CN101938856B - Method and system for configuring semi-static scheduling period - Google Patents

Abstract

The invention discloses a method and a system for configuring a semi-static scheduling period. The method comprises the following steps that: (1) both-side terminals establish connection and service signaling with a base station and a core network; (2) the both-side terminals report service coding and decoding capability to the core network; (3) the core network determines a service coding and decoding algorithm of a communication by matching the service coding and decoding capability of the both-side terminals and notifies to the both-side terminals and the base station; and (4) the base station determines the semi-static scheduling period according to the service coding and decoding algorithm of the communication and respectively configures to a media access control terminal and the both-side terminals. The system comprises the both-side terminals, the base station and the core network, wherein the core network notifies the service coding and decoding algorithm determined by the core network to the both-side terminals and the base station, and the base station determines the semi-static scheduling period and configures to relative sides. The invention well solves the problem of matching of the semi-static scheduling period and the service coding and decoding capability, enhances the service quality and the user experience and also saves the wireless resources.

Description

A kind of method and system that dispose semi-static scheduling cycle

Technical field

The invention belongs to the mobile communication technology field, particularly collocation method and the system of the semi-static scheduling cycle in LTE (long term evolution, the Long Term Evolution) mobile communication system.

Background technology

The LTE mobile communication system is referring to Fig. 1, mainly comprise: core net (CN) and Access Network (EvolvedUMTS Terrestrial Radio Access, evolved universal terrestrial radio access network, be called for short E_UTRAN), core net mainly comprises MME (Mobility Management Entity, Mobility Management Entity) and S-GW (Serving-Gateway, gateway), Access Network is by eNB (eNodeB, Node B in the long evolving system claims again the base station) consist of.By the intercommunication of S1 interface inter-link, interconnect by X2 interface between the inner different base station eNB of Access Network between core net and the Access Network.

Scheduling mode in the mobile communication system is divided into dynamically, static state and semi-static.It is many that the dynamic dispatching mode expends system resource, static scheduling mode underaction, can not adapt to professional variation.The semi-persistent scheduling mode combines both advantages, has great advantage in application.

The cycle of using the semi-persistent scheduling mode need to dispose semi-persistent scheduling.At present, the mode that base station eNB adopts database to table look-up more disposes semi-static scheduling cycle, professional and semi-static scheduling cycle employing fixed configurations in the allocation list, and set in advance in base station eNB.But business carries out that code decode algorithm might change in the process, and this will cause the cycle of semi-persistent scheduling and business datum codec not to mate, thereby causes quality of service not high, perhaps wastes system resource.

Summary of the invention

The technical problem to be solved in the present invention is for base station eNB provides a kind of method that disposes semi-static scheduling cycle, adopts the method that semi-static scheduling cycle and business datum coding/decoding capability are mated preferably.For this reason, the present invention also provides a kind of system that disposes semi-static scheduling cycle.

For solving the problems of the technologies described above, the method for the configuration semi-static scheduling cycle that the present invention proposes comprises the steps:

Step 1, both sides' terminal UE (User Equipment) are with base station eNB and core net connects and traffic signaling;

Step 2, both sides' terminal UE report core net with professional coding/decoding capability;

Step 3, core net are determined this communication service code decode algorithm by the professional coding/decoding capability of coupling both sides terminal UE, and it are informed both sides' terminal UE and base station eNB;

Step 4, base station eNB are determined semi-static scheduling cycle according to described this communication service code decode algorithm, and it is disposed respectively to MAC (Medium Access Control, media access control) and both sides' terminal UE.

Above-mentioned both sides' terminal UE comprises calling terminal UEA and terminal called UEB.

In the above-mentioned steps three, core net by and base station eNB between communication interface described this communication service code decode algorithm is sent to base station eNB.Send mode can have multiple, such as, core net is successfully mated the coding/decoding capability of both sides' terminal UE as a trigger event, after this event occured, core net just comprised the message of the code decode algorithm that both sides' terminal UE will use to one of base station eNB transmission; For another example, after terminal called UEB and base station eNB have been connected signaling with core net and have been connected, base station eNB just initiatively sends a query messages to core net, be used for this communication service code decode algorithm that the inquiry core net is determined according to the coding/decoding capability matching result of both sides' terminal UE, core net is exactly to send this communication service code decode algorithm of determining to the response of this message.

In the above-mentioned steps four, base station eNB determines that according to this communication service code decode algorithm the method for semi-static scheduling cycle can be: base station eNB with this communication service code decode algorithm as searching index, in the semi-static scheduling cycle table, search corresponding semi-static scheduling cycle, this semi-static scheduling cycle table is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm, is stored in the base station eNB.

For solving the problems of the technologies described above, the system of the configuration semi-static scheduling cycle that the present invention proposes comprises calling terminal UEA, terminal called UEB, base station eNB and core net.Wherein, calling terminal UEA and terminal called UEB all comprise professional coding/decoding capability reporting module, professional code decode algorithm receiver module and semi-static scheduling cycle receiver module.Described professional coding/decoding capability reporting module is used for the professional coding/decoding capability of this terminal is reported core net, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that core net is sent, and the semi-static scheduling cycle receiver module is used for receiving the semi-static scheduling cycle configuration that base station eNB is carried out this terminal.

Described core net comprises professional coding/decoding capability receiver module, professional code decode algorithm determination module and professional code decode algorithm notification module.Wherein, professional coding/decoding capability receiver module be used for to receive the professional coding/decoding capability of this terminal that calling terminal UEA and terminal called UEB report; Professional code decode algorithm determination module is used for determining this communication service code decode algorithm by the professional coding/decoding capability of matches caller terminal UE A and terminal called UEB; Professional code decode algorithm notification module is used for determined this communication service code decode algorithm is informed to calling terminal UEA, terminal called UEB and base station eNB.

Described base station eNB comprises professional code decode algorithm receiver module, semi-static scheduling cycle determination module and semi-static scheduling cycle configuration module.Wherein, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that core net is sent; The semi-static scheduling cycle determination module is used for determining semi-static scheduling cycle according to described this communication service code decode algorithm; The semi-static scheduling cycle configuration module is used for determined semi-static scheduling cycle is disposed respectively to media access control MAC, calling terminal UEA and terminal called UEB.

Compared with prior art, the present invention passes through such scheme, make semi-static scheduling cycle related with each time communication service code decode algorithm neatly, rather than mechanically bind with type of service, solved better the matching problem of semi-static scheduling cycle and professional coding/decoding capability, experience thereby improved quality of service and user, saved simultaneously Radio Resource, guaranteeing quality of service and saving between the system resource and obtain good balance.

Description of drawings

Fig. 1 is the network architecture diagram of LTE mobile communication system;

Fig. 2 is the method flow diagram that the present invention disposes semi-static scheduling cycle;

Fig. 3 is the system block diagram that the present invention disposes semi-static scheduling cycle.

Embodiment

Reach technological means and the effect that predetermined purpose is taked for further setting forth the present invention, below in conjunction with drawings and Examples, the method and system of the configuration semi-static scheduling cycle that the present invention is proposed are described in detail as follows.

Embodiment 1

Present embodiment is used for speech business.Referring to Fig. 2, the flow process of present embodiment configuration semi-static scheduling cycle is as follows:

The first step: calling terminal UEA and base station eNB are set up RRC (Radio Resource Control, radio resource control) and are connected, and enter the RRC_CONNECTED state;

Second step: calling terminal UEA initiates speech business, and sets up the traffic signaling carrying between the network;

The 3rd step: terminal called UEB receives paging, is connected RRC with base station eNB and connects, and terminal called UEB enters the RRC_CONNECTED state;

The 4th step: terminal called UEB accepts speech business, sets up the traffic signaling carrying between terminal called UEB and the network;

The 5th step: calling terminal UEA and terminal called UEB send to core net with oneself speech coding capacity and tone decoding ability;

The 6th step: after core net is received, the speech coding capacity of calling terminal UEA and the tone decoding ability of terminal called UEB are mated, and the tone decoding ability of calling terminal UEA and the speech coding capacity of terminal called UEB mated, determine the code decode algorithm that this communicating pair uses, do not state so this does not tire out for prior art, and the result is informed calling terminal UEA and terminal called UEB;

The 7th step: the code decode algorithm that the code decode algorithm that core net will be used this communication calling terminal UEA and terminal called UEB will use sends to base station eNB by the communication interface between core net and the base station eNB, be about to core net and successfully mate the coding/decoding capability of both sides' terminal UE as a trigger event, in case the match is successful, core net just sends a message that comprises the code decode algorithm that both sides' terminal UE will use to base station eNB;

The 8th the step: base station eNB with this professional voice coding/decoding algorithms as searching index, in the semi-static scheduling cycle table, search the semi-static scheduling cycle of corresponding up-downgoing channel, semi-static scheduling cycle with the up-downgoing channel disposes to MAC again, wherein, the semi-static scheduling cycle table in the base station eNB is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm; Then initiate the RRC reprovision, the semi-static scheduling cycle of up-downgoing channel is disposed to calling terminal UEA and terminal called UEB;

The 9th step: calling terminal UEA enters with terminal called UEB and communicates by letter, and flow process finishes.

Embodiment 2

Present embodiment is used for game service.Referring to Fig. 2, the flow process of present embodiment configuration semi-static scheduling cycle is as follows:

The first step: calling terminal UEA is connected RRC and connects with base station eNB, enter the RRC_CONNECTED state;

Second step: calling terminal UEA initiates the game request, and sets up the traffic signaling carrying between the network;

The 3rd step: terminal called UEB receives paging, is connected RRC with base station eNB and connects, and terminal called UEB enters the RRC_CONNECTED state;

The 4th step: terminal called UEB accepts the game request, set up the traffic signaling carrying between terminal called UEB and the network, this moment, base station eNB was initiatively sent a query messages to core net, was used for this communication service code decode algorithm that the inquiry core net is determined according to the coding/decoding capability matching result of both sides' terminal UE;

The 5th step: calling terminal UEA and terminal called UEB send to core net with oneself game code capacity and game decoding capability;

The 6th step: after core net is received, the game code capacity of calling terminal UEA and the game decoding capability of terminal called UEB are mated, and the game decoding capability of calling terminal UEA and the game code capacity of terminal called UEB mated, determine the code decode algorithm that this communicating pair uses, and the result is informed calling terminal UEA and terminal called UEB;

The 7th step: the code decode algorithm that the code decode algorithm that core net will be used this communication calling terminal UEA and terminal called UEB will use sends to base station eNB by the mode that sends message, i.e. the query messages sent of core net response base station eNB;

The 8th step: base station eNB is played code decode algorithm as searching index with this business, in the semi-static scheduling cycle table, search the semi-static scheduling cycle of corresponding up-downgoing channel, semi-static scheduling cycle with the up-downgoing channel disposes to MAC again, wherein, the semi-static scheduling cycle table in the base station eNB is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm; Then initiate the RRC reprovision, the semi-static scheduling cycle of up-downgoing channel is disposed to calling terminal UEA and terminal called UEB;

The 9th step: calling terminal UEA enters with terminal called UEB and communicates by letter, and flow process finishes.

Embodiment 3

Present embodiment is used for monitoring business.Referring to Fig. 2, the flow process of present embodiment configuration semi-static scheduling cycle is as follows:

The first step: calling terminal UEA is connected RRC and connects with base station eNB, enter the RRC_CONNECTED state;

Second step: calling terminal UEA initiates the monitoring request, and sets up the traffic signaling carrying between the network;

The 3rd step: terminal called UEB receives paging, is connected RRC with base station eNB and connects, and terminal called UEB enters the RRC_CONNECTED state;

The 4th step: terminal called UEB accepts the monitoring request, sets up the traffic signaling carrying between terminal called UEB and the network;

The 5th step: calling terminal UEA and terminal called UEB send to core net with oneself monitoring code capacity and monitoring decoding capability;

The 6th step: after core net is received, the monitoring code capacity of calling terminal UEA and the monitoring decoding capability of terminal called UEB are mated, and the monitoring decoding capability of calling terminal UEA and the monitoring code capacity of terminal called UEB mated, determine the code decode algorithm that this communicating pair uses, and the result is informed calling terminal UEA and terminal called UEB;

The 7th step: the code decode algorithm that the code decode algorithm that core net will be used this communication calling terminal UEA and terminal called UEB will use sends to base station eNB, sends hairdo and can adopt arbitrary mode or other any feasible modes among aforementioned two embodiment;

The 8th step: base station eNB is determined the semi-static scheduling cycle of up-downgoing channel by the monitoring business code decode algorithm, the method of determining can adopt method or other any feasible methods among aforementioned two embodiment, and the semi-static scheduling cycle with up-downgoing disposes to MAC again; Then initiate the RRC reprovision, semi-static scheduling cycle is disposed to calling terminal UEA and terminal called UEB;

The 9th step: calling terminal UEA enters with terminal called UEB and communicates by letter, and flow process finishes.

Embodiment 4

Referring to Fig. 3, the system of present embodiment configuration semi-static scheduling cycle comprises calling terminal UEA, terminal called UEB, base station eNB and core net.Wherein, calling terminal UEA and terminal called UEB all comprise professional coding/decoding capability reporting module, professional code decode algorithm receiver module and semi-static scheduling cycle receiver module.Described professional coding/decoding capability reporting module is used for the professional coding/decoding capability of this terminal is reported core net, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that core net is sent, and the semi-static scheduling cycle receiver module is used for receiving the semi-static scheduling cycle configuration that base station eNB is carried out this terminal.

Described core net comprises professional coding/decoding capability receiver module, professional code decode algorithm determination module and professional code decode algorithm notification module.Wherein, professional coding/decoding capability receiver module be used for to receive the professional coding/decoding capability of this terminal that calling terminal UEA and terminal called UEB report; Professional code decode algorithm determination module is used for determining this communication service code decode algorithm by the professional coding/decoding capability of matches caller terminal UE A and terminal called UEB; Professional code decode algorithm notification module is used for determined this communication service code decode algorithm is informed to calling terminal UEA, terminal called UEB and base station eNB.

Described base station eNB comprises professional code decode algorithm receiver module, semi-static scheduling cycle determination module and semi-static scheduling cycle configuration module.Wherein, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that core net is sent; The semi-static scheduling cycle determination module is used for determining semi-static scheduling cycle according to described this communication service code decode algorithm; The semi-static scheduling cycle configuration module is used for determined semi-static scheduling cycle is disposed respectively to media access control MAC, calling terminal UEA and terminal called UEB.

Professional code decode algorithm notification module in the above-mentioned core net can be with the coding/decoding capability of core net success matches caller terminal UE A and terminal called UEB as a trigger event, after this event occurs, just send a message that comprises the code decode algorithm that calling terminal UEA and terminal called UEB will use to base station eNB, thereby realization informs determined this communication service code decode algorithm to base station eNB.Perhaps, also can be after terminal called UEB and base station eNB be connected signaling with core net and be connected, initiatively send a query messages to core net by base station eNB, be used for this communication service code decode algorithm that the inquiry core net is determined according to the coding/decoding capability matching result of calling terminal UEA and terminal called UEB, and behind the coding/decoding capability of core net success matches caller terminal UE A and terminal called UEB, professional code decode algorithm notification module in the above-mentioned core net responds described query messages, sends described this communication service code decode algorithm to base station eNB.

Semi-static scheduling cycle determination module in the above-mentioned base station eNB can with described this communication service code decode algorithm for searching index, be searched corresponding semi-static scheduling cycle in the semi-static scheduling cycle table.This semi-static scheduling cycle table is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm, is stored in the base station eNB.

Explanation by above-mentioned embodiment, when can being to reach technological means and the effect that predetermined purpose takes to be able to more deeply and concrete understanding to the present invention, yet embodiment and appended diagram only provide with reference to the usefulness of explanation, the present invention is limited.In fact, the method and system of the configuration semi-static scheduling cycle that the present invention proposes are not only applicable to speech business, game service and monitoring business, also are suitable for adopting the type of service of semi-persistent scheduling mode applicable to other all.And for various types of traffic, various different implementation methods and the system of the configuration semi-static scheduling cycle that the present invention proposes all are suitable for.

Claims (10)

1. method that disposes semi-static scheduling cycle is characterized in that may further comprise the steps:

Step 1, both sides' terminal UE and base station eNB and core net connects and traffic signaling;

Step 2, both sides' terminal UE report core net with professional coding/decoding capability;

Step 3, core net are determined this communication service code decode algorithm by the professional coding/decoding capability of coupling both sides terminal UE, and it are informed both sides' terminal UE and base station eNB;

Step 4, base station eNB are determined semi-static scheduling cycle according to described this communication service code decode algorithm, and it is disposed respectively to media access control MAC and both sides' terminal UE;

Wherein, described both sides' terminal UE comprises calling terminal UEA and terminal called UEB.

2. the method for configuration semi-static scheduling cycle according to claim 1 is characterized in that, core Netcom crosses following mode described this communication service code decode algorithm is informed base station eNB in the described step 3:

Core net is successfully mated the coding/decoding capability of both sides' terminal UE as a trigger event, after this event occured, core net just comprised the message of the code decode algorithm that both sides' terminal UE will use to one of base station eNB transmission.

3. the method for configuration semi-static scheduling cycle according to claim 1 is characterized in that, core Netcom crosses following mode described this communication service code decode algorithm is informed base station eNB in the described step 3:

After terminal called UEB and base station eNB have been connected signaling with core net and have been connected, base station eNB initiatively sends a query messages to core net, be used for this communication service code decode algorithm that the inquiry core net is determined according to the coding/decoding capability matching result of both sides' terminal UE, core net responds this query messages behind the coding/decoding capability that successfully mates both sides' terminal UE, send described this communication service code decode algorithm to base station eNB.

4. according to claim 1 and 2 or the method for 3 described configuration semi-static scheduling cycles, it is characterized in that base station eNB is determined described semi-static scheduling cycle by the following method in the described step 4:

Base station eNB as searching index, is searched corresponding semi-static scheduling cycle with described this communication service code decode algorithm in the semi-static scheduling cycle table; Described semi-static scheduling cycle table is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm, is stored in the base station eNB.

5. the method for configuration semi-static scheduling cycle according to claim 4, it is characterized in that, the professional coding/decoding capability of core net coupling both sides terminal UE comprises in the described step 3: the code capacity of calling terminal UEA and the decoding capability of terminal called UEB are mated, and the decoding capability of calling terminal UEA and the code capacity of terminal called UEB are mated.

6. the method for configuration semi-static scheduling cycle according to claim 4 is characterized in that, described business is speech business or game service or monitoring business.

7. according to claim 1, the method for the described configuration semi-static scheduling cycle of any one in 2,3 and 5, it is characterized in that described business is speech business or game service or monitoring business.

8. system that disposes semi-static scheduling cycle, comprise calling terminal UEA, terminal called UEB, base station eNB and core net, it is characterized in that described calling terminal UEA and terminal called UEB all comprise professional coding/decoding capability reporting module, professional code decode algorithm receiver module and semi-static scheduling cycle receiver module; Wherein, professional coding/decoding capability reporting module is used for the professional coding/decoding capability of this terminal is reported described core net, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that described core net is sent, and the semi-static scheduling cycle receiver module is used for receiving the semi-static scheduling cycle configuration that described base station eNB is carried out this terminal;

Described core net comprises professional coding/decoding capability receiver module, professional code decode algorithm determination module and professional code decode algorithm notification module; Wherein, professional coding/decoding capability receiver module is used for receiving the professional coding/decoding capability of this terminal that calling terminal UEA and terminal called UEB report, professional code decode algorithm determination module is used for determining this communication service code decode algorithm by the professional coding/decoding capability of matches caller terminal UE A and terminal called UEB that professional code decode algorithm notification module is used for determined this communication service code decode algorithm is informed to calling terminal UEA, terminal called UEB and base station eNB;

Described base station eNB comprises professional code decode algorithm receiver module, semi-static scheduling cycle determination module and semi-static scheduling cycle configuration module; Wherein, professional code decode algorithm receiver module is used for receiving this communication service code decode algorithm information that described core net is sent, the semi-static scheduling cycle determination module is used for determining semi-static scheduling cycle according to described this communication service code decode algorithm that the semi-static scheduling cycle configuration module is used for determined semi-static scheduling cycle is disposed respectively to media access control MAC, calling terminal UEA and terminal called UEB.

9. the system of configuration semi-static scheduling cycle according to claim 8, it is characterized in that, professional code decode algorithm notification module in the described core net with the coding/decoding capability of core net success matches caller terminal UE A and terminal called UEB as a trigger event, after this event occurs, just comprise the message of the code decode algorithm that calling terminal UEA and terminal called UEB will use to one of base station eNB transmission;

Semi-static scheduling cycle determination module in the described base station eNB as searching index, is searched corresponding semi-static scheduling cycle with described this communication service code decode algorithm in the semi-static scheduling cycle table; Described semi-static scheduling cycle table is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm, is stored in the base station eNB.

10. the system of configuration semi-static scheduling cycle according to claim 8, it is characterized in that, after terminal called UEB and base station eNB have been connected signaling with core net and have been connected, base station eNB initiatively sends a query messages to core net, is used for this communication service code decode algorithm that the inquiry core net is determined according to the coding/decoding capability matching result of calling terminal UEA and terminal called UEB; Behind the coding/decoding capability of core net success matches caller terminal UE A and terminal called UEB, the professional code decode algorithm notification module in the described core net sends described this communication service code decode algorithm to base station eNB;

Semi-static scheduling cycle determination module in the described base station eNB as searching index, is searched corresponding semi-static scheduling cycle with described this communication service code decode algorithm in the semi-static scheduling cycle table; Described semi-static scheduling cycle table is semi-static scheduling cycle and the corresponding table of terminal code decode algorithm, is stored in the base station eNB.

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