminal) will be described.

The base station 20 always transmits a synchronization signal to the mobile station 10 (process 401).

When the power of the mobile station 10 is turned on and the mobile station 10 receives the synchronization signal transmitted from the base station (process 402), the mobile station 10 processes the registration operation indicated by the processes 404 to 413 for the base station 20. Is executed (process 403).

In this registration operation, the mobile station 10 must be registered with the control unit 27 of the base station 20 in order to perform packet communication with the base station 20. The mobile station 10 transmits a registration operation start request message to the base station 20 to perform this registration operation, and requests the control unit 27 of the base station 20 to be registered (process 404). When the base station 20 receives this request message, the base station 20 recognizes the existence (existence) of the mobile station 10. At the same time, the base station 20 sends a registration operation start permission message to the mobile station 10, and this registration operation start permission message is used to confirm the start of the registration operation (process 405).

When the mobile station 10 receives this permission message, the mobile station (wireless terminal) 10 transmits the function information to the base station 20 to request allocation of a carrier suitable for the function of the wireless terminal (process 406). This function information indicates whether its own terminal corresponds to a single carrier terminal or a multicarrier terminal. The base station 20 receives this function information, recognizes whether the mobile station 10 corresponds to a single carrier terminal or a multicarrier terminal, and then stores the function information of the mobile station 10 in the storage unit 28. . When this function information is stored in the storage unit 28, the base station 20 returns a function information reception message to the mobile station 10 (process 407). This function information reception message is a message confirming that the base station 20 has received the function information.

Next, the base station 20 allocates one or a plurality of carriers selected from carriers "1" to carriers "3" used to communicate with the mobile station 10 (process 408). Details of this carrier assignment will now be described with reference to FIG.

When the base station 20 allocates a carrier to the mobile station 10, the base station 20 transmits this allocated carrier information to the mobile station 10 as a carrier assignment message (process 409). When the mobile station 10 receives this carrier assignment message, the mobile station 10 sends a carrier assignment acknowledgment message to the base station 20 (process 410). This carrier assignment acknowledgment message indicates that carrier information has been received. The mobile station 10 changes the settings of the carrier in the radio unit (not shown) provided in the mobile station 10 so that the mobile station 10 communicates with the base station 20 by this assigned carrier (process 411). When the carrier setup is completed at the mobile station 10, the mobile station 10 transmits a carrier change complete message to the base station 20 (process 412). Upon receiving this carrier change complete message, the base station 20 recognizes that it can communicate using the carrier assigned to the mobile station 10, and sends a carrier change complete confirmation message to the mobile station 10 (process 413). ).

The carrier used for packet communication between the mobile station 10 and the base station 20 can be determined by the above-described processing operation. Subsequently, the base station 20 and the mobile station 10 can execute packet communication using this determined carrier.

5 is a flowchart for explaining a carrier allocation processing operation performed as a processing 408 in the base station 20.

First, the base station 20 refers to the function information of the mobile station 10 received in the processing 406 of FIG. 4 (process 501), and determines whether the mobile station 10 is a single carrier terminal or a multicarrier terminal (process 502). . If the mobile station 10 corresponds to a multicarrier terminal, the processing proceeds to processing 503. If the mobile station 10 corresponds to a single carrier terminal, the processing proceeds to processing 504.

In process 503, the base station 20 assigns all three of these carriers to be used for the mobile station 10 corresponding to the multi-carrier terminal.

In process 504, the base station 20 refers to the total number of mobile stations 10 assigned to carrier 1 and its traffic information, and also refers to the total number of mobile stations 10 assigned to carrier 3 and its traffic information.

Since the base station 20 always knows which carrier is assigned to which mobile station, it is easy to know how many mobile stations are allocated to each carrier. In addition, the base station 20 can compile the statistics of the time slots in each of these carriers to determine the free slot rate and the used slot rate, as well as the traffic of each carrier.

Next, the base station 20 determines a congestion state (dense state) based on the total number of mobile stations and traffic assigned to carrier 1 and carrier 3 (process 505). If carrier 1 is not crowded than carrier 3, base station 20 assigns this carrier 1 to the mobile station (process 506). If carrier 3 is not crowded than carrier 1, base station 20 assigns this carrier 3 to the mobile station (process 507). If Carrier 1 and Carrier 3 both become congested, the base station 20 assigns Carrier 2 to the mobile station (process 508).

Next, the operation of the base station 20 assigning the MAC index for the mobile station 10 will now be described with reference to FIG.

First, when the carrier is determined based on the sequential operation of FIG. 4 and the carrier used for packet communication is set, the mobile station 10 transmits a communication channel assignment request message to the base station 20, and transmits the communication channel to the base station 20. Is assigned (process 601). When the base station 20 receives this communication channel assignment request message, the base station 20 sends a communication channel assignment request response message confirming receipt of the request message to the mobile station 10 (process 602). Subsequently, the base station 20 transmits a MAC index allocation mobile station information request message requesting the necessary information (hereinafter, referred to as "mobile station information") when the MAC index is assigned to the mobile station 10. As the mobile station information, information on whether the mobile station 10 is a multicarrier terminal or a single carrier terminal and / or information on the communication quality state of the mobile station 10 is required (process 603).

When the mobile station 10 receives this information request message, the mobile station 10 provides, as mobile station information to the base station 20, an index assignment mobile station that includes information on the terminal type of the mobile station and information on the communication quality status of the mobile station. An information request response message is sent (process 604). When the base station 20 receives the mobile station information, the base station 20 transmits an information reception response message capable of confirming reception (process 605).

Based on this mobile station information, the base station 20 assigns a MAC index to the mobile station 10. This MAC index allocation processing operation will be described later with reference to FIG.

When the MAC index is assigned, the base station 20 sends a MAC index assignment message to the mobile station 10 to notify this MAC index (process 607). When the mobile station 10 receives this MAC index assignment message, the mobile station 10 sends an information reception response message confirming reception of the MAC index assignment message to the base station 20 (process 608). Subsequently, the mobile station 10 stores the assigned MAC index in a storage unit (not shown) provided in the mobile station, and sets the mobile station 10 to a state in which communication is possible so that a packet to which the MAC index is added can be transmitted and received (process 609). ).

As a result, the base station 20 and the mobile station 10 can perform data communication using the MAC index (process 610).

7 is a flowchart for explaining the details of the above-described MAC index allocation operation.

First, the base station 20 recognizes which terminal of the single carrier terminal or the multicarrier terminal corresponds to the mobile station 10 performing data communication based on the information received in the above-described process 406 of FIG. Is obtained (process 701), and the carrier of the mobile station 10 set in the above-described process 408 of FIG. 4 is recognized to obtain a recognized carrier (process 702).

When the base station 20 recognizes that the mobile station 10 corresponds to the multicarrier terminal based on the above-described information, the processing proceeds to processing 704. When the base station 20 recognizes that the mobile station 10 corresponds to the single carrier terminal based on the above-described information, the processing proceeds to processing 710 (process 703).

In process 704, the base station 20 determines whether there is an empty index allocated to the multi-carrier terminal in the MAC index. If there is an empty index for the multi-carrier terminal in the MAC index, the processing proceeds to process 705. In this process 705, the base station 20 assigns the MAC index to the mobile station 10, and stores the carrier used by the mobile station 10 in association with the MAC index.

The mobile station 10 and the carrier used by the mobile station 10 are allocated and stored in a code map of the MAC index. As a code map according to an embodiment of the present invention, a 6-bit code map (see Fig. 2) composed of 64 kinds of elements (that is, 0 to 63 elements) is used. At this time, by the base station 20, these 64 kinds of elements are assigned to the single carrier terminal in the forward direction, while the 64 kinds of elements are allocated to the multicarrier terminal in the reverse direction (for example, the MAC index). The code map is allocated by the base station 20 to the single carrier terminal in the order of 0, 1, 2, 3, 4, ..., and to the multicarrier terminal in the order of 63, 62, 61, ... ). As a result, carriers and time slots are exclusively assigned to each mobile station, so that time slots and carriers can be used as effectively as possible.

If the base station 20 determines that there is no empty index assignable to the multicarrier terminal in the MAC index in processing 704, the processing proceeds to processing 706, and the base station 20 assigns an empty index to the single carrier terminal among the MAC indexes. Determine if there is. If there is no allowable empty index in the single carrier terminal of the MAC index, the base station 20 determines that the current total number of mobile stations has reached or exceeded the limit of the number of communicable mobile stations in the cell of the base station 20, The message is sent to the mobile station (process 707), and the processing operation is completed.

On the other hand, if there is an empty index that can be allocated to a single carrier terminal among the MAC indexes, the base station 20 allocates an empty area of the MAC index that can be allocated to the single carrier terminal to an area of the MAC index that can be allocated to the multicarrier terminal (process 708). The MAC index of the added free area is allocated to the mobile station (i.e., multi-carrier terminal) (process 709).

In this embodiment of the present invention, the boundary between the area of the MAC index used by the single carrier terminal and the area of the MAC index used by the multicarrier terminal is set in advance. First, when one of the single carrier terminal and the multi-carrier terminal is in a congested state and the empty areas are lost, the boundary of these areas can be moved, so that the area with a high congestion state can be increased.

In contrast, the boundary between the region for the MAC index used by the single carrier terminal and the region for the MAC index used by the multicarrier terminal is fixed, and the ratio between the single carrier mobile station and the multicarrier mobile station that can communicate with each other in the same cell. Can also be set to a fixed value in advance.

In addition, separate code maps are prepared in a single carrier terminal and a multi-carrier terminal, and these code maps are individually assigned. In this case, the allocation of the code map is not affected by the congestion state of other types of terminals.

When the base station 20 determines in step 703 that the mobile station 10 that performs communication corresponds to the single carrier terminal, the base station 20 executes the same processing operations as those described in the above-described processes 704 to 709. Thereafter, the base station 20 transmits a message that the current communication state is under congestion, that is, waits for an empty area, and performs a processing operation or allocates a MAC index (processes 710 to 715).

Since the above-described processing operation is performed, the MAC index can be allocated from the base station 20 to the mobile station 10.

Next, the sequential operation performed when the base station 20 and the mobile station 10 perform packet communication based on the assigned MAC index will now be described.

When a data transmission request is generated from the mobile station 10, the base station 20 first obtains a carrier assigned to the mobile station 10 and the mobile station 10 by referring to the MAC index, and 1 for one MAC index. The frame corresponding to the time interval is allocated, and the packets are transmitted in the assigned order. This frame contains the time slot of each carrier. Note that this frame has a fixed or variable length.

9A and 9B, when the base station 20 allocates each mobile terminal included in the mobile station 10 to a frame, assuming that one time slot is recognized as one frame, a single carrier Frames allocated to the terminal and frames allocated to the multi-carrier terminal may be alternately allocated at the same interval.

When the frame allocation is determined, the base station 20 sequentially transmits packets to which a header including a MAC index is added.

The mobile station 10 receives the packet by recognizing the packet length, the time unit length, etc. with reference to the header. When the time unit ends, the mobile station 10 prepares to receive the next packet.

In the communication system of the cellular phone according to the present embodiment, as shown in Fig. 8B, when each mobile station 10 is assigned to each of the frames, the distribution of the frame allocated to the single carrier terminal to the frame allocated to the multicarrier terminal is distributed. May be managed and determined in terms of the base station 20.

This distribution is performed according to any of the following means.

(Method 1)

The ratio of frames used by the single carrier terminal and the multicarrier terminal in communication is preset, and these frames are allocated to these single carriers / multicarriers based on this set ratio.

(Means 2)

The ratio of the average value of the communication quality reported from each single carrier terminal to the average value of the communication quality reported from each multicarrier terminal is calculated, and a frame is allocated to these terminals based on this calculated ratio.

(Method 3)

The ratio of the maximum value of the communication quality reported from each single carrier terminal to the maximum value of the communication quality reported from each multicarrier terminal is calculated, and a frame is assigned to these terminals based on this calculated ratio.

(Method 4)

The ratio of the total number of single carrier terminals to the total number of multicarrier terminals is calculated, and frames are allocated based on this calculated ratio.

Hereinafter, each means will be described now. Note that in this embodiment, the allocation order in the case where the total number of time slots is 256 is described.

In means 1, in the communication executed in the same cell on the side of the base station 20, the ratio of the single carrier terminal to the multi-carrier terminal is predetermined by the base station 20, and the frame is allocated according to the determined ratio. For example, when the ratio of the single carrier terminal to the multicarrier terminal is determined to be 1: 3 in advance, the frame allocation is performed by using 64 (= 256 x (1/4)) time slots to configure a frame composed of one set. After allocating to a single carrier terminal, frame allocation is performed in the order of allocating different frames in one set using 192 (= 256 x (3/4)) time slots, and these frame allocations are alternately repeated. (See Figure 10). In this means 1, the amount of traffic in the cell can be collectively managed by the base station 20.

In means 2, after calculating the communication quality reported from the mobile station 10 to the base station 20, the ratio of the average value of the communication quality reported from each single carrier terminal and the average value of the communication quality reported from each multicarrier terminal is calculated. In response to this calculated ratio, the base station 20 dynamically manages allocation of frames.

11 is a flowchart for explaining a frame allocation sequential operation executed by this means 2. FIG.

First, the base station 20 obtains communication quality information of the multi-carrier terminal among the mobile stations 10 communicating in the downstream direction in one cell. Since the obtained communication quality information includes a header of a communication packet executed in the upstream direction from the mobile station 10 to the base station 20, the base station 20 receives this communication packet and interprets the header information. (Process 1101).

Next, an average value of communication quality information of the multicarriers is obtained. This average value is calculated according to the following equation (process 1102).

[Equation 1]

(Average value "Q _mc " of communication quality of multi-carrier terminal) = (total of received communication quality value) / (total number of multi-carrier terminal)

Similarly, communication quality information of a single carrier terminal is received (process 1103), and the average value thereof is calculated according to equation (2) (process 1104).

[Equation 2]

(Average value "Q _sc " of communication quality of single carrier terminal = [{(total number of communication quality values received at carrier 1) / (total number of single carrier terminals at carrier 1)} + {(received at carrier 2 Total of communication quality value) / (total number of single carrier terminals in carrier 2)} + {(total number of communication quality values received in carrier 3) / (total number of single carrier terminals in carrier 3)}] / 3

Next, the base station 20 determines the total number of frames to be allocated based on this calculated average value. First, the total number of time slots allocated to the multi-carrier terminal is calculated according to the following equation (process 1105).

[Equation 3]

N _slotmc = int (256 × Q _mc ÷ (Q _sc + Q _mc ))

Similarly, the total number of time slots allocated to a single carrier terminal is calculated according to the following equation (4) (process 1106).

[Equation 4]

N _slotmc = int (256 × Q _sc ÷ (Q _sc + Q _mc ))

Based on the calculated value, the base station 20 _assigns a plurality of time slots defined from the first time slot to the Nth _slotmc time slot for the three carriers defined as carriers 1 to 3 to the communication of the multicarrier terminal. (Process 1107). When a plurality of multi-carrier terminals are included in the mobile station 10, the base station 20 sets a frame constituted by subdividing this frame (arranged into "N _slotmc " time slots), and then each subdivided Each multicarrier terminal is assigned to a frame.

Next, the base station 20 _assigns a plurality of time slots defined as (N _slotmc +1) time slots to N slot _MC time slots for three carriers defined as carriers 1 to 3, respectively. Assign to communication (process 1108).

When a plurality of single carrier terminals are included in the mobile station 10, a frame constituted by subdividing these frames (arranged by "N _slotsc- (N _slotsc +1)" time slots) is set, and then each subdivision Each single carrier terminal is allocated to the allocated frame.

If communication is executed from the first time slot to the 256th time slot, the processing operations defined from the processing 1101 to the processing 1108 are repeatedly executed for the 256 next time slots.

In the means 2 described above, the ratio of the number of frames is determined based on the ratio of the average value of the communication quality of the single carrier terminal to the average value of the communication quality of the multicarrier terminal. As a result, the base station 20 can dynamically determine the priority of the communication in response to the communication quality status of each terminal in the cell.

The means 3 aggregates the communication quality reported from the mobile station 10 with respect to the base station 20, and the ratio of the maximum value of the communication quality reported from each single carrier terminal and the maximum value of the communication quality reported from each multicarrier terminal. And the base station 20 dynamically manages the allocation of these frames in response to this calculated ratio.

Fig. 12 is a flowchart for explaining the sequential operation of frame allocation by executing this means 3.

First, the base station 20 obtains communication quality information of the multi-carrier terminal among the mobile stations 10 communicating in the downstream direction in the cell. Since the obtained communication quality information includes the header of the communication packet along the upstream direction, the base station 20 receives this communication packet and interprets the header (process 1201).

Next, the maximum value "Q _Smc " of the communication quality information of these multicarrier terminals is obtained (process 1202).

Next, the base station 20 similarly receives communication quality information of the single carrier terminal (process 1203), and obtains the maximum value "Q _Ssc " (process 1204).

The base station 20 then determines the total number of frames to be allocated based on this calculated maximum value. First, the total number of time slots allocated to the multicarrier terminal is calculated according to the following equation (process 1205).

[Equation 5]

N _slotmc = int (256 × Q _Smc ÷ (Q _Ssc + Q _Smc ))

Similarly, the total number of time slots allocated to a single carrier terminal is calculated according to Equation 6 below (process 1206).

[Equation 6]

N _slotsc = int (256 × Q _Ssc ÷ (Q _Ssc + Q _Smc ))

Based on the operation result, the base station 20 _assigns a plurality of time slots defined from the first time slot to the Nth _slotmc time slot to the communication of the multicarrier terminal for three carriers defined from carrier 1 to carrier 3. (Process 1207). When a plurality of multi-carrier terminals are included in the mobile station 10, the base station 20 sets a frame configured by subdividing this frame (where "N _slotmc " time slots are arranged), and then each subdivided frame. Assign each multicarrier terminal to.

Next, the base station 20 _transmits a plurality of time slots defined from the (N _slotmc +1) time slots to the (N _slotsc ) time slots for the three carriers defined as carrier 3 from carrier 1 to a single carrier terminal. Is assigned to the communication (process 1208).

When a plurality of single carrier terminals are included in the mobile station 10, the base station 20 sets a frame configured by subdividing these frames (arranged into "N _slotsc- (N _slotmc +1)" time slots), Thereafter, each single carrier terminal is allocated to each subdivided frame.

If communication is executed from the first time slot to the 256th time slot, the processing operation defined from the processing 1201 to the processing 1208 is repeatedly executed for the next 256 time slots.

In the above means 3, the ratio of the number of frames is determined based on the ratio of the maximum value of the communication quality of the single carrier terminal to the maximum value of the communication quality of the multicarrier terminal. As a result, the base station 20 dynamically determines the priority order of communication in response to the communication quality status of each terminal in the cell.

The means 4 calculates the ratio of the total number of single carrier terminals to another total number of multicarrier terminals included in the terminal in the mobile station 10 communicating with the base station 20, so that the base station 20 calculates this calculated ratio. In response to this, the frame allocation is dynamically managed.

Fig. 13 is a flowchart for explaining a frame allocation processing operation by the execution of this means 4.

First, the base station 20 obtains the total number "N _mc " of the multicarrier terminals (process 1301).

Next, the base station 20 obtains the total number "N _sc " of the single carrier terminal (process 1302).

Subsequently, the base station 20 determines the total number of frames to be allocated based on the total number of each single carrier terminal / multicarrier terminal. First, the total number of time slots allocated to the multicarrier terminal is calculated based on Equation 7 below (process 1303).

[Equation 7]

N _slotmc = int (256 × N _mc ÷ (N _sc + N _mc ))

Similarly, the total number of time slots allocated to a single carrier terminal is calculated according to Equation 8 below (process 1304).

[Equation 8]

N _slotsc = int (256 × N _sc ÷ (N _sc + N _mc ))

Based on the calculation result, the base station 20 _transmits a plurality of time slots defined from the first time slot to the Nth _soltmc time slot for the three carriers defined from carrier 1 to carrier 3 for communication of the multicarrier terminal. Assignment (process 1305). When a plurality of multi- _carrier terminals are included in the mobile station 10, the base station 20 sets a frame configured by subdividing these frames (arranged by "N _slotmc " time slots), and sets each of the subdivided frames. Assign each multicarrier terminal.

Next, the base station 20 single carriers a plurality of time slots defined as (N _slotsc ) time slots from (N _slotmc +1) time slots to three carriers defined as carrier 3 through carrier 1. Assign to communication of the terminal (process 1306).

When a plurality of single carrier terminals are included in the mobile station 10, the base station 20 sets a frame constituted by subdividing these frames (arranged by "N _slotsc- (N _slotmc +1)" time slots). Then, each single carrier terminal is allocated to each subdivided frame.

When communication is executed from the first time slot to the 256th time slot, the processing operation defined by the processing 1301 to the processing 1306 is repeatedly executed for the next 256 time slots.

In the above means 4, the ratio of the number of frames is determined based on the total number of single carrier terminals and the total number of multicarrier terminals. As a result, the base station 20 dynamically allocates a large number of frames to a terminal having a large number of users when the total number of users using either the multi-carrier terminal or the single-carrier terminal is increased compared to the total number of users. May increase the priority of communication for the user.

As described above, according to the present invention, a wireless communication system capable of using both a multicarrier terminal and a single carrier terminal can be obtained.

Claims (25)

In a wireless communication system, Base station, A first wireless communication terminal performing packet communication with the base station using one carrier, A second wireless communication terminal performing packet communication with the base station using a plurality of carriers at the same time Provided with The base station, Allocation information storage means for storing allocation information consisting of allocation information for single carrier and allocation information for multicarrier; An allocation information assigning means for allocating the single carrier allocation information to the first radio communication terminal and allocating the multicarrier allocation information when the second radio communication terminal communicates using a plurality of carriers. doing Wireless communication system. The method of claim 1, The storage means arranges and stores the allocation information in a predetermined order; The assignment information assigning means allocates the single carrier assignment information to the first radio communication terminal from one of the assignment information arrays, and when the second radio communication terminal communicates using a plurality of carriers, Allocating the allocation information for the multicarrier from the other side Wireless communication system, characterized in that. The method of claim 2, The assignment information assigning means is one of the assignment information for the single carrier assigned to the first radio communication terminal and the assignment information for the multicarrier allocated when the second radio communication terminal performs communication using a plurality of carriers, The boundary in the said arrangement can be changed, The wireless communication system characterized by the above-mentioned. The method of claim 1, The storage means separates the single carrier allocation information allocated to the first radio communication terminal and the multicarrier allocation information allocated when the second radio communication terminal performs communication using a plurality of carriers. A wireless communication system characterized by storing as an array. The method of claim 1, The packet communication is performed using a variable length packet. The method of claim 1, The assignment information assigning means assigns the single carrier assignment information when the second radio communication terminal communicates using a plurality of carriers, when there is no space for the multicarrier assignment information. Communication system. The method of claim 1, And the allocation information assigning means assigns the multicarrier allocation information to the first radio communication terminal when there is no space for the single carrier allocation information. The method of claim 1, Further comprising frame allocation means for allocating frames for use by the first and second wireless communication terminals for packet communication; The frame allocation means assigns one of the first and second radio communication terminals to one unit of a frame for use by the first and second radio communication terminals for packet communication. Wireless communication system, characterized in that. The method of claim 8, The frame allocating means allocates one of the first and second radio communication terminals to one unit of a frame to be used by the first and second radio communication terminals for each carrier, and the first radio. And a communication terminal and the second wireless communication terminal are independently assigned. The method of claim 8, The frame allocating means allocates one of the first and second radio communication terminals to one unit of a frame to be used by the first and second radio communication terminals for each carrier, and the first radio. And a communication terminal and the second wireless communication terminal are alternately assigned. The method of claim 8, The packet communication is performed using a variable length packet. The method of claim 1, Frame allocation means for allocating frames for use in packet communication by the first and second wireless communication terminals; Time slot distribution determining means for determining the in-frame time slot distribution available to the first wireless communication terminal and the second wireless communication terminal Wireless communication system further comprising. The method of claim 12, The frame allocation means is independent of the time slot distribution usable by the first wireless communication terminal and the time slot distribution usable by the second wireless communication terminal, determined by the time slot distribution determining means, respectively. And a frame to be used for this communication. The method of claim 12, The time slot distribution determining means is usable by the first wireless communication terminal and the second wireless communication terminal based on a comparison result between the communication quality of the first wireless communication terminal and the communication quality of the second wireless communication terminal. Determine a time slot distribution within the frame. The method of claim 14, The time slot distribution determining means is further configured to determine the time slot distribution determining means based on a comparison result between the average value of the communication quality of the first wireless communication terminal and the average value of the communication quality of the second wireless communication terminal. And determining a time slot distribution within the frame available to the terminal. The method of claim 14, The time slot distribution determining means is further configured based on a comparison result between the maximum value of the communication quality of the first radio communication terminal and the maximum value of the communication quality of the second radio communication terminal, and the second radio communication terminal and the second radio communication terminal. And determine a time slot distribution within the frame available to a wireless communication terminal. The method of claim 12, The time slot distribution determining means is based on a comparison result between the number of the first radio communication terminals and the number of the second radio communication terminals, which are connected to the base station, and the first radio communication terminal and the second radio. And determine a distribution of time slots within the frame available to the communication terminal. A base station apparatus for performing packet communication with a first wireless communication terminal performing packet communication using one carrier and a second wireless communication terminal performing packet communication using a plurality of carriers at the same time, Allocation information storage means for storing allocation information consisting of allocation information for single carrier and allocation information for multicarrier; Allocation information assigning means for allocating the single carrier allocation information to the first radio communication terminal and allocating the multicarrier allocation information when the second radio communication terminal communicates using a plurality of carriers. Base station apparatus comprising a. The method of claim 18, And the packet communication is performed using a variable length packet. The method of claim 18, And the allocation information assigning means allocates the single carrier allocation information when the second radio communication terminal communicates using a plurality of carriers and there is no space for the multicarrier allocation information. Device. The method of claim 18, And the allocation information assigning means assigns the multicarrier allocation information to the first wireless communication terminal when there is no space for the single carrier allocation information. The method of claim 18, Frame allocation means for allocating frames for use in packet communication by the first and second wireless communication terminals; The frame allocation means assigns one of the first and second radio communication terminals to one unit of a frame for use by the first and second radio communication terminals for each carrier. Base station apparatus, characterized in that. The method of claim 22, And the packet communication is performed using a variable length packet. The method of claim 18, Frame allocation means for allocating frames for use in packet communication by the first and second wireless communication terminals; Time slot distribution determining means for determining a time slot distribution in the frame available to the first wireless communication terminal and the second wireless communication terminal The base station apparatus further comprises. The method of claim 24, And said packet communication is performed using a variable length packet.

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