CN102256356A

CN102256356A - Method and device for allocating high-speed physical downlink shared channel (HS-PDSCH) resource in high-speed downlink packet access (HSDPA)

Info

Publication number: CN102256356A
Application number: CN2010101843853A
Authority: CN
Inventors: 魏立梅; 沈东栋; 王大飞; 赵渊
Original assignee: TD Tech Ltd
Current assignee: TD Tech Ltd
Priority date: 2010-05-20
Filing date: 2010-05-20
Publication date: 2011-11-23
Anticipated expiration: 2030-05-20
Also published as: CN102256356B

Abstract

The invention provides a method for allocating a high-speed physical downlink shared channel (HS-PDSCH) resource in high-speed downlink packet access (HSDPA). The method comprises the following steps that: a radio network controller (RNC) divides an HS-PDSCH resource pool of a carrier wave allocated to an NODEB into two rectangular HS-PDSCH sub-resource pools, informs the NODEB of time slots which are occupied by the two rectangular HS-PDSCH sub-resource pools and accesses to user equipment (UE) of the carrier wave; and when the UE is dispatched, the NODEB selects a first rectangular resource from a first rectangular HS-PDSCH sub-resource pool and a second rectangular resource from a second rectangular HS-PDSCH sub-resource pool and sends time slot information carrying the first rectangular resource and the second rectangular resource, and a high-speed shared control channel (HS-SCCH) of channel code information to the UE. The invention further discloses a system for allocating the HS-PDSCH resource in the HSDPA.

Description

HS-PDSCH resource allocation methods and device among a kind of HSDPA

Technical field

The present invention relates to the 3G (Third Generation) Moblie technical field, particularly a kind of high-speed downstream bag inserts high-speed physical downlink shared channel (HS-PDSCH) (HS-PDSCH) resource allocation methods and the device in (HSDPA).

Background technology

In the prior art, on the HSDPA carrier wave, the HSDPA scheduler of base station (NODEB) is all once dispatched in each subframe.Scheduler is determined the UE that is scheduled in current subframe, and is that each UE distributes High-Speed Shared Control Channel (HS-SCCH), high-speed physical downlink shared channel (HS-PDSCH) (HS-PDSCH) and high-speed shared information channel (HS-SICH).HS-SCCH and HS-SICH by to the configuration.The High-Speed Shared Control Channel (HS-SCCH) of distributing to UE is that radio network controller (RNC) configuration is to a HS-SCCH in the HS-SCCH set of UE; The HS-SICH that distributes to UE is the HS-SICH that matches with the HS-SCCH that distributes to UE; The HS-PDSCH that distributes to UE is a part of resource or the whole resource in the HS-PDSCH resource pool, and the shared resource of HS-PDSCH of distributing to UE must be the rectangle resource.So-called rectangle resource is meant that at each shared time slot of HS-PDSCH, the channel code of distributing to HS-PDSCH is continuous and identical.

In HSDPA, the resource of channel occupancy can be unique definite with time slot and these two groups of parameters of channel code.If at each shared time slot of HS-PDSCH, the channel code of distributing to HS-PDSCH is continuous and identical, be that abscissa, channel code are with the time slot on the channel resource chart of ordinate then, the shape that the resource that HS-PDSCH takies is formed must be a rectangle.

In the prior art, HS-PDSCH resource allocation flow process comprises the steps: as shown in Figure 1

Step 101:RNC gives each HSDPA carrier wave configuration some to HS-SCCH and HS-SICH, and notifies NODEB with configuration information.

Step 102: to each HSUPA UE, on the HSUPA at this UE place carrier wave, NODEB selects the HS-SCCH set of several HS-SCCH as described UE from the HS-SCCH of this carrier wave of RNC configuration.Correspondingly, constitute the HS-SICH set of UE to the HS-SICH of the HS-SCCH pairing in the HS-SCCH set of UE with configuration.

Step 103:NODEB is with the configuration information notice RNC of HS-SCCH set and the HS-SICH set of UE; By RNC this configuration information is transmitted to UE.If the number of HS-SICH was K during the HS-SICH of the number of HS-SCCH and UE gathered in the HS-SCCH of the UE set _Pair, K _PairMaximum be K _Pair=4.

Step 104:NODEB carries out a HSDPA scheduling at each subframe n.Determine each UE of being scheduled in current subframe by dispatching, and be that each UE that is scheduled distributes HS-SCCH, HS-PDSCH and HS-SICH.

Step 105: to each UE that is scheduled, the HS-SCCH that NODEB will distribute to this UE sends to UE; To distribute the HS-PDSCH of this UE to send to UE; And the HS-SICH of reception UE feedback.This step detailed process is as follows:

Step 105-1:NODEB will distribute to the HS-PDSCH configuration information of resource of UE in (n+d) subframe and the information of high speed descending sharing channel (HS-DSCH) the data block decoding that is used for carrying on the HS-PDSCH resource sends to UE by the HS-SCCH that distributes to UE.Here, d represents the processing delay of the scheduler of NODEB.

Step 105-2: when UE when (n+d) subframe detects NODEB and sends to its HS-SCCH, UE determines to distribute to its HS-PDSCH according to the HS-PDSCH configuration information of resource of carrying on the HS-SCCH, determines each required parameter of HS-DSCH data block decoding according to the information that is used for the decoding of HS-DSCH data block of carrying on the HS-SCCH.UE also will distribute to its HS-SICH with the HS-SICH conduct of detected HS-SCCH pairing.

Step 105-3:NODEB is according to HS-DSCH data block of HS-PDSCH resource assembling of distributing to UE.The HS-PDSCH that NODEB will distribute to UE in the n+d+d1 subframe sends to UE.Here, d1=1 represents the timing difference between the subframe that subframe that HS-SCCH sends and HS-PDSCH send.

Step 105-4:UE will receive the HS-DSCH data block that NODEB sends by HS-PDSCH in (n+d+d1) subframe.If UE is correct to this data block decoding, UE will generate affirmation (ACK) information; Otherwise, will generate non-affirmation (NACK) information.UE also will generate channel quality indication (CQI) information of HS-PDSCH according to the signal to noise ratio (snr) of HS-PDSCH.

Step 105-5:UE sends to NODEB at the HS-SICH of (n+d+d1+d2) subframe by distributing to it with the CQI information of the HS-PDSCH of up-to-date generation and the ACK information of HS-DSCH data block (to HS-DSCH data block correct decoding time) or nack message (when the HS-DSCH data block error is deciphered).Here, d2=2 represents the timing difference between the subframe that subframe that HS-PDSCH sends and HS-SICH send.

Step 105-6:NODEB receives the HS-SICH that distributes to UE in (n+d+d1+d2) subframe.When NODEB when HS-SICH detects ACK information, NODEB will no longer retransmit this data block.When NODEB detects nack message, if the retransmitted number of times of this data block does not reach maximum number of retransmissions, then NODEB will retransmit this data block; Otherwise NODEB will no longer retransmit this data block.

When the scheduler of NODEB is dispatched continuously to a UE, will use same HS-SCCH.Such as: NODEB dispatches the 1st UE continuously in n subframe and n+1 subframe, it is the 1st HS-SCCH in the HS-SCCH set of UE that NODEB gives the HS-SCCH of the 1st UE in the n sub-frame allocation, then NODEB is when the n+1 subframe is dispatched this UE once more, and it must be the 1st HS-SCCH that NODEB distributes the HS-SCCH of this UE.

For UE, UE distributes to monitoring each HS-SCCH in its HS-SCCH set in first subframe.When UE listens to 1 HS-SCCH that distributes to it when (this HS-SCCH is called a HS-SCCH) in previous subframe, UE will only monitor a HS-SCCH in current subframe.When UE when previous subframe does not listen to the HS-SCCH that distributes to it, UE will monitor each HS-SCCH in the HS-SCCH set of distributing to it in current subframe.Above-mentioned UE shows the snoop procedure of HS-SCCH set: in the prior art, UE does not support NODEB in same subframe a plurality of HS-SCCH to be distributed to described UE.

In the transmission and receiving course of above-mentioned HS-SCCH, HS-PDSCH and HS-SICH, also there is following process of carrying out synchronously:

1, HS-SCCH and HS-SICH constitute descending power control (DLPC) loop of HS-SCCH:

The signal to noise ratio (snr) of the HS-SCCH that distributes to it that the UE basis receives and the SNR desired value of HS-SCCH generate the DLPC order of HS-SCCH; Distribute to the DLPC order that transmitting power control (TPC) territory on the HS-SICH of UE is used to carry the HS-SCCH of the up-to-date generation of UE; NODEB receives the HS-SICH that UE sends, and extracts the DLPC order that HS-SICH goes up the HS-SCCH of TPC territory carrying, adjusts the transmitting power of the HS-SCCH that distributes to UE according to this DLPC order.

2, HS-SCCH and HS-SICH constitute uplink power control (ULPC) loop of HS-SICH:

NODEB will generate the ULPC order of HS-SICH according to the SNR desired value of the SNR of HS-SICH and HS-SICH when receiving the HS-SICH of UE; Distribute to the ULPC order of HS-SICH that TPC territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and sends to its HS-SCCH, extracts the ULPC order that HS-SCCH goes up the HS-SICH of TPC territory carrying, adjusts the transmitting power of the HS-SICH that distributes to it according to this ULPC order.

3, HS-SCCH and HS-SICH constitute uplink synchronous control (ULSC) loop of HS-SICH:

NODEB will be according to the channel estimating of HS-SICH when receiving the HS-SICH that UE sends, or according to the channel estimating of HS-SICH with in the channel estimating of other up channels of same subframe UE, generates the ULSC order of UE; Distribute to the ULSC order that simultaneous bias (SS) territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and distributes to its HS-SCCH, extracts the ULSC order that HS-SCCH goes up the UE of SS territory carrying, adjusts the Timing Advance (TA) of the HS-SICH of UE according to this ULSC order.Perhaps, UE goes up SS territory carrying on other down channels of UE in the ULSC order of UE of SS territory carrying and the same subframe to HS-SCCH ULSC order merges, and UE is according to the TA of each up channel of the ULSC order adjustment UE that merges.

4, the down beam shaping of HS-SCCH (DLBF):

NODEB will be according to the channel estimating of the HS-SICH of the UE that receives or/and the channel estimating of other up channels of UE generates the DLBF weight vector of UE.The HS-SCCH that distributes to UE will adopt the DLBF weight vector of the up-to-date generation of NODEB UE to carry out down beam shaping.

In the HSDPA system, adopt the Typical Disposition of 2:4 or 3:3 usually.Under the Typical Disposition of 2:4, the HS-PDSCH resource pool that RNC distributes to NODEB takies 4.5 time slots usually.Under the Typical Disposition of 3:3, the HS-PDSCH resource pool that RNC distributes to NODEB takies 3.5 time slots usually.Under the HS-PDSCH of the above-mentioned employing rectangle resource pool method of salary distribution, when UE is scheduled, the HS-PDSCH resource of distributing to UE takies 4 time slots (during the 2:4 configuration) or 3 time slots (during the 3:3 configuration) at most, the resource of 4.5 time slots (during the 2:4 configuration) in the resource pool or 3.5 time slots (during the 3:3 configuration) all can not be distributed to UE.Like this, have at least the HS-PDSCH resource pool of 0.5 time slot not to be fully utilized.The descending peak rate of UE is merely able to reach the 1.5Mbps that 2Mbps that 4 time slots (during the 2:4 configuration) institute can support or 3 time slots institute can support, can not reach 4.5 time slots (when 2:4 disposes) the 2.2Mbps that can support or 3.5 time slots (when 3:3 disposes) the 1.75Mbps that can support.

Summary of the invention

The invention provides HS-PDSCH resource allocation methods and system among a kind of HSDPA, can give UE the HS-PDSCH resource allocation of non-rectangle.

HS-PDSCH resource allocation methods among a kind of HSDPA that the embodiment of the invention proposes comprises the steps:

The HS-PDSCH resource pool that A, RNC will distribute to the carrier wave of NODEB is divided into 2 rectangle HS-PDSCH child resource ponds, and notifies described NODEB with these two shared time slots in rectangle HS-PDSCH child resource pond;

When B, described UE are linked into described carrier wave under the described NodeB, the time slot notice UE that RNC is shared with two rectangle HS-PDSCH child resource ponds of described carrier wave;

C, when described UE is scheduled, described NODEB selects the first rectangle resource from the first rectangle HS-PDSCH child resource pond, select the second rectangle resource from the second rectangle HS-PDSCH child resource pond;

D, described NODEB determine HS-SCCH form with described UE state matches according to UE present located state, in this HS-SCCH form, carry the gap information and the channel code information of the described first rectangle resource and the second rectangle resource, and send the HS-SCCH of described HS-SCCH form to UE.

Preferably, before the described steps A, further comprise:

RNC receives first Indication message that UE reports, and described first Indication message is used to show that this UE has the ability of supporting non-rectangle HS-PDSCH resource allocation; RNC receives second Indication message that base station NODEB reports, and described second Indication message is used to show that this NODEB has the ability of supporting non-rectangle HS-PDSCH resource allocation;

RNC gives two HS-PDSCH child resource ponds of described carrier wave configuration of described NODEB, and when described UE was configured in described carrier wave under the described NODEB, RNC was transmitted to described NODEB with first Indication message that described UE reports.

Preferably, the described and HS-SCCH form UE state matches is HS-SCCH form 1, HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4, HS-SCCH form 6, HS-SCCH form 7 or HS-SCCH form 8.

Preferably, described gap information and channel code information of carrying the described first rectangle resource and the second rectangle resource in this HS-SCCH form comprises:

To distribute to the gap information notice UE of two rectangle HS-PDSCH resource occupation of UE by the gap information territory of 5 bits in this HS-SCCH form;

The channel code information notice UE of the first rectangle resource of UE will be distributed to 4 bits in the channel code collection territory of N bit in this HS-SCCH form, the channel code information notice UE of the second rectangle resource of UE will be distributed to a channel code collection territory other N-4 bit.

Preferably, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the described first rectangle resource.

Preferably, when N=8, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the second rectangle resource; When N=6, the minimum particle size of resource allocation is the channel code of 1 SF=4 in the second rectangle resource.

To distribute to the gap information notice UE of two rectangle HS-PDSCH resource occupation of UE by the gap information territory of 5 bits among this HS-SCCH;

Many yards information fields are renamed in the channel code collection territory of 8 bits in this HS-SCCH form, and many yards information fields are decomposed into two parts, first is the channel code collection territory of 6 bits, and second portion is the nodes domains of 2 bits; Distribute to the channel code collection domain representation of 6 bits of described first UE the first rectangle resource initial channel code and finish channel code, represent initial channel code with 3 bits wherein, represent to finish channel code with other 3 bits; Distribute to the node number of the shared channel code of the second rectangle resource of UE with the nodes domains indication of 2 bits of described second portion.

Many yards information fields are renamed in the channel code collection territory of 8 bits in this HS-SCCH form, and many yards information fields are resolved into the channel code collection territory of 5 bits and the nodes domains of 3 bits; The channel code collection territory of 5 bits is used for notifying described UE with the channel code information of distributing to the first rectangle resource of UE; The nodes domains of 3 bits is used for the described UE of node information notification that the second rectangle resource of distributing to UE is shared;

The partition size of the first rectangle HS-PDSCH resource is defined as the channel code of 1 SF=8, and the sign indicating number of channel code number is 1～8;

The channel code of 8 SF=8 is divided into two groups: first group comprises channel code 1～4, and second group comprises channel code 5～8; 4 channel code in first group are numbered: 0～3, channel code sign indicating number number is numbered i-1 for the channel code of i; 4 channel code in second group are numbered: 0～3, channel code sign indicating number number is numbered i-5 for the channel code of i;

The numbering of representing the initial channel code of the first rectangle resource with two bits in the channel code collection territory of 5 bits; The numbering of representing the end channel code of the first rectangle resource with two other bit; Represent initial channel code and finish channel code to lay respectively at first group and second group with a value of another bit, represent initial channel code and finish channel code all to be positioned at first group with another value of this bit;

The node number of representing to distribute to the shared channel code of the second rectangle resource of UE with the nodes domains of 3 bits; The node number scope that the nodes domains of 3 bits is represented is 0～7, with 0～6 node of representing to distribute to the second rectangle resource of UE respectively in this scope, the partition size of the second rectangle resource is the channel code of the channel code of 1 SF=1,1 SF=2 and the channel code of 1 SF=4, represents in the channel code collection territory of 5 bits initial channel code with node number 7 and finish channel code to be located in second group.

Preferably, after the described step D, further comprise:

The signal to noise ratio snr of the HS-SCCH that distributes to it that the UE basis receives and the SNR desired value of HS-SCCH generate the descending power control DLPC order of HS-SCCH; Distribute to the DLPC order that transmitting power control TPC territory on the HS-SICH of UE is used to carry the HS-SCCH of the up-to-date generation of UE; NODEB receives the HS-SICH that UE sends, and extracts the DLPC order that HS-SICH goes up the HS-SCCH of TPC territory carrying, adjusts the transmitting power of the HS-SCCH that distributes to UE according to this DLPC order;

The channel estimating of the HS-SICH of the UE that the NODEB basis receives is or/and the channel estimating of other up channels of UE generates the down beam shaping DLBF weight vector of UE; The DLBF weight vector that the HS-SCCH that distributes to UE will adopt the up-to-date generation of NODEB UE carries out down beam shaping to the HS-SCCH of UE;

Preferably, after the described step D, further comprise:

NODEB will generate the uplink power control TPC order of HS-SICH according to the SNR desired value of the signal to noise ratio snr of HS-SICH and HS-SICH when receiving the HS-SICH of UE; Distribute to the ULPC order of HS-SICH that TPC territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and sends to its HS-SCCH, extracts the ULPC order that HS-SCCH goes up the HS-SICH of TPC territory carrying, adjusts the transmitting power of the HS-SICH that distributes to it according to this ULPC order;

NODEB will be according to the channel estimating of HS-SICH when receiving the HS-SICH that UE sends, or according to the channel estimating of other up channels of the channel estimating of HS-SICH and UE, generates the uplink synchronous control ULSC order of UE; Distribute to the ULSC order that simultaneous bias SS territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and distributes to its HS-SCCH, extracts the ULSC order that HS-SCCH goes up the UE of SS territory carrying, adjusts the Timing Advance TA of the HS-SICH of UE according to this ULSC order; Or UE goes up SS territory carrying on other down channels of UE in the ULSC order of UE of SS territory carrying and the same subframe to HS-SCCH ULSC order merges, and UE is according to the TA of each down channel of the ULSC order adjustment UE that merges.

The embodiment of the invention also proposes the HS-PDSCH resource allocation methods among the another kind of HSDPA, comprises the steps:

UE detects each HS-SCCH in the HS-SCCH set of distributing to it in current subframe, if detect a HS-SCCH who distributes to it, determine HS-SCCH form with described state matches according to the present located state, resolve this HS-SCCH that is detected according to the definition in each territory in this HS-SCCH form and go up the loaded information bit, obtain the information that network side is distributed to its HS-PDSCH configuration information of resource and is used for the decoding of HS-DSCH data block;

UE will distribute to its HS-SICH with the HS-SICH conduct of detected HS-SCCH pairing.

Preferably, described UE detects in current subframe and distributes to its HS-SCCH and comprise:

UE each HS-SCCH in the HS-SCCH set that first subframe monitoring network side distributes; And

If UE listens to the HS-SCCH that distributes to it in the N subframe, then monitor described HS-SCCH, and do not monitor other HS-SCCH in the described HS-SCCH set in the N+1 subframe; If UE do not hear the HS-SCCH that distributes to it in the N subframe, then monitor each HS-SCCH in the described HS-SCCH set in the N+1 subframe.

The embodiment of the invention proposes the HS-PDSCH resource allocation system among a kind of HSDPA, comprises RNC and NODEB, it is characterized in that,

RNC comprises:

Resource pool is divided module, and the HS-PDSCH resource pool that is used for distributing to the carrier wave of described NODEB is divided into 2 rectangle HS-PDSCH child resource ponds; And

Notification module is used for notifying described NODEB with two shared time slots in rectangle HS-PDSCH child resource pond that described resource pool division Module Division obtains; And when described UE is linked into described carrier wave under the described NodeB, the time slot notice UE that two rectangle HS-PDSCH child resource ponds of described carrier wave are shared;

Described NODEB comprises:

Select module, be used for when described UE is scheduled, from the first rectangle HS-PDSCH child resource pond, select the first rectangle resource, from the second rectangle HS-PDSCH child resource pond, select the second rectangle resource; And

The HS-SCCH module, be used for HS-SCCH form definite according to UE present located state and described UE state matches, in this HS-SCCH form, carry gap information and the channel code information of selecting the selected first rectangle resource of module and the second rectangle resource, and send the HS-SCCH of described HS-SCCH form to UE.

Preferably, RNC further comprises:

Receiver module is used to receive first Indication message that UE reports, and described first Indication message is used to show that described UE has the ability of supporting non-rectangle HS-PDSCH resource allocation; And receiving second Indication message that NODEB reports, described second Indication message is used to show that described NODEB has the ability of supporting non-rectangle HS-PDSCH resource allocation;

Forwarding module is used for giving as RNC two HS-PDSCH child resource ponds of carrier wave configuration of described NODEB, and when described UE was configured in carrier wave under the described NODEB, first Indication message that described UE is reported was transmitted to described NODEB.

Preferably, described HS-SCCH module comprises:

First information dispensing unit is used for carrying in the gap information territory of HS-SCCH form 5 bits the gap information of two rectangle HS-PDSCH resource occupation distributing to UE;

The second information configuration unit, be used for the channel code information that 4 bits in the channel code collection territory of HS-SCCH form N bit carry the first rectangle resource of distributing to described UE, carry the channel code information of the second rectangle resource of distributing to described UE at a channel code collection territory other N-4 bit.

Preferably, described HS-SCCH module comprises:

The 3rd information configuration unit is used for many yards information fields are renamed in the channel code collection territory of HS-SCCH form 8 bits, and many yards information fields is decomposed into two parts, and first is the channel code collection territory of 6 bits, and second portion is the nodes domains of 2 bits; Carry the initial channel code of the first rectangle resource of distributing to UE and finish channel code with the channel code collection territory of 6 bits of described first, represent initial channel code, represent to finish channel code with other 3 bits with 3 bits wherein; Carry the node number of the shared channel code of the second rectangle resource of distributing to UE with the nodes domains of 2 bits of described second portion.

Preferably, described HS-SCCH module comprises:

The 4th information configuration unit is used for many yards information fields are renamed in the channel code collection territory of HS-SCCH form 8 bits, and many yards information fields is resolved into the channel code collection territory of 5 bits and the nodes domains of 3 bits; The channel code collection territory of 5 bits is used for notifying described UE with the channel code information of distributing to the first rectangle resource of UE; The nodes domains of 3 bits is used for the described UE of node information notification that the second rectangle resource of distributing to UE is shared;

The partition size of the first rectangle HS-PDSCH resource is defined as the channel code of 1 SF=8, and the sign indicating number of channel code number is 1～8; The channel code of 8 SF=8 is divided into two groups: first group comprises channel code 1～4, and second group comprises channel code 5～8; 4 channel code in first group are numbered: 0～3, channel code sign indicating number number is numbered i-1 for the channel code of i; 4 channel code in second group are numbered: 0～3, channel code sign indicating number number is numbered i-5 for the channel code of i;

Preferably, the HS-SCCH form of described and described UE state matches is HS-SCCH form 1, HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4, HS-SCCH form 6, HS-SCCH form 7 or HS-SCCH form 8;

The embodiment of the invention also proposes the HS-PDSCH resource allocation device among a kind of HSDPA, and this device is arranged in UE, comprising:

Detection module is used for detecting in current subframe each HS-SCCH of the HS-SCCH set of distributing to this device place UE, as if detecting a HS-SCCH who distributes to this device place UE, then enables HS-SCCH format module and parsing module;

The HS-SCCH format module is used for HS-SCCH form definite according to this device place UE present located state and described state matches;

Parsing module, be used for coming the detected HS-SCCH of resolved detection module to go up the loaded information bit, obtain the information that network side is distributed to the HS-PDSCH configuration information of resource of described UE and is used for the decoding of HS-DSCH data block according to the definition in definite each territory of HS-SCCH form of HS-SCCH format module; And

The HS-SICH module, be used for with the HS-SICH of the detected HS-SCCH of detection module pairing as the HS-SICH that distributes to this device place UE.

Preferably, described detection module is used for monitoring each HS-SCCH that network side is distributed to the HS-SCCH set of described UE in first subframe; And, then monitor described HS-SCCH in the N+1 subframe if listen to the HS-SCCH that distributes to this device place UE in the N subframe, and do not monitor other HS-SCCH in the described HS-SCCH set; If do not hear the HS-SCCH that distributes to described UE, then monitor each HS-SCCH in the described HS-SCCH set in the N+1 subframe in the N subframe.

As can be seen from the above technical solutions, the HS-PDSCH resource pool that RNC will distribute to the carrier wave of NODEB is divided into 2 rectangle HS-PDSCH child resource ponds, gap information and channel code information with two rectangle resources in a HS-SCCH pass to UE, have so just realized giving UE with the HS-PDSCH resource allocation of non-rectangle.

Description of drawings

Fig. 1 is a HS-PDSCH resource allocation schematic flow sheet of the prior art;

Fig. 2 is notified to the method flow diagram of UE by HS-SCCH for the non-rectangle HS-PDSCH resource that will distribute to UE.

Embodiment

In view of the HS-PDSCH resource distribution mode of rectangle has greatly limited the descending peak rate of UE, the present invention proposes: be the descending peak rate that improves UE, and the HS-PDSCH resource that can distribute non-rectangle to UE.Such as: under 2:4 configuration, the resource of 4.5 time slots of HS-PDSCH resource pool all can be distributed to UE, under the 3:3 configuration, 3.5 time slots of HS-PDSCH resource pool all can be distributed to UE.

For realizing distributing the HS-PDSCH resource of non-rectangle, need to distribute to the non-rectangle HS-PDSCH resource notification UE of UE to UE.The present invention's proposition will be distributed to the method for the non-rectangle resource notification UE of UE, and this method comprises following content:

1, the non-rectangle HS-PDSCH resource that will distribute to UE is notified to the method for UE by HS-SCCH;

2, UE distributes to the method for its non-rectangle HS-PDSCH resource by the HS-SCCH acquisition;

3, be used to distribute DLPC method and the DLBF method of the HS-SCCH of non-rectangle HS-PDSCH resource;

4, ULPC method and the ULSC method of the HS-SICH of the ACK/NACK information of feedback non-rectangle HS-PDSCH resource and CQI information.

Below by specific embodiment above-mentioned every method is set forth respectively respectively.

The method that the non-rectangle HS-PDSCH resource that will distribute to UE that the embodiment of the invention one proposes is notified to UE by HS-SCCH comprises the steps: as shown in Figure 2

The HS-PDSCH resource pool that step 201:RNC will distribute to the carrier wave of NODEB is divided into 2 rectangle HS-PDSCH child resource ponds, and notifies described NODEB with these two shared time slots in rectangle HS-PDSCH child resource pond;

Step 202: when described UE is linked into described carrier wave under the described NodeB, the time slot notice UE that RNC is shared with two rectangle HS-PDSCH child resource ponds of described carrier wave;

Step 203: when described UE was scheduled, described NODEB selected the first rectangle resource from the first rectangle HS-PDSCH child resource pond, selected the second rectangle resource from the second rectangle HS-PDSCH child resource pond;

Step 204: described NODEB determines HS-SCCH form with described UE state matches according to UE present located state, in this HS-SCCH form, carry the gap information and the channel code information of the described first rectangle resource and the second rectangle resource, and send the HS-SCCH of described HS-SCCH form to UE.

For making the distribution method backward compatibility of non-rectangle HS-PDSCH resource of the present invention, for the UE that supports non-rectangle HS-PDSCH resource allocation, UE need report first Indication message to give RNC, and described first Indication message is used to show that this UE has the ability of supporting non-rectangle HS-PDSCH resource allocation.For the NODEB that supports non-rectangle HS-PDSCH resource allocation, NODEB need report second Indication message to give RNC, and described second Indication message is used to show that this NODEB has the ability of supporting non-rectangle HS-PDSCH resource allocation.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, HS-PDSCH resource pool on any one carrier wave that RNC could support this NODEB is divided into two sub-resource pools and disposes to NODEB, simultaneously, RNC need be transmitted to the ability of the support non-rectangle HS-PDSCH resource allocation of UE the NODEB that supports non-rectangle HS-PDSCH resource allocation.RNC also needs to dispose two sub-resource pools on this UE place carrier wave to the UE that supports non-rectangle HS-PDSCH resource allocation.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, NODEB need give based on two sub-resource pools of each carrier wave and support the UE of non-rectangle HS-PDSCH resource allocation to distribute the non-rectangle resource on this carrier wave.

For supporting configuration more flexibly, RNC can select two the sub-resource pools of each carrier wave configuration to the NODEB that supports non-rectangle HS-PDSCH resource allocation, also can select all to dispose a resource pool to each carrier wave of the NODEB that supports non-rectangle HS-PDSCH resource allocation.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, when RNC gave two sub-resource pools of each carrier wave configuration of this NODEB, RNC need be transmitted to NODEB with the support " ability of non-rectangle HS-PDSCH resource allocation " of UE; RNC also needs to dispose two sub-resource pools on this UE place carrier wave to the UE that supports non-rectangle HS-PDSCH resource allocation.

When RNC gave two sub-resource pools of each carrier wave configuration of the NODEB that supports non-rectangle HS-PDSCH resource allocation, this NODEB need be based on the UE distribution non-rectangle resource of two sub-resource pools on each carrier wave to the support non-rectangle HS-PDSCH resource allocation on the corresponding carriers.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, when RNC gave 1 resource pool of each carrier wave configuration of this NODEB, the support " ability of non-rectangle HS-PDSCH resource allocation " that RNC will UE was transmitted to NODEB.This NODEB will distribute a rectangle resource for each UE that is positioned on this carrier wave based on 1 resource pool on each carrier wave.This NODEB distributes non-rectangle HS-PDSCH resource can not for any UE.

Further, RNC can also select to support the HS-PDSCH resource pool on any one carrier wave of NODEB of non-rectangle HS-PDSCH resource allocation to be divided into two sub-resource pools to dispose to NODEB, also can select not decompose the HS-PDSCH resource pool on this carrier wave of this NODEB, a resource pool is disposed to NODEB.

When RNC gave two sub-resource pools of this carrier wave configuration of this NODEB, the ability that RNC need will be positioned at the support non-rectangle HS-PDSCH resource allocation of the UE on this carrier wave was transmitted to NODEB.Simultaneously, RNC disposes this two sub-resource pools need for the UE of each the support non-rectangle HS-PDSCH resource allocation that is positioned on this carrier wave of this NODEB.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, when RNC had disposed two HS-PDSCH child resource ponds for its carrier wave, NODEB need distribute the non-rectangle resource for the UE of the support non-rectangle HS-PDSCH resource allocation that is positioned at this carrier wave based on these two sub-resource pools.

For the NODEB that supports non-rectangle HS-PDSCH resource allocation, when RNC has disposed a resource pool for its carrier wave, RNC will this carrier wave on the support " ability of non-rectangle HS-PDSCH resource allocation " of UE be transmitted to NODEB.For any UE that is positioned on this carrier wave, NODEB distributes the rectangle resource can only for this UE, distributes the non-rectangle resource can not for this UE.

In above-mentioned process of carrying out resource pool configuration for carrier wave, can be configured to different situations as required for different carrier waves, for example for the part carrier wave disposes a resource pool, then the UE on these carrier waves can not be assigned with the non-rectangle resource; For two sub-resource pools of other portion of carriers configuration, then on these carrier waves, can distribute the non-rectangle resource for UE.

A kind of HS-SCCH that supports non-rectangle HS-PDSCH resource allocation of the embodiment of the invention one definition, below this HS-SCCH is called many yards HS-SCCH, many yards HS-SCCH support many yards information fields of configuration, to support to distribute to UE by a HS-SCCH HS-PDSCH resource of non-rectangle.

When UE has the ability of supporting non-rectangle HS-PDSCH resource,, when NODEB scheduling UE, just distribute to the HS-PDSCH resource of UE by defined many yards HS-SCCH notice UE for the NODEB that supports non-rectangle HS-PDSCH resource allocation.

Generally, the HS-PDSCH resource pool that disposes to NODEB of RNC takies several complete time slots and one or more non-complete time slots.Therefore, in any subframe, the HS-PDSCH resource pool can be divided into 2 rectangle HS-PDSCH resources on the HSDPA carrier wave: first rectangle HS-PDSCH resource is made of several complete time slots, and second rectangle resource is made of one or more non-complete time slots.For the UE that supports non-rectangle HS-PDSCH resource allocation, when UE is scheduled, distributes to the non-rectangle HS-PDSCH resource of UE and be made up of two rectangle resources: first rectangle resource is made of the part resource in first rectangle resource in the above-mentioned HS-PDSCH resource pool or whole resource; Second rectangle resource by the part resource in second rectangle resource in the above-mentioned HS-PDSCH resource pool or all resource constitute.For the HS-SCCH that supports non-rectangle HS-PDSCH resource allocation is many yards HS-SCCH of the present invention, only needs above-mentioned shared gap information and the node information notification UE of each rectangle resource that distributes to UE.All channel code are unified numbering, be numbered 0～31, under this numbering, channel code is called node.One-to-one relationship between the number of node and the number of channel code sees also the 3GPP agreement.

For going up the least possible information bit above-mentioned two shared gap informations of rectangle resource are notified to UE by HS-SCCH, on a HSDPA carrier wave of the sub-district that the NODEB that supports non-rectangle HS-PDSCH resource allocation supports, when RNC gives this carrier wave configuration non-rectangle HS-PDSCH resource pool, the child resource pond that this non-rectangle HS-PDSCH resource pool is resolved into two rectangles.The shared time slot in child resource pond of these 2 rectangles differs from one another.For the UE that supports non-rectangle HS-PDSCH resource allocation, when reshuffling when giving the UE collocation wireless link when UE inserts this sub-district or to the Radio Link of UE, RNC is with the timeslot number notice UE of each the rectangle HS-PDSCH resource occupation in 2 rectangle child resource ponds of decomposing on this UE place carrier wave.

For making the compatible as much as possible existing HS-SCCH form of the HS-SCCH that supports non-rectangle HS-PDSCH resource, the HS-SCCH of the support non-rectangle HS-PDSCH resource allocation that the present invention proposes directly utilizes each territory that has now in the HS-SCCH form, to several territories wherein making different definition.

The HS-SCCH form has 9 kinds.When adopting MIMO technology and SF=1, just can adopt HS-SCCH form 5.Therefore, 5 supports of HS-SCCH form resource of distributing several whole time slots to UE.Therefore, can't under this HS-SCCH form, support non-rectangle HS-PDSCH resource allocation.When adopting the MIMO technology and adopt double fluid to send, just can adopt HS-SCCH form 9.The partition size of HS-PDSCH resource is very big under this form, therefore, there is no need to support non-rectangle HS-PDSCH resource allocation under this form.

All comprise the gap information territory of 5 bits and the channel code collection territory of N bit in other every kind of HS-SCCH form.N=8 in the HS-SCCH form that has, N=6 among the HS-SCCH that has.Such as: N=8 in HS-SCCH form 1, HS-SCCH form 6 and the HS-SCCH form 7; N=6 in HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4 and the HS-SCCH form 8.These HS-SCCH forms all need to support the distribution of non-rectangle HS-PDSCH resource.

In each HS-SCCH form of above-mentioned support non-rectangle HS-PDSCH resource allocation, every kind of HS-SCCH form also comprises other each territories.Such as: existing HS-SCCH Format Type 1 comprises following each territory:

The channel code collection territory of (1) 8 bit

The gap information territory of (2) 5 bits

The HS-DSCH data block length territory of (3) 6 bits

The mixed automatic retransmission request mark of (4) 3 bits (HARQ ID) territory

The redundancy versions of (5) 3 bits (RV) information field

The new data indication territory of (6) 1 bits

The HS-SCCH cyclic sequence territory of (7) 3 bits

Particularly, each territory of comprising of other each HS-SCCH forms sees also 3GPP agreement TS 25.222.

NODEB preserves UE state and the HS-SCCH form mapping table that sets in advance, in this mapping table, and the corresponding a kind of HS-SCCH form of each concrete UE state.When NODEB according to the described mapping table of UE status poll of living in, when determining that the HS-SCCH form is HS-SCCH form 1, HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4, HS-SCCH form 6, HS-SCCH form 7 and HS-SCCH form 8, can distribute non-rectangle HS-PDSCH resource to UE.Be two rectangle HS-PDSCH resources will distributing to UE shared time slot and node notice UE, the present invention proposes to support that the HS-SCCH of non-rectangle HS-PDSCH resource allocation realizes by following three kinds of methods:

Method one:

To distribute to the gap information notice UE of two rectangle HS-PDSCH resource occupation of UE by the gap information territory of 5 bits in above-mentioned each HS-SCCH form.

The channel code collection territory of N bit in above-mentioned each HS-SCCH form is become many yards information fields.The node information notification UE of first rectangle of UE will be distributed to 4 bits wherein, the node information notification UE of second rectangle of UE will be distributed to an other N-4 bit.For first rectangle, the minimum particle size of resource allocation is the channel code of 1 SF=8 in this rectangle; For second rectangle, when N=8, the minimum particle size of resource allocation also is the channel code of 1 SF=8 in this rectangle, and when N=6, the minimum particle size of resource allocation is the channel code of 1 SF=4 in this rectangle.Mapping relations between node and the channel code number are with the mapping relations of node and channel code among the HSUPA in the 3GPP standard.

Method two: when N=8, can also adopt following method to distribute non-rectangle HS-PDSCH resource to UE.

To distribute to the gap information notice UE of two rectangle HS-PDSCH resource occupation of UE by the gap information territory of 5 bits among above-mentioned each HS-SCCH.

Many yards information fields are renamed in the channel code collection territory of 8 bits among the above-mentioned HS-SCCH, and many yards information fields are decomposed into two parts, first is the channel code collection territory of 6 bits, and second portion is the nodes domains of 2 bits.Distribute to the channel code collection domain representation of 6 bits of described first UE first rectangle initial channel code and finish channel code; Distribute to the node of second rectangle of UE with the nodes domains indication of 2 bits of described second portion.For second rectangle, the minimum particle size of resource allocation is the channel code of 1 SF=4 in this rectangle.But generally, the partition size of this rectangle is the channel code of 1 SF=2.

Method three: when N=8, can adopt following method.

The gap information notice UE of two rectangle HS-PDSCH resource occupation of UE will be distributed in the gap information territory of 5 bits by above-mentioned HS-SCCH.

Many yards information fields are renamed in the channel code collection territory of 8 bits among the above-mentioned HS-SCCH, and many yards information fields are resolved into the channel code collection territory of 5 bits and the nodes domains of 3 bits.The channel code collection territory of 5 bits is used for notifying described UE with the channel code information of distributing to the first rectangle resource of UE; The nodes domains of 3 bits is used for the described UE of node information notification that the second rectangle resource of distributing to UE is shared;

The partition size of the first rectangle HS-PDSCH resource is defined as the channel code of 1 SF=8, and the sign indicating number of channel code number is 1～8.

The channel code of 8 SF=8 is divided into two groups: first group comprises channel code 1～4, and second group comprises channel code 5～8.4 channel code in first group are numbered: 0～3, channel code sign indicating number number is numbered i-1 for the channel code of i.4 channel code in second group are numbered: 0～3, channel code sign indicating number number is numbered i-5 for the channel code of i.

The numbering of initial channel code of representing to distribute to the first rectangle resource of UE with two bits in the channel code collection territory of 5 bits; The numbering of end channel code of representing to distribute to the first rectangle resource of UE with two other bit; Represent initial channel code and finish channel code to lay respectively at first group and second group with a value of another bit, represent initial channel code and finish channel code all to be positioned at first group with another value of this bit.

The node number of representing to distribute to second rectangle of UE with the nodes domains of 3 bits.The node number scope that the nodes domains of 3 bits is represented is 0～7.With 0～6 node of representing to distribute to second rectangle of UE respectively in this scope.The partition size of second rectangle is the channel code of the channel code of 1 SF=1,1 SF=2 and the channel code of 1 SF=4.Represent in the channel code collection territory of 5 bits initial channel code with node number 7 and finish channel code to be located in second group.

In sum, it is as follows to distribute to the method for non-rectangle HS-PDSCH resource of UE by the HS-SCCH notice UE that supports non-rectangle HS-PDSCH resource allocation:

(1) UE of support non-rectangle HS-PDSCH resource allocation reports RNC: the ability of supporting non-rectangle HS-PDSCH resource allocation when inserting.

(2) NODEB of support non-rectangle HS-PDSCH resource allocation reports RNC: the ability of supporting non-rectangle HS-PDSCH resource allocation.

(3) for the UE that supports non-rectangle HS-PDSCH resource allocation, when RNC was configured in this UE sub-district under the NODEB that supports the non-rectangle resource allocation, RNC was transmitted to NODEB with the ability of the non-rectangle HS-PDSCH resource allocation that this UE reports.

(4) for each carrier wave in the sub-district under the NODEB that supports the non-rectangle resource allocation, RNC is divided into two sub-resource pools with HS-PDSCH resource pool on this carrier wave, and these two shared time slots of sub-resource pool are notified to NODEB.

(5) when the UE that supports non-rectangle HS-PDSCH resource allocation is linked into sub-district under the NodeB that supports non-rectangle HS-PDSCH resource allocation, RNC when giving the Radio Link of UE collocation wireless link or reprovision UE, notice UE: the timeslot number of shared each time slot in each HS-PDSCH child resource pond in two HS-PDSCH child resource ponds on the carrier wave at this UE place.

(6) when the UE that supports non-rectangle HS-PDSCH resource allocation is scheduled, NODEB determines HS-SCCH form with UE state matches of living in according to the residing state of UE, and NODEB is by the gap information territory in this HS-SCCH form and the many yards information fields HS-PDSCH resource notification UE with non-rectangle then.Can the make an appointment constructive method of many yards information fields of NODEB and UE is a kind of method in above-mentioned three kinds of methods.Also can from the constructive method of above-mentioned three kinds of many yards information fields, select a kind of method, the method for selecting is notified to NODEB and UE by RNC.

(7) for the UE that supports non-rectangle HS-PDSCH resource allocation, when UE detects the HS-SCCH that distributes to it, UE determines to send to the form that its HS-SCCH adopts according to residing state, UE according to the definition resolved detection in each territory in this HS-SCCH form to HS-SCCH on information bit.Particularly, UE determines to distribute to the shared time slot of its two rectangle resources according to the gap information territory in this HS-SCCH form; UE determines to distribute to its shared channel code resource of two rectangle resources according to many yards information fields in this HS-SCCH form.

When the HS-SCCH that adopt to support non-rectangle HS-PDSCH resource allocation realized distributing non-rectangle HS-PDSCH resource to UE, this was supported the HS-SCCH of non-rectangle HS-PDSCH resource allocation and constitutes the DLPC loop of HS-SCCH with the HS-SICH of this HS-SCCH pairing.This circuit functionality is as follows:

The SNR (signal to noise ratio) of the HS-SCCH that distributes to it that the UE basis receives and the SNR desired value of HS-SCCH generate DLPC (descending power control) order of HS-SCCH; Distribute to the DLPC order that TPC (transmitting power control) territory on the HS-SICH of UE is used to carry the HS-SCCH of the up-to-date generation of UE; NODEB receives the HS-SICH that UE sends, and extracts the DLPC order that HS-SICH goes up the HS-SCCH of TPC territory carrying, adjusts the transmitting power of the HS-SCCH that distributes to UE according to this DLPC order.

The DLBF of this HS-SCCH (down beam shaping) process is as follows:

NODEB will be according to the channel estimating of the HS-SICH of the UE that receives or/and the channel estimating of other down channels of UE generates the DLBF weight vector of UE.The DLBF weight vector that the HS-SCCH that distributes to UE will adopt the up-to-date generation of NODEB UE carries out down beam shaping to the HS-SCCH of UE.

The embodiment of the invention two proposes a kind of UE distributes to its non-rectangle HS-PDSCH resource by the HS-SCCH acquisition method.

When adopting method notice described in the embodiment one (method of the HS-SCCH of non-rectangle HS-PDSCH resource allocation is supported in definition) to distribute under the situation of HS-PDSCH resource of non-rectangle of UE, the method for HS-PDSCH resource that UE obtains to distribute to it is as follows:

UE need monitor each HS-SCCH in the HS-SCCH set of distributing to it in first subframe.When UE when previous subframe does not listen to the HS-SCCH that distributes to it, UE need monitor each HS-SCCH in the HS-SCCH set in current subframe.When UE when previous subframe listens to the HS-SCCH that distributes to it, UE need monitor previous sub-frame allocation in current subframe and give its HS-SCCH, does not need to monitor other HS-SCCH.

If UE is when current subframe detects a HS-SCCH and distributes to it, UE will determine the form that HS-SCCH adopts according to state of living in, and resolve this HS-SCCH according to the definition in each territory in this HS-SCCH form and go up the loaded information bit, obtain the information that NODEB distributes to its HS-PDSCH configuration information of resource and is used for the decoding of HS-DSCH data block.Simultaneously, UE will distribute to its HS-SICH with the HS-SICH conduct of detected HS-SCCH pairing.Wherein, during according to this each territory of HS-SCCH format analysis, the parsing of many yards information fields in this HS-SCCH form resolved according to the method for making an appointment or dispose to the method for UE according to RNC resolve.

When adopting the HS-SCCH that supports non-rectangle HS-PDSCH resource distribution to realize non-rectangle HS-PDSCH resource allocation, ULPC and the ULSC of HS-SICH are as follows:

(1) HS-SCCH and HS-SICH constitute the ULPC loop of HS-SICH: NODEB when receiving the HS-SICH of UE, and the ULPC (descending power control) that will generate HS-SICH according to the SNR desired value of the SNR of HS-SICH and HS-SICH orders; Distribute to the ULPC order of HS-SICH that TPC territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and sends to its HS-SCCH, extracts the ULPC order that HS-SCCH goes up the HS-SICH of TPC territory carrying, adjusts the transmitting power of the HS-SICH that distributes to it according to this ULPC order.

(2) HS-SCCH and HS-SICH constitute the ULSC loop of HS-SICH: NODEB when receiving the HS-SICH of UE transmission, will be according to the channel estimating of HS-SICH, or according to the channel estimating of other up channels of the channel estimating of HS-SICH and UE, the ULSC (down-going synchronous control) that generates UE orders; Distribute to the ULSC order that SS (simultaneous bias) territory on the HS-SCCH of UE is used to carry the UE of the up-to-date generation of NODEB; UE receives NODEB and distributes to its HS-SCCH, extracts the ULSC order that HS-SCCH goes up the UE of SS territory carrying, adjusts the TA (Timing Advance) of the HS-SICH of UE according to this ULSC order.Or UE goes up SS territory carrying on other down channels of UE in the ULSC order of UE of SS territory carrying and the same subframe to HS-SCCH ULSC order merges, and UE is according to the TA of each down channel of the ULSC order adjustment UE that merges.

The above only is preferred embodiment of the present invention, and is in order to restriction the present invention, within the spirit and principles in the present invention not all, any modification of being made, is equal to replacement, improvement etc., all should be included within the scope of protection of the invention.

Claims

1. a high-speed downstream bag inserts the high-speed physical downlink shared channel (HS-PDSCH) HS-PDSCH resource allocation methods among the HSDPA, it is characterized in that, comprises the steps:

2. method according to claim 1 is characterized in that, before the described steps A, further comprises:

3. method according to claim 1, it is characterized in that the described and HS-SCCH form UE state matches is HS-SCCH form 1, HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4, HS-SCCH form 6, HS-SCCH form 7 or HS-SCCH form 8.

4. method according to claim 1 is characterized in that, described gap information and channel code information of carrying the described first rectangle resource and the second rectangle resource in this HS-SCCH form comprises:

5. method according to claim 4 is characterized in that, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the described first rectangle resource.

6. method according to claim 4 is characterized in that, when N=8, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the second rectangle resource; When N=6, the minimum particle size of resource allocation is the channel code of 1 SF=4 in the second rectangle resource.

7. method according to claim 1 is characterized in that, described gap information and channel code information of carrying the described first rectangle resource and the second rectangle resource in this HS-SCCH form comprises:

8. method according to claim 3 is characterized in that, described gap information and channel code information of carrying the described first rectangle resource and the second rectangle resource in this HS-SCCH form comprises:

9. according to each described method of claim 1 to 8, it is characterized in that, after the described step D, further comprise:

10. according to each described method of claim 1 to 8, it is characterized in that, after the described step D, further comprise:

11. a high-speed downstream bag inserts the high-speed physical downlink shared channel (HS-PDSCH) HS-PDSCH resource allocation methods among the HSDPA, it is characterized in that, comprises the steps:

12. method according to claim 11 is characterized in that, described UE detects in current subframe and distributes to its HS-SCCH and comprise:

13. a high-speed downstream bag inserts the high-speed physical downlink shared channel (HS-PDSCH) HS-PDSCH resource allocation system among the HSDPA, comprises RNC and NODEB, it is characterized in that,

RNC comprises:

Described NODEB comprises:

14. system according to claim 13 is characterized in that, RNC further comprises:

15. system according to claim 13 is characterized in that, described HS-SCCH module comprises:

16. system according to claim 15 is characterized in that, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the described first rectangle resource.

17. system according to claim 15 is characterized in that, when N=8, the minimum particle size of resource allocation is the channel code of 1 SF=8 in the second rectangle resource; When N=6, the minimum particle size of resource allocation is the channel code of 1 SF=4 in the second rectangle resource.

18. system according to claim 13 is characterized in that, described HS-SCCH module comprises:

19. system according to claim 13 is characterized in that, described HS-SCCH module comprises:

20. method according to claim 3, it is characterized in that the HS-SCCH form of described and described UE state matches is HS-SCCH form 1, HS-SCCH form 2, HS-SCCH form 3, HS-SCCH format 4, HS-SCCH form 6, HS-SCCH form 7 or HS-SCCH form 8;

21. a high-speed downstream bag inserts the high-speed physical downlink shared channel (HS-PDSCH) HS-PDSCH resource allocation device among the HSDPA, it is characterized in that this device is arranged in UE, comprising:

22. device according to claim 21 is characterized in that, described detection module is used for monitoring each HS-SCCH that network side is distributed to the HS-SCCH set of described UE in first subframe; And, then monitor described HS-SCCH in the N+1 subframe if listen to the HS-SCCH that distributes to this device place UE in the N subframe, and do not monitor other HS-SCCH in the described HS-SCCH set; If do not hear the HS-SCCH that distributes to described UE, then monitor each HS-SCCH in the described HS-SCCH set in the N+1 subframe in the N subframe.