KR19990084525A - Control Method of Medium Access Control Sublayer (MAC) of Mobile Communication System - Google Patents

Abstract

The present invention provides a communication system comprising a physical layer (PHY), an access control sublayer (MAC) that is higher than the physical layer, a link access control layer (LAC) that is higher than the access control sublayer, and a higher layer of the link access control layer. Medium access control sublayer of the mobile communication system that performs various preset functions between the mobile terminal and the network or the base station each having a stack structure of the protocol, and also performs various communication control functions which are higher and lower layers and preset. MAC) control method. Such a control method includes providing a MAC having a message for executing a predetermined control function according to a control command of an upper layer of a mobile terminal or a network to a MAC of a calling party, and each physical layer of the calling party, a mobile terminal, and a network. Establishing a communication path by connecting the two to each other, notifying that the request signal is received from the called party's MAC to the called party's LAC, and responding to the signal from the called party's RAC to the calling party's MAC; In step MAC, it indicates that there is a response signal from the upper layer of the calling party.

Description

Control Method of Medium Access Control Sublayer (MC) in Mobile Communication System

The present invention relates to a method for controlling a medium access control sub-layer (hereinafter referred to as a MAC) of a next generation mobile communication system. More particularly, the present invention relates to a method for controlling a next generation mobile communication system for multimedia communication. The present invention relates to a control method of a medium access control sublayer (MAC) of a mobile communication system that performs its own function and performs various communication control functions with a higher layer or a lower layer.

In recent years, the development of mobile communication system is very rapid in each country. The digital mobile communication methods proposed to date have been proposed such as frequency division multiple access (FDMA), time division multiple access (TDMA), and code division multiple access (CDMA). Some countries or regions may use only one of the various access methods described above, or may use different types of mobile communication systems in parallel. Moscow, for example, uses both a CDMA mobile communication system and a GSM (Global System for Mobile Communication) mobile communication system. In this case, each mobile terminal or networks (or base station) should be provided with at least two types of modulation and demodulation modules in order to control the two types of signals interchangeably. These conditions reverse the global trend of thin and short communication equipment, which weakens the product's competitiveness.

In addition, even if the same communication method is used in the same region, there are many restrictions on the size and function of the product depending on the characteristics of the manufacturers and operators of mobile terminals and other communication devices and the options of each product. At any time, these factors do not correspond to the requirements of the mobile communication service to provide a call service at any place.

Therefore, studies are being actively conducted to increase the compatibility of communication devices between users using the same communication method in the same region to provide mobile communication services regardless of manufacturers and communication operators. As a representative example thereof, a digital European Telecommunication (DECT) system may be mentioned. DECT was developed because of the need to provide wireless-coded communications that are voice-based and can accommodate some data communication needs. Therefore, DECT provides interoperability between equipments of manufacturers of different communication equipments, thereby providing users with various communication services for voice and data as basic services as well as optional extension services.

This layer of DECT defines a protocol of four layers as shown in FIG. 1 is a block diagram showing the structure of a layered protocol stack of a DECT.

Conventional DECT is divided hierarchically into OSI layer 1 (10) representing all of the physical layer and part of the MAC layer of the DECT, and OSI layer 2 (20) representing all of most of the MAC layer and the data link control layer (DLC). ) And OSI layer 3 (30) representing all network layers.

Here, the physical layer (PHY) of the DECT is for dividing a given radio spectrum into physical channels. This split occurs in two areas: time and frequency. The division of frequency and time uses time division multiple access (TDMA) operation for multiple wireless carriers. For example, in the conventional DECT, 10 carriers are provided in a frequency band between 1880-1900 MHz. DECT's Media Access Control Layer (MAC) has two main functions. First select a physical channel, and then establish and release a connection on that channel. Second, the control information is multiplexed or demultiplexed into a slot-type packet together with higher layer information and error control information.

DECT's Data Link Control Layers (DLC1, DLC2) are responsible for providing reliable data links to the Network Layer (NWK) and provide a higher level of data integration than the Media Access Control Layer (MAC) alone provides. It is closely related to the media access control layer (MAC) to provide a to the upper layer.

In Figure 1, the C-plane is common to all applications and provides a very reliable transport link of internal control signals and a limited amount of user information traffic. The U-plane, on the other hand, offers several alternative services, each of which is optimized for the specific needs of each type of service.

The network layer (NWK) of DECT is the main signal layer of the protocol. Conventional DECT employs a similar form to the ISDN Layer 3 protocol (ETS 300 102) and also provides similar functionality.

In the conventional DECT, the MAC controls the operation of creating, maintaining and releasing a bearer, and selecting an empty physical channel and evaluating the quality of a received signal by activating or deactivating a pair of physical channels.

However, since the conventional MAC has been developed to be suitable for wireless code communication that can accommodate a certain amount of data communication needs mainly on voice, many problems are expected when applied to the next generation mobile communication system. The reason is that the next generation mobile communication system is a highly compatible mobile communication device that can solve both the problems caused by the different options between the manufacturer and the operator of the communication equipment or the problems caused by the different mobile communication methods. And a system is required.

In addition, since data used in the next generation mobile communication system is multimedia information such as voice, video, and TEXT, and requires very good call quality, many optional options are required. However, the MAC of the conventional DECT provides only two functions, that is, a physical channel selection, and a function of multiplexing or demultiplexing control information into slot-type packets. Therefore, the situation cannot be applied as it is in the next generation mobile communication system in the future, and the control method of such MAC has not been presented.

The present invention has been made to solve the problems caused by the prior art, an object of the present invention is to provide a mobile wireless communication service that can be compatible even if the manufacturer and the communication operator is different under different mobile communication systems It is to provide a control method of a medium access control sublayer (MAC) of a communication system.

In the mobile communication system, an upper layer which performs radio barrier control, radio resource control and mobility management, a LAC sublayer controlling link connection, a Mac sublayer controlling intermediate connection, and a lower layer which is a physical layer area are sequentially formed. In the communication control method,

A feature of the present invention for achieving the above object is that the control method of the medium access control sublayer in the mobile communication system is to control the MAC sublayer by the communication control command generated from any one of the upper layer and the LAC sublayer. Delivered through.

1 is a block diagram showing the structure of a layered protocol stack of a conventional DECT.

2 is a block diagram illustrating a protocol stack of a mobile communication system according to the present invention.

FIG. 3 is a control flowchart illustrating the overall control method of the MAC shown in FIG. 2.

4A to 4J are control flowcharts for describing control operations of various MACs according to an embodiment of the present invention.

Explanation of symbols for main parts of the drawings

MM: Mobility Operation Layer RBCC: Radio Bearer Control Layer

RRC: Radio Resource Control Layer LAC: Link Access Control Layer

MAC: Medium Access Control Sublayer PHY: Physical Layer

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

2 is a block diagram illustrating a protocol stack of a mobile communication system according to the present invention.

2, a protocol stack of a mobile communication system according to the present invention includes a physical layer (PHY) as a first layer, a MAC and a link access control sublayer (LAC) as a second layer, And a mobility management (MM) layer, a radio bearer control (RRC) layer, and a radio resource control (RRC) layer.

Here, the common control channel group and the dedicated channel control group are provided in the MAC, and the functions of each channel are as follows.

The common channel control group has a type of logical channel, which is composed of a synchronization channel, a broadcast control channel, and a common control channel.

The Synchronization Channel (SCH) includes a system time for time information, and includes base information for network identification information such as a network.

The Broadcasting Control Channel (BCCH) broadcasts general system information. The system information includes access parameter information necessary for the mobile terminal to access the network, neighbor cell information informing RF information of surrounding cells, information on available frequencies, and the like.

The common control channel (CCCH) is used to establish a dedicated signal channel (SDCCH) between the mobile terminal and the network. In an embodiment of the present invention, a common control channel is used as a paging channel (PCH) used for a called party, a random access channel (RACH) used by a mobile terminal to access a network, and the network is a mobile terminal. It consists of a Forward Access Channel (FACH) for responding to the access. Here, RACH and FACH are used as a pair of channels.

In addition, the dedicated control channel group is a type of logical channel, and is composed of a dedicated control channel, an associated control channel, and a traffic channel.

Stand alone Dedicated Control Channel (SDCCH) is a connected bidirectional logical channel in which mobile terminals are formed between networks. All signal information from this communication channel right after the dedicated control channel is established until the communication state is transmitted using this channel. Setup of terminal association (TA), call setup, etc. can be delivered using this channel.

Associated Control Channel (ACCH) is a connected bidirectional logical channel used in conjunction with a traffic channel. All signal information after the communication state is transmitted using this channel. Power control information, handover signal information, and the like during communication can be delivered using this logical channel.

A traffic channel (TCH) is a connected bidirectional channel formed between a mobile terminal and a network, where the speed of the channel is determined by the type of service.

A control method of a MAC provided with such a channel will be described with reference to FIGS. 3 to 4 as follows.

FIG. 3 is a control flowchart illustrating the overall MAC control operation, and illustrates the control operation between the mobile station and the MAC of the network or the base station.

Referring to FIG. 3, first, a predetermined control command is transmitted from the upper layer (MM1 / RBC1 / RRC1) to the application layer of the mobile terminal MT to LAC1 of the mobile terminal MT in a primitive form (ST1). The LAC1 requests a message according to the control command to the MAC1 of the mobile terminal MT (ST2). The MAC1 of the mobile terminal MT transmits to the MAC2 of the network NTWK through the respective physical layers PHY1 and PHY2 of the mobile terminal MT and the network NTWK (ST3). Then, MAC2 transmits the request message of MAC1 to LAC2 of the network NTWK (ST4). The LAC2 transmits the message of MAC2 to upper layers (MM2, RBC2 / RRC2) to the application layer of the network NTWK (ST5), and sends a response signal to MAC2 (ST6). Subsequently, the MAC2 transmits the response signal to the MAC1 through the physical layer of the network NTWK and the mobile terminal MT (ST7). Then, MAC1 transmits a confirmation signal for the execution of the control command first instructed to LAC1 (ST8). Then, LAC1 reports this to the upper layer or the application layer.

However, not all control commands follow the order shown in FIG. 3, and the paths are selectively routed according to the characteristics of the control commands.

Hereinafter, a method of controlling a MAC in various cases according to an embodiment of the present invention will be described.

Broadcast control delivery procedure of synchronization and system information

The broadcast control transfer function of sync information and system information provides a point-to-multipoint service for visual information, system information, and paging. Broadcast control may be a continuous transmission or a periodic transmission (Store and Forward). Various system parameters received by the mobile terminal MT are updated with the latest information.

Hereinafter, a broadcast control transfer procedure of synchronization and system information will be described with reference to FIG. 4A.

The mobile terminal MT used when there is a message to be transmitted from the RRC of the network NTWK to the LAC of the network NTWK, and a primitive defined by LAC_UNIT_DATA_REQ, which is a primitive of the network NTWK, is transmitted (SA1 and SA11). Then, the LAC of the network NTWK (NTWK) receives the LAC_UNIT_DATA_REQ primitive and delivers the mobile terminal MT and MAC_UNIT_DATA_REQ, which are primitives of the network NTWK, when there is a message to be transmitted to the MAC of the network NTWK (NTWK). SA2, SA12). Then, the network NTWK performs a broadcasting control service on the synchronization information or the system information by using a continuous or periodic transmission method to the mobile terminal MT (ST3 and SA13).

Then, the MAC of the mobile station MT uses the MAC_UNIT_DATA_IND, which is a primitive of the mobile station MT and the network NTWK, used when there is a message to transmit to inform that there is a request for synchronization information or system information. To the LAC (SA4, SA14). Subsequently, the LAC of the mobile station MT transmits LAC_UNIT_DATA_IND, which is a primitive of the mobile station MT and the network NTWK used when there is a message to be transmitted, to the RRC of the mobile station MT (SA5 and SA15).

Accordingly, the RRC of the mobile station MT can transmit MMAC_SYNC_REQ, a primitive of the mobile terminal MT used for time synchronization between the network NTWK and the mobile terminal MT, to the MAC of the mobile terminal MT (SA6). , SA16), the MAC of the mobile station MT delivers a PHY_SYNC_REQ, a primitive for requesting synchronization information to the physical layer (hereinafter, abbreviated as PHY) (SA7, SA17).

Random Access Control Procedure

The random access control function uses a common control channel to provide a point-to-point connection between the MT and the network NTWK. SDCCH) is used to set. The mobile station MT can access the network NTWK through a random access control procedure and performs call setup using this signal channel.

Hereinafter, the random access control procedure will be described with reference to FIG. 4B.

In the LAC of the mobile station MT, the MAC_ACC_REQ, which is a primitive for requesting radio resources for establishing a dedicated signal channel between the mobile station MT and the network NTWK, is transmitted to the MAC of the mobile station MT (SB1). In response to the request, the MAC of the mobile station MT transmits PHY_UNIT_DATA_REQ, a primitive of the mobile terminal MT and the network NTWK, used when there is a message to be transmitted from the MAC to the physical layer, to the PHY of the mobile terminal MT. (SB2).

Subsequently, the PHY of the mobile station MT is used when there is a message to be transmitted to the MAC of the network NTWK to inform that there is a request for a radio resource for establishing a transmission signal channel in the mobile station MT. ) And PHY_UNIT_DATA_IND, which is a primitive of the network NTWK (SB3, SB4).

Next, when the network NTWK receives a CHANNEL REQUEST message sent from the mobile terminal MT, the MAC of the network NTWK checks the MAC and sends MAC_ACC_IND, a primitive of the network NTNTK, to the LAC to request radio resources. Forward to LAC of (NTWK) (SB5).

At this time, the MAC of the network NTWK uses PHY_UNIT_DATA_REQ, which is a primitive of the mobile terminal MT and the network NTWK, used when there is a message to be transmitted from the MAC to the physical layer in order to ACK a channel request. (SB6). Subsequently, the PHY of the network NTWK transfers an ACK signal for the channel request to the PHY of the mobile station MT.

In addition, when the LAC of the network (NTWK) receiving the MAC_ACC_IND primitive receives the MAC_ACC_IND primitive sent from the MAC to indicate whether to accept or reject this request, the network (NTWK) primitive sent by RRC to request radio resources. The MAC_ACC_RSP is transmitted to the MAC of the network NTWK (SB8). Then, the MAC of the network NTWK transfers the PHY_UNIT_DATA_REQ, which is a primitive of the mobile terminal MT and the network NTWK used when there is a message to be transmitted from the MAC to the physical layer, to the PHY of the network NTWK (SB10). Then, the PHY of the network NTWK transfers the channel response to the radio resource request for establishing a dedicated signal channel to the PHY of the mobile terminal MT (SB10). Then, the PHY of the mobile station MT delivers PHY_UNIT_DATA_IND, which is a primitive of the mobile terminal MT and the network NTWK used when there is a message to be transmitted to the MAC of the network NTWK to the MAC of the mobile station MT ( SB11). Subsequently, the MAC of the mobile station MT transmits MAC_ACC_CNF, which is a primitive of the mobile terminal MT used to inform the LAC that the new radio resource allocation is completed, to the LAC of the mobile terminal MT (SB12).

Physical Channel Activation and Deactivation Control Transfer Procedures

The physical channel activation and deactivation control procedure is to perform a control transfer function for activation and deactivation of a physical channel, and is commonly used for a dedicated signal channel and a traffic channel.

Referring to FIG. 4C, the physical channel activation and deactivation control transfer procedure will be described below.

In order to activate a communication channel from the RRC / RBC of the mobile terminal MT and the network NTWK to each MAC of the mobile terminal MT or the network NTWK for activation of the physical channel or deactivation of the physical channel, RBC and When deactivating MMAC_ACT_REQ, which is a primitive of MT and network (NTWK) or a communication path that RRC delivers to MAC, it is a primitive of MT and network (NTWK) that RBC and RRC deliver to MAC. MMAC_DEACT_REQ is transmitted to the mobile terminal or the MAC of the network (SC1, 11, 21, 31). Then, when each MAC of the mobile station MT and the network NTWK attempts to activate the communication path with the PHY, PHY_ACT_REQ or communication, which is a primitive of the mobile terminal MT and the network NTWK, which the MAC delivers to the physical layer, When deactivating the furnace, the MAC transmits PHY_DEACT_REQ, which is a primitive of the mobile station MT and the network NTWK, which are transmitted to the physical layer (SC2, 12, 22, 32).

Subsequently, in each PHY of the mobile terminal or the network, hardware and software of a communication channel for activating or deactivating a physical channel are set, and each PHY is a mobile terminal (MT) used by the physical layer to inform the MAC that the communication channel is activated. ) PHY_ACT_CNF, which is a primitive of network (NTWK), or PHY_DEACT_CNF, which is a primitive of mobile terminal (MT) and network (NTWK), used by the physical layer to inform MAC that the communication path is deactivated. To each of the MAC (SC3, 13, 23, 33).

Then, the MAC of the mobile station (MT) to the network (NTWK) that has received the PHY_ACT_CNF or PHY_DEACT_CNF primitive is a primitive of the mobile station (MT) and the network (NTWK) used by the MAC to inform the RBC and RRC that the channel has been activated. MMAC_ACT_CNF or MMAC_DEACT_CNF, which is a primitive of the mobile station MT and the network NTWK, used by the MAC to inform the RBC and RRC that the communication channel is deactivated, is transmitted to the RRC and RBC of the mobile station MT (SC4, 14, 24,34).

Cell environment and channel environment report delivery procedure

These procedures are necessary to satisfy the quality of service requirements of the subscriber when allocating traffic channels, and are measured by the mobile station MT and reported to the network NTWK.

When the MAC of the mobile station MT receives an instruction for measuring a cell environment or a channel environment of a corresponding cell from the RRC of the mobile station MT, the MAC of the mobile station MT instructs the physical layer of the mobile station MT to measure the cell environment. The physical layer measures a cell environment or a channel environment and provides the result back to the MAC of the mobile station MT. The MAC of the mobile station MT reports this information to the RRC of the mobile station MT. The RRC of the mobile station MT transmits the measurement result of the cell environment or the channel environment to the network NTWK through the LAC of the mobile station MT to use it at the time of traffic channel. Measurement conditions (periodical or necessary) for the cell environment or channel environment are obtained through system information messages in the network NTWK.

Hereinafter, the cell environment and channel environment reporting procedure will be described with reference to FIGS. 4D to 4E.

LAC_UNIT_DATA_REQ, which is a primitive of mobile terminal (MT) and network (NTWK) used when there is a message to send a request to measure cell environment and channel environment from RRC of network (NTWK) from LAC to LAC, is LAC of network (NTWK) (SD1, SE1). Subsequently, the mobile station MT used when there is a message to be transmitted from the LAC of the network NTWK to the MAC of the network NTWK and the MAC_UNIT_DATA_REQ, which is a primitive of the network NTWK, are transferred to the MAC of the mobile terminal MT (SD2). , SE2). Accordingly, the MAC of the mobile station MT transmits MAC_UNIT_DATA_IND, a primitive for requesting the report of the cell environment or the channel environment, to the LAC of the mobile station MT (SD3, SE3). The LAC of the mobile station MT transmits a LAC_UNIT_DATA_IND, a primitive indicating that there is a request for reporting a cell environment or channel environment, to the RRC of the mobile station MT (SD5, SE5). Accordingly, the RRC of the mobile station MT transmits MMAC_MEASURE_REQ, a primitive requesting the PHY of the mobile station MT to measure the cell environment and the channel environment (SD6, SE6). In addition, the PHY of the mobile station MT transmits the cell environment and the channel environment to the RRC of the mobile station MT, which is a primitive MMAC_MEASURE_CNF indicating that the measurement for the measurement request is completed (SD7, SE7).

Then, the RRC of the mobile station MT transmits the LAC_UNIT_DATA_REQ, which is a primitive indicating the measurement result of the cell environment and the channel environment requested by the network NTWK, to the LAC of the mobile station MT (SD8, SE8). Subsequently, the LAC of the mobile station MT transmits the MAC_UNIT_DATA_REQ, which is a primitive indicating the measurement result of the cell environment and the channel environment, to the MAC of the mobile station MT (SD9 and SE9). Subsequently, the measurement result information of the cell environment or the channel environment output from the MAC of the mobile station MT is transmitted to the MAC of the network NTWK (SD10, SE10), and the network of the network NTWK in the form of a MAC_UNIT_DATA_IND primitive. It is delivered to the LAC of (NTWK) (SD11, SE11), and then to the RRC of the network (NTWK) in the form of a LAC_UNIT_DATA_IND primitive (SD12, SE12).

LAC Information Passing Procedure

When a dedicated channel (including a signal channel and a traffic channel) is successfully established between the mobile terminal MT and the network NTWK, the dedicated channel controller performs the following two types of information transfer functions, namely, a control function (Control Information) transfer function and the like. It provides a function of transferring user information.

Hereinafter, an information delivery procedure of the LAC will be described with reference to FIG. 4F.

The LAC of the mobile station MT to the network NTWK transfers MAC_UNIT_DATA_REQ, a primitive used to request control information and user information, to the MAC of the mobile terminal MT to the network NTWK, respectively (SF1 and SF11). Then, the MAC of the mobile terminal MT or the network NTWK transfers PHY_UNIT_DATA_REQ, a primitive used when there is a message to be transmitted from the MAC to the physical layer, to the PHY of the mobile terminal MT or the network NTWK, respectively (SF2, SF12). Accordingly, each PHY of the MT and the NTWK transfers the PHY_UNIT_DATA_IND, a primitive used when there is a message to be transmitted from the physical layer to the MAC, to the MAC of the MT and the NTWK (SF3). , SF13). Subsequently, each MAC of the mobile terminal MT to the network NTWK transfers the MAC_UNIT_DATA_IND, a primitive used when there is a message to be transmitted from the MAC to the LAC, to the LAC of the mobile terminal MT to the network NTWK (SF4, SF14). ). Therefore, the control information and the user information of the mobile terminal MT to the network NTWK may be transmitted to the network NTWK to the mobile terminal MT, respectively.

Encryption control delivery procedure of MAC

In order to protect the data, this procedure refers to a procedure of requesting encryption from the MM of a mobile terminal (MT) to a network (NTWK) with a MAC, actually performing encryption at the physical layer, and then notifying the MM through the MAC. .

Hereinafter, the encryption control procedure of the MAC will be described with reference to FIG. 4G.

Mobile terminal MT to network NTWK MM delivers MMAC_CIPHER_REQ, which is a primitive of mobile terminal MT and network NTWK used to notify MAC for encryption, to its own MAC, and mobile terminal MT Each MAC from the network NTWK carries a PHY_CIPHER_REQ primitive to each PHY (SG1, SG11).

Each PHY of the mobile terminal MT to the network NTWK transfers PHY_CIPHER_CNF, a primitive used to confirm that encryption is completed by performing encryption of user data, to the MAC of the mobile terminal MT to the network NTWK, The MAC of the mobile station MT and the network NTWK uses MMAC_CIPHER_CNF, which is a primitive of the mobile station MT and the network NTWK used to inform the MM that the MAC has completed the encryption process, from the mobile station MT to the network NTWK. To each MM).

MAC handover control forwarding procedure

In this procedure, when the radio resource quality of the cell becomes worse than the radio resource quality of the neighbor cell, and the current radio environment is notified to the RRC by the MT or the NTWK MAC, The RBC issues a handover command to its MAC again. In addition, a procedure of performing a handover in the physical layer of the mobile station MT to the network NTWK and then notifying the RBC of the result is shown.

Hereinafter, the handover control transfer procedure of the MAC will be described with reference to FIG. 4H.

The mobile station MT to the network NTWK measures the error rate or interference level of the received transmission frame, the strength of the pilot signal, and the like, when reaching a preset threshold for handover. Each MAC of the NTWK forwards PHY_HO_TRIGGER_IND, which is a primitive of the mobile terminal MT to the network NTWK, used to inform the handover request to the RRC, to its RRC / RBC (SH1, SH11). The RRC / RBC of the MT-NTWK uses the MMAC _HO_REQ, a primitive of the MT and the NTWK, used for requesting handover, of the MT-NTWK. Pass to PHY (SH2, SH12).

In response to the handover request, the PHY of the mobile station MT to the network NTWK sends a PHY_HO_CNF, a primitive for performing the requested handover and confirming that the handover has been performed, to the MAC of the mobile terminal MT to the network NTWK. Each MAC forwards each MMAC_HO_CNF primitive to the mobile station MT and the network NTWK RRC (SH3, SH13).

Channel change control forwarding procedure of MAC

This procedure indicates the procedure that the RBC makes a request to the MAC and informs that the channel has been changed when the cell environment or channel environment is not good.

Hereinafter, a communication channel change control transfer procedure of a MAC will be described with reference to FIG. 4I.

In order to change the attributes of the communication path, the RBC of the MT or the NTWK uses its MAC, MMAC_MODIFY_REQ, which is a primitive of the MT and the network NTWK, which it sends when it wants to change the attributes of the communication path. It passes to its own PHY through (SI1, SI11).

In response to the communication channel change request, the PHY of the mobile terminal MT to the network NTWK performs the requested communication channel change request to the mobile terminal MT to the network NTWK, indicating that the change of the communication path is completed. The primitive MMAC_MODIFY_CNF is transmitted to each RBC of the mobile station MT through the network NTWK through the MAC of the mobile station MT through the network NTWK (SI2 and SI12).

Control procedure of radio failure situation control of MAC

This procedure tells the RBC to the RBC about any failure in the radio environment (lack of radio resources, network (NTWK) equipment failure, no radio resources available, no radio resource changes, etc.), and RBC stops setting up the radio bearer on the MAC. It shows the procedure to request the request and inform the RBC of the result again.

Hereinafter, the radio failure situation control procedure of the MAC will be described with reference to FIG. 4J.

When the failure of the wireless communication connection on the communication path occurs, the MAC of the mobile terminal MT or the network NTWK forwards MMAC_RADIO _FAIL_IND, a primitive that notifies all failures not defined in the MAC, to its RRC / RBC. SJ1, SJ11). The RRC / RBC of the MT or the NTWK moves to stop the setup of the radio bearer by using MMAC_DEACT_REQ, a primitive transmitted to recognize a failure state of the transmitted radio communication connection and to indicate that the communication path is deactivated. Requests are made to the PHY of the terminal MT to the network NTWK, respectively (SJ2 and SJ12). Accordingly, the PHY of the mobile station MT or the network NTWK stops setting up the radio bearer and uses the result of MMAC_DEACT_CNF as its RRC / RBC through its MAC. (SJ3, SJ13).

As described above, according to the present invention, a broadcast control transmission procedure of a synchronization and system information, a random access control procedure, a physical channel activation and deactivation control transmission procedure, a cell environment to a channel environment report transmission procedure, and LAC information transmission using a MAC Procedure, encryption control transfer procedure of MAC, handover control transfer procedure of MAC, communication path change control transfer procedure of MAC, and wireless failure situation control procedure of MAC.

Therefore, using a medium access control sublayer (MAC) according to the present invention and a communication control method using the same, the MAC is controlled to provide a compatible wireless mobile communication service even if the manufacturer and the communication operator are different under different mobile communication systems. It can be very useful in the next generation multimedia communication environment.

Claims (10)

In the mobile communication system, an upper layer which performs radio barrier control, radio resource control and mobility management, a LAC sublayer controlling link connection, a Mac sublayer controlling intermediate connection, and a lower layer which is a physical layer area are sequentially formed. In the communication control method, And a communication control command generated at any one of the upper layer and the LAC sublayer is transmitted through the control of the MAC sublayer. The method according to claim 1, wherein when the control command requires execution of synchronization between the mobile terminal and the network and transmission of broadcast control of system information, Providing time information, system information, and paging related information to a plurality of mobile terminals in the network; receiving information provided from the network at the mobile terminal, and updating synchronization request or system information to its physical layer; The method of controlling the medium access control sublayer in the mobile communication system, characterized in that the step of sequentially transmitting the request message. The method of claim 1, wherein the control command requires execution of a random access control procedure between the mobile terminal and the network. Requesting a radio resource from the mobile terminal to the network using its MAC; Informing that the request signal has been transmitted from the network to the MAC of the mobile terminal; Transmitting a response to a request for a radio resource from the network to the mobile terminal; And sequentially notifying the upper layer of the MAC of the mobile terminal that the response signal has been received by the MAC of the mobile terminal. The method of claim 1, wherein the control command requires execution of a physical channel activation and deactivation control transfer procedure of a mobile station or a network. Requesting activation or deactivation of a communication path to its own physical layer using its MAC in the mobile terminal or the network; selectively enabling or deactivating the communication path according to the request signal; And sequentially informing the result to the mobile terminal or the network requesting activation or deactivation of the communication path. The method of claim 1, wherein the control command requires execution of a cell environment or channel environment report transmission procedure of a mobile station. The network instructing a mobile terminal to measure a cell environment or a channel environment of a corresponding cell; The mobile terminal instructing the physical layer of the mobile terminal to measure a cell environment; Measuring, by the physical layer of the mobile terminal, a cell environment or a channel environment for the mobile terminal and providing the result to the mobile terminal; The mobile terminal sequentially performs the step of transmitting the measurement results of the cell environment or the channel environment to the network control method of the medium access control sublayer in the mobile communication system. The method of claim 1, wherein when the LAC layer requests control information and user information, requesting control information and user information from the mobile terminal or the LAC of the network using its MAC and physical layer to the network or mobile terminal. A method for controlling a medium access control sublayer in a mobile communication system. The method of claim 1, wherein the control command requires execution of an encryption control transfer procedure of a mobile terminal or a network. Requesting encryption at the physical layer of the mobile terminal or the network, executing encryption on the physical layer of the mobile terminal or the network according to the request, and performing the encryption at the same terminal or network. The method of controlling the medium access control sublayer in the mobile communication system, characterized in that sequentially performing the step of notifying the result. The method of claim 1, wherein the control command requires execution of a handover control transfer procedure of the MAC. Transmitting a handover execution command to its own physical layer in the mobile terminal or the network, and performing a handover according to the handover execution command and then applying the handover execution command to the mobile terminal or network execution result; The method of controlling the medium access control sublayer in the mobile communication system, characterized in that to sequentially perform the step of notifying. The method of claim 1, wherein the control command requires execution of a communication channel change control procedure between the mobile terminal and the network. Requesting a communication channel change request from a mobile terminal or a network to its own physical layer, and performing a communication channel change according to the communication channel change request, and notifying the mobile terminal or the network requesting the change of the communication path. The control method of the medium access control sublayer in the mobile communication system, characterized in that carried out. A physical layer (PHY), an access control sublayer (MAC) that is higher than the physical layer, a link access control layer (LAC) that is higher than the access control sublayer, a mobility management layer (MM), and a radio bearer control layer ( Between a mobile terminal and a network or a base station, each having a stack structure of a communication protocol composed of an upper layer of the link access control layer including an RBC and a radio resource control layer (RRC), a) providing a signal having a message for executing a predetermined control function to the calling party's MAC according to a control command of an upper layer of the calling party defined as any one of the mobile terminal and the network; b) forming a communication path by connecting each physical layer between the calling party, the called party, and the called party defined as the other party not selected as the calling party of the network; c) informing the LAC of the called party of the called party that the request signal of step a) has been received; d) responding to the signal of step c) in the called party's RAC from the called party's RAC; e) notifying that the response signal of step d) was received from the MAC of the calling party to the higher layer of the calling party; And controlling each of the steps selectively in accordance with the characteristics of the control command of the mobile terminal or the network.