CN107277918A - A kind of resource allocation methods and equipment - Google Patents

Abstract

The invention discloses a kind of resource allocation methods and equipment, methods described includes：Master base station P eNB receive physical uplink control channel (PUCCH) resource request；The PUCCH resource request is responded, first object PUCCH resource is chosen from the N number of available PUCCH resource being pre-configured with, the first object PUCCH resource is used for the corresponding uplink feedback of first downstream data of prothetic group station S eNB sides, and N is positive integer；The first object PUCCH resource manipulative indexing is sent to S eNB.

Description

A kind of resource allocation methods and equipment

Technical field

The present invention relates to the information processing technology, more particularly to a kind of resource allocation methods and equipment.

Background technology

To provide higher data rate, advanced long-term evolution system (Long Term to mobile subscriber Evolution Advance, abbreviation LTE-A) propose carrier aggregation technology (Carrier Aggregation, letter Claim CA), the purpose is to provide bigger broadband for the UE with respective capabilities, improve UE peak rate. Carrier aggregation is to polymerize the component carrier (Component Carrier, abbreviation CC) of two or more Come, the LTE-A UE with carrier aggregation capacity, can simultaneously on multiple component carriers transceiving data. The component carrier that UE is initially accessed is principal component carrier wave (Primary Component Carrier, PCC), base Stand also can be referred to as auxiliary component carrier by configuration change UE principal component carrier wave, other component carriers (Secondary Component Carrier, SCC), auxiliary component carrier is by base after UE enters connected state Stand what is configured.Serving cell on PCC is referred to as main serving cell (Primary Cell, PCell), in SCC On serving cell be referred to as auxiliary serving cell (Secondary Cell, SCell).Base station is only each UE points With a Radio Network Temporary Identifier (Cell-Radio Network Temporary Identity, C-RNTI), That is UE is identical in the C-RNTI of each serving cell.

UE is when configuring carrier aggregation, and only PCell can be with transmitting physical uplink control channel (Physical Uplink Control Channel, PUCCH) information.Therefore, it is poly- based on traditional carrier wave Conjunction technology, UE PUCCH transmission exists only in PCell, and does not have PUCCH transmission on S-eNB, The uplink feedback of UE downlink data is sent in S-eNB sides to be resolved.

The content of the invention

In view of this, the embodiment of the present invention provides a kind of resource point to solve problems of the prior art Method of completing the square and equipment.

What the technical scheme of the embodiment of the present invention was realized in：

The embodiment of the present invention provides a kind of resource allocation methods, and methods described is applied to master base station P-eNB, institute The method of stating includes：

Receive the request of physical uplink control channel PUCCH resource；

The PUCCH resource request is responded, is chosen from the N number of available PUCCH resource being pre-configured with First object PUCCH resource, the first object PUCCH resource is used for the of prothetic group station S-eNB sides The corresponding uplink feedback of one downlink data, N is positive integer；

The first object PUCCH resource manipulative indexing is sent to S-eNB.

In such scheme, methods described also includes：

When sending second downstream data, second is chosen from the N number of available PUCCH resource being pre-configured with Target PUCCH resource, the second target PUCCH resource is used for the described second descending of P-eNB sides The corresponding uplink feedback of data；

The second target PUCCH resource manipulative indexing and the second downstream data are sent to UE.

In such scheme, methods described also includes：

Receive the first downstream data sent in the first object PUCCH resource up accordingly Feedback；

The uplink feedback is sent to S-eNB.

In such scheme, methods described also includes：

The PUCCH resource provided by S-eNB is provided and configures auxiliary information；

Auxiliary information is configured according to the PUCCH resource and determines the pre- of N number of available PUCCH resource First configure.

The embodiment of the present invention also provides a kind of resource allocation methods, and methods described is applied to prothetic group station S-eNB, Methods described includes：

When sending first downstream data, the request of physical uplink control channel PUCCH resource is sent；

First object PUCCH resource manipulative indexing is received, the first object PUCCH resource is response During the PUCCH resource request, choose what is obtained from the N number of available PUCCH resource being pre-configured with PUCCH resource, N is positive integer；

The first object PUCCH resource manipulative indexing and the first downstream data are sent to UE.

The embodiment of the present invention provides a kind of resource allocation methods again, and methods described is applied to user equipment (UE), institute The method of stating includes：

Receive first object physical uplink control channel PUCCH resource manipulative indexing and first time line number According to；

It is corresponding with the first object PUCCH resource according to the N number of available PUCCH resource being pre-configured with Index, determines the first object PUCCH resource；

The corresponding uplink feedback of the first downstream data is sent in the first object PUCCH resource extremely Master base station P-eNB.

In such scheme, methods described also includes：

Receive the second target PUCCH resource manipulative indexing and second downstream data；

According to the N number of available PUCCH resource and the second target PUCCH resource being pre-configured with Manipulative indexing, determines the second target PUCCH resource；

The corresponding uplink feedback of the second downstream data is sent in the second target PUCCH resource extremely P-eNB。

The embodiment of the present invention also provides a kind of resource allocation methods, and methods described is applied to master base station P-eNB, Methods described includes：

Measurement gap is determined, data interaction is not present on the time point indicated by the measurement gap；

The measurement gap is sent to user equipment (UE) and S-eNB.

In such scheme, methods described also includes：Measurement gap configuration auxiliary information is received, between the measurement Gap configures auxiliary information and provided by prothetic group station S-eNB；

Auxiliary information is configured according to the measurement gap and determines the measurement gap.

The embodiment of the present invention also provides a kind of P-eNB, the P-eNB includes receiving module, choose module and Sending module；

The receiving module, for receiving the request of physical uplink control channel PUCCH resource；

The selection module, it is N number of available from what is be pre-configured with for responding the PUCCH resource request First object PUCCH resource is chosen in PUCCH resource, the first object PUCCH resource is used for auxiliary The corresponding uplink feedback of first downstream data of base station S-eNB sides, N is positive integer；

The sending module, for sending the first object PUCCH resource manipulative indexing to S-eNB.

In such scheme, the selection module is additionally operable to when sending second downstream data, from being pre-configured with N number of available PUCCH resource in choose the second target PUCCH resource, the second target PUCCH Resource is used for the corresponding uplink feedback of the second downstream data of P-eNB sides；The sending module, is also used In sending the second target PUCCH resource manipulative indexing and the second downstream data to UE.

In such scheme, the receiving module is additionally operable to receive in the first object PUCCH resource The corresponding uplink feedback of the first downstream data sent；The sending module, is additionally operable to send on described Row feeds back to S-eNB.

In such scheme, the P-eNB also includes configuration module；

The receiving module, is additionally operable to receive the PUCCH resource configuration auxiliary information provided by S-eNB； The configuration module, it is described N number of available for being determined according to PUCCH resource configuration auxiliary information PUCCH resource is pre-configured with.

The embodiment of the present invention provides a kind of S-eNB again, and the S-eNB includes sending module and receiving module；

The sending module, for when sending first downstream data, sending physical uplink control channel PUCCH resource is asked；

The receiving module, for receiving first object PUCCH resource manipulative indexing, the first object When PUCCH resource is asked to respond the PUCCH resource, from the N number of available PUCCH being pre-configured with Obtained PUCCH resource is chosen in resource, N is positive integer；

The sending module, is additionally operable to send the first object PUCCH resource manipulative indexing and described One downlink data is to UE.

The embodiment of the present invention also provides a kind of UE, it is characterised in that the UE includes receiving module, determined Module and sending module；

The receiving module, for receiving first object physical uplink control channel PUCCH resource pair It should index and first downstream data；

The determining module, for according to the N number of available PUCCH resource and first mesh being pre-configured with PUCCH resource manipulative indexing is marked, the first object PUCCH resource is determined；

The sending module, for sending first time line number in the first object PUCCH resource According to corresponding uplink feedback to master base station P-eNB.

In such scheme, the receiving module is additionally operable to receive the second target PUCCH resource manipulative indexing And second downstream data；The determining module, is additionally operable to the N number of available PUCCH being pre-configured with according to Resource and the second target PUCCH resource manipulative indexing, determine the second target PUCCH resource； The sending module, is additionally operable to send the second downstream data in the second target PUCCH resource Corresponding uplink feedback is to P-eNB.

The embodiment of the present invention provides a kind of P-eNB again, and the P-eNB includes determining module and sending module；

The determining module, for determining measurement gap, is not deposited on the time point indicated by the measurement gap In data interaction；

The sending module, for sending the measurement gap to user equipment (UE) and S-eNB.

In such scheme, the P-eNB also includes receiving module；

The receiving module, for receiving measurement gap configuration auxiliary information, the measurement gap configuration auxiliary Information is provided by prothetic group station S-eNB；

The determining module, is additionally operable to determine the measurement gap according to measurement gap configuration auxiliary information.

In the embodiment of the present invention, P-eNB receives the request of physical uplink control channel PUCCH resource； The PUCCH resource request is responded, first is chosen from the N number of available PUCCH resource being pre-configured with Target PUCCH resource, the first object PUCCH resource is used for the first downstream data of S-eNB sides Corresponding uplink feedback, N is positive integer；Send the first object PUCCH resource manipulative indexing extremely S-eNB.It so, it is possible flexibly to realize that PUCCH resource is configured, ensure and support that the carrier aggregation across base station is provided Source dispatch, effectively solve traditional carrier aggregation technology be sent in S-eNB sides UE downlink data it is upper The problem of row feedback can not be resolved, so as to lift Consumer's Experience.

Brief description of the drawings

Fig. 1 is the implementation process schematic diagram of the resource allocation methods of the embodiment of the present invention one；

Fig. 2 is the implementation process schematic diagram of the resource allocation methods of the embodiment of the present invention two；

Fig. 3 is the implementation process schematic diagram of the resource allocation methods of the embodiment of the present invention three；

Fig. 4 implements schematic flow sheet for the present invention application resource allocation methods of example one；

Fig. 5 implements schematic flow sheet for the present invention application resource allocation methods of example three；

Fig. 6 is the implementation process schematic diagram of the resource allocation methods of the embodiment of the present invention four；

Fig. 7 implements schematic flow sheet for the present invention application resource allocation methods of example four；

Fig. 8 is the P-eNB of the embodiment of the present invention five composition structural representation；

Fig. 9 is the S-eNB of the embodiment of the present invention six composition structural representation；

Figure 10 is the UE of the embodiment of the present invention seven composition structural representation；

Figure 11 is the P-eNB of the embodiment of the present invention eight composition structural representation；

Figure 12 is the composition structural representation of the resource allocation system of the embodiment of the present invention nine.

Embodiment

The technical solution of the present invention is further elaborated with specific embodiment below in conjunction with the accompanying drawings.

Embodiment one：

The embodiment of the present invention provides a kind of resource allocation methods, and methods described is applied to P-eNB, such as Fig. 1 institutes Show, methods described includes：

Step 101, reception PUCCH resource request；

Here, in traditional carrier aggregation technology, due to there is no PUCCH transmission on S-eNB, in S-eNB Side is sent to the uplink feedback of UE first downstream data and in the absence of workable PUCCH resource.Institute So that the embodiment of the present invention is when S-eNB is sending first downstream data to UE, and S-eNB can be to P-eNB Initiate PUCCH resource request.

Step 102, the response PUCCH resource request, from the N number of available PUCCH being pre-configured with First object PUCCH resource is chosen in resource, N is positive integer；

Wherein, the first object PUCCH resource is corresponding for the first downstream data of S-eNB sides Row feedback.

Here, N number of available PUCCH resource is provided with the P-eNB in advance, it is described N number of available PUCCH resource includes one or more sets the workable PUCCH time-frequency domain resources of UE being pre-configured with, and One or more sets PUCCH time-frequency domain resources workable for the UE being pre-configured with can also be by other UE It is shared to use.Certainly, can will be described after P-eNB is pre-configured with N number of available PUCCH resource The N number of available PUCCH resource being pre-configured with is sent to UE.

Accordingly, due to being provided with N number of available PUCCH resource in the P-eNB in advance, thus it is described P-eNB can timely respond to the PUCCH resource request after the PUCCH resource request is received, First object PUCCH resource is chosen from the N number of available PUCCH resource being pre-configured with, N is just whole Number, i.e., choose one from one or more sets PUCCH time-frequency domain resources workable for UE configurations in advance Cover the PUCCH time-frequency domain resources for being not used by or not used by other UE.

Step 103, the transmission first object PUCCH resource manipulative indexing to S-eNB.

Specifically, P-eNB sends the first object PUCCH resource manipulative indexing to SeNB, so that The uplink feedback for the first downstream data that the UE can send SeNB sides passes through the first object PUCCH resource is sent to P-eNB.

In one embodiment, methods described also includes：

P-eNB to UE when sending second downstream data, from the N number of available PUCCH moneys being pre-configured with The second target PUCCH resource is chosen in source, the second target PUCCH resource is used for P-eNB sides The corresponding uplink feedback of second downstream data；Send the second target PUCCH resource manipulative indexing With the second downstream data to UE.

Here, the first object PUCCH resource and the second target PUCCH resource can with identical, I.e. same UE is only carried out P-eNB sides, S-eNB sides descending using a set of PUCCH time-frequency domain resources The corresponding uplink feedback of data；Certainly, the first object PUCCH resource and the second target PUCCH Resource can also be different, i.e., same UE is carried out using a set of PUCCH time-frequency domain resources chosen respectively The corresponding uplink feedback of P-eNB sides, S-eNB sides downlink data.

In one embodiment, methods described also includes：P-eNB is received by UE in the first object The corresponding uplink feedback of first downstream data that the SeNB sides sent in PUCCH resource are sent； P-eNB sends the uplink feedback to S-eNB.

In one embodiment, methods described also includes：Reception is matched somebody with somebody by the S-eNB PUCCH resources provided Put auxiliary information；Auxiliary information is configured according to the PUCCH resource and determines N number of available PUCCH Resource is pre-configured with.

Here, the PUCCH resource configuration auxiliary information provided by S-eNB can exist including UE The downlink data of S-eNB sides sends plan, subframe occupancy situation as used etc..

By resource allocation methods described in the embodiment of the present invention, P-eNB receives physical uplink control channel PUCCH resource is asked；The PUCCH resource request is responded, from the N number of available PUCCH being pre-configured with First object PUCCH resource is chosen in resource, the first object PUCCH resource is used for S-eNB sides The corresponding uplink feedback of first downstream data, N is positive integer；Send the first object PUCCH moneys Source manipulative indexing is to S-eNB.It so, it is possible flexibly to realize that PUCCH resource is configured, ensure and support across base The carrier aggregation scheduling of resource stood, effectively solves traditional carrier aggregation technology and is sent to UE in S-eNB sides The uplink feedback of downlink data the problem of can not be resolved, so as to lift Consumer's Experience.

Embodiment two

The embodiment of the present invention provides a kind of resource allocation methods, and methods described is applied to S-eNB, such as Fig. 2 institutes State, methods described includes：

Step 201, send first downstream data when, send PUCCH resource request；

Here, in traditional carrier aggregation technology, due to there is no PUCCH transmission on S-eNB, in S-eNB Side is sent to the uplink feedback of UE first downstream data and in the absence of workable PUCCH resource.Institute So that the embodiment of the present invention is when S-eNB is sending first downstream data to UE, and S-eNB can be to P-eNB Initiate PUCCH resource request.

Step 202, reception first object PUCCH resource manipulative indexing；

Wherein, the first object PUCCH resource is responds during PUCCH resource request, from pre- Obtained PUCCH resource is chosen in the N number of available PUCCH resource first configured.Specifically, P-eNB After the PUCCH resource request is received, the PUCCH resource request is responded, from the N being pre-configured with First object PUCCH resource is chosen in individual available PUCCH resource, N is positive integer, first mesh Marking PUCCH resource is used for the corresponding uplink feedback of first downstream data of S-eNB sides；Further, send out The first object PUCCH resource manipulative indexing is sent to S-eNB, so that S-eNB receives first mesh Mark PUCCH resource manipulative indexing.

Step 203, the transmission first object PUCCH resource manipulative indexing and the first downstream data are extremely UE。

Specifically, S-eNB can be by the first object PUCCH resource manipulative indexing and described first descending Data are sent to UE together；So, UE can be by the first object PUCCH resource by SeNB The uplink feedback for the first downstream data that side is sent is sent to P-eNB.

In one embodiment, methods described also includes：SeNB is received by being directed to that the P-eNB is sent Itself sends the uplink feedback of first downstream data.

By resource allocation methods described in the embodiment of the present invention, it can flexibly realize that PUCCH resource is configured, The carrier aggregation scheduling of resource supported across base station is ensured, traditional carrier aggregation technology is effectively solved in S-eNB The problem of uplink feedback that side is sent to UE downlink data can not be resolved, so as to lift Consumer's Experience.

Embodiment three

The embodiment of the present invention provides a kind of resource allocation methods, and methods described is applied to UE, as described in Figure 3, Methods described includes：

Step 301, reception first object PUCCH resource manipulative indexing and first downstream data；

Here, when S-eNB is needing to send first downstream data to UE, by initiating PUCCH moneys The mode of source request, gets after first object PUCCH resource from P-eNB sides, can be by first mesh Mark PUCCH resource and the first downstream data send jointly to UE.

N number of available PUCCH resource and the first object PUCCH that step 302, basis are pre-configured with Resource manipulative indexing, determines the first object PUCCH resource；

Here, can will be described pre- due to after P-eNB is pre-configured with N number of available PUCCH resource The N number of available PUCCH resource first configured is sent to UE.Therefore when UE receives the first object After PUCCH resource manipulative indexing, can according to the first object PUCCH resource manipulative indexing and in advance N number of available PUCCH resource of configuration determines the first object PUCCH resource.

Step 303, send in the first object PUCCH resource first downstream data it is corresponding on Row feeds back to P-eNB.

In one embodiment, methods described also includes：Receive the second target PUCCH resource manipulative indexing And second downstream data；According to the N number of available PUCCH resource and second target being pre-configured with PUCCH resource manipulative indexing, determines the second target PUCCH resource；In second target The corresponding uplink feedback of the second downstream data is sent in PUCCH resource to P-eNB.

Here, the first object PUCCH resource and the second target PUCCH resource can with identical, I.e. same UE is only carried out P-eNB sides, S-eNB sides descending using a set of PUCCH time-frequency domain resources The corresponding uplink feedback of data；Certainly, the first object PUCCH resource and the second target PUCCH Resource can also be different, i.e., same UE is carried out using a set of PUCCH time-frequency domain resources chosen respectively The corresponding uplink feedback of P-eNB sides, S-eNB sides downlink data.

By resource allocation methods described in the embodiment of the present invention, it can flexibly realize that PUCCH resource is configured, The carrier aggregation scheduling of resource supported across base station is ensured, traditional carrier aggregation technology is effectively solved in S-eNB The problem of uplink feedback that side is sent to UE downlink data can not be resolved, so as to lift Consumer's Experience.

Using example one

The resource allocation methods with reference to described in the embodiment of the present invention one to three, the present invention application resource allocation of example one Method is applied to the information exchange between P-eNB, S-eNB and UE three, as shown in figure 4, of the invention Include using the resource allocation methods of example one：

Step 401, P-eNB are pre-configured with one or more sets PUCCH time-frequency domain resources (institutes workable for UE One or more sets PUCCH time-frequency domain resources workable for stating the UE being pre-configured with can also be total to by other UE Enjoy and using).

Step 402, P-eNB provide one or more sets PUCCH time-frequency domains workable for the UE being pre-configured with Source is sent to corresponding UE.

Step 403, P-eNB plan when subframe x sends downlink data to UE, first in corresponding subframe y Choose from one or more sets PUCCH time-frequency domain resources being pre-configured with for the UE a set of be not used by PUCCH time-frequency domain resources, as the corresponding uplink feedback of P-eNB sides downlink data.

Step 404, S-eNB plan, when subframe x sends downlink data to UE, first to P-eNB to apply In corresponding subframe y PUCCH time-frequency domain resources, as the corresponding uplink feedback of S-eNB sides downlink data.

Step 405, P-eNB are received to be provided from S-eNB in subframe y UE PUCCH time-frequency domains After the application of source, selected in subframe y from one or more sets PUCCH time-frequency domain resources being pre-configured with for UE A set of PUCCH time-frequency domain resources being not used by are taken, it is corresponding in S-eNB sides downlink data as UE Uplink feedback.

It is corresponding in S-eNB sides downlink data that selection is used as UE by step 406, P-eNB in subframe y The index of the PUCCH time-frequency domain resources of uplink feedback is sent to S-eNB.

Step 407, P-eNB will act as PUCCHs of the UE in the corresponding uplink feedback of P-eNB sides downlink data The index of time-frequency domain resources sends jointly to UE with downlink data.

Step 408, S-eNB will act as PUCCHs of the UE in the corresponding uplink feedback of S-eNB sides downlink data The index of time-frequency domain resources sends jointly to UE with downlink data.

Step 409, UE according to one or more sets PUCCH time-frequency domain resources being pre-configured with and respectively from The index for the PUCCH time-frequency domain resources that P-eNB, S-eNB are received, respectively determine for P-eNB sides, The specific PUCCH time-frequency domain resources of the corresponding uplink feedback of downlink data of S-eNB sides.

Step 410, UE it is determined that for P-eNB sides, S-eNB sides downlink data it is up accordingly In the specific PUCCH time-frequency domain resources of feedback, uplink feedback information is sent to P-eNB.

Step 411, P-eNB will be up accordingly for downlink datas of the UE in S-eNB sides on subframe y Feedback information is sent to S-eNB.

Using example two

The resource allocation methods with reference to described in the embodiment of the present invention one to three, the present invention application resource allocation of example two Method is applied to the information exchange between P-eNB, S-eNB and UE three, and present invention application example two is provided Source distribution method includes：

Step 501, P-eNB are pre-configured with one or more sets PUCCH time-frequency domain resources (institutes workable for UE One or more sets PUCCH time-frequency domain resources workable for stating the UE being pre-configured with can also be total to by other UE Enjoy and using).

Step 502, P-eNB provide one or more sets PUCCH time-frequency domains workable for the UE being pre-configured with Source is sent to corresponding UE.

Step 503, P-eNB plan when subframe x sends downlink data to UE, first in corresponding subframe y Choose from one or more sets PUCCH time-frequency domain resources being pre-configured with for the UE a set of be not used by PUCCH time-frequency domain resources n, as the corresponding uplink feedback of P-eNB sides downlink data.

Step 504, S-eNB plan, when subframe x sends downlink data to UE, first to P-eNB to apply The UE corresponding subframe y PUCCH time-frequency domain resources, as S-eNB sides downlink data it is corresponding on Row feedback.

Step 505, P-eNB are received to be provided from S-eNB in subframe y UE PUCCH time-frequency domains After the application of source, it is found that P-eNB have chosen a set of PUCCH time-frequency domain resources for the UE on subframe y N (is used as UE in the corresponding uplink feedback of P-eNB sides downlink data), PUCCH time-frequency domain resources n UE can also be used as in the corresponding uplink feedback of S-eNB sides downlink data.

It is corresponding in S-eNB sides downlink data that selection is used as UE by step 506, P-eNB in subframe y The PUCCH time-frequency domain resources n of uplink feedback index is sent to S-eNB.

Step 507, P-eNB will act as PUCCHs of the UE in the corresponding uplink feedback of P-eNB sides downlink data Time-frequency domain resources n index sends jointly to UE with downlink data.

Step 508, S-eNB will act as PUCCHs of the UE in the corresponding uplink feedback of S-eNB sides downlink data Time-frequency domain resources n index sends jointly to UE with downlink data.

Step 509, UE according to one or more sets PUCCH time-frequency domain resources being pre-configured with and from The index for the PUCCH time-frequency domain resources n that P-eNB, S-eNB are received, it is determined that for P-eNB sides, The specific PUCCH time-frequency domain resources of the corresponding uplink feedback of downlink data of S-eNB sides.

Step 510, UE it is determined that for P-eNB sides, S-eNB sides downlink data it is up accordingly In the specific PUCCH time-frequency domain resources of feedback, uplink feedback information is sent to P-eNB.

Step 511, P-eNB will be up accordingly for downlink datas of the UE in S-eNB sides on subframe y Feedback information is sent to S-eNB.

Using example three

The resource allocation methods with reference to described in the embodiment of the present invention one to three, the present invention application resource allocation of example three Method is applied to the information exchange between P-eNB, S-eNB and UE three, as shown in figure 5, of the invention Include using the resource allocation methods of example three：

UE PUCCH time-frequency domain resources are configured auxiliary information by step 0, S-eNB, and such as UE is in S-eNB The downlink data transmission plan of side is sent to P-eNB.

The PUCCH time-frequency domain resources configuration auxiliary letter for the UE that step 1, P-eNB combinations S-eNB are provided Breath, is pre-configured with UE one or more sets workable PUCCH time-frequency domain resources (described to be pre-configured with One or more sets PUCCH time-frequency domain resources workable for UE can also be shared by other UE to be used).

Step 2~step 11 can be equal to using step 402~step 411 in example one, can also wait It is same as applying step 502~step 511 in example two.

Example IV

The embodiment of the present invention provides a kind of resource allocation methods, and methods described is applied to P-eNB, such as Fig. 6 institutes State, methods described includes：

Step 601, measurement gap is determined, data are not present on the time point indicated by the measurement gap and hand over Mutually；

Wherein, data interaction is not present on the time point indicated by the measurement gap.

Specifically, the P-eNB is it is determined that before measurement gap, measurement gap configuration auxiliary can be received first Information；Afterwards, the measurement gap Measurement is determined further according to measurement gap configuration auxiliary information Gap。

Wherein, the measurement gap configuration auxiliary information is provided by prothetic group station S-eNB.Here, the measurement Gap configuration auxiliary information can include downlink datas of the UE in P-eNB sides and S-eNB sides and send plan etc. Information.

Specifically, downlink datas of the P-eNB according to UE in P-eNB sides and S-eNB sides sends plan etc. Information determines the configuration of UE measurement gap, and the configuration of the measurement gap should avoid P-eNB sides and S-eNB The downlink data of side sends plan.

Step 602, the transmission measurement gap to UE and S-eNB.

Specifically, the measurement gap is sent to UE and S-eNB by P-eNB, so, and S-eNB is in institute State and do not send data to UE on the time point indicated by measurement gap, also do not receive data from UE.

By resource allocation methods described in the embodiment of the present invention, it can effectively realize that measurement gap is configured, ensure The carrier aggregation across base station is supported, Consumer's Experience is improved.

Using example four

The resource allocation methods with reference to described in the embodiment of the present invention four, the present invention application resource allocation methods of example four Applied to the information exchange between P-eNB, S-eNB and UE three, as shown in fig. 7, present invention application The resource allocation methods of example four include：

Step 701, P-eNB determine UE measurement gap Measurement Gap configurations；

Specifically, the downlink data that the P-eNB can be according to UE in P-eNB sides and S-eNB sides is sent The information such as plan determine UE Measurement Gap configurations, and Measurement Gap configurations should be avoided The downlink data of P-eNB sides and S-eNB sides sends plan.

UE Measurement Gap configurations are sent to UE by step 702, P-eNB.

UE Measurement Gap configurations are sent to S-eNB by step 703, P-eNB.

Step 704, S-eNB do not send data on the time point that Measurement Gap are indicated to UE, Also data are not received from UE.

Embodiment five

The embodiment of the present invention provides a kind of P-eNB, as shown in figure 8, the P-eNB include receiving module 801, Choose module 802 and sending module 803；

The receiving module 801, for receiving the request of physical uplink control channel PUCCH resource；

The selection module 802, it is N number of from what is be pre-configured with for responding the PUCCH resource request It can use and first object PUCCH resource is chosen in PUCCH resource, the first object PUCCH resource is used The corresponding uplink feedback of first downstream data in prothetic group station S-eNB sides, N is positive integer；

The sending module 803, for sending the first object PUCCH resource manipulative indexing to S-eNB.

In one embodiment, the selection module 802, is additionally operable to when sending second downstream data, from The second target PUCCH resource, second mesh are chosen in the N number of available PUCCH resource being pre-configured with Marking PUCCH resource is used for the corresponding uplink feedback of the second downstream data of P-eNB sides；It is described to send Module 803, is additionally operable to send the second target PUCCH resource manipulative indexing and the second downstream data To UE.

In one embodiment, the receiving module 801, is additionally operable to receive in the first object PUCCH The corresponding uplink feedback of the first downstream data sent in resource；The sending module 803, is additionally operable to The uplink feedback is sent to S-eNB.

In one embodiment, the P-eNB also includes configuration module 804；

The receiving module 801, is additionally operable to receive the PUCCH resource configuration auxiliary letter provided by S-eNB Breath；

The configuration module 804, the N is determined for configuring auxiliary information according to the PUCCH resource Individual available PUCCH resource is pre-configured with.

The receiving module 801 and sending module 803 in P-eNB described in the embodiment of the present invention can pass through The communication component with transmission-receiving function in the P-eNB is realized；It is described to choose module 802 and match somebody with somebody Putting module 804 can be realized by the processor in P-eNB, can also be realized by specific logic circuit； Such as, in actual applications, can be by the central processing unit (CPU) in the P-eNB, microprocessor Device (MPU), digital signal processor (DSP) or field programmable gate array (FPGA) etc. are realized.

It need to be noted that be：Above P-eNB implements the description of item, is retouched with above method embodiment one It is similar to state, and with the same identical beneficial effect of embodiment of the method one, therefore is not repeated.For this hair The ins and outs not disclosed in bright P-eNB embodiments, it is real that those skilled in the art refer to the inventive method Apply the description of example one and understand, to save length, repeat no more here.

Embodiment six

The embodiment of the present invention provides a kind of S-eNB, as shown in figure 9, the S-eNB includes sending module 901 With receiving module 902；

The sending module 901, for when sending first downstream data, sending the control of physical uplink link Channel PUCCH resource is asked；

The receiving module 902, for receiving first object PUCCH resource manipulative indexing, first mesh PUCCH resource is marked to respond during the PUCCH resource request, it is N number of available from what is be pre-configured with Obtained PUCCH resource is chosen in PUCCH resource, N is positive integer；

The sending module 901, is additionally operable to send the first object PUCCH resource manipulative indexing and described First downstream data is to UE.

The sending module 901 and receiving module 902 in S-eNB described in the embodiment of the present invention can pass through The communication component with transmission-receiving function in the P-eNB is realized.

It need to be noted that be：Above S-eNB implements the description of item, is retouched with above method embodiment two It is similar to state, and with the same identical beneficial effect of embodiment of the method two, therefore is not repeated.For this hair The ins and outs not disclosed in bright S-eNB embodiments, it is real that those skilled in the art refer to the inventive method Apply the description of example two and understand, to save length, repeat no more here.

Embodiment seven

The embodiment of the present invention provides a kind of UE, as shown in Figure 10, the UE include receiving module 1001, Determining module 1002 and sending module 1003；

The receiving module 1001, for receiving first object physical uplink control channel PUCCH moneys Source manipulative indexing and first downstream data；

The determining module 1002, for according to N number of available PUCCH resource for being pre-configured with and described the One target PUCCH resource manipulative indexing, determines the first object PUCCH resource；

The sending module 1003, for being sent in the first object PUCCH resource under described first The corresponding uplink feedback of row data is to master base station P-eNB.

In one embodiment, the receiving module 1001, is additionally operable to receive the second target PUCCH resource Manipulative indexing and second downstream data；The determining module 1002, is additionally operable to the N being pre-configured with according to Individual available PUCCH resource and the second target PUCCH resource manipulative indexing, determine second mesh Mark PUCCH resource；The sending module 1003, is additionally operable in the second target PUCCH resource The corresponding uplink feedback of the second downstream data is sent to P-eNB.

The receiving module 1001 and sending module 1003 in UE described in the embodiment of the present invention can pass through The communication component with transmission-receiving function in the UE is realized；The determining module 1002 can lead to The processor crossed in UE is realized, can also be realized by specific logic circuit；Such as, in practical application In, it can be believed by the central processing unit (CPU) in the UE, microprocessor (MPU), numeral Number processor (DSP) or field programmable gate array (FPGA) etc. are realized.

It need to be noted that be：Above UE implements the description of item, is described with above method embodiment three It is similar, with the same identical beneficial effect of embodiment of the method three, therefore does not repeat.For the present invention The ins and outs not disclosed in UE embodiments, those skilled in the art refer to the inventive method embodiment three Description and understand, for save length, repeat no more here.

Embodiment eight

The embodiment of the present invention provides a kind of P-eNB, as shown in figure 11, and the P-eNB includes determining module 1101 and sending module 1102；

The determining module 1101, for determining measurement gap, on the time point indicated by the measurement gap In the absence of data interaction；

The sending module 1102, for sending the measurement gap to user equipment (UE) and S-eNB.

In one embodiment, as shown in figure 11, the P-eNB also includes receiving module 1103；

The receiving module 1103, for receiving measurement gap configuration auxiliary information, the measurement gap configuration Auxiliary information is provided by prothetic group station S-eNB；

The determining module 1101, is additionally operable to determine the measurement according to measurement gap configuration auxiliary information Gap.

The receiving module 1103 and sending module 1102 in P-eNB described in the embodiment of the present invention can lead to Cross and be located at the communication component with transmission-receiving function in the P-eNB to realize；The determining module 1101 It can be realized, can also be realized by specific logic circuit by the processor in P-eNB；Such as, exist In practical application, can by the central processing unit (CPU) in the P-eNB, microprocessor (MPU), Digital signal processor (DSP) or field programmable gate array (FPGA) etc. are realized.

It need to be noted that be：Above P-eNB implements the description of item, is retouched with above method example IV It is similar to state, and with same method example IV identical beneficial effect, therefore is not repeated.For this hair The ins and outs not disclosed in bright P-eNB embodiments, it is real that those skilled in the art refer to the inventive method Apply the description of example four and understand, to save length, repeat no more here.

Embodiment nine

The embodiment of the present invention provides a kind of resource allocation system, and as shown in figure 12, the system includes P-eNB1201, S-eNB1202 and UE1203；

The P-eNB1201, for receiving the request of physical uplink control channel PUCCH resource；Ring Answer the PUCCH resource to ask, the first mesh is chosen from the N number of available PUCCH resource being pre-configured with PUCCH resource is marked, the first object PUCCH resource is used for the first descending of prothetic group station S-eNB sides The corresponding uplink feedback of data, N is positive integer；Send the first object PUCCH resource manipulative indexing To S-eNB；

S-eNB1202, for when sending first downstream data, sending physical uplink control channel PUCCH resource is asked；Receive first object PUCCH resource manipulative indexing, the first object PUCCH When resource is asked to respond the PUCCH resource, from the N number of available PUCCH resource being pre-configured with Obtained PUCCH resource is chosen, N is positive integer；Send the first object PUCCH resource correspondence Index and the first downstream data to UE；

The UE1203, for receiving first object physical uplink control channel PUCCH resource correspondence Index and first downstream data；According to the N number of available PUCCH resource being pre-configured with and the first object PUCCH resource manipulative indexing, determines the first object PUCCH resource；In the first object The corresponding uplink feedback of the first downstream data is sent in PUCCH resource to master base station P-eNB.

, can in several embodiments provided herein, it should be understood that disclosed apparatus and method To realize by another way.Apparatus embodiments described above are only schematical, for example, institute The division of unit is stated, only a kind of division of logic function there can be other dividing mode when actually realizing, Such as：Multiple units or component can be combined, or be desirably integrated into another system, or some features can be neglected Slightly, or do not perform.In addition, the coupling each other of shown or discussed each part or directly coupling Close or communication connection can be by some interfaces, the INDIRECT COUPLING or communication connection of equipment or unit, can Be it is electrical, machinery or other forms.

The above-mentioned unit illustrated as separating component can be or may not be it is physically separate, as The part that unit is shown can be or may not be physical location；Both a place can be located at, also may be used To be distributed on multiple NEs；Part or all of unit therein can be selected according to the actual needs Realize the purpose of this embodiment scheme.

In addition, each functional unit in various embodiments of the present invention can be fully integrated into a processing unit, Can also be each unit individually as a unit, can also two or more units be integrated in one In individual unit；Above-mentioned integrated unit can both be realized in the form of hardware, it would however also be possible to employ hardware adds soft The form of part functional unit is realized.

One of ordinary skill in the art will appreciate that：Realize that all or part of step of above method embodiment can To be completed by the related hardware of programmed instruction, foregoing program can be stored in embodied on computer readable storage In medium, the program upon execution, performs the step of including above method embodiment；And foregoing storage is situated between Matter includes：Movable storage device, read-only storage (Read-Only Memory, ROM), arbitrary access Memory (Random Access Memory, RAM), magnetic disc or CD etc. are various can be with storage program The medium of code.

Or, if the above-mentioned integrated unit of the present invention is realized using in the form of software function module and as independently Production marketing or in use, can also be stored in a computer read/write memory medium.Based on so Understanding, the part that the technical scheme of the embodiment of the present invention substantially contributes to prior art in other words can To be embodied in the form of software product, the computer software product is stored in a storage medium, bag Some instructions are included to so that a computer equipment (can be personal computer, server or network Equipment etc.) perform all or part of each of the invention embodiment methods described.And foregoing storage medium bag Include：Movable storage device, ROM, RAM, magnetic disc or CD etc. are various can be with Jie of store program codes Matter.

The foregoing is only a specific embodiment of the invention, but protection scope of the present invention is not limited to This, any one skilled in the art the invention discloses technical scope in, can readily occur in Change or replacement, should all be included within the scope of the present invention.Therefore, protection scope of the present invention should It is defined by the scope of the claims.

Claims (18)

1. a kind of resource allocation methods, it is characterised in that methods described is described applied to master base station P-eNB Method includes：

Receive the request of physical uplink control channel PUCCH resource；

The PUCCH resource request is responded, is chosen from the N number of available PUCCH resource being pre-configured with First object PUCCH resource, the first object PUCCH resource is used for the of prothetic group station S-eNB sides The corresponding uplink feedback of one downlink data, N is positive integer；

The first object PUCCH resource manipulative indexing is sent to S-eNB.

2. according to the method described in claim 1, it is characterised in that methods described also includes：

When sending second downstream data, second is chosen from the N number of available PUCCH resource being pre-configured with Target PUCCH resource, the second target PUCCH resource is used for the described second descending of P-eNB sides The corresponding uplink feedback of data；

The second target PUCCH resource manipulative indexing and the second downstream data are sent to UE.

3. according to the method described in claim 1, it is characterised in that methods described also includes：

Receive the first downstream data sent in the first object PUCCH resource up accordingly Feedback；

The uplink feedback is sent to S-eNB.

4. the method according to any one of claims 1 to 3, it is characterised in that methods described also includes：

The PUCCH resource provided by S-eNB is provided and configures auxiliary information；

Auxiliary information is configured according to the PUCCH resource and determines the pre- of N number of available PUCCH resource First configure.

5. a kind of resource allocation methods, it is characterised in that methods described is applied to prothetic group station S-eNB, described Method includes：

When sending first downstream data, the request of physical uplink control channel PUCCH resource is sent；

First object PUCCH resource manipulative indexing is received, the first object PUCCH resource is response During the PUCCH resource request, choose what is obtained from the N number of available PUCCH resource being pre-configured with PUCCH resource, N is positive integer；

The first object PUCCH resource manipulative indexing and the first downstream data are sent to UE.

6. a kind of resource allocation methods, it is characterised in that methods described is applied to user equipment (UE), described Method includes：

Receive first object physical uplink control channel PUCCH resource manipulative indexing and first time line number According to；

It is corresponding with the first object PUCCH resource according to the N number of available PUCCH resource being pre-configured with Index, determines the first object PUCCH resource；

The corresponding uplink feedback of the first downstream data is sent in the first object PUCCH resource extremely Master base station P-eNB.

7. method according to claim 6, it is characterised in that methods described also includes：

Receive the second target PUCCH resource manipulative indexing and second downstream data；

According to the N number of available PUCCH resource and the second target PUCCH resource being pre-configured with Manipulative indexing, determines the second target PUCCH resource；

The corresponding uplink feedback of the second downstream data is sent in the second target PUCCH resource extremely P-eNB。

8. a kind of resource allocation methods, it is characterised in that methods described is described applied to master base station P-eNB Method includes：

Measurement gap is determined, data interaction is not present on the time point indicated by the measurement gap；

The measurement gap is sent to user equipment (UE) and S-eNB.

9. method according to claim 8, it is characterised in that methods described also includes：

Measurement gap configuration auxiliary information is received, the measurement gap configures auxiliary information by prothetic group station S-eNB There is provided；

Auxiliary information is configured according to the measurement gap and determines the measurement gap.

10. a kind of master base station P-eNB, it is characterised in that the P-eNB includes receiving module, chooses mould Block and sending module；

The receiving module, for receiving the request of physical uplink control channel PUCCH resource；

The selection module, it is N number of available from what is be pre-configured with for responding the PUCCH resource request First object PUCCH resource is chosen in PUCCH resource, the first object PUCCH resource is used for auxiliary The corresponding uplink feedback of first downstream data of base station S-eNB sides, N is positive integer；

The sending module, for sending the first object PUCCH resource manipulative indexing to S-eNB.

11. P-eNB according to claim 10, it is characterised in that

The selection module, is additionally operable to when sending second downstream data, N number of available from what is be pre-configured with The second target PUCCH resource is chosen in PUCCH resource, the second target PUCCH resource is used for The corresponding uplink feedback of the second downstream data of P-eNB sides；

The sending module, is additionally operable to send the second target PUCCH resource manipulative indexing and described the Two downlink datas are to UE.

12. P-eNB according to claim 10, it is characterised in that

The receiving module, is additionally operable to receive described the sent in the first object PUCCH resource The corresponding uplink feedback of one downlink data；

The sending module, is additionally operable to send the uplink feedback to S-eNB.

13. the P-eNB according to any one of claim 10 to 12, it is characterised in that the P-eNB Also include configuration module；

The receiving module, is additionally operable to receive the PUCCH resource configuration auxiliary information provided by S-eNB；

The configuration module, for according to the PUCCH resource configure auxiliary information determine it is described it is N number of can With being pre-configured with for PUCCH resource.

14. a kind of prothetic group station S-eNB, it is characterised in that the S-eNB includes sending module and receives mould Block；

The sending module, for when sending first downstream data, sending physical uplink control channel PUCCH resource is asked；

The receiving module, for receiving first object PUCCH resource manipulative indexing, the first object When PUCCH resource is asked to respond the PUCCH resource, from the N number of available PUCCH being pre-configured with Obtained PUCCH resource is chosen in resource, N is positive integer；

The sending module, is additionally operable to send the first object PUCCH resource manipulative indexing and described One downlink data is to UE.

15. a kind of user equipment (UE), it is characterised in that the UE include receiving module, determining module and Sending module；

The receiving module, for receiving first object physical uplink control channel PUCCH resource pair It should index and first downstream data；

The determining module, for according to the N number of available PUCCH resource and first mesh being pre-configured with PUCCH resource manipulative indexing is marked, the first object PUCCH resource is determined；

The sending module, for sending first time line number in the first object PUCCH resource According to corresponding uplink feedback to master base station P-eNB.

16. UE according to claim 15, it is characterised in that

The receiving module, is additionally operable to receive the second target PUCCH resource manipulative indexing and second time line number According to；

The determining module, is additionally operable to according to N number of available PUCCH resource for being pre-configured with and described Second target PUCCH resource manipulative indexing, determines the second target PUCCH resource；

The sending module, is additionally operable to send described second in the second target PUCCH resource descending The corresponding uplink feedback of data is to P-eNB.

17. a kind of master base station P-eNB, it is characterised in that the P-eNB includes determining module and sends mould Block；

The determining module, for determining measurement gap, is not deposited on the time point indicated by the measurement gap In data interaction；

The sending module, for sending the measurement gap to user equipment (UE) and S-eNB.

18. P-eNB according to claim 17, it is characterised in that the P-eNB also includes connecing Receive module；

The receiving module, for receiving measurement gap configuration auxiliary information, the measurement gap configuration auxiliary Information is provided by prothetic group station S-eNB；

The determining module, is additionally operable to determine the measurement gap according to measurement gap configuration auxiliary information.