KR100365624B1 - Device and method for designating frame offset of supplemental channel in cdma communication system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a code division multiple access (CDMA) type mobile communication system. In particular, in a code division multiple access type mobile communication system, a call connection state between a base station and a terminal is provided. The present invention relates to an apparatus and method for designating a frame offset for a supplemental channel used when a supplementary channel is connected in a state.

In the present invention, an additional channel is additionally allocated when a high speed data transmission is required in a traffic channel connection state between a base station and a terminal in a CDMA system. In this case, a frame offset different from that of the base channel can be designated. Allows multiple users who are assigned a frame offset to transmit at high speed simultaneously. The base station delivers information specifying the new frame offset through the non-negotiated service environment variable of the service connection message or the handoff indication message. The terminal receiving the frame offset information, in addition to the existing frame offset for the base channel, the frame option device and method for processing additional frame offset in the base channel and the additional channel by specifying a frame offset for the additional channel in addition to the existing It is characterized by.

Description

DEVICE AND METHOD FOR DESIGNATING FRAME OFFSET OF SUPPLEMENTAL CHANNEL IN CDMA COMMUNICATION SYSTEM}

The present invention relates to a communication apparatus and method of a code division multiple access mobile communication system, and more particularly, to an apparatus and method for allocating an additional channel in a code division multiple access mobile communication system.

In general, a mobile communication system using Code Division Multiple Access (hereinafter referred to as " CDMA ") is assigned a different frame offset for each user, thereby transmitting a frame with each user. Are separated.

In the conventional CDMA mobile communication system, the frame offset is divided into 16 equal parts by 20ms, and the respective frame offsets are allocated to each user. The frame offsets assigned to each of the users transmit / receive the data frame at a time delayed by the frame offset based on the system time.

The frame offset has the effect of distributing the load in the case of a voice call. In this case, when many users want to transmit data at the same time at the frame boundary of 20 ms, it may occur that the frames of all users cannot be processed at the same time. In this case, the frame processing time is delayed between the channel card, the base station controller, and the voice codec. Such a delay may be a major factor causing quality deterioration in a voice service. Thus, after dividing the frame section of 20ms into 16, the divided sections are equally distributed for each user, and the load is naturally distributed by using the reference time delayed by the corresponding frame offset between the base station and the terminal.

By the way, the conventional CDMA mobile communication system has mainly provided voice-oriented services, but in recent years, the emergence of the next generation CDMA mobile communication system that enables high-speed data transmission as well as voice. The next generation CDMA mobile communication system is commonly referred to as a mobile communication system of IMT-2000 standard. In the mobile communication system of the IMT-2000 standard, new services such as high quality voice, moving picture, and internet search are made possible.

In the conventional voice service, a constant load is often generated evenly at regular intervals. Therefore, in the voice service, users distributed evenly by frame offset could process voice data without delay. However, in the next generation CDMA mobile communication system centering on multimedia services, data having different characteristics from conventional voice data is generated. That is, the other data may be packet data or the like. In this case, the packet data is often generated in bursts, so that a certain amount of data does not occur continuously and a large amount of data is generated in a short time.

When traffic having the above characteristics occurs, the system allocates a supplemental channel in addition to the fundamental channel. In this case, the additional additional channel uses the same frame offset as that of the already connected basic channel.

When multiple users assigned the same frame offset need to transmit a large amount of data at a high data rate, a situation may occur in which the capacity of the traffic that can be transmitted without delay is exceeded at the corresponding frame offset. The call is set up using only the first base channel, and each user is assigned a unique frame offset for the first base channel.

In this case, several users may have the same frame offset, and a situation may occur where traffic exceeds the capacity of a link between a base station and a base station controller at a specific frame offset. This means that delays in data can occur. In the case of a service in which a delay of a voice service or the like that uses the base channel affects the quality of service, the quality of service may be lost.

In addition, in other aspects, various methods may be used in the current additional channel operation. In general, in the CDMA mobile communication system, when more data is generated than the amount of data that can be transmitted through the basic channel, an additional channel having a different code is used for each user. In this case, in the next generation CDMA mobile communication system, the additional channel due to the generation of additional traffic can be allocated while the basic call is connected. In this case, since the allocated additional channel is fixed for each user, there is a problem that a service delay and scheduling loss may occur. In addition, in a next generation system in which high speed transmission is inevitable, there may be a scheme in which a plurality of users divide time by using a plurality of additional channel elements without using additional channels divided by users. However, when using the above method, scheduling loss may occur due to users having different frame offsets.

Accordingly, an object of the present invention is to provide an apparatus and method for allocating a channel for transmitting data by designating a frame offset when a data transmission request is performed in a state where a basic call is connected in a code division multiple access communication system.

Another object of the present invention is to provide an apparatus and method for allocating an additional channel by designating a frame offset of the additional channel in a data transmission request in an traffic state of a code division multiple access communication system.

It is still another object of the present invention to provide an apparatus and method for designating new frame offset information so that a base station can allocate an additional channel by specifying a frame offset of an additional channel when a data transmission request is performed in an traffic state of a code division multiple access communication system. In providing.

It is still another object of the present invention to provide an apparatus and method for allowing a terminal to receive frame offset information from a base station and designate a frame offset of an additional channel when a data transmission request is performed in an traffic state of a code division multiple access communication system.

Another object of the present invention is to provide an apparatus and method for allocating a new frame offset for an additional channel in a handoff situation in a code division multiple access communication system.

It is still another object of the present invention to provide an apparatus and method for allocating a new frame offset for an additional channel when handing off an additional channel in a handoff situation in a code division multiple access communication system.

Another object of the present invention is to provide an apparatus and method for allocating an additional channel by newly designating a frame offset when a new channel is newly allocated in a handoff situation of a code division multiple access communication system.

It is still another object of the present invention to provide an apparatus and method for designating new frame offset information so that a base station can assign an additional channel or handoff by designating a frame offset of an additional channel in a handoff situation of a code division multiple access communication system. In providing.

It is still another object of the present invention to provide an apparatus and method for allowing a mobile station to receive frame offset information from a base station and designate a frame offset of an additional channel in a handoff situation of a code division multiple access communication system.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram illustrating a message procedure of additional channel allocation in a code division multiple access communication system.

2 is a flowchart illustrating an added procedure according to an offset specification of a frame when allocating an additional channel in a code division multiple access communication system according to an exemplary embodiment of the present invention.

FIG. 3 is a diagram illustrating an extended supplemental channel assignment message field definition state in which a field is newly added for allocation of a frame offset for an additional channel in FIG. 2; FIG.

4 is a diagram illustrating a structure of a signal demodulator of a receiver in a code division multiple access communication system.

5 is a diagram illustrating a structure of a combiner in a signal demodulator in a code division multiple access communication system according to an embodiment of the present invention.

FIG. 6 shows the structure of a timing generator in the combiner of FIG. 5; FIG.

7 is a diagram illustrating a message procedure for call setup in a code division multiple access communication system.

8 is a flowchart illustrating an added procedure according to an offset designation of a frame of an additional channel in service negotiation in a code division multiple access communication system according to an embodiment of the present invention.

9 is a diagram illustrating a handoff procedure of a code division multiple access mobile communication system according to an embodiment of the present invention.

10 is a flowchart illustrating a frame offset assignment procedure when allocating an additional channel during handoff in a code division multiple access mobile communication system according to an embodiment of the present invention.

11 is a diagram illustrating a form of an additional channel assignment message or a handoff indication message to which a non-negotiated service environment variable field is added according to an embodiment of the present invention.

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

First, the present invention to be described later will be applied in the case of the next generation CDMA mobile communication system. Therefore, in the embodiment of the present invention to be described later, the CDMA2000 system according to the US method will be described as an example, but the present invention can be applied to a UMTS system using the European method.

The present invention further provides an apparatus for additionally allocating an additional channel for transmitting data when a high speed data transmission is required in a call connection state between a base station and a terminal of a code division multiple access mobile communication system. And a method. More specifically, the present invention relates to an apparatus and method for specifying a frame offset of the Supplemental Channel appropriately according to the amount of data to be transmitted and received for each frame offset. To this end, in the CDMA communication system according to an embodiment of the present invention, an additional channel is additionally allocated when a high speed data transmission is required in the traffic channel connection state between the base station and the terminal, and the frame offset of the additional channel is currently used. Reset according to the amount of data to be transmitted / received for each frame offset. In this case, the additional channel may specify a frame offset different from the frame offset of the base channel currently being used or the same frame offset as the frame offset of the base channel. In this way, if the frame offset of the base channel and the additional channel is specified differently, multiple users assigned the same frame offset can simultaneously transmit at high speed. Then, the base station delivers information for designating a new frame offset to the terminal through an additional channel assignment message. In addition to the frame offset for the base channel, the terminal receiving the frame offset information from the base station may additionally specify a frame offset for the additional channel to operate different frame offsets in the base channel and the additional channel.

1 is a diagram illustrating a general additional channel allocation procedure in a code division multiple access mobile communication system. 1 illustrates a message procedure between modules on a terminal side and modules on a base station side.

Referring to FIG. 1, the terminal manages and controls a service processor (SIG), which is a part for processing a service option in which an application service is running, a control message related to channel setting, and a base station resource. It consists of a resource controller (RC) for performing a function. The configuration of the terminal side is similar in the case of the base station. The base station also includes a message processor (SIG) which processes a control message related to a part (ServiceOption) in which an application service is running, a channel setting, and the like, and a resource controller (RC) which manages and controls various logical and physical resources of the terminal. ) And so on.

Referring to the additional channel allocation process with reference to FIG. 1, when user data to be transmitted is generated from the terminal, the service option checks the size of the data and determines whether the additional channel is required. If it is determined that the allocation of the additional channel is necessary, a signal (Data_Tx_SCH.Req) requesting allocation of the additional channel is transmitted to the resource controller RC in step 110. In step 120, the resource controller RC transmits a signal SCH_Assign.Req to allow the allocation of the additional channel to the message controller SIG. The message processor (SIG) transmits a supplemental channel request message to the base station in step 130.

When the base station receives the additional channel request message transmitted from the terminal as described above, the message processor (SIG) of the base station confirms whether the additional channel allocation requested by the terminal can be requested by the resource control unit (RC) of the base station in step 140. Done. At this time, if the additional channel can be allocated, the resource control unit (RC) informs the service option (Service Option) of the application service layer of the base station that the data transmission request of the terminal in step 150. When the data transmission request is received as described above, the service option, which is an application service layer, undergoes various processes for receiving data.

Process 160 of FIG. 1 illustrates a processing result according to a request for data transmission in a service option of a base station. The process 160 may be described by distinguishing a case in which the terminal initiates a data transmission request from a case in which the base station activates. When the terminal is activated, the base station notifies the resource controller RC that data reception preparation (Data_Rx_SCH.Res) has been made in step 160. If the data was previously transmitted and received on the basic channel, there is no need to specially inform the data reception preparation. In addition, when the base station is activated, the base station transmits a signal (Data_Tx_SCH.Req) for requesting allocation of the forward additional channel to the resource control unit (RC) similarly to the activation process at the terminal in step 160.

In step 160, the resource control unit RC, which receives the data ready to be output by the service option or receives the allocation request signal of the data channel, checks whether the additional channel in the reverse or forward direction can be allocated. In this process, a frame offset reassignment procedure required by an embodiment of the present invention is added. In the added procedure, a process of setting a new frame offset with less load among parameters required for allocation of additional channels is added. Description of the added procedure will be described later in detail with reference to FIG. In step 170, the resource controller RC sends a message processing unit SIG whether to allocate an uplink or downlink additional channel. In this case, if the allocation of the additional channel for transmitting the data is allowed, the message processing unit (SIG) sends an Extended Supplemental Channel Assignment Message to the terminal in step 180.

When the message processing unit (SIG) of the terminal receives the additional channel allocation message transmitted from the message processing unit (SIG) of the base station, in step 190 transmits a control signal to the resource control unit (RC). In addition, a transmission channel or a reception channel of a corresponding additional channel is allocated. Finally, when the allocation of the additional channel is completed, the resource controller (RC) informs the transmission and reception of data to the service option, which is the application service layer of the terminal in step 195. After performing the above process, the base station and the terminal exchange data traffic through an additionally allocated additional channel.

FIG. 2 is a flowchart illustrating a frame offset allocation procedure for an additional channel to be proposed in an embodiment of the present invention among the additional channel allocation procedure performed by the procedure of FIG. 1. In FIG. 2, operations 210 through 250 illustrate operations performed by the base station (process 140 through process 170 of FIG. 1). Performing steps 260 to 295 illustrates an operation performed by the terminal (steps 180 to 195 of FIG. 1). The frame offset allocation procedure for the additional channel of the base station is processes 140 to 180 of FIG. 1, and the frame offset allocation procedure for the additional channel of the terminal is 110, 120, 130, 190, and 195.

When the UE requests an additional channel request message or traffic is generated in the application service layer of the base station, the resource controller RC requests the allocation of the additional channel to the resource controller RC. By determining whether logical resources are available, it is decided whether additional additional channels can be allocated in the reverse or forward direction. In this case, if the allocation of the additional channel is not allowed, the resource controller RC proceeds to step 230 to transmit data traffic to the already connected basic channel or dedicated control channel or to delay transmission of the data traffic and when the next command comes. Wait until

However, if the allocation of additional channels is possible in step 220 or if a SCRM (Supplemental Channel Request Message) is received from the UE, the resource controller RC proceeds to step 240. In step 240, the resource controller RC designates a frame offset available for the additional channel, notifies the message processing unit SIG, and informs the frame offset of the additional channel to the physical layer. Then, the physical layer sets this value as a dedicated frame offset for additional channel processing. Here, the frame offset of the additional channel configured for data transmission may be designated as an appropriate frame offset according to the amount of data to be transmitted and received for each frame offset. At this time, it may be set to have an offset different from the frame offset of the basic channel. It may also be the same as the frame offset of the base channel. The offset of the additional channel may be generated by using a preset value or by a separate operation at the base station. In the process of the resource controller (RC) designating the frame offset, it is necessary to appropriately distribute the load to set an appropriate value for data transmission without delay. Thereafter, the resource controller RC generates an additional channel assignment message to which an additional channel offset related field is added in step 250 and transmits the corresponding message to the terminal.

When the base station transmits the additional channel allocation message as described above, the message processing unit (SIG) of the terminal interprets the additional channel allocation message received in step 260, and passes the result to the resource controller (RC) of the terminal. In the process, the message processor SIG transmits, together with other additional channel parameters, whether the frame offset for the additional channel is specified and its value to the resource controller RC. Then, the resource controller RC receives the analysis result of the message processor SIG received in step 260 and checks whether a frame offset of the additional channel is designated in step 270. In this case, if the frame offset of the additional channel is designated, the frame offset for the additional channel corresponding to the value is set in step 280. If the frame offset for the additional channel is set or if the frame offset of the additional channel is not specified, a new frame offset is notified to the physical layer with the additional channel allocation signal in step 290. When the additional channel related signal is received from the resource controller (RC), the physical layer further allocates the additional channel and sets a frame offset for the additional channel to enable transmission / reception. If the reverse / forward additional channel is configured between the base station and the terminal as described above, data traffic of the application service is transmitted in step 295.

According to an embodiment of the present invention, a process of determining whether to allow an additional channel by a resource controller (RC) of the base station and a process of investigating a SCH frame offset to be used exclusively for the additional channel when the setting of the additional channel is determined. In addition, the present invention proposes a process of adding a frame offset message to the UE to make the frame offset as shown in FIG. 3 and assigning a frame offset specified in the physical layer to the allocated additional channel. In the process of specifying the frame offset by the resource controller (RC), it is necessary to appropriately distribute the load to set an appropriate value to which data can be transmitted without delay.

The terminal also checks the frame offset for the additional channel in the process of interpreting the additional channel assignment message, passes it to the resource controller, notifies the value so that the set value can be used in the physical channel by the resource controller, and the physical layer. Proposes a new frame offset when additional channels are allocated.

3 is a diagram illustrating a configuration of an additional channel assignment message field, and illustrates a modified form of an additional channel assignment message to which a frame offset related field for an additional channel is added.

Referring to the field for allocating the frame offset for the additional channel in the additional channel assignment message as shown in FIG. 3, a REV_SCH_FRAME_OFFSET_INCL field indicating whether to newly specify a frame offset when allocating the reverse subchannel and a REV_SCH_FRAME_OFFSET field for actually specifying a new frame offset Will be added. In addition, FOR_SCH_FRAME_OFFSET_INCL and FOR_SCH_FRAME_OFFSET, which indicate whether a frame offset is designated and a designated value, are added together when allocating a forward additional channel. In the existing system, the same value as the frame offset specified when the base channel or the dedicated control channel is allocated is allocated to the additional channel. However, in the present invention, 16 frame offsets within 20 ms when the REV_SCH_FRAME_OFFSET and the FOR_SCH_FRAME_OFFSET are specified to allocate the additional channel. You can specify one by 1.25ms.

4 is a diagram illustrating a demodulator configuration of a receiving apparatus in a CDMA communication system.

Referring to FIG. 4, 400 receives various signals as an antenna of a mobile station. 410 is a correlator that distinguishes signals received by each multipath from the input of the antenna 400. 420 is a combiner that combines the signals received in each multipath into one. The signal output from the combiner 420 is applied to a deinterleaver 430. The output of the deinterleaver 430 is transferred to a decoder 440 for a decoding process. The combiner 420 transmits a signal indicating a frame boundary in addition to the combined symbol to the deinterleaver 430 through the control line 450.

Referring to the operation of the demodulator having the configuration as shown in FIG. 4, the correlators 410 detect correlation values of signals received through respective multipaths, and the combiner 420 combines and outputs correlation values output from the correlators 410. . In addition, the combiner 420 generates a signal for distinguishing a frame at the boundary of the frame. In this embodiment, since the frame offset values of the base channel and the additional channel are set differently, the combiner 420 generates the frame boundary signals of the base channel and the additional channel at different times. This will be described in detail with reference to FIG. 5.

The deinterleaver 430 receives a frame boundary signal from the combiner 420 through the control line 450, and deinterleaves and outputs the symbols output from the combiner 420 in units of the frame period. In this case, the signals output through the control line 450 include signals indicating at least an FCH / DCCH frame boundary and an SCH frame boundary. The decoder 440 decodes the symbols output from the deinterleaver 430 to generate decoded data.

FIG. 5 is a diagram illustrating the structure of the combiner 420 of FIG. 4 in more detail.

Referring to FIG. 5, the combiner 420 includes a timing generator 540, a first symbol combiner 550 for combining symbols of FCH / DCCH, and a second symbol for combining symbols of an SCH. Couplers 555 should be provided. The timing generator 540 sets a frame boundary by inputting system time (System_Time), generates a frame boundary signal at the boundary of the set frame, and outputs the frame boundary signal to the first and second deinterleavers 431 and 435. In the embodiment of the present invention, since the frame offset of the additional channel is set at the time of assigning the additional channel, a frame offset different from the base channel and the dedicated control channel may be used. Accordingly, the timing generator 540 is a frame boundary control line 1 (FCH / DCCH) 565 of the FCH / DCCH corresponding to the system time and frame offset values of the FCH / DCCH and SCH, respectively. A second frame boundary signal (frame boundary control line 2 (SCH)) of 560 is generated. That is, when additional channel is to be allocated for data transmission, the timing generator 540 appropriately sets the frame offset of the additional channel so as to have a value different from the frame offset of the currently allocated base channel in the traffic state. The frame offset values of the FCH / DCCH and SCH are provided in a channel assignment message transmitted from the base station. The frame offset value of the FCH / DCCH is transmitted in a basic channel assignment message, and the frame offset value of the SCH is transmitted in a secondary channel assignment message. The channel allocation message is transmitted to the message processor 510, and the channel allocation message processed by the message processor 510 is provided to the resource controller 520 and output as a frame offset value for the base channel (FCH / DCCH) and the additional channel (SCH). do. The frame offset values for the base channel and the additional channel are transmitted to the timing generator 540.

The first symbol combiner 550 combines multipath symbols of a basic channel / dedicated control channel (FCH / DCCH), and the second symbol combiner 555 combines multipath symbols of an additional channel (SCH). Then, the first deinterleaver 431 deinterleaves the combined symbols output from the first symbol combiner 550 on a frame basis by the first frame boundary signal 565 output from the timing generator 540. The second deinterleaver 435 deinterleaves the combined symbols output from the second symbol combiner 555 on a frame basis by the second frame boundary signal 560 output from the timing generator 540.

FIG. 6 schematically shows the structure of the timing generator 540 of FIG. Delayers 620 and 630 are required to generate frame boundaries using system time 530 and frame offsets 610 and 640. In this case, the frame offsets 610 and 640 include a frame offset 610 corresponding to the base channel (FCH / DCCH) and a frame offset 640 corresponding to the additional channel (SCH). In this case, the frame offsets 610 and 640 are provided from the resource controller 520 shown in FIG. The delayer 620 uses a value delayed by the frame offset 610 set by the resource controller 520 using the transferred system time 530. That is, the delayer 620 outputs the base channel frame boundary signal 565 by delaying the system time 530 for a predetermined time by the base channel (FCH / DCCH) frame offset 610 provided from the resource controller 520. The delayer 630 uses a value delayed by the frame offset 640 set by the resource controller 520 using the transferred system time 530. That is, the delay unit 630 outputs the additional channel frame boundary signal 560 by delaying the system time 530 for a predetermined time by the additional channel (SCH) frame offset 640 provided from the resource controller 520. As described above, the present invention further includes two delayers 620 and 630 such that the base channel and the additional channel have different frame offsets. In addition, the additional delay units 620 and 630 are configured to perform a delay operation by their own frame offsets 610 and 640. That is, in the present invention, a delay for an additional channel is added to allocate a frame offset allocated for the additional channel.

FIG. 7 illustrates a general call setup procedure in a code division multiple access mobile communication system. FIG. 7 illustrates a message procedure between modules on a terminal side and modules on a base station side.

Referring to FIG. 7, the terminal side includes a message processor (SIG) which becomes a part for processing a control message related to channel setting, and a resource controller (RC) for managing and controlling a base station resource. . The configuration of the terminal side is similar in the case of the base station. The base station also includes a message processor (SIG), which is a part for processing control messages related to channel setting, and the like, and a resource controller (RC) for managing and controlling various logical and physical resources of the terminal.

Referring to the call setup process with reference to FIG. 7, when user data to be transmitted is generated in the terminal, a signal Call_Setup.Req requesting call setup is transmitted to the message controller SIG in step 710. The message processing unit SIG transmits a call establishment request message to the base station in step 712.

When the base station receives the call establishment request message (Origination Message) transmitted from the terminal as described above, the message processing unit (SIG) of the base station can set the call requested by the terminal to the resource control unit (RC) of the base station in step 714 Check whether or not (Call_Setup.Ind). In this case, if the call allocation is possible, the resource control unit RC sends a signal Call_Setup.Res to the message processor SIG to allow channel allocation in step 716. The message processing unit (SIG) transmits an extended channel assignment message (Extended Channel Assignment Message) to allow the channel assignment requested in step 718 to the terminal.

When the terminal receives an extended channel assignment message of the base station, the terminal transmits a signal Call_Setup.Conf indicating that call setup is made to the resource controller RC in step 720. As a result, a basic channel or a dedicated control channel can be set in both directions.

When the basic channel and the like are set up between the base station and the terminal by the above-described process, the service negotiation process is performed in step 722. When a service environment variable is agreed between the base station and the terminal in the service negotiation process, the message processing unit SIG of the base station transmits the agreed value to the terminal through a service connect message in step 724. In this case, the service connect message includes a non-negotiated service environment variable. The non-negotiated service environment variable is recorded in the non-negotiated service environment variable field assigned to the service connection message. In this process, the resource control unit (RC) of the base station designates a frame offset of the additional channel to be used until a re-negotiation process with the terminal in the future and records it in the non-negotiated service environment variable field. In step 726, the message processor SIG of the terminal transmits a signal Call_Setup.Conf indicating that the additional channel frame offset is set to the resource controller RC. In addition, the message processing unit (SIG) of the terminal completes the call setup process by transmitting a service connection completion message (Service Connect Completion Message) to the base station in step 728.

The non-negotiated service environment variable may be transmitted along with the service connection message or the handoff indication message when the new service is connected, when the service environment is changed, or when the handoff is performed, as well as the initial call setup. Therefore, it is clear that the frame offset of the additional channel added in the present invention can be newly designated in addition to the call setup situation.

FIG. 8 describes in detail the process of setting the frame offset of the additional channel occurring in the resource control unit RC in FIG. 7 for the additional channel to be proposed in the embodiment of the present invention during a call setup or a new service connection process. The flowchart illustrating the frame offset allocation procedure is described above. That is, the control flow shown in FIG. 8 discloses a process of setting an additional channel frame offset when performing call setup or new service connection according to an embodiment of the present invention.

Meanwhile, operations 810 to 818 described in FIG. 8 illustrate operations performed by the base station, and operations 820 through 828 illustrate operations performed by the terminal. The frame offset allocation procedure for the additional channel performed by the base station in steps 810 to 818 is a procedure that is arbitrarily processed internally while performing step 722 of FIG. 7. Meanwhile, the frame offset allocation procedure for the additional channel performed by the terminal in steps 820 to 828 is a procedure performed after receiving the service connection message from the base station in step 724.

When a call setup request message or a new service request message comes up from the terminal, it is determined whether the base station can allocate the additional channel in the reverse or forward direction. In this case, when the initial call setup or the connection of additional traffic or service is determined, the base station transmits a channel assignment message in steps 810 and 812. Thereafter, a traffic channel is established between the base station and the terminal or a new service is further connected. At this time, the base station and the terminal negotiate information for call setup or new service connection.

On the other hand, when the service negotiation through the process 820 is completed in step 814, the base station finally determines the non-negotiated service environment variable constituting the service connection message to be transmitted to the terminal. That is, the base station sets an unnegotiated service environment variable to be added to the service connection message in step 814. At this time, whether to newly specify the frame offset of the additional channel added to the present invention is determined through the resource controller (RC). If it is determined in step 814 that a new frame offset is assigned to the additional channel, an appropriate frame offset is determined in consideration of traffic characteristics of the established call or newly connected service and resources of the base station. In this case, the additional channel frame offset may be set to have an offset value different from the frame offset of the base channel or to be the same as the frame offset of the base channel. Here, the frame offset of the additional channel may be generated by using a preset value or by a separate operation at the base station. In the process of the resource controller RC designating the additional channel frame offset, it is necessary to appropriately distribute the load so as to set an appropriate value for transmitting data without delay. The additional channel frame offset determined as described above is notified to the message processing unit (SIG) and recorded in the field of the non-negotiated service environment variable. Meanwhile, as described above, the operation of determining the additional channel frame offset and recording the determined additional channel frame offset in the field in which the non-negotiated service environment variable is recorded is performed in step 816. The stored frame offset for the additional channel is set to a value of the frame offset of the additional channel to be allocated in the future. Meanwhile, in step 818, the message processing unit SIG of the base station transmits a service connection message including the service environment variable and the non-negotiated service environment variable to the terminal.

When the base station transmits the service connection message for call setup or new service connection as described above, the message processing unit SIG of the terminal receives the service connection message in step 820. In step 822, the message processing unit SIG of the terminal that receives the service connection message interprets the received service connection message. The result is then passed to the resource controller RC of the terminal. That is, the message processing unit SIG of the terminal interprets the non-negotiated service environment variable together with other service environment variables (negotiated service environment variables) in step 822. On the other hand, the message processing unit (SIG) transmits the result of the analysis of the non-negotiated service environment variable, that is, whether the additional channel frame offset designation and the value in step 822 to the resource control unit (RC).

The resource control unit RC receiving the analysis result determines whether an additional channel frame offset is recorded in the unnegotiated service environment variable field in step 824. The message processing unit SIG proceeds to step 826 if the additional channel frame offset is recorded according to the determination. Otherwise, the message processing unit SIG proceeds to step 828. In step 826, the resource control unit RC allocates an additional channel frame offset provided from the message processing unit SIG to a corresponding additional channel or requires additional channel allocation or a supplemental channel request from a terminal. Save for use in response to Message). Finally, the terminal completes the frame offset setting process by transmitting a service connection completion message corresponding to the service connection message in step 828.

As described above, when the base station needs to allocate the additional channel after the additional channel frame offset is stored or receives a supplemental channel request message (SCRM) from the terminal, the stored additional channel frame offset may be used.

As described above, in the embodiment of the present invention, when the additional channel is allocated, it is possible to give a frame offset of a value different from that of the base channel exclusively for the additional channel, thereby reducing the loss that may occur due to the excess capacity of the link.

Meanwhile, handoff may occur when data is transmitted through the allocated additional channel according to the above-described embodiment of the present invention. Therefore, in the present invention, even if the additional channel and the base channel use different frame offsets, handoff should be possible, and there should be a proposal for this. In this proposal, when the handoff occurs, the target base station (Target BS) is already using the frame offset value of the existing additional channel, so that the existing frame offset value for the additional channel cannot be supported. shall. It will be apparent that such a situation may cause a problem in that continuous service provision is impossible.

Accordingly, the present invention provides a frame offset of a target BS in a source BS when handoffing or newly assigning an additional channel in a handoff situation between a base station and a terminal of a code division multiple access method. The present invention proposes an apparatus and method for designating or resetting a frame offset of an appropriate supplemental channel by measuring each load. To this end, in the CDMA communication system according to an embodiment of the present invention, in the handoff situation between the base station and the terminal, the additional channel may specify a value different from the frame offset of the currently used base channel or a frame offset already specified. Then, the base station delivers information for designating a new frame offset to the terminal through a handoff indication message. In addition to the frame offset for the base channel, the terminal receiving the frame offset information from the base station may additionally specify a frame offset for the additional channel or operate a value different from the already designated additional channel frame offset.

Hereinafter, a procedure for performing handoff required as an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 9 is a diagram illustrating a general handoff procedure in a code division multiple access mobile communication system. 9 illustrates a message procedure between modules on a terminal side and modules on a base station side.

Referring to FIG. 9, the terminal side includes a message processing unit (SIG) which is a couple performing a task of processing a control message, and a resource control unit (RC) which manages and controls terminal resources. The base station also includes a message processor (SIG), which is a part for processing control messages related to channel setting, and the like, and a resource controller (RC) for managing and controlling various logical and physical resources of the base station. In this case, the base station includes both the source base station corresponding to the base station currently providing the service and the target base station newly providing the service due to handoff.

Referring to the additional channel handoff allocation process with reference to FIG. 9, when a pilot channel having a new PN value is detected by the resource control unit (RC) of the terminal, the corresponding measurement value is transmitted to the message processor (SIG) in step 1110 and a new pilot channel is obtained. Command to send a Pilot Strength Measurement Message or Extended Pilot Strength Measurement Message. The message processing unit (SIG) receiving this command transmits a pilot channel strength measurement message to the base station in step 1120.

When the source base station receives the pilot channel strength measurement message transmitted from the terminal as described above, the message processing unit (SIG) of the source base station is a strength measurement value of the pilot raised by the terminal to the resource control unit (RC) of the source base station in step 1130 Based on this, it is determined whether to add to a new active set. When it is determined to add to the active set, the resource controller RC of the source base station in step 1140 asks the resource controller RC of the target base station whether resource allocation for handoff is possible (Handoff.Req). One of factors determining whether the resource allocation is possible may include content related to the additional channel. When the target base station can accept the handoff, the handoff acceptance response (Handoff.Conf) is given to the resource controller RC of the source base station in step 1150.

When the handoff acceptance response (Handoff.Conf) is received from the target base station, in step 1160, the source base station delivers a handoff direction message (Universal Handoff Direction Message) including the new active set to the terminal. In this case, when the handoff is permitted in the target base station, a new physical channel is formed. However, the actual generating part is a message processing unit (SIG) of the source base station, the generated message is delivered to the terminal using the physical layer of the source and target base station. The handoff indication message generated and transmitted in this way includes additional channel related information when a new channel is newly allocated or handoffed. When checking whether the handoff is possible in step 1140, the resource control unit RC of the target base station checks whether the additional channel in the reverse or forward direction can be allocated. In this process, a frame offset reassignment procedure is added during handoff required by an embodiment of the present invention. The re-designation procedure is a procedure included in the Handoff.Req and Handoff.Conf, and a frame offset portion should be added to the additional channel related factor in the Handoff.Req message transmitted to the target base station. If the target base station accepts the same frame offset as the subchannel frame offset currently being serviced, soft handoff of the subchannel is possible without reassignment of the frame offset. However, if the target base station cannot accommodate the same frame offset as the additional channel frame offset currently being serviced, the source base station and the target base station may perform a frame offset for the additional channel that the target base station can accept through a predetermined negotiation procedure with the source base station. The same frame offset is newly designated to be performed in the form of a hard handoff. In the added procedure, a process of setting a new frame offset is added. This process is described in detail in FIG.

In step 1170, the message processing unit SIG of the terminal transmits a control signal handoff.Req to the resource control unit RC of the terminal and allocates a transmission channel or a reception channel of a corresponding base channel and an additional channel. Finally, when resource allocation necessary for handoff is completed, the resource controller RC informs that data can be transmitted / received to a service option, which is an application service layer of the terminal, in step 1180 (Handoff.Conf). Finally, in step 1190, a handoff completion message (Handoff Completion Message) is notified that the handoff procedure is completed. In this case, the message is processed by the message processor (SIG) of the source base station. When the above process is completed, the base station and the terminal exchange data traffic through the base station and the additional channel with the base station associated with the handoff.

FIG. 10 is a flowchart illustrating a frame offset allocation procedure for an additional channel to be proposed in an embodiment of the present invention during a handoff process performed in the procedure of FIG. 9. In FIG. 10, operations 1210 through 1224 illustrate operations performed by the source base station and the target base station (steps 1130 and 1150 of FIG. 9). In addition, performing steps 1226 to 1236 illustrates an operation performed in the terminal (step 1170 to step 1190 of FIG. 9). The frame offset allocation procedure for the additional channel of the source base station and the target base station occurs between steps 1140 and 1150 of FIG. 9. The frame offset allocation procedure for the additional channel of the UE is a process 1170, a process 1180.

When the UE transmits a pilot strength measurement message as in step 1210, first, in step 1212, the resource controller RC determines whether to add a pilot having a newly added PN value to the active set based on the pilot strength. do. If the determination is not made to add to the active set, the process proceeds to step 1214 where handoff is not performed. However, if it is determined by the determination, it is checked in step 1216 whether the additional channel is currently allocated with other resources. If the additional channel is not allocated, the process proceeds to step 1220 to hand off only the basic or dedicated control channel. In contrast, if the additional channel is allocated, the process proceeds to step 1218 to determine whether the additional channel is handed off. In this case, it is necessary to check whether the handoff resource allocation of the additional channel is possible not only for the source base station but also for the target base station. If it is difficult to handoff the additional channel, the process proceeds to step 1220 to hand off only the basic or dedicated control channel. However, if a handoff is possible, additionally look for a less-loaded frame offset on both the source and target base stations.

Accordingly, the resource controller (RC) of the source and target base station specifies the frame offset available for the additional channel in step 1222, and informs the message processor (SIG) at the same time as the physical layer of the source and target base station. Informs the frame offset for the additional channel. In this case, if the target base station accepts the same frame offset as the additional channel frame offset currently being serviced, the frame offset reassignment procedure is unnecessary. However, when not performed with the same frame offset, the frame offset for the additional channel that can be accommodated by the target base station is negotiated with the source base station to newly designate a frame offset in both the source and the target base station. Then, the physical layer sets this value as an additional channel offset frame offset value. In this case, the frame offset of the additional channel configured for data transmission may be designated as an appropriate frame offset according to the amount of data (load) to be transmitted and received for each frame offset. At this time, it may be set to have an offset value different from the frame offset of the base channel or may be the same as the frame offset of the base channel. The frame offset is an appropriate value determined so that the data can be transmitted without delay by properly distributing the loads of the service base station and the target base station specifying the frame offset. Subsequently, the resource controller RC of the source base station instructs generation of a handoff indication message to which a frame offset related field for additional channels is added in step 1224. The message processing unit (SIG) of the source base station which receives this generates the corresponding message and transmits the corresponding message to the terminal through the physical layer of the source base station and the target base station.

When the base station transmits the handoff instruction message as described above, the message processing unit (SIG) of the terminal interprets the handoff instruction message received in step 1226, and passes the result to the resource controller (RC) of the terminal. When the analysis is completed, the process 1228 is performed based on the analysis result. In step 1228, it is determined whether the additional channel is included. In response to the determination that the additional channel is included, the message processor SIG transmits, together with other additional channel parameters, whether a frame offset for the additional channel is specified and its value to the resource controller RC. Then, the resource controller RC receives the analysis result of the message processor SIG and checks whether a frame offset of an additional channel is designated in step 1230. In this case, if the frame offset of the additional channel is designated, the frame offset value for the additional channel corresponding to the value is set in step 1232, and the physical layer is informed of the new frame offset value together with the additional channel allocation signal. When the additional channel related signal is received from the resource controller (RC), the physical layer may additionally set the additional channel frame offset value so that the additional channel may be allocated and transmitted / received. When the reverse / forward additional channel is set up between the base station and the terminal as described above, in step 1234, the handoff is performed including the set additional channel. However, if it is determined in step 1228 that the additional channel is not included, a handoff is performed for the basic / dedicated channel in step 1236. On the other hand, when the handoff is completed, the process proceeds to step 1236 and the data traffic of the application service is transmitted after the handoff completion message (HCM) is transmitted.

In an embodiment of the present invention, the process of the resource controller (RC) of the base station to determine whether the additional channel is allowed, the process of examining a frame offset (SCH frame offset) to be used only for the additional channel when the setting of the additional channel is determined. In addition, the present invention proposes a process of adding a frame offset value to the additional channel allocation message to transmit the frame offset to the terminal, as shown in FIG. 11, and assigning a frame offset value designated in the physical layer to the allocated additional channel. In the process of specifying the frame offset by the resource controller (RC), it is necessary to appropriately distribute the load to set an appropriate value to which data can be transmitted without delay.

The terminal also checks the frame offset value for the additional channel in the process of interpreting the additional channel assignment message, passes it to the resource controller, notifies the value so that the set value can be used in the physical channel by the resource controller, and physical It is proposed a process of newly setting the frame offset when additional channels are allocated in the layer.

FIG. 11 is a diagram illustrating a configuration of an additional channel assignment message or a handoff indication message including an unnegotiated service environment variable field according to an embodiment of the present invention. FIG. 11 illustrates a modified form of an unnegotiated service environment variable field to which a frame offset related field for additional channels is added.

Referring to the non-negotiated service environment variable field in the additional channel assignment message or the handoff indication message as shown in FIG. 11, when a reverse additional channel is allocated, whether to newly designate a REV_SCH_ID field and a frame offset indicating an identifier of a channel allocated to each terminal A REV_SCH_FRAME_OFFSET_INCL field indicating whether or not and a REV_SCH_FRAME_OFFSET field that actually specifies a new frame offset value are added. In the case of forward additional channel allocation, a FOR_SCH_ID field indicating an identifier of a channel allocated to each UE, a FOR_SCH_FRAME_OFFSET_INCL field indicating whether or not a frame offset is specified, and a FOR_SCH_FRAME_OFFSET field are also added. In the existing system, even when a handoff situation, the first allocated frame offset is used to allocate the same value in all channels. However, in the present invention, one of 16 frame offsets is allocated within 20 ms when the additional channel is allocated by specifying the REV_SCH_FRAME_OFFSET and FOR_SCH_FRAME_OFFSET values. It can be specified in 1.25ms units. Although the frame offset of the additional channel is specified in the physical layer through the above message, conventionally, the physical layer has values of REV_SCH_FRAME_OFFSET and FOR_SCH_FRAME_OFFSET indicating the frame offset of the additional channel in a stored form, but this is determined at the time of service negotiation. The value is changed in units of 20ms by the value of REV_MULTI_FRAME_OFFSET field or FOR_MULTI_FRAME_OFFSET according to the size of the multi frame of the additional channel specified in the service configuration record. In the present invention, the variable value can be changed in units of 1.25 ms, so that the variable value can be changed in units of 1.25 ms when allocating additional channels.

As described above, the present invention is implemented when traffic is generated in a state where a basic call is connected to a next generation code division multiple access mobile communication system so that an additional channel is allocated. Providing a procedure and method for designating a new frame offset for the additional channel, the additional channel is fixed per user, so that traffic such as data service may burst, resulting in traffic concentrating on a specific frame offset. There is an effect that can reduce the transmission delay and scheduling loss that can occur in the operation of the additional channel.

Claims (26)

A method of transmitting spread data, which is spread with data of a plurality of users with an orthogonal code assigned to each user, through frames on a plurality of additional channels, The spreading data of different users among the plurality of users is transmitted on the additional channels in other frames having a frame offset time determined according to the data amount of the respective additional channels among the additional channels. The method. The method of claim 1, The additional channels are allocated corresponding to the basic channels that are already allocated. The method of claim 1, The additional channels are reverse additional channels. The method of claim 1, The additional channels are forward additional channels. In a method of allocating an additional channel corresponding to one of the basic channels among a plurality of basic channels using the same frame offset, If there is an additional channel allocation request corresponding to one of the basic channels, the allocation is requested by the amount of data transmitted through the allocated additional channels corresponding to the plurality of basic channels using the same frame offset. The frame offset of the additional channel is specified to be different from the frame offsets of the allocated additional channels. The method of claim 5, The request for allocation of the additional channel is an additional channel request message from a mobile station to which the base channel is already allocated. The method of claim 6, The additional channels are reverse additional channels. The method of claim 5, The request for allocation of the additional channel is generated due to data to be transmitted to a mobile station to which the base channel is already allocated. The method of claim 8, The additional channels are forward additional channels. In a method of allocating a plurality of basic channels having a predetermined frame offset corresponding to a plurality of mobile terminals and allocating additional channels corresponding to the basic channels, Checking the amount of transmission data for each frame offset of the additional channels currently allocated corresponding to the basic channels if there is an allocation request for the additional channels corresponding to the basic channels; And the frame offset of the additional channel requested to be allocated is designated by the amount of transmission data for each frame offset. The method of claim 10, The request for allocation of the additional channel is an additional channel request message from a mobile station to which the base channel is already allocated. The method of claim 11, The additional channels are reverse additional channels. The method of claim 10, The request for allocation of the additional channel is generated due to data to be transmitted to a mobile station to which the base channel is already allocated. The method of claim 13, The additional channels are forward additional channels. In a method of allocating a plurality of basic channels having a predetermined frame offset corresponding to a plurality of mobile terminals and allocating additional channels corresponding to the basic channels, If there is a request for allocation of additional channels corresponding to the basic channels, the amount of transmission data for each frame offset of the additional channels currently allocated corresponding to the basic channels is checked, and the amount of transmission data for each of the checked frame offsets is checked. Specifying a frame offset of the additional channel requested by the allocation and transmitting the same through an additional channel allocation message; And receiving an additional channel assignment message and allocating an additional channel having the specified frame offset when the frame offset of the additional channel is specified in the received additional channel assignment message. Way. The method of claim 15, The request for allocation of the additional channel is an additional channel request message from a mobile station to which the base channel is already allocated. The method of claim 16, The additional channels are reverse additional channels. The method of claim 15, The request for allocation of the additional channel is generated due to data to be transmitted to a mobile station to which the base channel is already allocated. The method of claim 18, The additional channels are forward additional channels. A method of performing a handoff from a source base station to a target base station of a mobile station to which a plurality of base channels having a predetermined frame offset and additional channels corresponding to the base channel are allocated, the method comprising: When the handoff request for the mobile station occurs, the source base station providing frame offset information of the base channel and the additional channel allocated to the mobile station to the target base station to check whether the additional channel is accepted; and, Performing a soft handoff for the mobile station using the frame offset of the additional channel if the target base station can accommodate the frame offset of the additional channel; If it is impossible to accommodate the frame offset of the additional channel by the target base station, a frame offset different from the frame offset of the additional channel is specified through the shape between the target base station and the source base station, and the frame offset of the designated additional channel is determined. And performing a hard handoff with respect to the mobile terminal. The method of claim 20, The handoff request is generated by the source base station receiving a pilot signal from the mobile station and generated by the power value of the received pilot signal. The method of claim 20, The method according to claim 1, wherein the target base station determines whether the target base station can transmit data using a frame offset of the additional channel. In the apparatus for receiving a plurality of base channels having a predetermined frame offset corresponding to a plurality of mobile terminals and additional channels corresponding to the base channels, and receiving data transmitted through the base channel and the additional channel , The frame offset of the base channel, the frame offset of the additional channel, and the system time are inputted, and the system time delayed by the frame offset of the base channel is output as a base channel boundary signal, and the frame offset of the additional channel is delayed. A timing generator for outputting the system time as an additional channel boundary signal; A first symbol combiner for combining the multipath symbol data transmitted through the base channel; A second symbol combiner for combining the multipath symbol data transmitted through the additional channel; A first deinterleaver for inputting symbols from the first symbol combiner and the base channel boundary signal, and deinterleaving the symbols from the first symbol combiner in a frame unit determined by the base channel boundary signal; And a second deinterleaver configured to input symbols from the second symbol combiner and the additional channel boundary signal, and deinterleave the symbols from the second symbol combiner in a frame unit determined by the additional channel boundary signal. The device, characterized in that. The method of claim 23, wherein the timing generator, A first delay unit configured to input the frame offset of the base channel and the system time, delay the system time for a predetermined time by the frame offset of the base channel, and output the signal as the base channel boundary signal; And a second delay unit configured to input the frame offset of the additional channel and the system time and delay the system time for a predetermined time by the frame offset of the additional channel to output the additional channel boundary signal. The device. The method of claim 23, wherein The frame offset of the base channel and the frame offset of the additional channel is different from each other. The method of claim 23, wherein The frame offset of the additional channel is specified by an amount of data transmitted for each frame offset of the additional channels allocated to the plurality of basic channels.