CN101795494B - Method, device and system for data distribution in LET-A system - Google Patents

Abstract

The invention discloses a method for data distribution in a LTE-A system, which comprises that: an RLC layers of network nodes receive a plurality of RLC SDUs transmitted by PDCP layers, wherein the RLC SDUs comprise communication data of at least one communication opposite terminal; and the RLC layers distribute the plurality of received RLC SDUs to carriers according to preset scheduling policies and transmit plurality of distributed RLC SDUs to the communication opposite terminals through protocol layers below the layer. Thus, compared with the LTE system, the LTE-A system has the advantages of avoiding the change of the protocol design and equipment of the protocol layers below the RLC layers of the network nodes and consequently saving research and development cost to a great extent. In addition, the invention also discloses a communication device and the LTE-A system.

Description

The intrasystem data distribution method of a kind of LTE-A, Apparatus and system

Technical field

The present invention relates to the communications field, the intrasystem data distribution method of particularly a kind of LTE-A, Apparatus and system.

Background technology

Along with the development of technology, wireless communication system is to improving the demand sustainable growth of data rate.At third generation partner program (3rd Generation Partnership Project; 3GPP); In order to satisfy growing data-rate requirements; (Long Term Evolution-senior (Long Term Evolution-Advance LTE-A) system need support the bandwidth of maximum 100MHz for Long Term Evolution, LTE) the evolution version of system as Long Term Evolution.At present, to this target, the LTE-A system is under the prerequisite of considering rational UE complexity; Adopt carrier aggregation technology to realize the bandwidth expansion; So-called carrier aggregation technology promptly is that a plurality of existing LTE carrier waves are carried out polymerization, thus use when realizing continuous frequency spectrum with discontinuous spectrum.In the LTE-A system, adopt carrier aggregation technology, can make data transmission simultaneously on a plurality of carrier waves, thereby before sending data, must carry out data distribution to same UE.

Under the prior art, the LTE-A Installed System Memory describes in detail two kinds of data distribution modes below.

Consult shown in Figure 1ly, first kind of data distribution mode is: (Physical Layer PHY) carries out data distribution in physical layer.

What is called is carried out data distribution at the PHY layer, is meant when transfer of data to MAC layer, and the data that belong to same UE are constituted a transmission block (Transport Block based on all carrier waves; TB) (when adopting space multiplexing technique is two TB), then, when transfer of data to PHY layer; With the data that belong to same UE, the Resource Block that adopts identical modulation coding mode to map to distribute to this UE in each carrier wave (Resource Block, RB) on; Wherein, A Resource Block comprises at least one subcarrier, and generally, a Resource Block consists of a plurality of sub-carriers.

Consult shown in Figure 2ly, second kind of data distribution mode is: (Media Access Control MAC) carries out data distribution in medium access control system sublayer.

What is called is carried out data distribution at the MAC layer; Be meant when transfer of data to MAC layer, the data that belong to same UE to be constituted an independent transmission block on each carrier wave, then; When transfer of data to PHY layer; In each carrier wave,, adopt identical modulation coding mode to map on the Resource Block of distributing to this UE in this carrier wave with the data that belong to same UE.In addition, in each carrier wave, the data that belong to different UEs can adopt different modulation coding modes to carry out the resource mapping.

As depicted in figs. 1 and 2, under the prior art, in the LTE-A system; No matter adopt PHY layer data shunting mode, or MAC layer data shunting mode, all need be to (the Radio Link Control of control sub layer of wireless link in the LTE standard; RLC) design of protocol below and equipment realize carrying out modify; For example, when adopting PHY layer data shunting mode, need the maximum of Resource Block be defined again; And when adopting MAC layer data shunting mode, need to revise the capacity of rlc layer metadata cache equipment.Obviously, these operations all can increase equipment development and cost of developing to a certain extent, thereby have brought certain inconvenience for the development in the future of LTE-A system.

Summary of the invention

The embodiment of the invention provides the intrasystem data distribution method of a kind of LTE-A, Apparatus and system, in order to reduce the R&D costs of LTE-A system.

The concrete technical scheme that the embodiment of the invention provides is following:

The intrasystem data distribution method of a kind of LTE-A comprises:

RLC layers of network nodes receives some RLC SDU that the PDCP layer issues, and comprises the communication data of at least one Correspondent Node among the said RLC SDU;

Said rlc layer is assigned on each carrier wave according to some RLC SDU that preset scheduling strategy will receive, and the some RLC SDU adding RLC packet header after will distributing forms some wireless link control protocol data cell RLC PDU, and it is sent into the MAC layer;

The MAC layer according to each carrier wave can data quantity transmitted in the unit interval size, the RLC PDU that is dispensed to each carrier wave is carried out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave;

Some RLC PDU after said MAC layer will distribute add MAC packet header and form some transmission block TB, and through the PHY layer said some TB are mail to Correspondent Node.

The intrasystem communicator of a kind of LTE-A comprises:

The packet scheduling module; Belong to rlc layer, be used to receive some RLC SDU that the PDCP layer issues, and some RLC SDU that will receive according to preset scheduling strategy are assigned on each carrier wave; Wherein, the communication data that comprises at least one Correspondent Node among the said RLC SDU;

The rlc layer functional module belongs to rlc layer, is used for that the some RLC SDU after distributing are added RLC packet header and forms some RLC PDU, and it is sent into the MAC layer; The scheduling of resource module that belongs to the MAC layer can the data quantity transmitted size in the unit interval according to each carrier wave; RLC PDU to being dispensed to each carrier wave carries out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave; Some RLC PDU after MAC layer function module will be distributed add MAC packet header and form some TB, and through the PHY layer said some TB are mail to Correspondent Node.

A kind of LTE-A system comprises a plurality of communicators, and wherein, said communicator comprises:

The packet scheduling module belongs to rlc layer, is used to receive some RLC SDU that the PDCP layer issues,

And some RLC SDU that will receive according to preset scheduling strategy are assigned on each carrier wave, wherein, comprise the communication data of at least one Correspondent Node among the said RLC SDU;

The rlc layer functional module belongs to rlc layer, is used for that the some RLC SDU after distributing are added RLC packet header and forms some RLC PDU, and it is sent into the MAC layer; The scheduling of resource module that belongs to the MAC layer can the data quantity transmitted size in the unit interval according to each carrier wave; RLC PDU to being dispensed to each carrier wave carries out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave; Some RLC PDU after MAC layer function module will be distributed add MAC packet header and form some TB, and through the PHY layer said some TB are mail to Correspondent Node.

In the embodiment of the invention, in the LTE-A system, through set up a packet scheduling module in each RLC layers of network nodes; Realize data distribution based on RLC; Like this, with respect to the LTE system, just need not realize changing to the design of protocol and the equipment of the following protocal layers of rlc layer in each network node; Thereby can farthest reuse existing protocol design of LTE system and equipment and realize that this has saved the R&D costs of LTE-A system to a great extent.

Description of drawings

Fig. 1 is a PHY layer data shunting mode sketch map under the prior art;

Fig. 2 is a MAC layer data shunting mode sketch map under the prior art;

Fig. 3 is communication system architectural framework figure in the embodiment of the invention;

Fig. 4 is base station functions structure chart in the truth example of the present invention;

Fig. 5 is a rlc layer data distribution mode flow chart in the embodiment of the invention;

Fig. 6 is the rlc layer data distribution sketch map that is directed against many UE in the embodiment of the invention;

Fig. 7 for UE in the truth example of the present invention to the downlink data that the receives sketch map that reorders.

Embodiment

In order to save the R&D costs of LTE-A system; In the embodiment of the invention; In the LTE-A system; The control sub layer of wireless link of network node (Radio Link Control, RLC) receiving block data convergence protocol sublayer (Packet Data Convergence Protocol, some Radio Link control service data unit (the Radio Link Control:RLC Service Data Unit that PDCP) issue; RLC SDU), the communication data that comprises at least one Correspondent Node among the said RLC SDU; Said rlc layer is assigned on each carrier wave according to some RLC SDU that preset scheduling strategy will receive, and the some RLC SDU after will distributing mail to said Correspondent Node through the following protocal layers of this layer.

Can find out from foregoing description; The inventive point of the embodiment of the invention comprises: carry out data distribution at rlc layer; Promptly in RLC layers of network nodes will belong to data map to each carrier wave of same Correspondent Node on the corresponding resource blocks; In the present embodiment, be that user terminal (UE) is that example is introduced with Correspondent Node.

Below in conjunction with accompanying drawing the preferred embodiment of the present invention is elaborated.

Consult shown in Figure 3; In the present embodiment, the LTE-A system comprises a plurality of network nodes and a plurality of user terminal, wherein; Network node sends downlink data through intrasystem each carrier wave to each user terminal, and network node can be base station, base station controller or the like network side network element.

Consult shown in Figure 4ly, in the present embodiment, the data link layer in the network node is accepted physical layer (Physical Layer; PHY) service; And to network layer service is provided, data link layer comprise medium insert the sublayer (Media Access Control, MAC), control sub layer of wireless link (RLC) and packet data convergence protocol sublayer (PDCP); Comprise functional module 1, packet scheduling module 10, functional module 2, scheduling of resource module 11 and functional module 3 in the network node, wherein:

Packet scheduling module 10; Belong to rlc layer, be used to receive some RLCSDU that the PDCP layer issues, and some RLC SDU that will receive according to preset scheduling strategy are assigned on each carrier wave; Wherein, the communication data that comprises at least one Correspondent Node among the said RLC SDU;

Functional module 2 belongs to rlc layer, is used for the RLC SDU after distributing is mail to said Correspondent Node through the following protocal layers of this layer.

The concrete effect of other functional modules will be set forth in following examples in detail.

In the present embodiment, be that example is introduced, so, consult shown in Figure 5ly that the detailed process that network node is shunted the downlink data of UE 1 at local rlc layer is following with a user terminal (below be called UE 1):

When the downlink data of step 500:UE1 passed through the PDCP layer, the functional module 1 in the PDCP layer was carried out the compression and the encryption of IP packets headers to it, formed the some RLC SDU that arrive rlc layer.

Step 510: some RLC SDU that functional module 1 will form are sent to the packet scheduling module 10 in the rlc layer.

Step 520: packet scheduling module 10 is assigned on each carrier wave according to some RLC SDU that preset scheduling strategy will receive, and the some RLC SDU that are about to receive are buffered in the interior corresponding formation of each carrier wave.

In the present embodiment, the scheduling strategy that packet scheduling module 10 adopts comprises but is not limited to: Random assignment strategy, poll allocation strategy and load balancing strategy or the like.

On the other hand; If there is the downlink data of a plurality of UE, so, in a carrier wave; The downlink data that all UE can be set is shared a formation; The downlink data that each UE also can be set has different queue, and the downlink data that the different business of each UE use can also be set has different queue, repeats no more at this.

Functional module 2 in the step 530:RLC layer is given the some RLC SDU that are dispensed to each carrier wave; Add RLC packet header and form some wireless link control protocol data cells (Radio Link Control Protocol Data Unit; RLC PDU), and with it send into the MAC layer.

As shown in Figure 4, in the LTE-A system, network node is provided with an independently scheduling of resource module 11 to each carrier wave in the local mac layer, be used for the Resource Block on each carrier wave is distributed; Therefore; Correspondingly, in step 530, (subframe is the minimum time scheduling unit of LTE-A system in each subframe; Usually its duration is set to 1ms); Functional module 2 need be according to the indication of the scheduling of resource module 11 of MAC layer, the number of the RLC SDU that decision is taken out in each carrier wave buffer queue, and it is added the subsequent operation in RLC packet header.

Some RLCPDU on each carrier wave of 11 pairs of receptions of scheduling of resource module in the step 540:MAC layer carry out cascade or/and cut apart, and it is dispensed on the Resource Block corresponding in each carrier wave.

With carrier wave i is example; I ∈ [1; L], in each subframe, some RLC PDU that the functional module 2 on the scheduling of resource module 11 reception carrier i on the carrier wave i transmits; And in corresponding subframe, can the data quantity transmitted size carry out cascade or/and cut apart, and cascade will be passed through or/and some RLC PDU of cutting apart are dispensed in the carrier frequency i on the corresponding resource blocks to above-mentioned some RLC PDU according to carrier wave i; So-called cascade is about to a plurality of RLC PDU and condenses together, and what is called cuts apart soon that a RLC PDU is divided into a plurality of.

Functional module 3 in the step 550:MAC layer give the some RLC PDU that receive add MAC packet header form transmission blocks (Transport Block, TB),

Functional module 3 in the step 560:MAC layer is sent the TB on each carrier wave into the PHY layer and is transmitted, to send to UE1.

Based on the foregoing description, consult shown in Figure 6, if there be a N UE; Be respectively UE 1 ... simultaneously, there be L carrier wave in UE N; Be respectively carrier wave 1 ... carrier wave L, so, network node just can branch to the downlink data of N UE respectively on L the carrier wave through the flow process of above-mentioned steps 500-step 560 record; Make and to pass through L carrier wave, thereby improved the transmission rate of data to a great extent simultaneously to N UE transmitting downlink data.

Can find out from the foregoing description; In the LTE-A system; Only need set up a packet scheduling module 10, promptly can realize the shunting of UE downlink data, and design of protocol of each layer below the rlc layer and equipment are realized need not changing with respect to the LTE system based on rlc layer at rlc layer; Do like this and can farthest reuse existing protocol design of LTE system and equipment realization, saved the R&D costs of LTE-A system to a great extent.

Based on above embodiment; In the LTE-A system, network node can be through based on the automatic repetitive requests (Automatic Retransmission Request:ARQ) of rlc layer with based on mixed automatic repeat request (the Hybrid Automatic Retransmission.Request of MAC layer in the process of transmitting downlink data; HARQ) design; Guarantee to arrive the downlink data of UE1, after being resolved to RLCSDU, can arrive PDCP layer in the UE1 in proper order according to setting by UE1.

Perhaps; The downlink data that belongs to UE 1 that on same carrier wave, transmits can be according to preset sequence arrangement; And the downlink data that belongs to UE 1 that on different carrier, transmits can send according to preset order, to guarantee that the downlink data that UE 1 receives is an order.

For example; As shown in Figure 7; On carrier wave 1; In the downlink data of UE 1 the PDCP sequence number be 6,7,8 RLC SDU according to its sequence number sequence arrangement from small to large, and on carrier wave 2, the PDCP sequence number is that 9,10 and 11 RLC SDU is also according to its sequence number sequence arrangement from small to large in the data of UE 1; To UE 1 time; Network node is earlier 6,7,8 RLC SDU to UE 1 transmission PDCP sequence number through carrier wave 1; Set at interval duration (as; 100 milliseconds) after, sending the PDCP sequence number through carrier wave 2 to UE 1 again is 9,10,11 RLC SDU, is 6,7,8,9,10 thereby make the order of the RLC SDU that UE 1 receives; By that analogy, can guarantee to a certain extent just that by the way UE1 receives RLC SDU according to preset order.

In the practical application, because network environment is complicated, each carrier wave may not necessarily arrive according to the order of setting sometimes, like this, just can make UE 1 receive out of order downlink data, thereby influence its subsequent operation.So; For fear of this situation, further guarantee the quality of the downlink data that UE 1 receives, in the present embodiment; UE1 resequences to the RLC SDU that receives at the PDCP of this locality layer, can guarantee further that so just UE 1 receives RLC SDU according to preset order.

Consult shown in the table 1, in order to realize the rearrangement of data, need the setting section parameter, it thes contents are as follows:

Table 1

Variable/constant name	Meaning
		?Last_Submitted_PDCP_RX_SN	Variable, the lower window edge that reorders, i.e. initial value
?Reordering?Window	Constant, the size of the window that reorders
		?Maximum_PDCP_SN	Constant, the maximum of PDCP sequence number

From above-mentioned table 1, can find out; In the present embodiment, UE 1 uses the window that reorders in the PDCP of this locality layer, the RLC SDU that receives to be reordered, promptly be reserve certain memory space (as; Buffer memory); And set the memory space of this memory space, the window size that promptly reorders (Reordering Window), and the maximum (Maximum_PDCP_SN) of setting reorder ultra initial value of window (Last_Submitted_PDCP_RX_SN) and RLC SDUPDCP sequence number; Then, UE 1 just can be provided with parameter according to these RLC SDU that receives has been reordered.

For example; The window size that reorders is 5, and the window initial value that reorders is 1, and the maximum of the RLCSDUPDCP sequence number that can receive is 5; I.e. explanation; The window that reorders can only hold five RLCSDU at most, and the current PDCP of receiving only sequence number is 1,2,3,4 and 5 RLC SDU, and the RLC SDU that does not meet this condition will be dropped (network node can retransmitted after a while).In the process that receives above-mentioned 5 RLCSDU, these 5 RLC SDU are arranged and preserve according to its PDCP sequence number order from small to large, and after reception finishes, it is mail to the upper strata; Then, the window initial value that reorders becomes 6 by 1, and the maximum of the RLC SDUPDCP sequence number that can receive becomes 10 by 5; The window size that reorders still is 5; So, at this moment, it is 6,7,8,9,10 RLC SDU that the window that reorders just can continue to receive the PDCP sequence number; And it is reordered and uploaded, by that analogy.

Certainly, the numbering of PDCP sequence number has regulation, can not infinitely increase, and the maximum of PDCP sequence number is the twice of length of window of reordering.At present, to 10, the PDCP sequence number of next RLC SDU just needs again from 1 open numbering; In like manner, if the maximum of the RLC SDUPDCP sequence number that can receive greater than 10, then also needs again from 1 open numbering.

For example: the window initial value that reorders is 8; The maximum of the RLC SDUPDCP sequence number that then can receive is 8+5-10=3; The i.e. explanation current PDCP sequence number that can only receive of window that reorders is 8,9,10 RLC SDU; If receive the PDCP sequence number and be 6 RLC SDU, then it is dropped on outside the window that reorders, abandon.It is behind 10 the RLC SDU that window to be reordered is received the PDCP sequence number; Again initial initial value is set to 1, and the maximum of RLC SDUPDCP sequence number is set to 5, like this; The window that reorders just can get into next round RLC SDU and receive; Again be that 1 RLCSDU begins to have received the follow-up RLC SDU that is sent to from the PDCP sequence number, by that analogy, UE 1 just can reorder to the whole RLC SDU that parse according to the setting order; Thereby improved the accuracy of the downlink data that self receives, repeated no more at this.

Obviously, those skilled in the art can carry out various changes and modification to the embodiment among the present invention and not break away from the spirit and scope of the present invention.Like this, belong within the scope of claim of the present invention and equivalent technologies thereof if these in the embodiment of the invention are revised with modification, then the embodiment among the present invention also is intended to comprise these changes and modification interior.

Claims (8)

1. the intrasystem data distribution method of LTE-A is characterized in that, comprising:

Some Radio Links that the control sub layer of wireless link RLC receiving block data convergence protocol sublayer PDCP of network node issues are controlled service data unit RLC SDU, comprise the communication data of at least one Correspondent Node among the said RLC SDU;

Said rlc layer is assigned on each carrier wave according to some RLC SDU that preset scheduling strategy will receive, and the some RLC SDU adding RLC packet header after will distributing forms some wireless link control protocol data cell RLC PDU, and it is sent into the MAC layer;

The MAC layer according to each carrier wave can data quantity transmitted in the unit interval size, the RLC PDU that is dispensed to each carrier wave is carried out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave;

Some RLC PDU after said MAC layer will distribute add MAC packet header and form some transmission block TB, and through the PHY layer said some TB are mail to Correspondent Node.

2. the method for claim 1 is characterized in that, said preset scheduling strategy comprises Random assignment strategy, poll allocation strategy or load balancing strategy.

3. according to claim 1 or claim 2 method is characterized in that, said Correspondent Node is resequenced to said some RLCSDU in the PDCP of this locality layer after receiving some RLC SDU that said network node sends.

4. method as claimed in claim 3 is characterized in that, said Correspondent Node is resequenced to the some RLC SDU that receive in local PDCP layer and comprised:

The PDCP sequence number of some RLC SDU that said PDCP layer will receive and pre-conditioned comparing obtain comparative result;

Said PDCP layer will meet said pre-conditioned RLC SDU according to said comparative result to be preserved, and according to the PDCP sequence number order from small to large of the RLC SDU that preserves it is sorted;

When said PDCP layer confirms that the number of the RLC SDU of preservation reaches setting threshold, it is mail to the above protocal layers of this layer.

5. the intrasystem communicator of LTE-A is characterized in that, comprising:

The packet scheduling module; Belong to rlc layer, be used to receive some RLC SDU that the PDCP layer issues, and some RLC SDU that will receive according to preset scheduling strategy are assigned on each carrier wave; Wherein, the communication data that comprises at least one Correspondent Node among the said RLC SDU;

The rlc layer functional module belongs to rlc layer, is used for that the some RLC SDU after distributing are added RLC packet header and forms some RLC PDU, and it is sent into the MAC layer; The scheduling of resource module that belongs to the MAC layer can the data quantity transmitted size in the unit interval according to each carrier wave; RLC PDU to being dispensed to each carrier wave carries out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave; Some RLC PDU after MAC layer function module will be distributed add MAC packet header and form some TB, and through the PHY layer said some TB are mail to Correspondent Node.

6. a LTE-A system is characterized in that, comprises a plurality of communicators, and wherein, said communicator comprises:

The packet scheduling module belongs to rlc layer, is used to receive some RLC SDU that the PDCP layer issues,

And some RLC SDU that will receive according to preset scheduling strategy are assigned on each carrier wave, wherein, comprise the communication data of at least one Correspondent Node among the said RLC SDU;

The rlc layer functional module belongs to rlc layer, is used for that the some RLC SDU after distributing are added RLC packet header and forms some RLC PDU, and it is sent into the MAC layer; The scheduling of resource module that belongs to the MAC layer can the data quantity transmitted size in the unit interval according to each carrier wave; RLC PDU to being dispensed to each carrier wave carries out cascade or/and cut apart, and will pass through cascade or/and the RLC PDU of cutting apart is dispensed on the Resource Block corresponding in each carrier wave; Some RLC PDU after MAC layer function module will be distributed add MAC packet header and form some TB, and through the PHY layer said some TB are mail to Correspondent Node.

7. system as claimed in claim 6 is characterized in that, also comprises:

Correspondent Node after being used to receive some RLC SDU of said network node transmission, is resequenced to said some RLC SDU in the PDCP of this locality layer.

8. system as claimed in claim 7; It is characterized in that, when said Correspondent Node is resequenced to the some RLC SDU that receive in local PDCP layer, PDCP sequence number and pre-conditioned the comparing of the RLC SDU that receives; Obtain comparative result; Then, will meet said pre-conditioned RLC SDU according to said comparative result and preserve, and it sorted according to the PDCP sequence number order from small to large of the RLC SDU that preserves; And when the number of the RLC SDU that confirms to preserve reaches setting threshold, it is mail to the above protocal layers of this layer.

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