CN101959319A - Information transmission method in subcarrier time slot 0 - Google Patents

Abstract

The invention provides an information transmission method in a subcarrier time slot (TS) 0, which comprises the following step of: configuring one or any combination of downlink channels related to a DL DPCH and HSDPA (including an HS-SCCH and an HS-PDSCH), downlink channels related to HSUPA (including an E-AGCH and an E-HICH) and an FPACH in the subcarrier TS0 so as to transmit information between a NodeB and user equipment (UE) on the configured corresponding channels. By the method, the channel is configured in the subcarrier TS0 and corresponding data transmission is performed on the configured channel, so that the utilization rate of a frequency spectrum is greatly improved.

Description

Information transferring method on a kind of auxilliary carrier wave time slot 0

Technical field

The present invention relates to the technology of TD-SCDMA system, the information transferring method on particularly a kind of auxilliary carrier wave time slot 0 (TS0).

Background technology

The subframe structure of TD-SCDMA comprises uplink pilot time slot (UpPTS), protection (GP), descending pilot frequency time slot (DwPTS) at interval as shown in Figure 1, and 7 business time-slots of TS0～TS6.Wherein, TS1～TS6 is the general service time slot, according to the different needs of up-downgoing transfer of data, 6 general service time slots can be configured to different uplink and downlink timeslot ratios, and for example, uplink and downlink timeslot ratio is 5: 1, show that then TS1～TS5 is an ascending time slot, TS6 is a descending time slot; Uplink and downlink timeslot ratio is 4: 2, shows that then TS1～TS4 is an ascending time slot, and TS5～TS6 is a descending time slot.In single-carrier system, TS0 is used for delivery system broadcasting as the downlink broadcast time slot.

Along with further developing of TD-SCDMA technology, the TD-SCDMA system of multicarrier has appearred, and promptly a sub-district can take a plurality of carrier resources, comprises a main carrier and at least one auxilliary carrier wave.In multi-carrier TD-SCDMA system, the TS0 of main carrier still is used as the downlink broadcast time slot, and the TS0 of auxilliary carrier wave then temporarily is not used, and this just causes auxilliary spectrum of carrier utilance lower.

Be the downlink or uplink transmittability of further enhanced system, the TD-SCDMA system has introduced high speed downlink packet access (HSDPA) and high speed uplink packet inserts (HSUPA) technology.Wherein, in HSDPA, NodeB is a UE allocation of downlink HS-PDSCH resource, and by HS-SCCH concrete schedule information is handed down to UE, utilizes scheduling to send downlink data to corresponding UE for the HS-PDSCH of each UE again; The schedule information that UE issues according to NodeB determines that scheduling gives the HS-PDSCH resource of self, and on this HS-PDSCH downlink data receiving, again by HS-SICH to information such as NodeB feeding back ACK/NACK.

In HSUPA, NodeB is that UE distributes up E-PUCH resource, and by E-AGCH concrete schedule information is handed down to UE; The schedule information that UE issues according to NodeB is determined the E-PUCH resource of scheduling to self, utilizes this E-PUCH resource to send upstream data to NodeB; NodeB receives the upstream data that UE sends distributing on the E-PUCH of UE, and by E-HICH to information such as UE feeding back ACK/NACK.

Summary of the invention

In view of this, the invention provides the information transferring method on a kind of auxilliary carrier wave TS0, can utilize auxilliary carrier wave TS0 time slot to carry out message transmission, improve auxilliary spectrum of carrier utilance.

For achieving the above object, the present invention adopts following technical scheme:

Information transferring method on a kind of auxilliary carrier wave time slot 0 comprises:

For the UE and the NodeB that support that auxilliary carrier wave time slot 0 (TS0) uses, RNC is configured in the DL DPCH of UE on the auxilliary carrier wave TS0, and NodeB sends data to described UE on the DL DPCH of configuration.

Preferably, RNC divides multiplex mode to be configured on the described auxilliary carrier wave TS0 by frame the DL DPCH of different UEs.

Preferably, when RNC was configured on the described auxilliary carrier wave TS0 at the DL DPCH with described UE, RNC obtained the different-frequency measure time of described UE, and the DL DPCH that guarantees configuration not with the different-frequency measure time conflict of described UE.

Preferably, RNC obtains the different-frequency measure time of described UE, if the DLDPCH of RNC configuration and the different-frequency measure time conflict of described UE, then the data of NodeB on the temporary transient DL of termination of conflict time DPCH send, perhaps, described UE temporarily stops or postpones the different-frequency measure of conflict time in the conflict time, receives the data that DL DPCH goes up transmission.

Preferably, UE and the NodeB that supports auxilliary carrier wave TS0 to use reports to RNC: support auxilliary carrier wave TS0.

Information transferring method on a kind of auxilliary carrier wave time slot 0 comprises:

For the NodeB that supports that auxilliary carrier wave time slot 0 (TS0) uses, RNC is configured in arbitrary down channel of HSDPA on the auxilliary carrier wave time slot 0 (TS0), described NodeB is the HSDPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, for the UE that supports auxilliary carrier wave TS0, arbitrary down channel that permission will be configured on the described auxilliary carrier wave TS0 is distributed to described UE;

Be configured in HSDPA UE on the described auxilliary carrier wave TS0 for the down channel that is assigned with, NodeB sends downlink information or data to it on described arbitrary down channel of configuration.

Preferably, described RNC is configured in arbitrary down channel of HSDPA on the auxilliary carrier wave TS0 and is: RNC is configured in HS-SCCH and/or HS-PDSCH resource pool on the described auxilliary carrier wave TS0; Described HS-SCCH comprises HS-SCCH that sends the HS-SCCH instruction and the HS-SCCH that sends the HS-DSCH control information, wherein, the HS-SCCH that sends the HS-SCCH instruction comprises HS-SCCH orders typeA and typeB, and the HS-SCCH that sends the HS-DSCH control information comprises HS-SCCH type1～type9.

Preferably, when NodeB is the HSDPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, the scheduler of described NodeB obtains the different-frequency measure time of described UE, and guarantee scheduling give described UE's and be configured in time of the arbitrary down channel on the described auxilliary carrier wave TS0, not with the different-frequency measure time conflict of described UE.

Preferably, the HSDPA UE that the auxilliary carrier wave TS0 of arbitrary support uses when carrying out different-frequency measure, does not monitor HS-SCCH.

Preferably, NodeB is when being configured in the HSDPAUE allocation of downlink channel of the auxilliary carrier wave TS0 use of support on the described auxilliary carrier wave, the scheduler of described NodeB obtains the different-frequency measure time of described UE, if NodeB dispatch to described UE's and be configured in the time of the HS-PDSCH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE

Described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, stops to receive data from described HS-PDSCH, and does not feed back corresponding HS-SICH and give NodeB.

Preferably, in the HS-PDSCH resource allocation of scheduling, for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPAUE of proprietary UE ID is arranged,

The HS-SCCH of the scheduling that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB is configured in described auxilliary carrier wave TS0 when going up, the HS-SCCH of described scheduling and the HS-PDSCH of scheduling be in two adjacent subframes, two subframes at interval between the HS-SCCH of described scheduling and the HS-SICH of scheduling;

The HS-PDSCH of the scheduling that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB is configured in described auxilliary carrier wave TS0 when going up, the HS-PDSCH of HS-SCCH and the described scheduling of scheduling is in two adjacent subframes, subframe in interval between the HS-PDSCH of described scheduling and the HS-SICH of scheduling.

Preferably, in the HS-PDSCH resource allocation of scheduling, for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPAUE of proprietary UE ID is arranged, when RNC is configured in described auxilliary carrier wave TS0 when going up with the HS-PDSCH resource pool of scheduling

The HS-SCCH of all scheduling on the described auxilliary carrier wave all is not configured on the TS5 and TS6 of described auxilliary carrier wave;

Perhaps, the HS-SCCH of at least one scheduling on the described auxilliary carrier wave is not configured on the TS5 and TS6 of described auxilliary carrier wave, at NodeB is when being configured in the HSDPA UE allocation of downlink channel that the auxilliary carrier wave TS0 of support on the described auxilliary carrier wave uses, and the HS-SCCH scheduling of forbidding being configured in the scheduling of described auxilliary carrier wave TS5 and TS6 is configured in the HS-PDSCH resource of the scheduling on the described auxilliary carrier wave TS0.

Preferably, when the HSDPA UE of the auxilliary carrier wave TS0 use of arbitrary support determined that scheduling comprises that the HS-SCCH of described auxilliary carrier wave TS0 and described UE is positioned at TS5 or TS6 for its HS-PDSCH, described UE determined the HS-SCCH decoding error.

Preferably, in HS-SCCH instruction sent, the HS-SCCH that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB was configured in described auxilliary carrier wave TS0 when going up, two subframes in interval between described HS-SCCH and the corresponding HS-SICH.

Preferably, in semi-static HS-PDSCH resource allocation, when NodeB is that HS-SCCH that a HSDPA UE who supports auxilliary carrier wave TS0 to use distributes is configured in described auxilliary carrier wave TS0 when going up, described HS-SCCH and first HS-PDSCH subframe are positioned at two adjacent subframes.

Preferably, in semi-static HS-PDSCH resource allocation, when semi-static HS-PDSCH was configured on the described auxilliary carrier wave TS0, HS-SCCH and first HS-PDSCH subframe were positioned at two adjacent subframes.

Preferably, in semi-static HS-PDSCH resource allocation, when semi-static HS-PDSCH is configured on the described auxilliary carrier wave TS0,

All HS-SCCH on the described auxilliary carrier wave all are not configured on the TS5 and TS6 of described auxilliary carrier wave;

Perhaps, at least one HS-SCCH on the described auxilliary carrier wave is not configured on the TS5 and TS6 of described auxilliary carrier wave, at NodeB is to be configured in HSDPA UE that the auxilliary carrier wave TS0 of arbitrary support on the described auxilliary carrier wave uses when distributing semi-static resource, and the HS-SCCH scheduling of forbidding being configured in described auxilliary carrier wave TS5 and TS6 is configured in the semi-static HS-PDSCH resource on the described auxilliary carrier wave TS0.

Preferably, in semi-static HS-PDSCH resource allocation, the HS-PDSCH that distributes as the HSDPA UE that uses for the auxilliary carrier wave TS0 of arbitrary support is configured in described auxilliary carrier wave TS0 when going up, subframe at interval between described HS-PDSCH and the HS-SICH.

Preferably, this method further comprises: for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPA UE of proprietary UE ID is arranged, NodeB issues to the HSDPAUE that the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave uses by HS-SCCH, and scheduling gives in the HS-PDSCH resource of this UE whether comprise described auxilliary carrier wave TS0.

Preferably, issue scheduling by HS-SCCH to described UE and give in the HS-PDSCH resource of this UE whether comprise that the mode of described auxilliary carrier wave TS0 is:

Utilize the arbitrary idle bit among the HS-SCCH to issue, scheduling gives in the HS-PDSCH resource of described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, HS-SCCH for channel code collection information field with 8 bits, utilize preceding 3 bits in the described channel code collection information field to represent to begin channel code sign indicating number number, utilize the 4th bit in the described channel code collection information field to represent to dispatch in the HS-PDSCH resource to described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, utilize a bit among the H-RNTI of described UE, the expression scheduling gives in the HS-PDSCH resource of described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, the H-RNTI that sets in advance all HSUPA UE is even number, gives when comprising described auxilliary carrier wave TS0 in the HS-PDSCH resource of described UE when scheduling, sends H-RNTI+1 to described UE by HS-SCCH; Give when not comprising described auxilliary carrier wave TS0 in the HS-PDSCH resource of described UE when scheduling, send H-RNTI to described UE by HS-SCCH.

Preferably, this method further comprises: for being in the CELL_PCH state and not having proprietary UE ID or be in the HSDPA UE of CELL_URA state, issue to the HSDPA UE that the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave uses by broadcasting, scheduling gives in the HS-PDSCH resource of this UE whether comprise described auxilliary carrier wave TS0.

Preferably, UE and the NodeB that supports auxilliary carrier wave TS0 to use reports to RNC: support auxilliary carrier wave TS0.

Information transferring method on a kind of auxilliary carrier wave time slot 0 comprises:

For the NodeB that supports that auxilliary carrier wave time slot 0 (TS0) uses, arbitrary down channel of HSUPA is configured on the auxilliary carrier wave TS0, for being configured in the HSUPAUE allocation of downlink channel of the auxilliary carrier wave TS0 use of support on the described auxilliary carrier wave, be configured in HSUPAUE on the described auxilliary carrier wave TS0 for the down channel that is assigned with, NodeB sends downlink information or data to it on described arbitrary down channel of configuration.

Preferably, described arbitrary down channel with HSUPA is configured on the auxilliary carrier wave TS0 and is: RNC is configured in E-AGCH and/or E-HICH on the described auxilliary carrier wave TS0; Described E-AGCH comprises E-AGCH that sends the E-AGCH instruction and the E-AGCH that sends the E-DCH control information.

Preferably, when RNC is configured in described auxilliary carrier wave with the non-scheduling E-PUCH of described UE,

RNC will be configured on the time slot of non-TS0 with the corresponding E-HICH of described E-PUCH;

Perhaps, RNC will be configured on the described auxilliary carrier wave TS0 with the corresponding E-HICH of described E-PUCH, and guarantee each described E-HICH subframe not with the different-frequency measure time conflict of described UE.

Preferably, when the HSUPA scheduler is the HSUPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, described HSUPA scheduler is determined the different-frequency measure time according to the different-frequency measure parameter of described UE, and guarantee scheduling give described UE's and be configured in time of the arbitrary down channel on the described auxilliary carrier wave TS0, not with the different-frequency measure time conflict of described UE.

Preferably, the HSUPA UE that the described auxilliary carrier wave TS0 of arbitrary support uses does not monitor E-AGCH when carrying out different-frequency measure.

Preferably, RNC is configured in after HSDPA UE on the described auxilliary carrier wave distributes the E-PUCH of non-scheduling, if UE that the auxilliary carrier wave TS0 of described support uses and NodeB divide the multiplexing parameters prediction according to the frame of E-PUCH, scheduling give this UE's and be configured in the time of the E-HICH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE

Then described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, does not send E-PUCH to NodeB, and does not receive corresponding E-HICH from NodeB, and NodeB does not receive E-PUCH in the conflict time, does not also send corresponding E-HICH.

Preferably, after the HSUPA scheduler is the E-HICH of the E-PUCH of the E-AGCH that is configured in the HSDPA UE allocation schedule on the described auxilliary carrier wave, scheduling and scheduling, if the UE that the auxilliary carrier wave TS0 of described support uses according to the E-AGCH that receives predict scheduling give this UE's and be configured in the time of the E-HICH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE, then described UE determines the E-AGCH decoding error, carry out different-frequency measure in the conflict time, do not send E-PUCH, do not receive corresponding E-HICH yet; Perhaps, described UE sends E-PUCH, and stops different-frequency measure or postpone the different-frequency measure of conflict time in the conflict time, receives corresponding E-HICH from NodeB.

Preferably, the E-AGCH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe of the E-AGCH of described scheduling and E-PUCH interval;

The E-AGCH of the transmission E-AGCH instruction that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe in interval between the E-PUCH of described E-AGCH and UE feedback acknowledgment information;

In semi-static E-PUCH resource allocation, the E-AGCH that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe in interval between the E-AGCH that carries out semi-static resource authorization and first E-PUCH subframe.

Preferably, the E-HICH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, NodeB determine according to ability and the E-HICH of the corresponding E-PUCH of E-HICH of described scheduling and described scheduling between timing difference, and reporting RNC, RNC disposes this timing difference to described UE;

In semi-static E-PUCH resource allocation, the E-HICH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, NodeB determine according to ability and the E-HICH of the corresponding E-PUCH of E-HICH of described scheduling and described scheduling between timing difference, and reporting RNC, RNC disposes this timing difference to described UE.

Preferably, when disposing a plurality of E-HICH in the sub-district,

RNC is configured in TS0 simultaneously with all E-HICH in this sub-district and goes up or be configured in simultaneously on the time slot of non-TS0;

Perhaps, not only support the E-PUCH that dispatches but also support the support of the E-PUCH of non-scheduling to assist the described UE that carrier wave TS0 uses for one, RNC is configured in TS0 simultaneously and goes up or be configured in simultaneously on the time slot of non-TS0 for the E-HICH and the NodeB of the non-scheduling of this UE configuration are each E-HICH in the E-HICH set of the scheduling of this UE configuration;

Perhaps, not only support the E-PUCH that dispatches but also support the support of the E-PUCH of non-scheduling to assist the described UE that carrier wave TS0 uses for one, RNC is each E-HICH in the E-HICH set of the scheduling of this UE configuration for the E-HICH and the NodeB of the non-scheduling of this UE configuration, be not configured in simultaneously that TS0 goes up or the time slot of non-TS0 on, then UE and NodeB all keep the timing relationship between two groups of E-PUCH and the E-HICH, are respectively the timing relationship between the E-HICH of the E-PUCH of timing relationship between the E-HICH of the E-PUCH of non-scheduling and non-scheduling, scheduling and scheduling.

Preferably, the HSUPA UE that uses as the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave initiates in the E-RUCCH process, if described UE sends the time of the subframe of uplink synchronous sequence, the subframe that receives FPACH, transmission E-RUCCH subframe, the time of carrying out different-frequency measure with described UE clashes

Described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time, carried out described E-RUCCH process in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, and described E-RUCCH process is postponed.

As seen from the above technical solution, among the present invention, configuration DL DPCH, down channel (comprising HS-SCCH and HS-PDSCH) that HSDPA is relevant, down channel (comprising E-AGCH and E-HICH) that HSUPA is relevant and a kind of or combination in any in the FPACH channel on auxilliary carrier wave TS0, thus on the respective channel that disposes between NodeB and UE transmission information.Like this, behind configurating channel on the auxilliary carrier wave TS0, improved the availability of frequency spectrum greatly.

Description of drawings

Fig. 1 is the frame structure schematic diagram of existing TD-SCDMA system.

Embodiment

For making purpose of the present invention, technological means and advantage clearer, the present invention is described in further details below in conjunction with accompanying drawing.

Among the present invention, the relevant down channel (comprising HS-SCCH and HS-PDSCH) of DL DPCH, HSDPA, the relevant down channel of HSUPA (comprising E-AGCH and E-HICH) and FPACH are configured on the auxilliary carrier wave TS0, utilize the information on this auxilliary carrier wave TS0 transmission respective channel, thereby improve the availability of frequency spectrum.

Do not support the use of auxilliary carrier wave TS0 in existing 3GPP standard, therefore, RNC, NODEB and UE do not support the use of auxilliary carrier wave TS0 at present.

As mentioned above, be further to improve the availability of frequency spectrum, will be on auxilliary carrier wave TS0 among the present invention configurating channel, the realization of this configuration needs network and UE to support to assist the use of carrier wave TS0 simultaneously.Therefore preferably, report the use of whether supporting auxilliary carrier wave TS0 to RNC, thereby make RNC in supporting the UE and NodeB that auxilliary carrier wave TS0 uses, assist the channel configuration on the carrier wave TS0 by UE and NodeB.Particularly, when UE supports the use of auxilliary carrier wave TS0, need report RNC: support the use of auxilliary carrier wave TS0; When NODEB supported the use of auxilliary carrier wave TS0, NODEB need report RNC: support the use of auxilliary carrier wave TS0.

When NODEB supported the use of auxilliary carrier wave TS0, RNC can be configured in the down channel of being correlated with auxilliary carrier wave TS0 (HS-SCCH, HS-PDSCH, E-AGCH, E-HICH, DL DPCH, FPACH).For the UE that supports that auxilliary carrier wave TS0 uses, RNC can be configured in the relevant down channel (DL DPCH and non-scheduling E-HICH) of this UE auxilliary carrier wave TS0.For the UE that does not report " supporting auxilliary carrier wave TS0 to use ", RNC can not be configured in the relevant down channel (DL DPCH and non-scheduling E-HICH) of this UE auxilliary carrier wave TS0.

When NODEB did not support that auxilliary carrier wave TS0 uses, RNC can not be configured in the down channel of being correlated with auxilliary carrier wave TS0 (HS-SCCH, HS-PDSCH, E-AGCH, E-HICH, DL DPCH, FPACH).When NODEB did not support that auxilliary carrier wave TS0 uses, even the UE that inserts supports the use of auxilliary carrier wave TS0, RNC can not be configured in the relevant down channel (DL DPCH and non-scheduling E-HICH) of this UE auxilliary carrier wave TS0.Next, suppose that UE and NodeB all report the use of supporting auxilliary carrier wave TS0 to RNC, to carrying out channel configuration among the present invention on auxilliary carrier wave TS0, and the transfer of data of carrying out based on this channel configuration is described in detail.

UE in the network carries out different-frequency measure at time slot TS0, and therefore, with above-mentioned possible channel configuration on auxilliary carrier wave TS0 the time, the different-frequency measure that need avoid carrying out with UE conflicts mutually.Next, just respectively to above-mentioned channel configuration at auxilliary carrier wave TS0 and in the concrete processing procedure of the channel information of this configuration, be described in detail respectively.

In addition, may there be a plurality of auxilliary carrier waves in the sub-district, can be on any one or more auxilliary carrier wave TS0 with above-mentioned channel configuration, configuration on each auxilliary carrier wave TS0 and to carry out the concrete technical finesse of message transmission based on this configuration all identical describes to be configured to example on an auxilliary carrier wave TS0 below.

(1) DL DPCH is configured on the TS0 of auxilliary carrier wave A.

Suppose that a UE is configured on the auxilliary carrier wave A, RNC is configured in the DL DPCH of this UE on the TS0 of auxilliary carrier wave A, and NodeB utilizes the DL DPCH that is configured on the auxilliary carrier wave TS0 to send downlink data to this UE.

In the time of on DL DPCH being configured in auxilliary carrier wave TS0, RNC can divide multiplex mode to be configured by frame the DLDPCH of different UEs, and preferably, RNC should guarantee as far as possible: conflicting does not appear in the moment that frame branch multiplexing parameters and the UE of DL DPCH carries out different-frequency measure.If conflict appears in the moment that RNC can't avoid DL DPCH and UE to carry out different-frequency measure, problem can manage conflict according to a kind of method in following two kinds of methods:

1, in the moment that conflict occurs, NODEB temporarily stops the transmission of DL DPCH, guarantees that UE carries out different-frequency measure regularly;

2, in the moment that conflict occurs, UE temporarily stops or postpones different-frequency measure one time.

(2) HSDPA is relevant HS-SCCH and/or HS-PDSCH are configured on the TS0 of auxilliary carrier wave A.

RNC is configured in the HS-PDSCH resource pool and/or the HS-SCCH of this sub-district on the TS0 of auxilliary carrier wave A, promptly comprises the TS0 of auxilliary carrier wave A in the HS-PDSCH resource pool, and/or at least one among the HS-SCCH is configured on the TS0 of auxilliary carrier wave A.

Suppose that a HSDPA UE is configured on the auxilliary carrier wave A, in RNC is HS-SCCH, HS-PDSCH resource pool and the HS-SICH of cell configuration, select corresponding HS-SCCH, HS-PDSCH resource and HS-SICH, distribute to this UE by NodeB.For the UE that has distributed the channel on the TS0 that is configured in auxilliary carrier wave A, NodeB utilizes respective channel transmission information on auxilliary carrier wave TS0.Wherein, HS-SCCH comprises: the HS-SCCH that is used to send the HS-SCCH of HS-DSCH control information and is used to send the HS-SCCH instruction.The HS-SCCH that is used to send the HS-DSCH control information comprises: HS-SCCH type 1～HS-SCCH type 9; The HS-SCCH that is used to send the HS-SCCH instruction comprises: HS-SCCH orders type A and type B.

At NodeB is that UE distributes in the HSDPA respective channel process, if the channel configuration that distributes on auxilliary carrier wave TS0, then needs to avoid to conflict mutually constantly with the different-frequency measure of this UE.Particularly, the scheduler of NodeB is determined the different-frequency measure moment of this UE according to the different-frequency measure parameter (H-RNTI/E-RNTI of UE and M_REP) of UE, and guarantee scheduling give this UE's and be configured in HS-SCCH and/or HS-PDSCH subframe on the auxilliary carrier wave TS0, do not conflict constantly with the different-frequency measure of this UE.Wherein, determine that according to the different-frequency measure parameter of UE different-frequency measure mode constantly is identical with existing mode, just repeat no more here.

At NodeB is the HS-SCCH that distributes of UE and/or HS-PDSCH when being configured on the auxilliary carrier wave TS0, can cause certain influence to the timing relationship of the related physical interchannel of HSDPA.Wherein, be included in timing relationship influence, HS-SCCH instruction in the HSDPA resource allocation of scheduling send in the influence and the influence of the timing relationship in the semi-static HS-PDSCH resource allocation of timing relationship, describe respectively below.

(A) influence of the timing relationship in the HSDPA resource allocation of scheduling

For the HSDPA business on the auxilliary carrier wave, when HS-SCCH and HS-PDSCH were not configured in TS0, HS-SCCH, the HS-PDSCH and the HS-SICH that distribute to a UE satisfied following timing relationship:

HS-SCCH sends in the n subframe; HS-PDSCH sends in the n+1 subframe; HS-SICH sends in the n+3 subframe.

When HS-SCCH was configured in TS0, UE had time decoding HS-SCCH and preparation reception HS-PDSCH more fully.Therefore, the defining relation between HS-SCCH, HS-PDSCH and the HS-SICH can remain unchanged.

For the timing relationship between HS-SCCH and the HS-PDSCH, when HS-PDSCH is configured in TS0, if HS-SCCH is configured in the descending time slot before TS4 or the TS4, then the interval of HS-SCCH and HS-PDSCH more than or equal to 2 time slots (in the 3GPP standard, minimum interval between definition HS-SCCH and the HS-PDSCH is 2 time slots), at this moment the timing relationship of HS-SCCH and HS-PDSCH can be constant.That is: HS-SCCH sends in the n subframe; HS-PDSCH sends in the n+1 subframe;

When HS-PDSCH was configured in TS0, if HS-SCCH is configured in TS5 or TS6, then the interval between HS-SCCH and the HS-PDSCH was less than 2 time slots, and UE can't accomplish so: send HS-SCCH in the n subframe; Send HS-PDSCH in the n+1 subframe.Can be backward compatible for the use that guarantees TS0 as far as possible, carry out following setting among the present invention:

When HS-PDSCH is configured in TS0, preferably, forbid that all HS-SCCH on this carrier wave are configured in TS5 or TS6;

Be configured in TS5 or TS6 if can't forbid all HS-SCCH, guarantee that at least one HS-SCCH is not configured in TS5 or TS6, and, forbid being configured in the HS-PDSCH resource of the HS-SCCH scheduling TS 0 of TS5 or TS6, the HS-PDSCH resource of auxilliary carrier wave TS0 is merely able to by the HS-SCCH scheduling that is configured in other descending time slot positions except that TS5 and TS6.

For the timing relationship between HS-PDSCH and the HS-SICH, when HS-PDSCH is configured in TS0, if HS-SICH is configured in TS2 or the later ascending time slot of TS2, and according in the present 3GPP standard about the timing relationship between HS-PDSCH and HS-SICH, then can occur: HS-PDSCH sends in the n subframe, and HS-SICH sends in the n+1 subframe.But obviously, this timing relationship is different with present timing relationship, and is therefore constant for guaranteeing the timing relationship between HS-PDSCH and the HS-SICH, and makes the use of TS0 backward compatible as much as possible, and the present invention carries out following setting:

When HS-PDSCH is configured in TS0, subframe in interval between HS-PDSCH and the HS-SICH.That is: HS-PDSCH sends in the n subframe, and HS-SICH sends in the n+2 subframe.

UE and NodeB carry out the transmission of HS-PDSCH and HS-SICH according to the timing relationship of above-mentioned setting.

(B) timing relationship during HS-SCCH instruction sends between HS-SCCH and the relevant HS-SICH

When NODEB sends following HS-SCCH instruction by HS-SCCH, UE will receive the affirmation information of instruction by relevant HS-SICH feedback.

(1) sets up uplink synchronous instruction (only being applicable to HS-SCCH instruction TYPE A)

(2) order UE discharges the instruction of the semi-static HS-PDSCH resource of distributing to it

(3) instruction of the discontinuous reception of activation UE

(4) instruction of the discontinuous reception of deexcitation UE

Under above-mentioned HS-SCCH instruction transmission situation, if HS-SCCH does not dispose on the throne in TS0, timing relationship between HS-SCCH and the HS-SICH satisfies: the HS-SCCH that instructs as transmission HS-SCCH sends in the n subframe, and the HS-SICH that feedback receives the affirmation information of instruction sends in the n+3 subframe.

When the HS-SCCH that sends the HS-SCCH instruction is configured in auxilliary carrier wave TS0, if according in the present 3GPP standard about the timing difference between HS-SCCH and HS-SICH, the HS-SCCH instruction to occur and send in the n subframe, the HS-SICH that feedback receives the affirmation information of instruction sends in the n+2 subframe.For the timing relationship between maintenance HS-SCCH and the HS-SICH is constant, and make the use of TS0 backward compatible as much as possible, carry out following setting among the present invention:

When the HS-SCCH that sends the HS-SCCH instruction is configured in TS0, two subframes in interval between HS-SCCH and the HS-SICH.That is: HS-SCCH sends in the n subframe, and HS-SICH sends in the n+3 subframe.UE and NodeB carry out the transmission of HS-SCCH and HS-SICH according to the timing relationship of this setting.

(C) influence of the timing relationship in the semi-static HS-PDSCH resource allocation

In existing semi-static resource allocation, the timing relationship between HS-SCCH and first HS-PDSCH subframe satisfies: HS-SCCH sends in the n subframe, and first HS-PDSCH subframe sends in the n+1 subframe.

Semi-static HS-PDSCH and the timing relationship between the HS-SICH satisfy: HS-PDSCH sends in the n subframe, and the HS-SICH that is used to feed back the ACK/NACK of this HS-PDSCH sends in the n+2 subframe.

When HS-SCCH was configured in auxilliary carrier wave TS0, timing relationship remained unchanged between HS-SCCH and first HS-PDSCH subframe.Concrete analysis is referring to the description in aforementioned (A).

When HS-PDSCH is configured in auxilliary carrier wave TS0, identical with situation about describing in aforementioned (A):

(1) when HS-PDSCH is configured in auxilliary carrier wave TS0, if HS-SCCH is configured in the descending time slot before TS4 or the TS4, then the timing relationship of HS-SCCH and HS-PDSCH can be constant.That is: HS-SCCH sends in the n subframe; HS-PDSCH sends in the n+1 subframe.

(2) when HS-PDSCH is configured in auxilliary carrier wave TS0, if HS-SCCH is configured in TS5 or TS6, can be backward compatible for the use that guarantees TS0 as far as possible, carry out following setting among the present invention:

When HS-PDSCH is configured in auxilliary carrier wave TS0, preferably, forbid that all HS-SCCH on this carrier wave are configured in TS5 or TS6;

Be configured in TS5 or TS6 if can't forbid all HS-SCCH, need at least to guarantee have a HS-SCCH not to be configured in TS5 or TS6, and, forbid that the HS-SCCH that is configured in TS5 or TS6 dispatches the HS-PDSCH resource of assisting carrier wave TS0.The HS-PDSCH resource of auxilliary carrier wave TS0 is merely able to by the HS-SCCH scheduling that is configured in other descending time slot positions except that TS5 and TS6.

(3) when HS-PDSCH is configured in auxilliary carrier wave TS0, carry out between following setting: HS-PDSCH and the HS-SICH subframe at interval among the present invention.That is: HS-PDSCH sends in the n subframe, and HS-SICH sends in the n+2 subframe.

UE and NodeB carry out the transmission of HS-PDSCH and HS-SICH according to the timing relationship of the invention described above setting.

Above-mentioned being is configured in the HS-SCCH of UE and/or HS-PDSCH after auxilliary carrier wave TS0 goes up, for the influence of timing relationship between relevant each physical channel of HSDPA.

In HSDPA, if RNC is configured in the HS-PDSCH resource pool of scheduling on the auxilliary carrier wave TS0, promptly Tiao Du HS-PDSCH resource pool comprises auxilliary carrier wave TS0, then the HS-PDSCH resource of distributing for UE just may comprise TS0, need indicate the HS-PDSCH resource of distributing to this UE whether to comprise this auxilliary carrier wave TS0 in HS-SCCH.

Particularly, the mode that whether is scheduled by HS-SCCH indication TS0 can have following three kinds:

(1) for the HS-SCCH that has idle bit, can adopt a default idle bit to indicate TS0 whether to be scheduled, for example utilize first idle bit indication.This bit is that 1 expression TS0 is scheduled; This bit is that 0 expression TS0 is not scheduled.

(2) for the HS-SCCH of the channel code collection information field with 8 bits, whether the method for beginning channel code sign indicating number that can be by redefining this UE number is saved a bit, indicate TS0 to be scheduled with this bit.Preceding four bits represent to begin the sign indicating number number of channel code in the channel code collection information field of 8 bits, can represent whether TS0 is scheduled with the 4th bit.First three bit in four bits of expression beginning channel code sign indicating number number is used for representing that the channel code sign indicating number number is the some channel code in 8 channel code of even number.If the numerical value of first three bit of expression beginning channel code sign indicating number number is N (N=0,1,2,3,4,5,6,7), then expression beginning channel code yard number is: 2N.

(3) for there not being idle bit, channel code collection information field does not have the HS-SCCH of the bit that can save yet, and be provided with: the ID of UE " H-RNTI " is necessary for even number.If comprise TS0 among the HS-PDSCH, then send H-RNTI+1 to UE; If do not comprise TS0 among the HS-PDSCH, send H-RNTI to UE.By detecting UE ID is that H-RNTI still is that H-RNT1 determines whether TS0 is scheduled;

Perhaps, whether a bit directly using H-RNTI is used to indicate TS0 to be scheduled: whether first bit (most significant bit) with H-RNTI indicates TS0 to be scheduled.That is: the H-RNTI of UE represents with 16 bits, and wherein first bit one is decided to be: 0.When the H-RNTI that carries on the HS-SCCH that sends to UE equaled the H-RNTI of UE, expression TS0 was not scheduled to this UE; First bit of the H-RNTI that carries on UE finds HS-SCCH is when to be 1 other 15 bits identical with back 15 bits of the H-RNTI that is somebody's turn to do, represent that this HS-SCCH also is scheduling to this UE, and TS0 is scheduled to this UE.

(4) when not supporting the time slot switching point in the time of 1: 5, by being used for indicating scheduling whether to be scheduled with leftmost bit indication TS0 to 5 bits of the time slot of UE among the HS-SCCH: for example utilizing leftmost bit is that 1 expression TS0 is scheduled; This bit is that 0 expression TS0 is not scheduled.

Next, specify the mode whether the indication TS0 that may adopt is scheduled at HS-SCCH type1～HS-SCCH type9 respectively.

(a)HS-SCCH?type?1

HS-SCCH type 1 has channel code collection information field.The channel code collection information field of this HS-SCCH comprises 8 information bit: x _{Ccs, 1}, x _{Ccs, 2}, x _{Ccs, 3}, x _Ccs4, x _{Ccs, 5}, x _{Ccs, 6}, x _{Ccs, 7}, x _{Ccs, 8}Four bits of beginning are represented the channel code number that begins.Next four bits are represented the channel code number that finishes.

For supporting the use of TS0, can the channel code territory of 8 bits be redefined.Regulation:

The channel code of beginning is necessarily from even number, and the channel code that has even number in descending 16 channel code has only 8.Therefore, determine that with 3 bits the sign indicating number of the channel code that begins most is number just passable.If the numerical value of 3 bits of beginning is N, then the sign indicating number of expression beginning channel code number is: 2N.

The 4th bit is used to indication and whether comprises TS0 in HS-PDSCH.If being 1 expression HS-PDSCH, this bit comprises TS0; If this bit is 0, expression HS-PDSCH does not comprise TS0.

Four last bits are used for representing the channel code number that finishes.

Under above-mentioned definition, stipulate: if three bits that begin most are: 111, the bit of end is: 1111 expression SF=1.

Simultaneously, whether this HS-SCCH also can adopt preceding method (3) to indicate TS0 to be scheduled.

(b)HS-SCCH?type?2

In HS-SCCH type 2, adopt first idle bit to indicate TS0 whether to be scheduled.Whether this HS-SCCH also can adopt preceding method (3) to indicate TS0 to be scheduled.

(c)HS-SCCH?type?3

In HS-SCCH type 3, adopt a unique idle bit to indicate TS0 whether to be scheduled.Whether this HS-SCCH also can adopt method 3 to indicate TS0 to be scheduled.

(d)HS-SCCH?type?4

In HS-SCCH type 4, adopt a unique idle bit to indicate TS0 whether to be scheduled.Whether this HS-SCCH also can adopt method 3 to indicate TS0 to be scheduled.

(e)HS-SCCH?type?5

This HS-SCCH does not have idle bit to utilize.Whether this HS-SCCH can adopt method 3 to indicate TS0 to be scheduled.

(f)HS-SCCH?type?6

Can represent whether TS0 is scheduled with first idle bit.Whether this HS-SCCH also can adopt method 3 to indicate TS0 to be scheduled.

(g)S-SCCH?type?7

Whether HS-SCCH type 7 can adopt method 1, method 2 and mode 3 to indicate TS0 to be scheduled:

(1) in HS-SCCH type 7, can adopt first idle bit to indicate TS0 whether to be scheduled.

(2) can indicate TS0 whether to be scheduled with the 4th bit in the channel code collection information field of this HS-SCCH.

(3) whether this HS-SCCH also can adopt method 3 to indicate TS0 to be scheduled.

(h)HS-SCCH?type?8

Whether this HS-SCCH can adopt method 3 to indicate TS0 to be scheduled.

(i)HS-SCCH?type?9

Whether this HS-SCCH can adopt method 3 to indicate TS0 to be scheduled.

As mentioned above, when HS-PDSCH being configured in after auxilliary carrier wave TS0 goes up, be to need to revise for the form of HS-SCCH, except that this HS-SCCH, to the form of the form of HS-PDSCH and HS-SICH all less than influencing.

When auxilliary carrier wave TS0 configuration HSDPA was correlated with down channel, UE was subjected to following influence, and correspondingly adjusts, particularly:

(1) UE does not monitor HS-SCCH in the moment of carrying out different-frequency measure.

(2) when UE found that it receives HS-PDSCH and conflicts with the moment that it carries out different-frequency measure, UE can adopt one of following dual mode:

(2-1) UE suspends or postpones different-frequency measure one time

(2-2) UE carries out different-frequency measure on time, stops to receive HS-PDSCH, does not also feed back corresponding HS-SICH and gives NODEB.

(3) go up indication TS0 for its HS-SCCH (comprising: the HS-SCCH of the HS-PDSCH resource allocation that is used to dispatch and the HS-SCCH that is used for semi-static resource HS-PDSCH distribution) and be scheduled when UE finds scheduling to it, but the HS-SCCH that it receives but is positioned at TS5 or TS6, when UE can't accomplish to receive HS-PDSCH data on the TS0 of next subframe at all on time, UE determined to occur the HS-SCCH decoding error.In this case, UE does not receive HS-PDSCH and does not feed back HS-SICH yet and give NODEB.

(4) UE follows following timing relationship:

(4-1) HS-SICH of the HS-PDSCH of Tiao Du HS-SCCH, scheduling and scheduling sends in n subframe, n+1 subframe and n+3 subframe respectively.

(4-2) timing that sends between the HS-SICH of the HS-SCCH of HS-SCCH instruction and the affirmation information that feedback receives instruction is: HS-SCCH sends in the n subframe, and HS-SICH sends in the n+3 subframe.

(4-3) in the semi-static HS-PDSCH resource allocation, the timing relationship between HS-SCCH and first HS-PDSCH subframe is: HS-SCCH sends in the n subframe, and first HS-PDSCH subframe sends in the n+1 subframe.

(4-4) in the semi-static HS-PDSCH resource allocation, timing relationship between the HS-SICH of HS-PDSCH and feeding back ACK/nack message is: HS-PDSCH sends in the n subframe, and the HS-SICH that feeds back the ACK/NACK information of this HS-PDSCH sends in the n+2 subframe.

(3) HSUPA is relevant E-AGCH and/or E-HICH are configured on the TS0 of auxilliary carrier wave A.

In HSUPA, E-PUCH is used for the transmitting high speed upstream data.System is that the E-PUCH that UE distributes is divided into two classes, and the E-PUCH of scheduling and the E-PUCH of non-scheduling for the E-PUCH of non-scheduling, are carried out the distribution of corresponding non-scheduling E-PUCH and non-scheduling E-HICH by RNC; E-PUCH for scheduling is carried out the distribution of the E-HICH of corresponding E-AGCH, scheduling E-PUCH and scheduling by NodeB.

Suppose that a HSUPA UE is configured on the auxilliary carrier wave, is distributed the E-HICH of E-AGCH and scheduling for this UE by the HSUPA scheduler.If E-AGCH that this UE is assigned with and/or E-HICH are configured on the auxilliary carrier wave TS0, then NodeB utilizes respective channel transmission information on auxilliary carrier wave TS0.

At the HSUPA scheduler is that UE distributes in the HSUPA channel procedure, if the channel configuration that distributes on auxilliary carrier wave TS0, then needs to avoid to conflict mutually constantly with the different-frequency measure of this UE.Particularly, the HSUPA scheduler obtains each and is configured in the parameter (H-RNT of UE or E-RNTI and M_REP) that HSUPA UE on this carrier wave carries out different-frequency measure.By these parameters, scheduler can determine accurately that UE carries out the moment of different-frequency measure.The moment that scheduler need be avoided carrying out different-frequency measure at UE is distributed E-AGCH or E-HICH to UE.Here, E-AGCH comprises the E-AGCH that is used to send the E-AGCH of E-DCH control information and sends the E-AGCH instruction.

When distribute to UE be the E-PUCH of non-scheduling the time, carry out channel allocation by RNC, then RNC is configured in this E-HICH non-TS0 time slot as far as possible for the E-HICH of the UE configuration non-scheduling corresponding with non-scheduling E-PUCH the time.If can't avoid E-HICH is configured in TS0, then RNC is according to the timing relationship between the E-HICH of the E-PUCH of non-scheduling and non-scheduling, when the frame of E-PUCH of the non-scheduling of configuration divides multiplexing parameters, guarantee as far as possible: with each E-PUCH in the cycle the corresponding E-HICH subframe of each E-PUCH subframe can not conflict constantly with the different-frequency measure of UE.If can't avoid this conflict, then RNC, NODEB and UE all carry out following processing:

Conflict with the moment that UE receives E-HICH when the measurement moment of UE, UE can suspend or postpone different-frequency measure one time;

Perhaps, UE can be by non-scheduling the frame branch multiplexing parameters prediction of the E-PUCH reception that E-HICH whether can occur conflict constantly with the different-frequency measure of UE, when UE predicts conflict,, do not receive the E-HICH of NODEB feedback for the UE that avoids conflict does not send corresponding E-PUCH to NODEB yet.And NODEB predicts conflict too, does not constantly receive E-PUCH in corresponding conflict, does not send E-HICH.

With similar ground among the HSDPA, be configured in when assisting on the carrier wave TS0 at the E-AGCH that distributes for UE and/or E-HICH, can cause certain influence to the timing relationship of the related physical interchannel of HSUPA.Wherein, be included in timing relationship influence, E-AGCH instruction in the E-PUCH resource allocation of scheduling send in the influence and the influence of the timing relationship in the semi-static E-PUCH resource allocation of timing relationship, describe respectively below.

(A ') timing relationship influence in the E-PUCH resource allocation of scheduling

For the HSUPA business on the auxilliary carrier wave, when E-AGCH was not configured in auxilliary carrier wave TS0, E-AGCH, the E-PUCH and the E-HICH that distribute to a UE satisfied following timing relationship:

E-AGCH sends in the n subframe; E-PUCH sends in the n+2 subframe; E-HICH sends in the n+2+D subframe.D represents the timing difference between E-PUCH and the E-HICH.

When E-AGCH is configured in TS0, according to stipulating that the timing relationship between E-AGCH, E-PUCH and the E-HICH will change in the present 3GPP standard: E-AGCH sends in the n subframe, and E-PUCH sends in the n+1 subframe, and E-HICH sends in the n+1+D subframe.

Below by analyzing explanation: when E-AGCH when the n subframe sends, UE can't accomplish in the n+1 subframe E-PUCH to be sent to NODEB.Make a concrete analysis of as follows:

After UE received E-AGCH, for sending E-PUCH, UE need finish following processing:

(1) E-AGCH is carried out joint-detection, demodulation and decoding, obtain the E-DCH control information

(2) the MAC-e/MAC-i entity of UE need carry out the E-TFC selection, according to the E-TFC selection result MAC-e/MAC-i data be packed according to power mandate, code channel mandate and the time slot authorization message of E-PUCH in the E-DCH control information, generates the E-DCH data block.

(3) physical layer of UE need be encoded, modulate the E-DCH data block, and the symbol sebolic addressing that modulation is obtained is multiplexed on the E-PUCH

(4) the MAC-e/MAC-i entity of UE need determine that E-UCCH goes up the loaded information bit: the TB SIZE of E-DCH data block (data block size), RSN (cyclic sequence number) and HARQ ID (ID of HARQ)

(5) physical layer of UE to the information bit on the E-UCCH channel encode, QPSK modulation, then E-UCCH is multiplexed on the E-PUCH

(6) be multiplexed on the E-PUCH after the DLPC Command field bit modulation of UE physical layer with the E-AGCH of generation

(7) UE sends the E-PUCH channel to NODEB

Processing of finishing based on above-mentioned needs and the disposal ability of UE, UE can't finish above-mentioned processing in the time of a subframe.Therefore, UE can't support: E-AGCH sends in the n subframe, and E-PUCH sends in the n+1 subframe.

With among the aforementioned HSDPA similarly, constant for guaranteeing the timing relationship between E-AGCH and the E-PUCH, and make the use of TS0 backward compatible as much as possible, the present invention carries out following setting:

E-PUCH and relevant E-AGCH be the time of a subframe at interval, and promptly E-AGCH sends in the n subframe, and E-PUCH sends in the n+2 subframe.

When E-HICH is configured in TS0, the timing difference between E-PUCH and the E-HICH can be determined according to ability by NODEB, after determining this timing parameters is reported RNC, is disposed to UE by RNC.Like this, can keep identical E-PUCH and the timing relationship between the E-HICH between NODEB and the UE.

In HSUPA, a sub-district may be configured a plurality of E-HICH, for simplifying the processing of NodeB and UE, when in the sub-district during the more than E-HICH of configuration, preferably, RNC is configured in all E-HICH in the sub-district on the TS0 simultaneously, perhaps, be configured in simultaneously on the time slot of non-TS0, promptly should avoid as far as possible: the E-HICH that has is configured in TS0, and the E-HICH that has is configured in non-TS0.

If RNC can't carry out above-mentioned configuration, then for the UE of an E-PUCH who not only supports non-scheduling E-PUCH but also support to dispatch, preferably, RNC gives each E-HICH in the E-HICH set of the E-HICH of non-scheduling of this UE configuration and the scheduling that NODEB gives this UE configuration, be configured in simultaneously on the TS0, perhaps, be configured in simultaneously on the time slot of non-TS0, should avoid as far as possible: the E-HICH that has is configured in TS0, and the E-HICH that has is configured in non-TS0.Illustrate this below and configure the problem of bringing now.

Suppose: uplink and downlink timeslot ratio is 5: 1 configuration (be that TS1～TS5 is an ascending time slot, TS6 is a descending time slot), and the E-PUCH of the non-scheduling E-PUCH of UE and scheduling is configured in TS5.If the non-scheduling E-HICH of UE is configured in TS0, and when the timing difference between E-PUCH and the E-HICH is 4 time slots, timing relationship between the E-PUCH of the non-scheduling of this UE and the E-HICH of non-scheduling is: E-PUCH sends in the n subframe, and E-HICH sends in the n+2 subframe.When the E-HICH of the scheduling of UE set includes only an E-HICH and this E-HICH when being configured in TS6, if the timing difference between E-PUCH and the E-HICH still is set to 4 time slots, then the timing relationship between the E-HICH of the E-PUCH of the scheduling of this UE and scheduling is: E-PUCH sends in the n subframe, and E-HICH sends in the n+1 subframe.

In above-mentioned example, under the situation that the timing difference of E-PUCH and E-HICH remains unchanged, because the difference of the time slot position of E-HICH configuration causes timing relationship and inequality between E-PUCH and the E-HICH.Like this,,, need to safeguard two timing relationships, cause handling complexity and improve for guaranteeing the accuracy of transfer of data for NodeB and UE.Therefore, preferably, need avoid distributing to a plurality of E-SICH of a UE, part is configured on the TS0, and part is configured on the time slot of non-TS0.

In like manner, when comprising a more than E-HICH in the E-HICH of the scheduling of the UE set, NODEB should avoid as far as possible: distribute in the E-HICH set of scheduling of UE and not only comprise the E-HICH that is configured in TS0 but also comprise the E-HICH that is configured in non-TS0.

For a sub-district of supporting HSUPA, this sub-district can be supported 32 E-HICH at most.For this sub-district, the E-HICH of a scheduling is just enough.The E-HICH number of scheduling is many more in the sub-district, and the channel code resource of the SF=16 that E-HICH expends is just many more.Therefore, there is no need E-HICH a plurality of scheduling of cell configuration.Under the situation of the E-HICH of a scheduling of cell configuration, NODEB includes only an E-HICH for the E-HICH set of the scheduling of each UE configuration, therefore, NODEB can avoid: distribute in the E-HICH set of scheduling of UE and not only comprise the E-HICH that is configured in TS0 but also comprise the E-HICH that is configured in non-TS0.

Support the UE of the E-PUCH that dispatches again for an E-PUCH who supports non-scheduling simultaneously, only dispose in the sub-district under the E-HICH situation of a scheduling, RNC distributes to the non-scheduling E-HICH of this UE and should be promptly may be configured in TS0 simultaneously or be configured in non-TS0 simultaneously with the E-HICH of the scheduling of this sub-district.If RNC can't accomplish above-mentioned configuration, then UE side and NODEB side just need to keep following two kinds of timing relationships: the timing relationship between the E-HICH of the timing relationship between the E-PUCH of non-scheduling and the E-HICH of non-scheduling, the E-PUCH of scheduling and scheduling.

Timing relationship between the E-AGCH that (B ') sends the E-AGCH instruction and the relevant E-PUCH

Can send the instruction of the semi-static E-PUCH resource of release to corresponding UE by E-AGCH, UE receives after the instruction, need to give NODEB by E-PUCH feedback acknowledgment information, NODEB regains in the semi-static E-PUCH resource that the affirmation information that receives the UE transmission just can be distributed to this UE later on.

Timing relationship between the E-AGCH of transmission E-AGCH instruction and the E-PUCH of feedback acknowledgment information when E-AGCH is not configured in TS0 is: E-AGCH sends in the n subframe; E-PUCH sends in the n+2 subframe.

When E-AGCH was configured in TS0, the analysis in (A ') as described above was the variation of avoiding timing relationship and backward compatible, and be provided with: no matter whether E-AGH is configured in TS0, and E-AGCH sends in the n subframe; E-PUCH sends in the n+2 subframe.NodeB and UE carry out message transmission according to the timing relationship that is provided with.

Timing relationship in (C ') semi-static E-PUCH resource allocation

In semi-static E-PUCH resource allocation, as E-AGCH during not at TS0, carry out the E-AGCH of semi-static E-PUCH resource authorization and the timing relationship of first E-PUCH subframe and be: E-AGCH sends in the n subframe, and E-PUCH sends in the n+2 subframe.

When E-AGCH is configured in TS0, if according in the present 3GPP standard about the timing relationship between E-AGCH and E-PUCH, then the timing relationship between E-AGCH and first E-PUCH can change: E-AGCH sends in the n subframe; First E-PUCH subframe sends in the n+1 subframe.

Analysis in (A ') as described above is configured in TS0 and guarantees that timing relationship is backward compatible for supporting E-AGCH, is provided with among the present invention: be used for 1 subframe that is spaced apart between the E-AGCH of semi-static resource allocation and first E-PUCH subframe.That is: E-AGCH sends in the n subframe, and E-PUCH sends in the n+2 subframe.

In the distribution of semi-static E-PUCH resource, ACK/NACK information and the TPC ﹠amp of E-PUCH and feedback E-PUCH; Timing relationship between the E-HICH of SS order reports RNC after still being determined by NODEB, and by RNC this timing relationship is transmitted to UE.When E-HICH was configured in TS0, NODEB need determine the timing difference between E-PUCH and the E-HICH according to self-ability, and this timing difference is reported RNC.

NodeB and UE carry out message transmission according to the timing relationship of above-mentioned setting.

Above-mentioned being is configured in the E-AGCH of UE and/or E-HICH after auxilliary carrier wave TS0 goes up, for the influence of timing relationship between relevant each physical channel of HSUPA.

When UE when auxilliary carrier wave is initiated the E-RUCCH process, the subframe of subframe that UE sends SYNC-UL, NODEB feedback FPACH may appear and UE sends the subframe of E-RUCCH and the moment that UE carries out different-frequency measure clashes.If clash, can adopt one of following two kinds of methods:

(1) the E-RUCCH process is preferential.When E-RUCCH process and UE carry out different-frequency measure when conflicting mutually, UE stops or postpones current different-frequency measure, initiates the E-RUCCH process on time.

(2) different-frequency measure is preferential.When E-RUCCH process and UE carry out different-frequency measure when conflicting mutually, UE carries out different-frequency measure on time, and the E-RUCCH process is postponed.

When auxilliary carrier wave TS0 disposes the HSUPA correlated channels, can cause following influence to UE, correspondingly, UE need suitably adjust, particularly:

(1) when UE has the E-PUCH of non-scheduling, if each E-PUCH in the cycle the corresponding E-HICH subframe of each E-PUCH subframe can not avoid fully conflicting constantly with the measurement of UE.Then UE carries out following processing:

UE can suspend or postpone different-frequency measure one time;

Perhaps, UE can be by non-scheduling the frame branch multiplexing parameters prediction of the E-PUCH reception that E-HICH whether can occur conflict constantly with the different-frequency measure of UE, when UE predicts when conflicting, for avoiding conflict, UE does not send corresponding E-PUCH to NODEB, does not receive the E-HICH that NODEB sends yet.And NODEB predicts conflict too, does not constantly receive E-PUCH in corresponding conflict, does not send E-HICH.

(2) initiate moment that E-RUCCH process and UE carry out different-frequency measure when clashing as UE, can adopt one of following two kinds of methods:

(2-1) the E-RUCCH process is preferential.UE suspends or postpones different-frequency measure one time, initiates the E-RUCCH process on time.

(2-2) different-frequency measure is preferential.UE carries out different-frequency measure on time, and the E-RUCCH process is postponed.

(3) E-AGCH monitoring and the timing relationship that UE is carried out carries out following processing:

(3-1) UE does not monitor E-AGCH in the moment of carrying out different-frequency measure.

(3-2) no matter whether E-AGCH is configured in TS0, and the timing difference between E-AGCH and the E-PUCH is 2, that is: E-AGCH sends n subframe, and corresponding E-PUCH sends n+2 subframe.

(4) find to distribute to its E-HICH of E-PUCH correspondence of scheduling and the different-frequency measure of UE when clashing constantly as UE, UE determines: mistake appears in the decoding to E-AGCH, UE carries out different-frequency measure on time, does not send corresponding E-PUCH, does not also receive corresponding E-HICH; Perhaps, described UE sends E-PUCH on time, and stops different-frequency measure or postpone the different-frequency measure of conflict time in the conflict time, receives corresponding E-HICH from NodeB.

When being configured in the E-AGCH of UE and/or E-HICH on the auxilliary carrier wave TS0, E-AGCH, E-PUCH and E-HICH being gone up loaded information be provided with all and do not influence.

Above-mentioned using method about auxilliary carrier wave TS0 all is to be in the CELL_DCH state at UE.At last, from residing other states of UE, when research UE is in other states, when relevant down channel is configured on the above-mentioned auxilliary carrier wave TS0, to the influence of NODEB and UE.

At first, introduce influence to the UE that is in the CELL_FACH state.

When UE is in the CELL_FACH state and when having proprietary UE ID, UE monitors the public HS-SCCH set on the carrier wave of appointment.When the UE ID that carries on by HS-SCCH found the HS-SCCH that sends to it is arranged, UE received the data block that sends to it on the HS-PDSCH according to the indication of HS-SCCH.And give NODEB by the ACK/NACK information of corresponding HS-SICH feedback HS-PDSCH in the public HS-SICH set.

When UE is in the CELL-FACH state, but when UE did not have H-RNTI, then UE monitored the public HS-SCCH set on the carrier wave of appointment.When the public ID that carries on by HS-SCCH found to send to its HS-SCCH, UE received corresponding HS-PDSCH according to the indication of this HS-SCCH.And the decode results of HS-PDSCH is sent to the high level of UE.The high level of UE can determine by the IMSI information of carrying in the data whether the data on this HS-PDSCH are to send to this UE.

When HS-SCCH and HS-PDSDH are not configured in auxilliary carrier wave TS0, the corresponding relation the when timing relationship when UE is in the CELL_FACH state between HS-SCCH and the HS-PDSCH is in the CELL_DCH state with UE.That is: HS-SCCH sends in the n subframe, and HS-PDSCH sends in the n+1 subframe.

According to the description in aforementioned (two), when HS-SCCH and HS-PDSCH are configured in auxilliary carrier wave TS0, can obtain as drawing a conclusion:

(1) when HS-SCCH is configured in TS0, timing relationship remains unchanged between HS-SCCH and first HS-PDSCH subframe: HS-SCCH sends in the n subframe, and HS-PDSCH sends in the n+1 subframe;

(2) when HS-PDSCH is configured in TS0,, can obtain following identical conclusion referring to aforementioned analysis:

(2-1) when HS-PDSCH is configured in TS0, if HS-SCCH is configured in TS4 or TS4 descending time slot before, then the timing relationship of HS-SCCH and HS-PDSCH can be constant.That is: HS-SCCH sends in the n subframe; HS-PDSCH sends in the n+1 subframe.

(2-2) when HS-PDSCH is configured in TS0, if HS-SCCH is configured in TS5 or TS6, then UE can't accomplish: send HS-SCCH in the n subframe; Send HS-PDSCH in the n+1 subframe.Can be backward compatible for the use that guarantees TS0 as far as possible, carry out following setting:

(2-2-1) when HS-PDSCH is configured in TS0, preferably, forbid that all HS-SCCH on this carrier wave are configured in TS5 or TS6;

If (2-2-2) can't forbid that all HS-SCCH are configured in TS5 or TS6, guarantee that at least one HS-SCCH is not configured in TS5 or TS6, and, the HS-PDSCH resource of forbidding being configured in the HS-SCCH scheduling TS 0 of TS5 or TS6.The HS-PDSCH resource of TS0 is merely able to by the HS-SCCH scheduling that is configured in other descending time slot positions.

(3) when HS-PDSCH is configured in TS0, be provided with: subframe in interval between HS-PDSCH and the HS-SICH.That is: HS-PDSCH sends in the n subframe, and HS-SICH sends in the n+2 subframe.

(4) may comprise TS0 owing to send to the HS-PDSCH of UE, therefore, need whether be scheduled by the corresponding information indication TS0 of HS-SCCH to UE.Concrete indicating mode repeats no more as previously mentioned here.

Next, introduce influence to the UE that is in CELL_PCH and CELL_URA state.

When UE was in CELL_PCH and proprietary UE ID is arranged, UE monitored PICH, received HS-SCCH according to the indication on the PICH then.And receive corresponding HS-PDSCH according to the timing relationship between HS-SCCH and the HS-PDSCH.

Above-mentioned HS-SCCH and the timing relationship between the HS-PDSCH are as follows:

When HS-SCCH and HS-PDSDH are not configured in auxilliary carrier wave TS0, the corresponding relation the when timing relationship between HS-SCCH and the HS-PDSCH is in the CELL_DCH state with UE.That is: HS-SCCH sends in the n subframe, and HS-PDSCH sends in the n+1 subframe.

According to the analysis in aforementioned (two), when HS-SCCH and HS-PDSCH are configured in auxilliary carrier wave TS0, can obtain being in conclusion identical under the CELL_DCH state with UE.Here repeat specification is as follows:

(1) when HS-SCCH is configured in TS0, timing relationship remains unchanged between HS-SCCH and first HS-PDSCH subframe: HS-SCCH sends in the n subframe, and HS-PDSCH sends in the n+1 subframe.

(2) when HS-PDSCH is configured in TS0,, can obtain following identical conclusion referring to analysis above:

(2-1) when HS-PDSCH is configured in TS0, if HS-SCCH is configured in TS4 or TS4 descending time slot before, then the timing relationship of HS-SCCH and HS-PDSCH can be constant.That is: HS-SCCH sends in the n subframe; HS-PDSCH sends in the n+1 subframe.

(2-2) when HS-PDSCH is configured in TS0, if HS-SCCH is configured in TS5 or TS6, then UE can't accomplish: send HS-SCCH in the n subframe; Send HS-PDSCH in the n+1 subframe.Can be backward compatible for the use that guarantees TS0 as far as possible, can provide following regulation:

(2-2-1) when HS-PDSCH is configured in TS0, preferably, forbid that all HS-SCCH on this carrier wave are configured in TS5 or TS6.

If (2-2-2) can't forbid that all HS-SCCH are configured in TS5 or TS6, guarantee that at least one HS-SCCH is not configured in TS5 or TS6, and, the HS-PDSCH resource of forbidding being configured in the HS-SCCH scheduling TS 0 of TS5 or TS6.The HS-PDSCH resource of TS0 is merely able to by the HS-SCCH scheduling that is configured in other descending time slot positions.

(3) may comprise TS0 owing to send to the HS-PDSCH of UE, therefore, need whether be scheduled by the corresponding information indication TS0 of HS-SCCH to UE.Concrete mode repeats no more as previously mentioned here.

When UE is in the CELL_URA state or is in CELL_PCH but when not having proprietary UE ID, UE monitors PICH, receives corresponding HS-PDSCH according to the indication on the PICH then.The high level of UE is gone up the IMSI information that comprises in the data carried by data according to HS-PDSCH and can be determined to send to this UE's when this data block whether.Under these two states, owing to do not have HS-SCCH, and HS-PDSCH may comprise therefore, whether HS-PDSCH need being comprised that TS0 is notified to UE by other modes by auxilliary carrier wave TS0, for example is broadcast to relevant UE by self-defining broadcasting format.

Being preferred embodiment of the present invention only below, is not to be used to limit protection scope of the present invention.Within the spirit and principles in the present invention all, any modification of being done, be equal to replacement, improvement etc., all should be included within protection scope of the present invention.

Claims (33)

1. the information transferring method on the auxilliary carrier wave time slot 0 is characterized in that this method comprises:

For the UE and the NodeB that support that auxilliary carrier wave time slot 0 (TS0) uses, RNC is configured in the DL DPCH of UE on the auxilliary carrier wave TS0, and NodeB sends data to described UE on the DL DPCH of configuration.

2. method according to claim 1 is characterized in that, RNC divides multiplex mode to be configured on the described auxilliary carrier wave TS0 by frame the DL DPCH of different UEs.

3. method according to claim 1 and 2, it is characterized in that, when RNC was configured on the described auxilliary carrier wave TS0 at the DL DPCH with described UE, RNC obtained the different-frequency measure time of described UE, and the DL DPCH that guarantees configuration not with the different-frequency measure time conflict of described UE.

4. method according to claim 1 and 2, it is characterized in that, RNC obtains the different-frequency measure time of described UE, if the DL DPCH of RNC configuration and the different-frequency measure time conflict of described UE, then the data of NodeB on the temporary transient DL of termination of conflict time DPCH send, perhaps, described UE temporarily stops or postpones the different-frequency measure of conflict time in the conflict time, receives the data that DL DPCH goes up transmission.

5. method according to claim 1 is characterized in that, the UE and the NodeB that support auxilliary carrier wave TS0 to use report to RNC: support auxilliary carrier wave TS0.

6. the information transferring method on the auxilliary carrier wave time slot 0 is characterized in that this method comprises:

For the NodeB that supports that auxilliary carrier wave time slot 0 (TS0) uses, RNC is configured in arbitrary down channel of HSDPA on the auxilliary carrier wave time slot 0 (TS0), described NodeB is the HSDPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, for the UE that supports auxilliary carrier wave TS0, arbitrary down channel that permission will be configured on the described auxilliary carrier wave TS0 is distributed to described UE;

Be configured in HSDPA UE on the described auxilliary carrier wave TS0 for the down channel that is assigned with, NodeB sends downlink information or data to it on described arbitrary down channel of configuration.

7. method according to claim 6 is characterized in that, described RNC is configured in arbitrary down channel of HSDPA on the auxilliary carrier wave TS0 and is: RNC is configured in HS-SCCH and/or HS-PDSCH resource pool on the described auxilliary carrier wave TS0; Described HS-SCCH comprises HS-SCCH that sends the HS-SCCH instruction and the HS-SCCH that sends the HS-DSCH control information, wherein, the HS-SCCH that sends the HS-SCCH instruction comprises HS-SCCH orders typeA and typeB, and the HS-SCCH that sends the HS-DSCH control information comprises HS-SCCH type1～type9.

8. method according to claim 6, it is characterized in that, when NodeB is the HSDPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, the scheduler of described NodeB obtains the different-frequency measure time of described UE, and guarantee scheduling give described UE's and be configured in time of the arbitrary down channel on the described auxilliary carrier wave TS0, not with the different-frequency measure time conflict of described UE.

9. method according to claim 8 is characterized in that, the HSDPA UE that the auxilliary carrier wave TS0 of arbitrary support uses when carrying out different-frequency measure, does not monitor HS-SCCH.

10. method according to claim 6, it is characterized in that, NodeB is when being configured in the HSDPA UE allocation of downlink channel of the auxilliary carrier wave TS0 use of support on the described auxilliary carrier wave, the scheduler of described NodeB obtains the different-frequency measure time of described UE, if NodeB dispatch to described UE's and be configured in the time of the HS-PDSCH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE

Described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, stops to receive data from described HS-PDSCH, and does not feed back corresponding HS-SICH and give NodeB.

11. method according to claim 6 is characterized in that, in the HS-PDSCH resource allocation of scheduling, and for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPA UE of proprietary UE ID is arranged,

The HS-SCCH of the scheduling that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB is configured in described auxilliary carrier wave TS0 when going up, the HS-SCCH of described scheduling and the HS-PDSCH of scheduling be in two adjacent subframes, two subframes at interval between the HS-SCCH of described scheduling and the HS-SICH of scheduling;

The HS-PDSCH of the scheduling that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB is configured in described auxilliary carrier wave TS0 when going up, the HS-PDSCH of HS-SCCH and the described scheduling of scheduling is in two adjacent subframes, subframe in interval between the HS-PDSCH of described scheduling and the HS-SICH of scheduling.

12. method according to claim 6, it is characterized in that, in the HS-PDSCH resource allocation of scheduling, for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPA UE of proprietary UE ID is arranged, when RNC is configured in the HS-PDSCH resource pool of dispatching on the described auxilliary carrier wave TS0

The HS-SCCH of all scheduling on the described auxilliary carrier wave all is not configured on the TS5 and TS6 of described auxilliary carrier wave;

Perhaps, the HS-SCCH of at least one scheduling on the described auxilliary carrier wave is not configured on the TS5 and TS6 of described auxilliary carrier wave, at NodeB is when being configured in the HSDPA UE allocation of downlink channel that the auxilliary carrier wave TS0 of support on the described auxilliary carrier wave uses, and the HS-SCCH scheduling of forbidding being configured in the scheduling of described auxilliary carrier wave TS5 and TS6 is configured in the HS-PDSCH resource of the scheduling on the described auxilliary carrier wave TS0.

13. method according to claim 12, it is characterized in that, when the HSDPA UE of the auxilliary carrier wave TS0 use of arbitrary support determined that scheduling comprises that the HS-SCCH of described auxilliary carrier wave TS0 and described UE is positioned at TS5 or TS6 for its HS-PDSCH, described UE determined the HS-SCCH decoding error.

14. method according to claim 6, it is characterized in that, in HS-SCCH instruction sent, the HS-SCCH that distributes for the HSDPA UE that supports auxilliary carrier wave TS0 to use as NodeB was configured in described auxilliary carrier wave TS0 when going up, two subframes in interval between described HS-SCCH and the corresponding HS-SICH.

15. method according to claim 6, it is characterized in that, in semi-static HS-PDSCH resource allocation, when NodeB is that HS-SCCH that a HSDPAUE who supports auxilliary carrier wave TS0 to use distributes is configured in described auxilliary carrier wave TS0 when going up, described HS-SCCH and first HS-PDSCH subframe are positioned at two adjacent subframes.

16. method according to claim 6 is characterized in that, in semi-static HS-PDSCH resource allocation, when semi-static HS-PDSCH was configured on the described auxilliary carrier wave TS0, HS-SCCH and first HS-PDSCH subframe were positioned at two adjacent subframes.

17. method according to claim 6 is characterized in that, in semi-static HS-PDSCH resource allocation, and when semi-static HS-PDSCH is configured on the described auxilliary carrier wave TS0,

All HS-SCCH on the described auxilliary carrier wave all are not configured on the TS5 and TS6 of described auxilliary carrier wave;

Perhaps, at least one HS-SCCH on the described auxilliary carrier wave is not configured on the TS5 and TS6 of described auxilliary carrier wave, at NodeB is to be configured in HSDPA UE that the auxilliary carrier wave TS0 of arbitrary support on the described auxilliary carrier wave uses when distributing semi-static resource, and the HS-SCCH scheduling of forbidding being configured in described auxilliary carrier wave TS5 and TS6 is configured in the semi-static HS-PDSCH resource on the described auxilliary carrier wave TS0.

18. method according to claim 6, it is characterized in that, in semi-static HS-PDSCH resource allocation, the HS-PDSCH that distributes as the HSDPA UE that uses for the auxilliary carrier wave TS0 of arbitrary support is configured in described auxilliary carrier wave TS0 when going up, subframe at interval between described HS-PDSCH and the HS-SICH.

19. method according to claim 6, it is characterized in that, this method further comprises: for being in the CELL_DCH state or being in the CELL_FACH state or being in the CELL_PCH state and the HSDPA UE of proprietary UE ID is arranged, NodeB issues to the HSDPA UE that the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave uses by HS-SCCH, and scheduling gives in the HS-PDSCH resource of this UE whether comprise described auxilliary carrier wave TS0.

20. method according to claim 19 is characterized in that, issues scheduling by HS-SCCH to described UE and gives in the HS-PDSCH resource of this UE whether comprise that the mode of described auxilliary carrier wave TS0 is:

Utilize the arbitrary idle bit among the HS-SCCH to issue, scheduling gives in the HS-PDSCH resource of described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, HS-SCCH for channel code collection information field with 8 bits, utilize preceding 3 bits in the described channel code collection information field to represent to begin channel code sign indicating number number, utilize the 4th bit in the described channel code collection information field to represent to dispatch in the HS-PDSCH resource to described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, utilize a bit among the H-RNTI of described UE, the expression scheduling gives in the HS-PDSCH resource of described UE whether comprise described auxilliary carrier wave TS0;

Perhaps, the H-RNTI that sets in advance all HSUPA UE is even number, gives when comprising described auxilliary carrier wave TS0 in the HS-PDSCH resource of described UE when scheduling, sends H-RNTI+1 to described UE by HS-SCCH; Give when not comprising described auxilliary carrier wave TS0 in the HS-PDSCH resource of described UE when scheduling, send H-RNTI to described UE by HS-SCCH.

21. method according to claim 6, it is characterized in that, this method further comprises: for being in the CELL_PCH state and not having proprietary UE ID or be in the HSDPAUE of CELL_URA state, issue to the HSDPA UE that the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave uses by broadcasting, scheduling gives in the HS-PDSCH resource of this UE whether comprise described auxilliary carrier wave TS0.

22. method according to claim 6 is characterized in that, the UE and the NodeB that support auxilliary carrier wave TS0 to use report to RNC: support auxilliary carrier wave TS0.

23. the information transferring method on the auxilliary carrier wave time slot 0 is characterized in that this method comprises:

For the NodeB that supports that auxilliary carrier wave time slot 0 (TS0) uses, arbitrary down channel of HSUPA is configured on the auxilliary carrier wave TS0, for being configured in the HSUPAUE allocation of downlink channel of the auxilliary carrier wave TS0 use of support on the described auxilliary carrier wave, be configured in HSUPAUE on the described auxilliary carrier wave TS0 for the down channel that is assigned with, NodeB sends downlink information or data to it on described arbitrary down channel of configuration.

24. method according to claim 23 is characterized in that, described arbitrary down channel with HSUPA is configured on the auxilliary carrier wave TS0 and is: RNC is configured in E-AGCH and/or E-HICH on the described auxilliary carrier wave TS0; Described E-AGCH comprises E-AGCH that sends the E-AGCH instruction and the E-AGCH that sends the E-DCH control information.

25. method according to claim 23 is characterized in that, when RNC is configured in described auxilliary carrier wave with the non-scheduling E-PUCH of described UE,

RNC will be configured on the time slot of non-TS0 with the corresponding E-HICH of described E-PUCH;

Perhaps, RNC will be configured on the described auxilliary carrier wave TS0 with the corresponding E-HICH of described E-PUCH, and guarantee each described E-HICH subframe not with the different-frequency measure time conflict of described UE.

26. method according to claim 23, it is characterized in that, when the HSUPA scheduler is the HSUPA UE allocation of downlink channel that is configured on the described auxilliary carrier wave, described HSUPA scheduler is determined the different-frequency measure time according to the different-frequency measure parameter of described UE, and guarantee scheduling give described UE's and be configured in time of the arbitrary down channel on the described auxilliary carrier wave TS0, not with the different-frequency measure time conflict of described UE.

27. method according to claim 26 is characterized in that, the HSUPA UE that the described auxilliary carrier wave TS0 of arbitrary support uses does not monitor E-AGCH when carrying out different-frequency measure.

28. method according to claim 23, it is characterized in that, RNC is configured in after HSDPA UE on the described auxilliary carrier wave distributes the E-PUCH of non-scheduling, if UE that the auxilliary carrier wave TS0 of described support uses and NodeB divide the multiplexing parameters prediction according to the frame of E-PUCH, scheduling give this UE's and be configured in the time of the E-HICH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE

Then described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, does not send E-PUCH to NodeB, and does not receive corresponding E-HICH from NodeB, and NodeB does not receive E-PUCH in the conflict time, does not also send corresponding E-HICH.

29. method according to claim 23, it is characterized in that, the HSUPA scheduler is the E-AGCH that is configured in the HSDPA UE allocation schedule on the described auxilliary carrier wave, behind the E-PUCH of scheduling and the E-HICH of scheduling, if the UE that the auxilliary carrier wave TS0 of described support uses predicts scheduling according to the E-AGCH that receives and gives this UE's, and be configured in the time of the E-HICH on the described auxilliary carrier wave TS0, different-frequency measure time conflict with described UE, then described UE determines the E-AGCH decoding error, carry out different-frequency measure in the conflict time, do not send E-PUCH, do not receive corresponding E-HICH yet; Perhaps, described UE sends E-PUCH, and stops different-frequency measure or postpone the different-frequency measure of conflict time in the conflict time, receives corresponding E-HICH from NodeB.

30. method according to claim 23 is characterized in that, the E-AGCH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe of the E-AGCH of described scheduling and E-PUCH interval;

The E-AGCH of the transmission E-AGCH instruction that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe in interval between the E-PUCH of described E-AGCH and UE feedback acknowledgment information;

In semi-static E-PUCH resource allocation, the E-AGCH that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, subframe in interval between the E-AGCH that carries out semi-static resource authorization and first E-PUCH subframe.

31. method according to claim 23, it is characterized in that, the E-HICH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, NodeB determine according to ability and the E-HICH of the corresponding E-PUCH of E-HICH of described scheduling and described scheduling between timing difference, and reporting RNC, RNC disposes this timing difference to described UE;

In semi-static E-PUCH resource allocation, the E-HICH of the scheduling that distributes as the UE that uses for the auxilliary carrier wave TS0 of described support is configured in described auxilliary carrier wave TS0 when going up, NodeB determine according to ability and the E-HICH of the corresponding E-PUCH of E-HICH of described scheduling and described scheduling between timing difference, and reporting RNC, RNC disposes this timing difference to described UE.

32. method according to claim 31 is characterized in that, when disposing a plurality of E-HICH in the sub-district,

RNC is configured in TS0 simultaneously with all E-HICH in this sub-district and goes up or be configured in simultaneously on the time slot of non-TS0;

Perhaps, not only support the E-PUCH that dispatches but also support the support of the E-PUCH of non-scheduling to assist the described UE that carrier wave TS0 uses for one, RNC is configured in TS0 simultaneously and goes up or be configured in simultaneously on the time slot of non-TS0 for the E-HICH and the NodeB of the non-scheduling of this UE configuration are each E-HICH in the E-HICH set of the scheduling of this UE configuration;

Perhaps, not only support the E-PUCH that dispatches but also support the support of the E-PUCH of non-scheduling to assist the described UE that carrier wave TS0 uses for one, RNC is each E-HICH in the E-HICH set of the scheduling of this UE configuration for the E-HICH and the NodeB of the non-scheduling of this UE configuration, be not configured in simultaneously that TS0 goes up or the time slot of non-TS0 on, then UE and NodeB all keep the timing relationship between two groups of E-PUCH and the E-HICH, are respectively the timing relationship between the E-HICH of the E-PUCH of timing relationship between the E-HICH of the E-PUCH of non-scheduling and non-scheduling, scheduling and scheduling.

33. method according to claim 23, it is characterized in that, the HSUPAUE that uses as the auxilliary carrier wave TS0 of the support that is configured in described auxilliary carrier wave initiates in the E-RUCCH process, if described UE sends the time of the subframe of uplink synchronous sequence, the subframe that receives FPACH, transmission E-RUCCH subframe, the time of carrying out different-frequency measure with described UE clashes

Described UE stopped different-frequency measure or postpones the different-frequency measure of conflict time in the conflict time, carried out described E-RUCCH process in the conflict time;

Perhaps, described UE carries out different-frequency measure in the conflict time, and described E-RUCCH process is postponed.

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