CN102291732B - Processing method, device and system for transmission gap style sequences - Google Patents

Abstract

The invention discloses a processing method, a device and a system for transmission gap style sequences. The method comprises the following steps that: in the process that a node B and a terminal use a first transmission gap style sequence to generate transmission gaps, the node B receives information for indicating a second transmission gap style sequence from a wireless network controller; and the node B and the terminal use the second transmission type style sequence for replacing the first transmission gap style sequence to generate the transmission gaps. The invention ensures the measurement between systems and the measurement between the carrier frequencies of terminal execution based on a compression mode, and in addition, the performance of system equipment and the communication of the terminal are ensured.

Description

The processing method of transmission gap pattern sequence, Apparatus and system

Technical field

The present invention relates to the communications field, in particular to a kind of processing method, Apparatus and system of transmission gap pattern sequence.

Background technology

Along with the continuous evolution of communications wireless network technology, from global mobile system (the Global System Mobile of the second generation, referred to as GSM) system is to Wideband Code Division Multiple Access (WCDMA) (the Wideband Code Division Multiple Access of the third generation, referred to as WCDMA) system, arrive enhancement mode global radio access network (the Enhanced UniversalRadio Access of the third generation again, referred to as E-UTRA) system,, there is multiple types system and the situation of depositing in the network design also inevitable demand according to user of operator.The common radio network functions of current operator is orientated as: the gsm system of the second generation is mainly used in voice-over, the WCDMA system of the third generation is mainly used in carrying packet switch domain service and conversation class, video class business, and the E-UTRA system for the third generation focuses on carrying superfast packet switch domain service.

Therefore, for existing network design, the mobility between the system of the gsm system of the second generation and the WCDMA system of the third generation is very important; Further, in the near future, in the mobile management of the E-UTRA system of the third generation, as being switched to E-UTRA system hot spot region, also will become important.Meanwhile, it is also necessary in the network of multi-carrier frequency networking for switching between the frequency based on load balancing between each layer carrier frequency.

Mobile management between these above-mentioned systems, and load balancing between each layer carrier frequency, the handoff procedure caused, all needs, in prior handoff preparation phase, to measure goal systems and target carrier frequency, accurately to carry out handover decisions.

Compact model plays very important effect in measuring between carrier frequency and between system.When adopting compact model, terminal just can measure the carrier frequency of non-serving and the carrier frequency of other system by not needing configuration double-receiver.When being only configured with the terminal of a receiver, from third generation WCDMA system move to only have second generation gsm system to cover regional time, be merely able to adopt compact model to carry out the measurement between system.Equally, compact model also can be used for the multi-carrier frequency overlay area of terminal turnover third generation WCDMA system.In a compressed mode, terminal can be measured another one non-serving carrier frequency and not be lost in any data that service carrier frequency transmits.

Compact model is defined as a kind of transmission mode, and in this way, transfer of data will be produced a transmission gap in time domain by compressing.The receiver of terminal can utilize this section of transmission gap be tuned to another one carrier frequency is measured.

Transmission gap is described determined by " transmission gap pattern sequence ".Every suit " transmission gap pattern sequence " is uniquely identified by " transmission gap pattern sequence mark ", only can be used in one " transmission gap pattern sequence measures purposes ", each wherein one measured such as namely " Frequency Division Duplexing (FDD) measurement "/" time division duplex measurement "/" GSM carrier received signal intensity instruction (Received SignalStrength Indication) is measured "/" GSM identification of base stations colour coding initial identification "/" identification of GSM identification of base stations colour coding is reaffirmed "/" multi-carrier frequency measurement "/" E-UTRA measurement " measure purposes.

Fig. 1 is the schematic diagram of " transmission gap pattern sequence " according to correlation technique, and wherein, every suit " transmission gap pattern sequence " comprises 2 kinds " transmission gap patterns 1 " and " transmission gap pattern 2 " of replacing.Often kind " transmission gap pattern " provides one or two transmission gaps in one " transmission gap pattern length ".In addition, every suit " transmission gap pattern sequence " also comprises the transmission gap Connection Frame Number (Connection Frame Number, referred to as CFN) of instruction start/stop compact model time, number of repetition of transmission gap pattern etc.These parameters are all determined according to " transmission gap pattern sequence measures purposes ".

When considering that great amount of terminals appears at a community, this cell available resources may be not enough to the service quality of all business ensureing all terminals, causes congested or overload.In correlation technique, be reply small area jam or overload, load balancing mechanism can be adopted, namely traffic balancing to the adjacent area compared with underload, this method can reach the object of traffic balancing to the adjacent area compared with underload with lower cost.When needs carry out load balancing between different nodes B or between different system, only have radio network controller could make the decision-making of load balancing according to the information on load of community, and the compact model that must start when switching or intersystem handover between preparing frequently according to this decision-making carry out measuring between inter-frequency measurement or system.

Considering quickening handoff procedure, the reliability of switching can be increased, especially in the region of radio signal quality high progression, the risk of conversation loss can be reduced by accelerating handoff procedure.The time of compression mode starting is more late better, and the time that compact model continues is more short better, improves power system capacity and user throughput.So, can be bad by the radio signal quality of terminal judges current carrier frequency, start compact model to Node B application to measure between carrier frequency/system between adjacent area, and controlled the start/stop of compact model by Node B.Corresponding, when Node B determines start/stop, " the transmission gap pattern sequence " of start/stop is informed terminal by Node B.

Therefore, cause starting compact model because the radio signal quality of current carrier frequency is bad between terminal and Node B to measure.According to " transmission gap pattern sequence " generations " transmission gap " when terminal and Node B start compact model, and stopping " transmission gap pattern sequence " when terminal and Node B stop compact model.

But, the problem of the compact model conflict of following startup when above-mentioned technology is used in engineering, may be produced.Radio signal quality residing for terminal is bad, and terminal starts compact model to Node B application and measures adjacent area between carrier frequency, and Node B control terminal start with the compact model being measured as object between carrier frequency.In addition, radio network controller also notifies that Node B starts the compact model to be measured as object between system in order to the execution of load balancing.Therefore, just there is the situation that two cover compact models clash in Node B, thus cause terminal to perform measuring based on carrying between inter-frequency measurement or system of compact model, finally cause system loading cannot reduce the performance of influential system equipment, terminal also can be caused in addition not switch and call drop in time.

Summary of the invention

For in correlation technique Node B start compact model conflict problem and the present invention is proposed, for this reason, main purpose of the present invention is the processing method, the Apparatus and system that provide a kind of transmission gap pattern sequence, to solve the problem.

To achieve these goals, according to an aspect of the present invention, a kind of processing method of transmission gap pattern sequence is provided.

Processing method according to transmission gap pattern sequence of the present invention comprises: use the first transmission gap pattern sequence to produce in the process of transmission gap in Node B and terminal, and Node-B receiver is to the message being used to indicate the second transmission gap pattern sequence from radio network controller; Node B and terminal use the second transmission gap pattern sequence to replace the first transmission gap pattern sequence to produce transmission gap.

Further, Node B and terminal use the second transmission gap pattern sequence to replace the first transmission gap pattern sequence to produce transmission gap to comprise: the message being used to indicate use second transmission gap pattern sequence and producing transmission gap is sent to terminal by Node B; Node B and terminal stop using the first transmission gap pattern sequence to produce transmission gap; Node B and terminal use the second transmission gap pattern sequence to produce transmission gap.

Further, use the second transmission gap pattern sequence to replace after the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise: the operation whether terminal stops the radio signal quality performing the current carrier frequency determined belonging to it to satisfy condition.

Further, use before the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise: terminal receives the message from radio network controller, wherein message carries and determines for terminal the threshold value whether radio signal quality of the current carrier frequency belonging to it satisfies condition; Terminal uses threshold value, determines that the radio signal quality of the current carrier frequency belonging to it does not satisfy condition; Terminal sends the message of the generation being used for trigger communication gap to Node B; Node-B receiver to the message of the generation for trigger communication gap, and sends the message being used to indicate use first transmission gap pattern sequence generation transmission gap to terminal.

Further, use before the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise: Node B, terminal and radio network controller pre-determine the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence.

Further, the pattern of Node B, terminal and the radio network controller pattern and the second transmission gap pattern sequence that pre-determine the first transmission gap pattern sequence comprises: radio network controller sends the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence by radio resource control layer control signal to terminal; Radio network controller sends the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence by Node B application block NBAP protocol layer control signal to Node B.

Further, the first transmission gap pattern sequence and the second transmission gap pattern sequence include: transmission gap pattern sequence identifies, transmission gap pattern sequence measures purposes, the first transmission gap pattern and/or the second transmission gap pattern.

To achieve these goals, according to another aspect of the present invention, a kind of Node B is provided.

Node B according to the present invention comprises: the first generation module, for using the first transmission gap pattern sequence to produce transmission gap with terminal; First receiver module, for receiving the message being used to indicate the second transmission gap pattern sequence from radio network controller; Second generation module, for using the second transmission gap pattern sequence to replace the first transmission gap pattern sequence to produce transmission gap with terminal.

To achieve these goals, according to another aspect of the present invention, a kind of terminal is additionally provided.

Terminal according to the present invention comprises: the second receiver module, for receiving the message being used to indicate use second transmission gap pattern sequence generation transmission gap from Node B; 3rd generation module, for using the second transmission gap pattern sequence to produce transmission gap with Node B; Stopping modular, the operation whether radio signal quality for stopping performing the current carrier frequency determined belonging to it satisfies condition.

To achieve these goals, according to another aspect of the present invention, a kind for the treatment of system of transmission gap pattern sequence is further provided.

Above-mentioned Node B and above-mentioned terminal is comprised according to the treatment system of transmission gap pattern sequence of the present invention.

Pass through the present invention, Node B and terminal is adopted to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

Accompanying drawing explanation

Accompanying drawing described herein is used to provide a further understanding of the present invention, and form a application's part, schematic description and description of the present invention, for explaining the present invention, does not form inappropriate limitation of the present invention.In the accompanying drawings:

Fig. 1 is the schematic diagram of " transmission gap pattern sequence " according to correlation technique;

Fig. 2 is the flow chart of the processing method of transmission gap pattern sequence according to the embodiment of the present invention;

Fig. 3 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention one;

Fig. 4 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention two;

Fig. 5 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention three;

Fig. 6 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention four;

Fig. 7 is the structured flowchart of the Node B according to the embodiment of the present invention;

Fig. 8 is the structured flowchart of the terminal according to the embodiment of the present invention.

Embodiment

It should be noted that, when not conflicting, the embodiment in the application and the feature in embodiment can combine mutually.Below with reference to the accompanying drawings and describe the present invention in detail in conjunction with the embodiments.

According to embodiments of the invention, provide a kind of processing method of transmission gap pattern sequence.Fig. 2 is the flow chart of the processing method of transmission gap pattern sequence according to the embodiment of the present invention, comprises following step S202 to step S204.

Step S202, uses the first transmission gap pattern sequence to produce in the process of transmission gap in Node B and terminal, and Node-B receiver is to the message being used to indicate the second transmission gap pattern sequence from radio network controller.

Step S204, Node B and terminal use the second transmission gap pattern sequence to replace the first transmission gap pattern sequence to produce transmission gap.

In correlation technique, if Node B control terminal starts the compact model based on the first transmission gap pattern sequence, receiving again the message for starting the compact model based on the second transmission gap pattern sequence from radio network controller, just there is the situation that two cover compact models clash in Node B.In the embodiment of the present invention, the second transmission gap pattern sequence is forced to replace the first transmission gap pattern to produce transmission gap by Node B, thus the compact model started based on the second transmission gap pattern sequence, the situation that two cover compact models clash can be avoided, thus ensure that terminal execution is measured based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

Preferably, Node B and terminal use the second transmission gap pattern sequence to replace the first transmission gap pattern sequence to produce transmission gap to comprise: the message being used to indicate use second transmission gap pattern sequence and producing transmission gap is sent to terminal by Node B; Node B and terminal stop using the first transmission gap pattern sequence to produce transmission gap; Node B and terminal use the second transmission gap pattern sequence to produce transmission gap.

It should be noted that, be responsible for coordinating to solve the startup compact model conflict that may occur by Node B in this preferred embodiment, and with radio network controller conversion for principle, the final transmission gap pattern sequence determining to perform.This preferred embodiment implementation is simple, reliable, and it comprises two kinds of following situations:

Situation one

If when terminal and Node B are performing the first transmission gap pattern sequence, radio network controller is needing to carry out startup second transmission gap pattern sequence to this terminal.Node B for principle, finally determines execution second transmission gap pattern sequence with radio network controller conversion.

Situation two

If radio network controller needs to carry out the second transmission gap pattern sequence to terminal.Node B for principle, finally determines execution second transmission gap pattern sequence with radio network controller conversion, and during this period, terminal stops triggering new compact model.

Preferably, use the second transmission gap pattern sequence to replace after the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise: the operation whether terminal stops the radio signal quality performing the current carrier frequency determined belonging to it to satisfy condition.

It should be noted that, because terminal performs the object determining the operation whether radio signal quality of current carrier frequency belonging to it satisfies condition, be the message reporting the generation for trigger communication gap to Node B.But the second transmission gap pattern sequence that Node B has forced use radio network controller to issue and terminal produce transmission gap.That is, no matter whether terminal reports the message of the generation for trigger communication gap, and Node B all can not be considered it.Therefore, this preferred embodiment, while terminal communication, can save the resource of this terminal.

Preferably, use before the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise: terminal receives the message from radio network controller, wherein message carries and determines for terminal the threshold value whether radio signal quality of the current carrier frequency belonging to it satisfies condition; Terminal uses threshold value, determines that the radio signal quality of the current carrier frequency belonging to it does not satisfy condition; Terminal sends the message of the generation being used for trigger communication gap to Node B; Node-B receiver to the message of the generation for trigger communication gap, and sends the message being used to indicate use first transmission gap pattern sequence generation transmission gap to terminal.

Preferably, use before the first transmission gap pattern sequence produces transmission gap in Node B and terminal, also comprise Node B, terminal and radio network controller and pre-determine the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence.

It should be noted that, the communication between Node B, terminal and radio network controller all can take the pattern of the first transmission gap pattern sequence or the pattern of the second transmission gap pattern sequence.When Node B, terminal and radio network controller determine employing first transmission gap pattern sequence or the second transmission gap pattern sequence produces transmission gap, it needs by sending the message being used to indicate employing first transmission gap pattern sequence or the second transmission gap pattern sequence generation transmission gap, and need not transmit the pattern of the first transmission gap pattern sequence or the pattern of the second transmission gap pattern sequence.Therefore, this preferred embodiment can reduce the transmission of information in network, and avoids the mode transfer mistake of transmission gap pattern sequence.

Preferably, the pattern of pattern and the second transmission gap pattern sequence that Node B, terminal and radio network controller pre-determine the first transmission gap pattern sequence comprises: radio network controller sends the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence by wireless heterogeneous networks (Radio Resource Control, referred to as RRC) protocol layer control signal to terminal; Radio network controller sends the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence by Node B application block (NodeB Application Part, referred to as NBAP) protocol layer control signal to Node B.

It should be noted that, in this preferred embodiment, the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence is sent by radio network controller, thus realizing the unification of the pattern of transmission gap pattern sequence in Node B, terminal and radio network controller, implementation is easy.

It should be noted that, pattern that is a set of or many covers transmission gap pattern sequence is sent to Node B and terminal by above-mentioned radio network controller.

Preferably, the first transmission gap pattern sequence and the second transmission gap pattern include: transmission gap pattern sequence identifies, transmission gap pattern sequence measures purposes, the first transmission gap pattern and/or the second transmission gap pattern.

It should be noted that, it is that Node B and terminal are necessary in the process producing transmission gap that transmission gap pattern sequence mark, transmission gap pattern sequence measure purposes, the first transmission gap pattern and/or the second transmission gap pattern.In addition, the first transmission gap pattern and/or the second transmission gap pattern can provide the information of transmission gap in a transmission gap pattern length.

Preferably, the first transmission gap pattern sequence and the second transmission gap pattern sequence can also comprise: the information of the number of repetition of transmission gap pattern.

Be described in detail below in conjunction with the implementation procedure of example to the embodiment of the present invention.

It should be noted that, High-Speed Dedicated Physical Control Channel (High Speed DedicatedPhysical Control Channel, referred to as HS-DPCCH) be the control channel of up direction, be used for carrying the feedback information for the successful downlink data receiving of " confirmation "/" denying " of downlink data reception condition, and the quality feedback information of bearing downlink data reception quality.In HS-DPCCH physical channel, the territory of the quality feedback information of bearing downlink data reception quality is called " channel quality instructions field "." channel quality instructions field " is made up of 5 bits.The value of 1-30 has been used in prior art.Following embodiment is by the value of use 31.Wherein during " channel quality instructions field " value 31, represent " triggering compact model ".

High-Speed Shared Control Channel (High Speed Shared Control Channel, referred to as HS-SCCH) be used to carrying high-speed downlink shared channel (High SpeedDownlink Shared Channel, referred to as HS-DSCH) information required for rectification is the control channel of down direction.Node B can send high-speed shared control channel command (HS-SCCH order) by HS-SCCH physical channel and carry out the corresponding control of command terminal do to terminal.

HS-SCCH order has 3 bits to represent the type of high-speed shared control channel command, the concrete high-speed shared control channel command under having 3 bits to carry out this type.Prior art only only used the type that value is 2 kinds of high-speed shared control channel commands of 0 and 1.

Use value is the type of the new high-speed shared control channel command of 2 by following embodiment, represents " startup " compact model; Use value is the type of the new high-speed shared control channel command of 3 by following embodiment, represents " stopping " compact model; These 3 bits that following embodiment will use " the concrete high-speed shared control channel command under having 3 bits to carry out this type ", the value that following embodiment will use these 3 bits from 1 to 7, represent respectively this " transmission gap pattern sequence mark ", be used for identifying " transmission gap pattern sequence ".

Preferred embodiment one

This preferred embodiment one describes the description of the transmission gap pattern sequence identified according to transmission gap pattern sequence mark 1 in terminal and Node B in the process producing transmission gap, the transmission gap pattern sequence that the transmission gap pattern sequence mark 6 that Node-B receiver sends to radio network controller identifies, then terminal and Node B identify the description of this cover transmission gap pattern sequence that 6 identify to produce transmission gap according to transmission gap pattern sequence.

Fig. 3 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention one, comprises following step S302 to step S332.

Step S302: terminal and Node B, radio network controller arranges " transmission gap pattern sequence " information starting compact model in advance, or radio network controller configures " transmission gap pattern sequence " information starting compact model to " transmission gap pattern sequence " information of terminal configuration startup compact model and radio network controller by RRC protocol layer control signal to Node B by NBAP protocol layer control signal.

" transmission gap pattern sequence " information starting compact model specifically comprises:

First set " transmission gap pattern sequence ", for the measurement purposes of " Frequency Division Duplexing (FDD) measurement ", " transmission gap pattern sequence mark " is 1.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced.Often kind " transmission gap pattern " provides a transmission gap in one " transmission gap pattern length ".

Second cover " transmission gap pattern sequence ", for the measurement purposes of " GSM identification of base stations colour coding initial identification ", " transmission gap pattern sequence mark " is 6.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced, and often kind " transmission gap pattern " provides two transmission gaps in one " transmission gap pattern length ".

Step S304: the bad condition of radio signal quality of radio network controller setting current carrier frequency, and inform terminal by RRC protocol layer control signal.The condition that the radio signal quality of current carrier frequency is bad is: terminal measures CPICHRSCP, in the time span continuing 600 milliseconds, is less than or is less than or equal to-102dBm.

Step S306: the CPICHRSCP that terminal carries out current carrier frequency measures, judges to meet the condition that the radio signal quality of current carrier frequency is bad, is namely less than in the time span continuing 600 milliseconds or is less than or equal to-102dBm.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S308: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S310: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

Step S312: Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, it is 6 these covers " transmission gap pattern sequence " identified that radio network controller advised nodes B needs to start " the transmission gap pattern sequence mark " of specifying to this terminal.Carry the mark of this terminal in this signaling, start the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S314: Node B is responsible for trade-off solution and has been decided existing startup compact model conflict, with radio network controller conversion for principle, the final transmission gap pattern sequence determining to perform is transmission gap pattern sequence mark " be 6 these covers " transmission gap pattern sequence " identified.

Step S316: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S318: terminal and Node B interrupt this cover " transmission gap pattern sequence " that " transmission gap pattern sequence mark " 1 identifies, and the description of this cover " transmission gap pattern sequence " identified according to " transmission gap pattern sequence mark " 6 is to produce transmission gap.

Step S320: terminal stops judging to meet the bad condition of the radio signal quality of current carrier frequency, and " triggering compact model " information that no longer sends is to Node B.

Step S322: Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, radio network controller advised nodes B needs to stop " the transmission gap pattern sequence mark " of specifying to be 6 these covers " transmission gap pattern sequence " identified to this terminal.Carry the mark of this terminal in this signaling, stop the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S324: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the stopping action of compact model and " the transmission gap pattern sequence mark " of stopping to terminal.Wherein: stop the action of compact model to be that the type being the new high-speed shared control channel command of 3 by use value represents; " the transmission gap pattern sequence " that stop identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S326: this cover " transmission gap pattern sequence " that terminal and Node B stop " transmission gap pattern sequence mark " 6 to identify.

Step S328: terminal is recovered to judge to meet the bad condition of the radio signal quality of current carrier frequency, the CPICHRSCP carrying out current carrier frequency when terminal measures, judge to meet the condition that the radio signal quality of current carrier frequency is bad, be namely less than in the time span continuing 600 milliseconds or be less than or equal to-102dBm.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S330: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S332: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

It should be noted that, this preferred embodiment one adopts Node B and terminal to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

Preferred embodiment two

This preferred embodiment two describes the description of the transmission gap pattern sequence identified according to transmission gap pattern sequence mark 1 in terminal and Node B in the process producing transmission gap, the transmission gap pattern sequence that the transmission gap pattern sequence mark 6 that Node-B receiver sends to radio network controller identifies, then terminal and Node B identify the description of this cover transmission gap pattern sequence that 6 identify to produce transmission gap according to transmission gap pattern sequence.

This preferred embodiment two with the difference of preferred embodiment one is, the number of repetition that radio network controller pre-sets the transmission gap pattern sequence that transmission gap pattern sequence mark 1 identifies is 20 times, and the number of repetition of the transmission gap pattern sequence that transmission gap pattern sequence mark 6 identifies is 60 times.Then, Node B has carried out corresponding operation with reference to this number of repetition.

Fig. 4 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention two, comprises following step S402 to step S428.

Step S402: terminal and Node B, radio network controller arranges " transmission gap pattern sequence " information starting compact model in advance, or radio network controller configures " transmission gap pattern sequence " information starting compact model to " transmission gap pattern sequence " information of terminal configuration startup compact model and radio network controller by RRC protocol layer control signal to Node B by NBAP protocol layer control signal.

" transmission gap pattern sequence " information starting compact model specifically comprises:

First set " transmission gap pattern sequence ", for the measurement purposes of " Frequency Division Duplexing (FDD) measurement ", " transmission gap pattern sequence mark " is 1.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced.Often kind " transmission gap pattern " provides a transmission gap in one " transmission gap pattern length ".The number of repetition of this cover " transmission gap pattern sequence " is 20 times.

Second cover " transmission gap pattern sequence ", for the measurement purposes of " GSM identification of base stations colour coding initial identification ", " transmission gap pattern sequence mark " is 6.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced, and often kind " transmission gap pattern " provides two transmission gaps in one " transmission gap pattern length ".The number of repetition of this cover " transmission gap pattern sequence " is 60 times.

Step S404: the bad condition of radio signal quality of radio network controller setting current carrier frequency, and inform terminal by RRC protocol layer control signal.The condition that the radio signal quality of current carrier frequency is bad is: terminal measures CPICH Ec/Io, in the time span continuing 600 milliseconds, is less than or is less than or equal to-12dB.

Step S406: the CPICH Ec/Io that terminal carries out current carrier frequency measures, judges to meet the condition that the radio signal quality of current carrier frequency is bad, is namely less than in the time span continuing 600 milliseconds or is less than or equal to-12dB.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S408: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S410: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

Step S412: before the number of repetition of this cover " transmission gap pattern sequence " (being designated 1) completes for 20 times, Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, it is 6 these covers " transmission gap pattern sequence " identified that radio network controller advised nodes B needs to start " the transmission gap pattern sequence mark " of specifying to this terminal.Carry the mark of this terminal in this signaling, start the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S414: Node B is responsible for trade-off solution and has been decided existing startup compact model conflict, with radio network controller conversion for principle, the final transmission gap pattern sequence determining to perform is transmission gap pattern sequence mark " be 6 these covers " transmission gap pattern sequence " identified.

Step S416: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S418: terminal and Node B interrupt this cover " transmission gap pattern sequence " that " transmission gap pattern sequence mark " 1 identifies, and the description of this cover " transmission gap pattern sequence " identified according to " transmission gap pattern sequence mark " 6 is to produce transmission gap.

Step S420: terminal stops judging to meet the bad condition of the radio signal quality of current carrier frequency, and " triggering compact model " information that no longer sends is to Node B.

Step S422: after the number of repetition of this cover " transmission gap pattern sequence " (being designated 6) completes for 60 times, this cover " transmission gap pattern sequence " that terminal and Node B stop " transmission gap pattern sequence mark " 6 to identify.

Step S424: terminal is recovered to judge to meet the bad condition of the radio signal quality of current carrier frequency, the CPICH Ec/Io carrying out current carrier frequency when terminal measures, judge to meet the condition that the radio signal quality of current carrier frequency is bad, namely in the time span continuing 600 milliseconds, be less than or be less than or equal to-12dB.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S426: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S428: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

It should be noted that, this preferred embodiment two adopts Node B and terminal to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

In addition, this preferred embodiment two by counterweight again number limit, namely according to actual needs, the number of repetition of the first transmission gap pattern sequence or the second transmission gap pattern sequence can be adjusted, thus transmission gap pattern sequence process ground flexibility can be improved.

Preferred embodiment three

This preferred embodiment three describes the transmission gap pattern sequence that Node-B receiver identifies to the transmission gap pattern sequence mark 6 that radio network controller sends, then terminal and Node B identify the description of this cover transmission gap pattern sequence that 6 identify to produce transmission gap according to transmission gap pattern sequence.

This preferred embodiment three with the difference of preferred embodiment one is, terminal is in the process judged the radio signal quality of current carrier frequency, the descriptions of this cover transmission gap pattern sequence identified according to transmission gap pattern sequence mark 6 receiving that Node B sends are to produce the message of transmission gap, then identify the description of this cover transmission gap pattern sequence that 6 identify to produce transmission gap according to transmission gap pattern sequence, and stop the judgement to the radio signal quality of current carrier frequency.

Fig. 5 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention three, comprises following step S502 to step S524.

Step S502: terminal and Node B, radio network controller arranges " transmission gap pattern sequence " information starting compact model in advance, or radio network controller configures " transmission gap pattern sequence " information starting compact model to " transmission gap pattern sequence " information of terminal configuration startup compact model and radio network controller by RRC protocol layer control signal to Node B by NBAP protocol layer control signal.

" transmission gap pattern sequence " information starting compact model specifically comprises:

First set " transmission gap pattern sequence ", for the measurement purposes of " Frequency Division Duplexing (FDD) measurement ", " transmission gap pattern sequence mark " is 1.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced.Often kind " transmission gap pattern " provides a transmission gap in one " transmission gap pattern length ".

Second cover " transmission gap pattern sequence ", for the measurement purposes of " GSM identification of base stations colour coding initial identification ", " transmission gap pattern sequence mark " is 6.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced, and often kind " transmission gap pattern " provides two transmission gaps in one " transmission gap pattern length ".

Step S504: the bad condition of radio signal quality of radio network controller setting current carrier frequency, and inform terminal by RRC protocol layer control signal.The condition that the radio signal quality of current carrier frequency is bad is: terminal measures CPICHRSCP, in the time span continuing 600 milliseconds, is less than or is less than or equal to-102dBm.

Step S506: Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, it is 6 these covers " transmission gap pattern sequence " identified that radio network controller advised nodes B needs to start " the transmission gap pattern sequence mark " of specifying to this terminal.Carry the mark of this terminal in this signaling, start the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S508: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S510: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 6 is to produce transmission gap.

Step S512: because this compact model started is that nonterminal triggers, so terminal stops judging to meet the bad condition of the radio signal quality of current carrier frequency, " triggering compact model " information that do not send is to Node B.

Step S514: Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, radio network controller advised nodes B needs to stop " the transmission gap pattern sequence mark " of specifying to be 6 these covers " transmission gap pattern sequence " identified to this terminal.Carry the mark of this terminal in this signaling, stop the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S516: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the stopping action of compact model and " the transmission gap pattern sequence mark " of stopping to terminal.Wherein: stop the action of compact model to be that the type being the new high-speed shared control channel command of 3 by use value represents; " the transmission gap pattern sequence " that stop identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S518: this cover " transmission gap pattern sequence " that terminal and Node B stop " transmission gap pattern sequence mark " 6 to identify.

Step S520: the compact model triggered due to this nonterminal terminates, so terminal is recovered to judge to meet the bad condition of the radio signal quality of current carrier frequency, the CPICHRSCP carrying out current carrier frequency when terminal measures, judge to meet the condition that the radio signal quality of current carrier frequency is bad, be namely less than in the time span continuing 600 milliseconds or be less than or equal to-102dBm.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S522: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S524: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

It should be noted that, this preferred embodiment three adopts Node B and terminal to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

In addition, this preferred embodiment three judges whether the function of the message received from Node B for terminal adds, and stops the judgement to the radio signal quality of current carrier frequency when receiving this message, can save the resource of this terminal.

Preferred embodiment four

This preferred embodiment four describes the transmission gap pattern sequence that Node-B receiver identifies to the transmission gap pattern sequence mark 6 that radio network controller sends, then terminal and Node B identify the description of this cover transmission gap pattern sequence that 6 identify to produce transmission gap according to transmission gap pattern sequence.

This preferred embodiment four with the difference of preferred embodiment three is, the number of repetition that radio network controller pre-sets the transmission gap pattern sequence that transmission gap pattern sequence mark 1 identifies is 20 times, and the number of repetition of the transmission gap pattern sequence that transmission gap pattern sequence mark 6 identifies is 60 times.Then, Node B has carried out corresponding operation with reference to this number of repetition.

Fig. 6 is the interaction diagrams of the processing procedure according to the preferred embodiment of the present invention four, comprises following step S602 to step S620.

Step S602: terminal and Node B, radio network controller arranges " transmission gap pattern sequence " information starting compact model in advance, or radio network controller configures " transmission gap pattern sequence " information starting compact model to " transmission gap pattern sequence " information of terminal configuration startup compact model and radio network controller by RRC protocol layer control signal to Node B by NBAP protocol layer control signal.

" transmission gap pattern sequence " information starting compact model specifically comprises:

First set " transmission gap pattern sequence ", for the measurement purposes of " Frequency Division Duplexing (FDD) measurement ", " transmission gap pattern sequence mark " is 1.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced.Often kind " transmission gap pattern " provides a transmission gap in one " transmission gap pattern length ".The number of repetition of this cover " transmission gap pattern sequence " is 20 times.

Second cover " transmission gap pattern sequence ", for the measurement purposes of " GSM identification of base stations colour coding initial identification ", " transmission gap pattern sequence mark " is 6.This cover " transmission gap pattern sequence " comprises 2 kinds of " transmission gap patterns 1 " and " transmission gap pattern 2 " replaced, and often kind " transmission gap pattern " provides two transmission gaps in one " transmission gap pattern length ".The number of repetition of this cover " transmission gap pattern sequence " is 60 times.

Step S604: the bad condition of radio signal quality of radio network controller setting current carrier frequency, and inform terminal by RRC protocol layer control signal.The condition that the radio signal quality of current carrier frequency is bad is: terminal measures CPICH Ec/Io, in the time span continuing 600 milliseconds, is less than or is less than or equal to-12dB.

Step S606: Node-B receiver sends NBAP protocol layer control signal to radio network controller, compact model order.By this signaling, it is 6 these covers " transmission gap pattern sequence " identified that radio network controller advised nodes B needs to start " the transmission gap pattern sequence mark " of specifying to this terminal.Carry the mark of this terminal in this signaling, start the action of compact model, " transmission gap pattern sequence mark " is 6.

Step S608: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 6, and " transmission gap pattern sequence mark " 6 is 6 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S610: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 6 is to produce transmission gap.

Step S612: because this compact model started is that nonterminal triggers, so terminal stops judging to meet the bad condition of the radio signal quality of current carrier frequency, " triggering compact model " information that do not send is to Node B.

Step S614: after the number of repetition of this cover " transmission gap pattern sequence " (being designated 6) completes for 60 times, this cover " transmission gap pattern sequence " that terminal and Node B stop " transmission gap pattern sequence mark " 6 to identify.

Step S616: the compact model triggered due to this nonterminal terminates, so terminal is recovered to judge to meet the bad condition of the radio signal quality of current carrier frequency, the CPICH Ec/Io carrying out current carrier frequency when terminal measures, judge to meet the condition that the radio signal quality of current carrier frequency is bad, namely in the time span continuing 600 milliseconds, be less than or be less than or equal to-12dB.Terminal sends to Node B by HS-DPCCH physical channel." triggering compact model " information HS-DPCCH physical channel " channel quality instructions field " value 31 represents " triggering compact model ".

Step S618: Node B sends " HS-SCCHorder (high-speed shared control channel command) " by HS-SCCH physical channel and informs the startup action of compact model and " the transmission gap pattern sequence mark " of startup to terminal.Wherein: the action starting compact model is that the type being the new high-speed shared control channel command of 2 by use value represents; " the transmission gap pattern sequence " that start identifies with " transmission gap pattern sequence mark " 1, and " transmission gap pattern sequence mark " 1 is 1 to represent by these 3 bit values of the concrete high-speed shared control channel command of " having the concrete high-speed shared control channel command that 3 bits come under this type ".

Step S620: the description of this cover " transmission gap pattern sequence " that terminal and Node B identify according to " transmission gap pattern sequence mark " 1 is to produce transmission gap.

It should be noted that, this preferred embodiment four adopts Node B and terminal to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

In addition, this preferred embodiment four by counterweight again number limit, namely according to actual needs, the number of repetition of the first transmission gap pattern sequence or the second transmission gap pattern sequence can be adjusted, thus transmission gap pattern sequence process ground flexibility can be improved.

It should be noted that, can perform in the computer system of such as one group of computer executable instructions in the step shown in the flow chart of accompanying drawing, and, although show logical order in flow charts, but in some cases, can be different from the step shown or described by order execution herein.

According to embodiments of the invention, additionally provide a kind of Node B, this Node B may be used for the processing method realizing above-mentioned transmission gap pattern sequence.Fig. 7 is the structured flowchart of the Node B according to the embodiment of the present invention, comprises the first generation module 72, first receiver module 74 and the second generation module 76.Below its structure is described in detail.

First generation module 72, for using the first transmission gap pattern sequence to produce transmission gap with terminal; First receiver module 74, for receiving the message being used to indicate the second transmission gap pattern sequence from radio network controller; Second generation module 76, be connected to the first generation module 72 and the first receiver module 74, the first transmission gap pattern sequence that the second transmission gap pattern sequence for using the first receiver module 74 to receive with terminal replaces the first generation module 72 and terminal to use produces transmission gap.

In correlation technique, if Node B control terminal starts the compact model based on the first transmission gap pattern sequence, receiving again the message for starting the compact model based on the second transmission gap pattern sequence from radio network controller, just there is the situation that two cover compact models clash in Node B.In the embodiment of the present invention, the second transmission gap pattern sequence is forced to replace the first transmission gap pattern to produce transmission gap by the second generation module 76, thus the compact model started based on the second transmission gap pattern sequence, the situation that two cover compact models clash can be avoided, thus ensure that terminal execution is measured based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

According to embodiments of the invention, additionally provide a kind of terminal, this terminal may be used for the processing method realizing above-mentioned transmission gap pattern sequence.Fig. 8 is the structured flowchart of the terminal according to the embodiment of the present invention, comprises the second receiver module the 82, three generation module 84 and stopping modular 86.Below its structure is described in detail.

Second receiver module 82, for receiving the message being used to indicate use second transmission gap pattern sequence generation transmission gap from Node B; 3rd generation module 84, is connected to the second receiver module 82, produces transmission gap for the second transmission gap pattern sequence using the second receiver module 82 to receive with Node B; Stopping modular 86, be connected to the 3rd generation module 84, for using after the second transmission gap pattern sequence produces transmission gap in the 3rd generation module 84 and Node B, the operation whether radio signal quality of the current carrier frequency stopping execution determining belonging to it satisfies condition.

According to embodiments of the invention, additionally provide a kind for the treatment of system of transmission gap pattern sequence, this system may be used for the processing method realizing above-mentioned transmission gap pattern sequence.This system comprises the above-mentioned Node B comprising the first generation module 72, first receiver module 74 and the second generation module 76, also comprises the above-mentioned terminal comprising the second receiver module the 82, three generation module 84 and stopping modular 86.

It should be noted that, the treatment system of the Node B described in said apparatus embodiment, terminal and above-mentioned transmission gap pattern sequence corresponds to above-mentioned embodiment of the method, its concrete implementation procedure carried out detailed description in embodiment of the method, did not repeat them here.

In sum, according to the abovementioned embodiments of the present invention, a kind of processing method, Apparatus and system of transmission gap pattern sequence is provided.It is responsible for coordinating to solve the startup compact model conflict that may occur mainly through Node B, with radio network controller conversion for principle, and the final transmission gap pattern sequence determining to perform.Particularly, Node B and terminal is adopted to use the second transmission gap pattern sequence received from radio network controller, the first transmission gap pattern sequence is replaced to produce transmission gap, solve the problem of the compact model conflict that the Node B in correlation technique starts, ensure that terminal performs to measure based on carrying between inter-frequency measurement or system of compact model, and ensure the performance of system equipment and the communication of terminal.

Obviously, those skilled in the art should be understood that, above-mentioned of the present invention each module or each step can realize with general calculation element, they can concentrate on single calculation element, or be distributed on network that multiple calculation element forms, alternatively, they can realize with the executable program code of calculation element, thus, they can be stored and be performed by calculation element in the storage device, or they are made into each integrated circuit modules respectively, or the multiple module in them or step are made into single integrated circuit module to realize.Like this, the present invention is not restricted to any specific hardware and software combination.

The foregoing is only the preferred embodiments of the present invention, be not limited to the present invention, for a person skilled in the art, the present invention can have various modifications and variations.Within the spirit and principles in the present invention all, any amendment done, equivalent replacement, improvement etc., all should be included within protection scope of the present invention.

Claims (10)

1. a processing method for transmission gap pattern sequence, is characterized in that, comprising:

Use the first transmission gap pattern sequence to produce in the process of transmission gap in Node B and terminal, described Node-B receiver is to the message being used to indicate the second transmission gap pattern sequence from radio network controller;

If described Node B has controlled the compact model of described terminal startup based on described first transmission gap pattern sequence, described Node B and described terminal have used described second transmission gap pattern sequence to replace described first transmission gap pattern sequence to produce transmission gap.

2. method according to claim 1, is characterized in that, described Node B and described terminal use described second transmission gap pattern sequence to replace described first transmission gap pattern sequence to produce described transmission gap to comprise:

Described Node B sends to described terminal by being used to indicate the message using described second transmission gap pattern sequence to produce described transmission gap;

Described Node B and described terminal stop using described first transmission gap pattern sequence to produce described transmission gap;

Described Node B and described terminal use described second transmission gap pattern sequence to produce described transmission gap.

3. method according to claim 1, is characterized in that, uses described second transmission gap pattern sequence to replace after described first transmission gap pattern sequence produces described transmission gap, also comprise in described Node B and described terminal:

The operation whether described terminal stops the radio signal quality performing the current carrier frequency determined belonging to it to satisfy condition.

4. method according to claim 1, is characterized in that, uses before described first transmission gap pattern sequence produces described transmission gap, also comprise in described Node B and described terminal:

Described terminal receives the message from described radio network controller, and wherein said message carries determines for described terminal the threshold value whether radio signal quality of the current carrier frequency belonging to it satisfies condition;

Described terminal uses described threshold value, determines that the radio signal quality of the current carrier frequency belonging to it does not satisfy condition;

Described terminal sends the message of the generation for triggering described transmission gap to described Node B;

Described Node-B receiver to the message of the described generation for triggering described transmission gap, and sends the message being used to indicate and using described first transmission gap pattern sequence to produce described transmission gap to described terminal.

5. method according to any one of claim 1 to 4, it is characterized in that, use before described first transmission gap pattern sequence produces described transmission gap in described Node B and described terminal, also comprise: described Node B, described terminal and described radio network controller pre-determine the pattern of described first transmission gap pattern sequence and the pattern of described second transmission gap pattern sequence.

6. method according to claim 5, is characterized in that, the pattern of pattern and described second transmission gap pattern sequence that described Node B, described terminal and described radio network controller pre-determine described first transmission gap pattern sequence comprises:

Described radio network controller sends the pattern of described first transmission gap pattern sequence and the pattern of described second transmission gap pattern sequence by radio resource control layer control signal to described terminal;

Described radio network controller sends the pattern of described first transmission gap pattern sequence and the pattern of described second transmission gap pattern sequence by Node B application block NBAP protocol layer control signal to described Node B.

7. method according to claim 5, is characterized in that, described first transmission gap pattern sequence and described second transmission gap pattern sequence include:

Transmission gap pattern sequence mark, transmission gap pattern sequence measure purposes, the first transmission gap pattern and/or the second transmission gap pattern.

8. a Node B, is characterized in that, comprising:

First generation module, for using the first transmission gap pattern sequence to produce transmission gap with terminal;

First receiver module, for receiving the message being used to indicate the second transmission gap pattern sequence from radio network controller;

Second generation module, if controlled the startup of described terminal based on the compact model of described first transmission gap pattern sequence for described Node B, described second transmission gap pattern sequence has been used to replace described first transmission gap pattern sequence to produce transmission gap with described terminal.

9. a terminal, is characterized in that, comprising:

Second receiver module, is used to indicate from Node B the message that use second transmission gap pattern sequence produces described transmission gap for receiving;

3rd generation module, for using described second transmission gap pattern sequence to produce transmission gap with described Node B;

Stopping modular, the operation whether radio signal quality for stopping performing the current carrier frequency determined belonging to it satisfies condition.

10. a treatment system for transmission gap pattern sequence, is characterized in that, comprises Node B according to claim 8 and terminal according to claim 9.