TW201316793A - Method for implementing fast-dynamic channel allocation radio resource management procedures - Google Patents

Method for implementing fast-dynamic channel allocation radio resource management procedures Download PDF

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TW201316793A
TW201316793A TW101125200A TW101125200A TW201316793A TW 201316793 A TW201316793 A TW 201316793A TW 101125200 A TW101125200 A TW 101125200A TW 101125200 A TW101125200 A TW 101125200A TW 201316793 A TW201316793 A TW 201316793A
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information
time slot
wtru
configuration
coding
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Xiaochun Xu Fisher
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Interdigital Tech Corp
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Priority claimed from US10/744,800 external-priority patent/US7107060B2/en
Priority claimed from US10/747,733 external-priority patent/US7212826B2/en
Priority claimed from US10/747,297 external-priority patent/US7130637B2/en
Priority claimed from US10/750,135 external-priority patent/US7110771B2/en
Priority claimed from US10/750,129 external-priority patent/US7136656B2/en
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Publication of TW201316793A publication Critical patent/TW201316793A/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W16/00Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
    • H04W16/02Resource partitioning among network components, e.g. reuse partitioning
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W16/00Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
    • H04W16/02Resource partitioning among network components, e.g. reuse partitioning
    • H04W16/10Dynamic resource partitioning
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/06TPC algorithms
    • H04W52/14Separate analysis of uplink or downlink
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/18TPC being performed according to specific parameters
    • H04W52/24TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • H04W72/0446Resources in time domain, e.g. slots or frames
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/54Allocation or scheduling criteria for wireless resources based on quality criteria
    • H04W72/541Allocation or scheduling criteria for wireless resources based on quality criteria using the level of interference
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/50Allocation or scheduling criteria for wireless resources
    • H04W72/54Allocation or scheduling criteria for wireless resources based on quality criteria
    • H04W72/542Allocation or scheduling criteria for wireless resources based on quality criteria using measured or perceived quality
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W16/00Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
    • H04W16/14Spectrum sharing arrangements between different networks
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W72/00Local resource management
    • H04W72/04Wireless resource allocation
    • H04W72/044Wireless resource allocation based on the type of the allocated resource
    • H04W72/0466Wireless resource allocation based on the type of the allocated resource the resource being a scrambling code
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W74/00Wireless channel access
    • H04W74/04Scheduled access

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Quality & Reliability (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

A method of optimizing a fast dynamic channel allocation radio resource management algorithm in a wireless communication system includes a pre-code allocation process, a signal-independent code allocation process, and a post-code allocation process. The pre-code allocation process includes receiving and processing an input message and obtaining system measurements and information from a centralized database. The code allocation process begins by checking the availability of a code set in the cell and generating timeslot sequences for the available timeslots. A code set is assigned to the available timeslots in a timeslot sequence, wherein a successful assignment is a solution. The interference signal code power (ISCP) is calculated for each solution and the solution having the lowest weighted ISCP is selected as an optimal solution. The post-code allocation process includes storing allocation information in a centralized database and creating an output message.

Description

實詩快速動態頻道配置無線資源管理程序之方法 Real poetry fast dynamic channel configuration wireless resource management program method

本發明大致有關無線通信系統中之無線資源管理,及更特別有關實施快速動態頻道配置(F-DCA)無線資源管理(RRM)程序。 The present invention relates generally to radio resource management in a wireless communication system, and more particularly to implementing a Fast Dynamic Channel Configuration (F-DCA) Radio Resource Management (RRM) procedure.

無線通信系統中,無線資源管理通常負責使用空中介面資源。無線資源管理係被用來保證服務品質(QoS),以提供有效使用無線資源,並增加系統容量。無線資源管理包含允許控制,交換,功率控制及壅塞控制功能。允許控制可被分為使用者允許控制及呼叫允許控制(CAC)。使用者允許控制可接受或拒絕無線傳輸/接收單元(WTRU)所要求之無線資源控制(RRC)連接。使用者允許控制可接受或拒絕建立或修改無線存取網路(RAN)中之無線存取承載(RAB)。呼叫允許控制(CAC)係被放置於控制無線網路控制器(C-RNC)。 In wireless communication systems, radio resource management is typically responsible for using empty interfacing resources. Radio resource management is used to guarantee quality of service (QoS) to provide efficient use of radio resources and increase system capacity. Radio resource management includes control, switching, power control and congestion control functions. Allowable control can be divided into User Allowed Control and Call Admission Control (CAC). The user allows control to accept or reject the Radio Resource Control (RRC) connection required by the WTRU. The user allows control to accept or refuse to establish or modify a Radio Access Bearer (RAB) in the Radio Access Network (RAN). Call Admission Control (CAC) is placed in the Control Radio Network Controller (C-RNC).

具有兩動態頻道配置(DCA)功能,慢速動態頻道配置及快速動態頻道配置(S-DCA,F-DCA)。慢速動態頻道配置可配置無線資源至胞元,而快速動態頻道配置可配置無線資源至承載服務。快速動態頻道配置呼叫允許控制(CAC)功能係負責有效配置或改變實體資源之配置。當實體資源之要求被接收 時,呼叫允許控制(CAC)將以胞元中之實體資源可用性及干擾位準為基礎接受或拒絕該要求。該要求僅於上鏈及下鏈呼叫允許控制承認它時才可被接受。否則,該要求被拒絕。 It has two dynamic channel configuration (DCA) functions, slow dynamic channel configuration and fast dynamic channel configuration (S-DCA, F-DCA). The slow dynamic channel configuration configures wireless resources to cells, while the fast dynamic channel configuration configures wireless resources to bearer services. The Fast Dynamic Channel Configuration Call Admission Control (CAC) feature is responsible for effectively configuring or changing the configuration of physical resources. When the requirements of the physical resource are received The Call Admission Control (CAC) will accept or reject the request based on the availability and interference levels of the physical resources in the cell. This requirement is only acceptable if the uplink and downlink calls allow control to recognize it. Otherwise, the request is rejected.

為了保證服務品質及最小化干擾,特定快速動態頻道配置呼叫允許控制(CAC)演算目前被實施。但快速動態頻道配置呼叫允許控制(CAC)演算先前實施係具有若干限制。限制之一係因主介面功能很大且對編碼配置功能之輸入(其形成快速動態頻道配置呼叫允許控制(CAC)演算之核心功能)須視信號訊息而定,所以很難被其他無線資源管理功能重複使用。第二個限制係快速動態頻道配置呼叫允許控制(CAC)演算之過去實施通常僅適用於即時(RT)服務。 To ensure quality of service and minimize interference, specific Fast Dynamic Channel Configuration Call Admission Control (CAC) calculus is currently implemented. However, the Fast Dynamic Channel Configuration Call Admission Control (CAC) calculus has several limitations with previous implementations. One of the limitations is that the main interface is very functional and the input to the encoding configuration function (which forms the core function of the fast dynamic channel configuration call admission control (CAC) calculus) depends on the signal message, so it is difficult to be managed by other radio resources. Function reuse. The second limitation is that the past implementation of fast dynamic channel configuration call admission control (CAC) calculus is usually only available for immediate (RT) services.

可以演算型式之兩快速動態頻道配置功能係於穩定狀態操作下被無線資源管理執行:一用於背景干擾降低而一用於逸出機構。 The two fast dynamic channel configuration functions of the calculus type are performed by the radio resource management under steady state operation: one for background interference reduction and one for escape mechanism.

快速動態頻道配置背景干擾降低程序係被使用藉由重新指派無線資源(時間槽及編碼)至既存無線承載來一直保持無線資源管理及系統資源使用於合理位準。快速動態頻道配置背景干擾降低程序係藉由無線資源管理定期觸動。觸動背景干擾降低程序之周期係為設計參數;本發明較佳實施例中,該周期為兩秒鐘。在三種快速動態頻道配置演算之中具有相當低優先性。 Fast Dynamic Channel Configuration The Background Interference Reduction procedure is used to maintain radio resource management and system resource usage at a reasonable level by reassigning radio resources (time slots and codes) to existing radio bearers. Fast Dynamic Channel Configuration Background Interference reduction procedures are periodically triggered by radio resource management. The period of the touch background interference reduction procedure is a design parameter; in the preferred embodiment of the invention, the period is two seconds. There is a fairly low priority among the three fast dynamic channel configuration calculus.

快速動態頻道配置逸出機構係被用來解決使用者之鏈結問題。其係被當做經歷高干擾或不能藉由重新指派無線資源至既存無線承載來滿足服務品質之特定使用者(或部份使用者服務)或基地台之逸出機構。快速動態頻道配置逸出機構可為穩定狀態中之所有無線傳輸/接收單元(WTRU)即時服務運作於一胞元中。其並不應用至非即時(NRT)服務。 The fast dynamic channel configuration escape mechanism is used to solve the user's link problem. It is treated as a specific user (or part of the user service) or a base station's escape mechanism that experiences high interference or cannot reassign wireless resources to an existing radio bearer to satisfy the quality of service. The fast dynamic channel configuration escape mechanism can operate in one cell for all wireless transmit/receive unit (WTRU) instant services in steady state. It is not applied to non-instant (NRT) services.

僅一快速動態頻道配置於給定時間較佳運作於控制 無線網路控制器中,因為一功能輸出可影響另一功能之決定。若這些功能超過一個精確同時被觸動,則這些功能之優先性係為逸出程序首先運作,呼叫允許控制(CAC)其次運作,而背景干擾降低程序最後運作。 Only a fast dynamic channel configuration works better at a given time than control In a wireless network controller, because one function output can influence the decision of another function. If these functions are more than one precise and simultaneously touched, the priority of these functions is that the escape program operates first, Call Admission Control (CAC) operates second, and the background interference reduction program ends.

交換(handover)係被用於轉換從一胞元至另一個之無線鏈結而不岔斷呼叫以維持所需服務品質。無線鏈結增添程序係針對無線傳輸/接收單元(WTRU)於交換時已具有通信脈絡下被用來建立節點B中之新無線鏈結之實體資源。 A handover is used to translate a wireless link from one cell to another without interrupting the call to maintain the desired quality of service. The wireless link addition procedure is for the WTRU to have physical resources that are used to establish a new wireless link in Node B when communicating.

針對分時雙工(TDD)模式,無線鏈結設立程序係被用來建立有關即時或非即時服務之新無線鏈結所需之無線資源。無線鏈結被設立後,無線鏈結重新配置程序係被用來附加、修改或刪除此既存無線鏈結之任何實體資源。快速動態頻道配置呼叫允許控制(CAC)演算係被用來接收該要求訊息。 For Time Division Duplex (TDD) mode, the wireless link setup procedure is used to establish the wireless resources needed for new wireless links for immediate or non-instant service. After the wireless link is established, the wireless link reconfiguration procedure is used to attach, modify, or delete any physical resources of the existing wireless link. The Fast Dynamic Channel Configuration Call Admission Control (CAC) algorithm is used to receive the request message.

預期提供適用於即時及非即時服務之快速動態頻道配置呼叫允許控制(CAC)演算之最佳實施,且其可克服已知演算之缺點。亦預期提供均可滿足上述要求之改良逸出機構及背景干擾降低程序實施。進一步預期提供用於無線鏈結附加及無線鏈結重新配置之快速動態頻道配置呼叫允許控制(CAC)演算之最佳實施,其適用於即時或非即時服務,且其可克服已知演算之缺點。 It is expected to provide an optimal implementation of fast dynamic channel configuration call admission control (CAC) calculus for both immediate and non-instant service, and which overcomes the shortcomings of known algorithms. It is also contemplated to provide improved escape mechanisms and background interference reduction procedures that meet the above requirements. It is further contemplated to provide an optimal implementation of fast dynamic channel configuration call admission control (CAC) calculus for wireless link attachment and wireless link reconfiguration, which is suitable for immediate or non-instant service, and which overcomes the shortcomings of known algorithms .

本發明藉由調變/歸類快速動態頻道配置演算功能及使對這些演算之核心頻道配置功能之輸入獨立於信號訊息來改善及最佳化該已知快速動態頻道配置演算。更特別是,信號依賴(signal-dependent)之快速動態頻道配置呼叫允許控制(CAC)演算先前實施中之特定功能係藉由本發明改變為信號獨立(signal-independent),使該被改變功能於逸出機構實施中 可重複使用。本發明係以分時雙工方案中之層3脈絡來說明,但亦可應用而不受其他傳輸模式限制。 The present invention improves and optimizes the known fast dynamic channel configuration calculus by modulating/classifying fast dynamic channel configuration calculus functions and making input to the core channel configuration functions of these calculus independent of signal messages. More particularly, the signal-dependent fast dynamic channel configuration call admission control (CAC) calculus of a particular function in a previous implementation is changed to signal-independent by the present invention, making the changed function In the implementation of the institution reusable. The present invention is illustrated by layer 3 in the time division duplexing scheme, but can also be applied without being limited by other transmission modes.

第三代無線電信系統目前發展係需要最新及有效無線資源管理。本發明係提供無線資源管理中之快速動態頻道配置演算最佳實施。發明性方法可將快速動態頻道配置演算實施調變及修改為三個處理:事先編碼配置,編碼配置及事後編碼配置。事先編碼配置處理及事後編碼配置處理中之功能係信號依賴,而配置處理中之功能係信號獨立。事先編碼配置處理係被用來說明如何及從何處檢索來自輸入訊息及資料庫之資訊,及如何準備編碼配置處理所需之輸入。事後編碼配置處理係被用來決定何種資訊應被儲存於資料庫中,及何種資訊應被提供至輸出訊息。本發明之被調變功能可藉由即時服務及非即時服務中之其他無線資源管理演算來重複使用。 The current development of the third generation of wireless telecommunications systems requires up-to-date and effective radio resource management. The present invention provides an optimal implementation of fast dynamic channel configuration calculus in wireless resource management. The inventive method can modulate and modify the fast dynamic channel configuration algorithm into three processes: pre-coding configuration, encoding configuration, and post-coding configuration. The functions in the pre-coding configuration processing and the post-coding configuration processing are signal dependent, and the functions in the configuration processing are independent. The pre-coded configuration process is used to explain how and where to retrieve information from input messages and databases, and how to prepare the input required for the code configuration process. The post-coding configuration process is used to determine what information should be stored in the database and what information should be provided to the output message. The modulated functionality of the present invention can be reused by other wireless resource management algorithms in both immediate and non-instant services.

本發明係提供用於無線資源管理中之無線鏈結設立程序之快速動態頻道配置呼叫允許控制(CAC)演算實施。最佳化無線通信系統中之快速動態頻道配置呼叫允許控制(CAC)演算方法係包含事先編碼配置處理,信號獨立編碼配置處理及事後編碼配置處理。事先編碼配置處理包含接收及處理要求訊息及獲得系統量測及來自集中式資料庫之資訊。編碼配置處理係由檢查胞元中之可用編碼及產生可用時間槽之時間槽序列開始。編碼組係被指派至時間槽序列中之可用時間槽,其中成功指派係為解。干擾信號編碼功率(ISCP)係針對各為解被計算,且具有最低加權干擾信號編碼功率之為解係被選為最佳為解。事後編碼配置處理包含將配置資訊儲存於集中式資料庫中及建立回應訊息。 The present invention provides a fast dynamic channel configuration call admission control (CAC) calculus implementation for a wireless link setup procedure in wireless resource management. The fast dynamic channel configuration call admission control (CAC) calculus method in the optimized wireless communication system includes pre-coding configuration processing, signal independent coding configuration processing, and post-coding configuration processing. The pre-coding configuration process includes receiving and processing request messages and obtaining system measurements and information from a centralized database. The code configuration process begins by examining the available codes in the cell and the time slot sequence that produces the available time slots. The code group is assigned to the available time slots in the time slot sequence, where the success assignment is a solution. The Interference Signal Coding Power (ISCP) is calculated for each solution, and the solution with the lowest weighted interference signal coding power is selected as the best solution. Post-coding configuration processing involves storing configuration information in a centralized repository and establishing a response message.

用於無線通信系統中之快速動態頻道配置呼叫允許控制(CAC)方法係以接收及處理要求訊息以啟動呼叫允許控制(CAC)功能為開始。節點B量測,可用時間槽列表及編碼組 列表係被檢索自集中式資料庫。一組編碼係被配置至可用時間槽,而配置資訊係被儲存於集中式資料庫。回應訊息係被傳送編碼配置處理結果。 The Fast Dynamic Channel Configuration Call Admission Control (CAC) method for use in a wireless communication system begins by receiving and processing a request message to initiate a Call Admission Control (CAC) function. Node B measurement, available time slot list and coding group The list is retrieved from a centralized repository. A set of coding systems is configured into available time slots, and configuration information is stored in a centralized repository. The response message is transmitted by the encoding configuration processing result.

本發明提供實施無線資源管理中之快速動態頻道配置逸出機構之方法,其係藉由如下運作來增加系統效率。當以下三條件之一被滿足時,快速動態頻道配置逸出機構係被無線資源管理觸動以特定上鏈或下鏈無線傳輸/接收單元(WTRU)之編碼合成傳輸頻道(CCTrCH): The present invention provides a method for implementing a fast dynamic channel configuration escaping mechanism in wireless resource management, which increases system efficiency by operating as follows. When one of the following three conditions is met, the fast dynamic channel configuration escape mechanism is activated by the radio resource management to a specific uplink or downlink wireless transmit/receive unit (WTRU) coded composite transmission channel (CCTrCH):

1)藉由無線傳輸/接收單元(WTRU)量測之下鏈(DL)時間槽干擾信號編碼功率(ISCP)係大於門檻值。 1) The under-chain (DL) time slot interference signal coding power (ISCP) is greater than the threshold by the WTRU measurement.

2)藉由節點B量測之上鏈(UL)時間槽干擾信號編碼功率(ISCP)係大於門檻值。這兩個門檻值係為設計參數,且可為相同值或不同值。 2) The upper chain (UL) time slot interference signal coding power (ISCP) is measured by the Node B to be greater than the threshold value. These two threshold values are design parameters and can be the same value or different values.

3)節點B達到最大允許傳輸功率。 3) Node B reaches the maximum allowed transmission power.

實施無線通信系統中快速動態頻道配置逸出程序之方法係包含信號獨立編碼配置程序及事後編碼配置程序。事後編碼配置程序可接收觸動信號,從無線資源控制共享胞元資料庫獲得無線傳輸/接收單元(WTRU)量測及節點B量測,從集中式資料庫獲得胞元配置資訊及無線傳輸/接收單元(WTRU)資訊,決定將被重新指派之候選編碼合成傳輸頻道,及將被重新指派之候選編碼。編碼配置程序可檢查胞元中之可用編碼,檢查候選時間槽之被傳輸功率,檢查其他時間槽之干擾信號編碼功率(ISCP)是否低於候選時間槽者,產生可用時間槽所需之時間槽序列,指派候選編碼組至時間槽序列中之可用時間槽,其中成功指派係為解;計算各解之干擾信號編碼功率(ISCP);及選擇具有最低加權干擾信號編碼功率之解為最佳解。事後編碼配置程序可將重新配置資訊儲存於集中式資料庫並建立實體頻道重新配置要求訊息。 The method for implementing the fast dynamic channel configuration escape program in the wireless communication system includes a signal independent coding configuration program and a post-coding configuration program. The post-coding coding configuration program can receive the touch signal, obtain the WTRU measurement and the Node B measurement from the RRC resource sharing shared cell database, obtain the cell configuration information and the wireless transmission/reception from the centralized database. The unit (WTRU) information determines the candidate coded composite transmission channel to be reassigned, and the candidate code to be reassigned. The code configuration program can check the available codes in the cell, check the transmitted power of the candidate time slot, check whether the interference signal coding power (ISCP) of other time slots is lower than the candidate time slot, and generate the time slot required for the available time slot. Sequence, assigning candidate code groups to available time slots in the time slot sequence, wherein the successful assignment is a solution; calculating the interference signal coding power (ISCP) of each solution; and selecting the solution with the lowest weighted interference signal coding power as the optimal solution . The post-code configuration program stores the reconfiguration information in a centralized repository and establishes a physical channel reconfiguration request message.

實施無線通信系統中快速動態頻道配置逸出機構之方法係以接收及處理觸動信號來開始。無線傳輸/接收單元(WTRU)及節點B量測係被檢索自集中式資料庫,而決定將被重新指派之實體資源。編碼組係被配置至可用時間槽,且配置資訊係被儲存於集中式資料庫中。實體頻道重新配置要求訊息係被傳送,包含此無線傳輸/接收單元(WTRU)之新配置資訊。 The method of implementing a fast dynamic channel configuration escape mechanism in a wireless communication system begins by receiving and processing a touch signal. The WTRU and Node B metrics are retrieved from the centralized repository and determine the physical resources to be reassigned. The coding group is configured into an available time slot, and the configuration information is stored in a centralized repository. The physical channel reconfiguration request message is transmitted, including the new configuration information of the WTRU.

本發明提供實施無線資源管理中快速動態頻道配置背景干擾降低程序之方法。實施無線通信系統中快速動態頻道配置背景干擾降低程序之方法係包含事先編碼配置程序,信號獨立編碼配置程序及事後編碼配置程序。事先編碼配置程序可接收背景計時觸動信號;從無線資源控制共享胞元資料庫獲得無線傳輸/接收單元(WTRU)量測及節點B量測;從集中式資料庫獲得胞元及無線傳輸/接收單元(WTRU)資訊;決定將被重新指派之候選時間槽(一用於上鏈方向而一用於下鏈方向);從集中式資料庫檢索將被用於重新指派之可用時間槽;及決定將被重新指派之候選編碼。編碼配置程序可檢查胞元中之可用編碼組;檢查候選時間槽之傳輸功率;產生用於可用時間槽之時間槽序列;指派候選編碼組至時間槽序列中之可用時間槽,其中成功指派係為解;計算各解之干擾信號編碼功率(ISCP);及選擇具有最低加權干擾信號編碼功率之解為解。事後編碼配置程序可將重新配置資訊儲存於集中式資料庫並建立實體頻道重新配置要求訊息。 The present invention provides a method for implementing a fast dynamic channel configuration background interference reduction procedure in wireless resource management. The method for implementing the fast dynamic channel configuration background interference reduction program in the wireless communication system includes a pre-coding configuration program, a signal independent coding configuration program, and a post-coding configuration program. The pre-coding configuration program can receive the background timing trigger signal; obtain the WTRU measurement and the Node B measurement from the radio resource control shared cell database; obtain the cell and wireless transmission/receive from the centralized database Cell (WTRU) information; determine candidate time slots to be reassigned (one for the uplink direction and one for the downlink direction); retrieve the available time slots from the centralized repository that will be used for reassignment; and decide The candidate code to be reassigned. The encoding configuration program can check the available encoding groups in the cell; check the transmission power of the candidate time slots; generate a time slot sequence for the available time slots; assign the candidate coding groups to the available time slots in the time slot sequence, where the successful assignment is For the solution; calculate the interference signal coding power (ISCP) of each solution; and select the solution with the lowest weighted interference signal coding power as the solution. The post-code configuration program stores the reconfiguration information in a centralized repository and establishes a physical channel reconfiguration request message.

實施無線通信系統中快速動態頻道配置背景干擾降低程序之方法係包含事先編碼配置處理,信號獨立編碼配置處理及事後編碼配置處理。事先編碼配置處理係以接收計時觸動信號為開始。系統量測係被檢索自集中式資料庫。將被重新指派之實體資源係基於優質數來決定。編碼配置程序係以檢查胞元中之可用編碼組及產生用於可用時間槽之時間槽序列為開 始。編碼組係被指派至時間槽序列中之可用時間槽,其中成功指派係為解。干擾信號編碼功率(ISCP)係被用來計算各解且具有最低加權干擾信號編碼功率係被選擇為最佳解。重新配置資訊係被儲存於集中式資料庫。包含配置資訊之實體頻道重新配置要求訊息係被傳送。 The method for implementing the fast dynamic channel configuration background interference reduction program in the wireless communication system includes pre-coding configuration processing, signal independent coding configuration processing, and post-coding configuration processing. The pre-coding configuration process begins with receiving a timing trigger signal. The system measurement system was retrieved from a centralized database. The physical resources to be reassigned are based on the quality number. The code configuration program is to check the available code groups in the cell and generate a time slot sequence for the available time slots. beginning. The code group is assigned to the available time slots in the time slot sequence, where the success assignment is a solution. Interference Signal Coding Power (ISCP) is used to calculate each solution and has the lowest weighted interfering signal coding power system selected as the optimal solution. The reconfiguration information is stored in a centralized repository. The physical channel reconfiguration request message containing the configuration information is transmitted.

本發明係提供實施無線資源管理中之無線鏈結附加程序之快速動態頻道配置呼叫允許控制(CAC)演算。實施無線通信系統中之快速動態頻道配置呼叫允許控制(CAC)演算方法係包含事先編碼配置處理,信號獨立編碼配置處理及事後編碼配置處理。事先編碼配置處理包含接收及處理無線鏈結附加要求訊息及從集中式資料庫檢索系統資訊。編碼配置處理係包括檢查胞元中之可用編碼組;產生時間槽序列;指派編碼組至時間槽序列中之可用時間槽,其中成功指派係為解;計算各解之干擾信號編碼功率(ISCP);及選擇具有最低加權干擾信號編碼功率(ISCP)之解為最佳解。事後編碼配置處理包含將配置資訊儲存於集中式資料庫中及建立無線鏈結附加回應訊息。 The present invention provides a fast dynamic channel configuration call admission control (CAC) calculus that implements a wireless link add-on procedure in wireless resource management. The fast dynamic channel configuration call admission control (CAC) algorithm in the implementation of the wireless communication system includes pre-coding configuration processing, signal independent coding configuration processing, and post-coding configuration processing. The pre-coding configuration process includes receiving and processing the wireless link attach request message and retrieving the system information from the centralized database. The encoding configuration processing includes checking the available encoding groups in the cells; generating a time slot sequence; assigning the encoding groups to the available time slots in the time slot sequence, wherein the successful assignment is a solution; calculating the interference signal encoding power (ISCP) of each solution And select the solution with the lowest weighted interference signal coding power (ISCP) as the best solution. Post-coding configuration processing involves storing configuration information in a centralized repository and establishing a wireless link attachment response message.

用於無線通信系統中之無線鏈結附加之快速動態頻道配置呼叫允許控制(CAC)演算方法係以接收無線鏈結附加要求訊息以啟動呼叫允許控制(CAC)功能為開始。要求訊息係被處理,且可用時間槽列表及編碼組列表係被檢索自集中式資料庫。編碼組係被配置至新胞元中之可用時間槽,而配置資訊係被儲存於集中式資料庫。無線鏈結附加回應訊息係被傳送編碼配置處理結果。 The Fast Dynamic Channel Configuration Call Admission Control (CAC) algorithm for wireless link attachment in wireless communication systems begins by receiving a wireless link attach request message to initiate a Call Admission Control (CAC) function. The request message is processed, and the list of available time slots and the list of code groups are retrieved from the centralized database. The code group is configured into the available time slots in the new cell, and the configuration information is stored in the centralized database. The wireless link attach response message is transmitted by the code configuration processing result.

本發明係提供實施無線資源管理中之無線鏈結重新配置程序之快速動態頻道配置呼叫允許控制(CAC)演算。實施無線通信系統中之快速動態頻道配置呼叫允許控制(CAC)演算方法係包含事先編碼配置處理,信號獨立編碼配置處理及事後編碼配置處理。事先編碼配置處理包含接收及處理要求訊息 及從集中式資料庫檢索系統資訊。編碼配置處理係包括檢查胞元中之可用編碼組;產生時間槽序列;指派編碼組至時間槽序列中之可用時間槽,其中成功指派係為解;計算各解之干擾信號編碼功率(ISCP);及選擇具有最低加權干擾信號編碼功率之解為最佳解。事後編碼配置處理包含將配置資訊儲存於集中式資料庫中及建立回應訊息。 The present invention provides a fast dynamic channel configuration call admission control (CAC) calculus that implements a wireless link reconfiguration procedure in wireless resource management. The fast dynamic channel configuration call admission control (CAC) algorithm in the implementation of the wireless communication system includes pre-coding configuration processing, signal independent coding configuration processing, and post-coding configuration processing. The pre-coding configuration process includes receiving and processing request messages. And retrieve system information from a centralized database. The encoding configuration processing includes checking the available encoding groups in the cells; generating a time slot sequence; assigning the encoding groups to the available time slots in the time slot sequence, wherein the successful assignment is a solution; calculating the interference signal encoding power (ISCP) of each solution And selecting the solution with the lowest weighted interference signal coding power as the optimal solution. Post-coding configuration processing involves storing configuration information in a centralized repository and establishing a response message.

用於無線通信系統中之無線鏈結重新配置之快速動態頻道配置呼叫允許控制(CAC)演算方法係以接收要求訊息以啟動呼叫允許控制(CAC)功能為開始。要求訊息係被處理,且可用時間槽列表及編碼組列表係被檢索自集中式資料庫。編碼組係被配置至可用時間槽,而配置資訊係被儲存於集中式資料庫。具編碼配置處理結果之回應訊息係接著被傳送。 A Fast Dynamic Channel Configuration Call Admission Control (CAC) algorithm for wireless link reconfiguration in a wireless communication system begins by receiving a request message to initiate a Call Admission Control (CAC) function. The request message is processed, and the list of available time slots and the list of code groups are retrieved from the centralized database. The code group is configured to the available time slot, and the configuration information is stored in the centralized database. A response message with the result of the encoding configuration process is then transmitted.

本發明可以下列較佳實施例說明及附圖而得到更詳細了解。 The invention can be understood in more detail by the following description of the preferred embodiments and the accompanying drawings.

CAC‧‧‧呼叫允許控制 CAC‧‧‧ Call Admission Control

WTRU‧‧‧無線傳輸/接收單元 WTRU‧‧‧Wireless Transmission/Reception Unit

RRC‧‧‧無線資源控制 RRC‧‧‧Wireless Resource Control

RAN‧‧‧無線存取網路 RAN‧‧‧Wireless Access Network

RAB‧‧‧無線存取承載 RAB‧‧‧Wireless Access Bearer

C-RNC‧‧‧控制無線網路控制器 C-RNC‧‧‧Control wireless network controller

TDD‧‧‧分時雙工 TDD‧‧‧time division duplex

ISCP‧‧‧干擾信號編碼功率 ISCP‧‧‧Interference signal coding power

CCTrCH‧‧‧編碼合成傳輸頻道 CCTrCH‧‧‧Coded Synthetic Transmission Channel

TFCI‧‧‧傳輸格式編碼指標 TFCI‧‧‧Transport Format Coding Indicators

第一圖為無線鏈結設立之快速動態頻道配置呼叫允許控制(CAC)演算概觀。 The first picture shows an overview of the Fast Dynamic Channel Configuration Call Admission Control (CAC) calculus established by the wireless link.

第二a-c圖為第一圖所示無線鏈結設立之快速動態頻道配置呼叫允許控制(CAC)演算流程圖。 The second a-c diagram is a flow chart of the fast dynamic channel configuration call admission control (CAC) calculation established by the wireless link shown in the first figure.

第三a及三b圖為第二圖所示快速動態頻道配置呼叫允許控制(CAC)演算之頻道配置功能流程圖。 The third and third b diagrams are flow chart of the channel configuration function of the fast dynamic channel configuration call admission control (CAC) calculus shown in the second figure.

第四圖為依據本發明之快速動態頻道配置逸出程序概觀。 The fourth figure is an overview of the fast dynamic channel configuration escape procedure in accordance with the present invention.

第五a及五b圖為第四圖所示快速動態頻道配置逸出程序之流程圖。 The fifth and fifth b diagrams are flow charts of the fast dynamic channel configuration escape procedure shown in the fourth figure.

第六圖顯示第五a及五b圖所示快速動態頻道配置逸出程序之頻道配置功能流程圖之第一部份。 The sixth figure shows the first part of the flow chart configuration function flow chart of the fast dynamic channel configuration escape program shown in the fifth and fifth b-pictures.

第七圖為依據本發明之快速動態頻道配置背景干擾降低程序概觀。 The seventh figure is an overview of the background resolution reduction procedure for fast dynamic channel configuration in accordance with the present invention.

第八a及八b圖顯示第七圖所示快速動態頻道配置背景干擾降低程序之流程圖。 Figures 8a and 8b show a flow chart of the fast dynamic channel configuration background interference reduction procedure shown in the seventh figure.

第九圖為依據本發明之無線鏈結附加快速動態頻道配置呼叫允許控制(CAC)程序概觀。 The ninth diagram is an overview of a wireless link add-on fast dynamic channel configuration call admission control (CAC) procedure in accordance with the present invention.

第十a-c圖為第九圖所示快速動態頻道配置呼叫允許控制(CAC)程序流程圖。 The tenth a-c diagram is a flow chart of the fast dynamic channel configuration call admission control (CAC) program shown in the ninth figure.

第十一圖為依據本發明之無線鏈結重新配置快速動態頻道配置呼叫允許控制(CAC)程序概觀。 Figure 11 is a diagram of a wireless link reconfiguration fast dynamic channel configuration call admission control (CAC) procedure in accordance with the present invention.

第十二圖為第十一圖所示快速動態頻道配置呼叫允許控制(CAC)程序流程圖。 Figure 12 is a flow chart of the fast dynamic channel configuration call admission control (CAC) program shown in Figure 11.

第十三a-c圖為第十二圖所示無線鏈結重新配置之快速動態頻道配置呼叫允許控制(CAC)程序之實體頻道配置程序流程圖。 The thirteenth a-c diagram is a flow chart of the physical channel configuration procedure of the fast dynamic channel configuration call admission control (CAC) program of the wireless link reconfiguration shown in FIG.

無線鏈結設立之呼叫允許控制(CAC) Call Admission Control (CAC) established by wireless link

無線鏈結設立程序102之快速動態頻道配置呼叫允許控制(CAC)演算概觀100係被顯示於第一圖。快速動態頻道配置呼叫允許控制(CAC)演算102主要功能係包含三部份:事先編碼配置處理104,編碼配置處理106及事後編碼配置處理108。事先編碼配置處理104可從無線鏈結設立要求訊息110讀取無線傳輸/接收單元(WTRU)量測,從無線資源控制共享胞元資料庫112讀取節點B量測,及替編碼配置準備輸入(來自無線資源管理胞元資料庫116之可用時間槽列表及來自操作及維護(OAM)無線資源管理表資料庫114之編碼組列表)。 The Fast Dynamic Channel Configuration Call Admission Control (CAC) Logic Overview 100 of the Wireless Link Setup Procedure 102 is shown in the first figure. The Fast Dynamic Channel Configuration Call Admission Control (CAC) Logic 102 main function consists of three parts: a pre-coding configuration process 104, an encoding configuration process 106, and a post-coding configuration process 108. The pre-coding configuration process 104 can read the WTRU measurements from the wireless link setup request message 110, the Node B measurements from the RRC shared cell repository 112, and prepare the inputs for the code configuration. (List of available time slots from the Radio Resource Management Cell Library 116 and a list of coded groups from the Operation and Maintenance (OAM) Radio Resource Management Table Library 114).

編碼配置處理106可檢查胞元中之可用編碼,產生 時間槽序列,找尋編碼組之最佳解(指派編碼組中之編碼至可用時間槽),及從無線資源管理胞元資料庫116之編碼向量配置該集中式編碼。事後編碼配置處理108係負責建立無線傳輸/接收單元(WTRU)於無線資源管理無線傳輸/接收單元(WTRU)資料庫118中,記錄被配置實體頻道於無線資源管理無線傳輸/接收單元(WTRU)資料庫118中,記錄實體頻道參數及功率控制資訊於無線鏈結設立回應訊息120中。 Encoding configuration process 106 can check for available encoding in the cell, resulting in The time slot sequence looks for the best solution for the code group (assigning the code in the code group to the available time slot) and configuring the centralized code from the code vector of the radio resource management cell library 116. The post-coding configuration process 108 is responsible for establishing a wireless transmit/receive unit (WTRU) in the radio resource management wireless transmit/receive unit (WTRU) database 118, recording the configured physical channel to the radio resource management radio transmission/reception unit (WTRU). In the database 118, physical channel parameters and power control information are recorded in the wireless link setup response message 120.

除了處理及資料庫間之資料交換,資料交換亦直接發生於處理之間。無線傳輸/接收單元(WTRU)量測,節點B量測,胞元中之可用時間槽列表,特定資料速率之編碼組列表及無線傳輸/接收單元(WTRU)性能資訊,係從事先編碼配置處理104被傳送至編碼配置處理106。實體頻道資訊(時間槽列表及各時間槽中之頻道化編碼)係從編碼配置處理106被傳送至事後編碼配置處理108。 In addition to processing and data exchange between databases, data exchange also occurs directly between processing. WTRU measurement, Node B measurement, list of available time slots in cells, code group list for specific data rates, and WTRU performance information, from pre-coding configuration processing 104 is passed to encoding configuration process 106. The physical channel information (time slot list and channelization code in each time slot) is transmitted from the code configuration process 106 to the post-code configuration process 108.

本發明中,快速動態頻道配置呼叫允許控制(CAC)演算102之快速動態頻道配置呼叫允許控制(CAC)演算功能係被調變為兩組功能:輸入為信號訊息部份之信號依賴功能,及輸入獨立於信號訊息之信號獨立功能。分隔信號依賴功能及信號獨立功能之目的係增加信號獨立功能之重複使用性。事先編碼配置處理104及事後編碼配置處理108之功能係為信號依賴功能。相對地,編碼配置處理106之功能係為信號獨立功能。應注意編碼配置處理106之功能可藉由如交換,快速動態頻道配置逸出機構及快速動態頻道配置背景干擾降低演算之其他無線資源管理實施中之其他程序來重複使用。 In the present invention, the fast dynamic channel configuration call admission control (CAC) calculus 102 fast dynamic channel configuration call admission control (CAC) calculus function is modulated into two sets of functions: the input is a signal dependent function of the signal portion, and Enter a signal independent function that is independent of the signal message. The purpose of separating the signal dependent function and the signal independent function is to increase the reusability of the signal independent function. The functions of the pre-encoding configuration processing 104 and the post-coding configuration processing 108 are signal dependent functions. In contrast, the functionality of the encoding configuration process 106 is a signal independent function. It should be noted that the functionality of the code configuration process 106 can be reused by other programs in other wireless resource management implementations such as switching, fast dynamic channel configuration escape mechanisms, and fast dynamic channel configuration background interference reduction algorithms.

無線鏈結設立之快速動態頻道配置呼叫允許控制(CAC)演算功能之流程圖係被顯示於第二a-c及三a-b圖。第二a-c圖顯示無線鏈結設立之快速動態頻道配置呼叫允許控制(CAC)演算之主要介面功能200。功能200係藉由獲得無線鏈 結設立要求訊息(此後被稱為"要求訊息";步驟202)及從要求訊息擷取參數來開始(步驟204)。要求訊息係包含編碼合成傳輸頻道(CCTrCH)資訊,專用頻道(DCH)資訊,具有或沒有無線傳輸/接收單元(WTRU)量測之無線鏈結資訊及無線傳輸/接收單元(WTRU)性能資訊。被擷取自要求訊息之參數係包含無線傳輸/接收單元(WTRU)識別,胞元識別,無線鏈結識別,及無線傳輸/接收單元(WTRU)性能資訊(每時間槽最大實體頻道數及每框最大時間槽數)。 A flow chart of the fast dynamic channel configuration call admission control (CAC) calculus function set up by the wireless link is shown in the second a-c and three a-b diagrams. The second a-c diagram shows the main interface functionality 200 of the Fast Dynamic Channel Configuration Call Admission Control (CAC) calculus established by the wireless link. Function 200 is achieved by obtaining a wireless chain A setup request message (hereinafter referred to as a "request message"; step 202) and starting from the request message extraction parameter (step 204). The request message includes Coded Synthetic Transport Channel (CCTrCH) information, Dedicated Channel (DCH) information, with or without WTRU measurement of wireless link information and WTRU performance information. The parameters retrieved from the request message include WTRU identification, cell identification, wireless link identification, and WTRU performance information (maximum number of physical channels per time slot and per The maximum number of slots in the box).

無線資源管理胞元資料庫之入口識別係被獲得(步驟206)。接著,決定包含下鏈干擾信號編碼功率(DL ISCP)之無線傳輸/接收單元(WTRU)量測是否被包含於要求訊息中(步驟208)。若無線傳輸/接收單元(WTRU)量測不被包含於要求訊息中,則檢查以決定是否所有專用頻道均為非即時(NRT;步驟210及212)。若所有專用頻道均為即時,則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。失敗情況意指無線傳輸/接收單元(WTRU)無實體資源可用。應注意所有僅為即時之專用頻道並非失敗情況。當沒有無線傳輸/接收單元(WTRU)量測及所有專用頻道均為即時時係為失敗情況。 The entry identification of the radio resource management cell database is obtained (step 206). Next, a determination is made as to whether the WTRU measurement including the downlink interference signal coding power (DL ISCP) is included in the request message (step 208). If the WTRU measurement is not included in the request message, a check is made to determine if all of the dedicated channels are non-instant (NRT; steps 210 and 212). If all of the dedicated channels are instant, the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216). A failure condition means that no wireless resource/receiving unit (WTRU) is available. It should be noted that all dedicated channels that are only instant are not a failure. A failure condition occurs when there is no WTRU measurement and all dedicated channels are instantaneous.

若所有專用頻道均為非即時(步驟212),則低速率暫時專用頻道係被配置用於目前編碼合成傳輸頻道(CCTrCH)(步驟218)。頻道被配置後,係決定資源配置是否成功(步驟220)。若資源配置不成功,則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。若資源配置成功(步驟220),則無線傳輸/接收單元(WTRU)入口係被建立且無線傳輸/接收單元(WTRU)資訊及實體頻道參數係被記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫中(步驟222)。被記錄至無線傳輸/接收單元(WTRU)入口之資訊係包含無線傳輸/接收單元(WTRU)識別,交易識別,上鏈無線傳輸/接收 單元(WTRU)性能資訊,下鏈無線傳輸/接收單元(WTRU)性能資訊,及無線鏈結資訊。上鏈無線傳輸/接收單元(WTRU)性能資訊包含每框最大時間槽數及每時間槽最大上鏈實體頻道數。下鏈無線傳輸/接收單元(WTRU)性能資訊包含每框最大時間槽數及每時間槽最大下鏈實體頻道數。無線鏈結資訊包含無線鏈結識別,胞元識別,上鏈編碼合成傳輸頻道資訊及下鏈編碼合成傳輸頻道資訊。編碼合成傳輸頻道(CCTrCH)資訊包含編碼合成傳輸頻道(CCTrCH)識別,編碼合成傳輸頻道(CCTrCH)狀態,編碼合成傳輸頻道(CCTrCH)信號對干擾比率(SIR)目標,保證資料速率,允許資料速率,及專用實體頻道(DPCH)資訊。專用實體頻道資訊包含時間槽列表,訓練序列(midamble)移位及叢發類型,傳輸格式編碼指標(TFCI)呈現及編碼資訊。編碼資訊包含頻道化編碼,編碼使用狀態,專用實體頻道識別及編碼信號對干擾目標。 If all of the dedicated channels are non-instant (step 212), the low rate temporary dedicated channel is configured for the current coded composite transmission channel (CCTrCH) (step 218). After the channel is configured, it is determined whether the resource configuration is successful (step 220). If the resource configuration is unsuccessful, the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216). If the resource configuration is successful (step 220), the WTRU entry is established and the WTRU information and physical channel parameters are recorded in the RRC radio transmission/reception unit (WTRU). ) in the database (step 222). Information recorded to the WTRU entry includes WTRU identification, transaction identification, uplink wireless transmission/reception Cell (WTRU) performance information, downlink WTRU performance information, and wireless link information. The uplink wireless transmit/receive unit (WTRU) performance information includes the maximum number of slots per frame and the maximum number of uplink physical channels per slot. The downlink wireless transmit/receive unit (WTRU) performance information includes the maximum number of slots per frame and the maximum number of downlink physical channels per slot. The wireless link information includes wireless link identification, cell identification, uplink coded composite transmission channel information, and downlink coded composite transmission channel information. The coded composite transmission channel (CCTrCH) information includes a coded composite transmission channel (CCTrCH) identification, a coded composite transmission channel (CCTrCH) state, a coded composite transmission channel (CCTrCH) signal to interference ratio (SIR) target, a guaranteed data rate, and a data rate allowed. , and Dedicated Physical Channel (DPCH) information. The dedicated entity channel information includes a time slot list, a training sequence (midamble) shift and burst type, a transport format coding indicator (TFCI) presentation and encoding information. The coding information includes channelization coding, coding usage status, dedicated physical channel identification and coding signals for interference targets.

接著,實體頻道資訊及功率控制資訊係被放入無線鏈結設立回應訊息(步驟224),狀態旗標係被設定標示成功情況(步驟226),且功能終止(步驟216)。實體頻道資訊包含各時間槽中之時間槽列表及頻道化編碼。時間槽資訊包含重複週期及重複長度。功率控制資訊包含上鏈目標信號對干擾比率,最大上鏈信號對干擾比率,最小上鏈信號對干擾比率,啟始下鏈傳輸功率,最小下鏈傳輸功率,及最大允許上鏈傳輸功率。本發明一實施中,單資料結構係被用於要求訊息及回應訊息,因為這兩個訊息係包含大量共用資訊。 Next, the physical channel information and power control information are placed in the wireless link setup response message (step 224), the status flag is set to indicate the success (step 226), and the function is terminated (step 216). The physical channel information includes a list of time slots and channelization codes in each time slot. The time slot information includes the repetition period and the repetition length. The power control information includes the uplink target signal to interference ratio, the maximum uplink signal to interference ratio, the minimum uplink signal to interference ratio, the start downlink transmission power, the minimum downlink transmission power, and the maximum allowable uplink transmission power. In one implementation of the present invention, a single data structure is used for request messages and response messages because the two messages contain a large amount of shared information.

若要求訊息中具有可用無線傳輸/接收單元(WTRU)量測(步驟208),則無線傳輸/接收單元(WTRU)量測係被檢索自要求訊息,而節點B量測係被獲得自無線資源控制共享胞元資料庫(步驟228)。節點B量測包含共用量測及專用量測。節點B共用量測包含上鏈干擾信號編碼功率及下鏈傳輸載波 功率。節點B專用量測包含下鏈傳輸編碼功率。快速下鏈編碼合成傳輸頻道係被選擇(步驟230),且獲得該被選擇編碼合成傳輸頻道(CCTrCH)之服務類型(步驟232)。若服務類型為即時(RT;步驟234),則胞元中之可用時間槽係被決定(步驟236)。若無時間槽可用(步驟238),則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。 If there is available WTRU measurement in the request message (step 208), the WTRU measurement is retrieved from the request message and the Node B measurement is obtained from the radio resource. The shared cell metadata library is controlled (step 228). The Node B measurement includes a shared measurement and a dedicated measurement. The Node B shared measurement includes the uplink interference signal coding power and the downlink transmission carrier. power. The Node B dedicated measurement includes the downlink transmission coding power. The fast downlink encoded composite transmission channel is selected (step 230) and the service type of the selected encoded composite transmission channel (CCTrCH) is obtained (step 232). If the service type is immediate (RT; step 234), the available time slot in the cell is determined (step 236). If no time slot is available (step 238), the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216).

若有時間槽可用(步驟238),則被要求之資料速率係被計算(步驟240)。被計算資料速率之編碼組係被獲得(步驟242),而目前編碼合成傳輸頻道(CCTrCH)之實體頻道(時間槽及編碼)係被配置,而最佳解若被找到則被記錄之(步驟244)。步驟244中之配置功能係以以下第三a及三b圖做更詳細討論。若資源配置失敗(步驟246),則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。 If a time slot is available (step 238), the requested data rate is calculated (step 240). The coded group of calculated data rates is obtained (step 242), while the current physical channel (time slot and code) of the coded composite transmission channel (CCTrCH) is configured, and the best solution is recorded if found (steps) 244). The configuration functions in step 244 are discussed in more detail in the following third and third b diagrams. If the resource configuration fails (step 246), the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216).

若資源配置成功(步驟246),則決定是否具有將被檢查之附加編碼合成傳輸頻道(步驟248)。若資源配置成功(步驟246),則決定是否具有將被檢查之附加編碼合成傳輸頻道(步驟248)。若具有將被檢查之附加編碼合成傳輸頻道,則下一個編碼合成傳輸頻道(CCTrCH)係被選擇(步驟250),而功能繼續於步驟232。若無將被檢查之附加編碼合成傳輸頻道(步驟248),則決定上鏈編碼合成傳輸頻道是否已被檢查(步驟252)。若上鏈編碼合成傳輸頻道尚未被檢查,則第一上鏈編碼合成傳輸頻道係被選擇(步驟254),而功能繼續於步驟232。若所有上鏈編碼合成傳輸頻道均已被考慮(步驟252),則功能如上述繼續於步驟222。 If the resource configuration is successful (step 246), then it is determined if there is an additional coded composite transmission channel to be checked (step 248). If the resource configuration is successful (step 246), then it is determined if there is an additional coded composite transmission channel to be checked (step 248). If there is an additional coded composite transmission channel to be examined, the next coded composite transmission channel (CCTrCH) is selected (step 250) and the function continues at step 232. If there is no additional coded composite transmission channel to be checked (step 248), it is determined if the uplink encoded composite transmission channel has been checked (step 252). If the uplink encoded composite transmission channel has not been checked, the first uplink encoded composite transmission channel is selected (step 254) and the function continues at step 232. If all of the uplink coded composite transmission channels have been considered (step 252), then the function continues as in step 222 as described above.

若服務類型為非即時(步驟234),則胞元中之可用時間槽係被決定(步驟256)。若無可用時間槽(步驟258),則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。 If the service type is non-instant (step 234), the available time slot in the cell is determined (step 256). If no time slot is available (step 258), the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216).

若具有可用時間槽(步驟258),則適用於非即時服務之所有資料速率係被決定(步驟260),且最高資料速率係被選擇(步驟262)。被選擇資料速率之編碼組係被獲得(步驟264),現行編碼合成傳輸頻道(CCTrCH)之正常暫時專用頻道係被配置,而最佳解若被找到則被記錄(步驟266)。應注意步驟244及266本質上相同;非即時服務中,專用頻道係為暫時。 If there is an available time slot (step 258), then all data rates applicable to the non-instant service are determined (step 260) and the highest data rate is selected (step 262). The coded set of selected data rates is obtained (step 264), the normal temporary dedicated channel of the current coded composite transmission channel (CCTrCH) is configured, and the best solution is recorded if found (step 266). It should be noted that steps 244 and 266 are essentially the same; in non-instant service, the dedicated channel is temporary.

若資源配置失敗(步驟268),則決定是否具有將被檢查之附加資料速率(步驟270)。若無將被檢查之其他資料速率,則狀態旗標係被設定標示為失敗情況(步驟214)且功能終止(步驟216)。若資源配置成功(步驟268),則功能如上述繼續於步驟248。 If the resource configuration fails (step 268), it is determined if there is an additional data rate to be checked (step 270). If there are no other data rates to be checked, the status flag is set to indicate a failure condition (step 214) and the function terminates (step 216). If the resource configuration is successful (step 268), then the function continues as in step 248 as described above.

應注意步驟230,252及254中,任一方向(下鏈或上鏈)可首先被執行。如上述,下鏈方向係優先於上鏈方向被檢查。功能200將以相同方式操作,否則上鏈將優先下鏈被檢查。 It should be noted that in either of steps 230, 252 and 254, either direction (downlink or winding) may be performed first. As described above, the lower chain direction is checked in preference to the winding direction. Function 200 will operate in the same manner, otherwise the winding will prioritize the lower chain to be checked.

步驟244及266係有關呼叫快速動態頻道配置演算來配置實體頻道。此核心功能300係為信號獨立且以第三a及b圖做說明。功能300係以接收編碼組及可用時間槽作為輸入而開始(步驟302)。第一編碼組係被選擇(步驟304),且決定編碼組是否可用於胞元中(步驟306及308)。若該被選擇編碼組於胞元中不可用,則決定是否具有將被檢查之更多編碼組(步驟310)。若具有更多編碼組,則下一個編碼組係被選擇(步驟312),而功能繼續於步驟306。若無編碼組,則此標示失敗情況,狀態旗標係被設定標示無解(步驟314)且功能終止(步驟316)。 Steps 244 and 266 are related to the call fast dynamic channel configuration algorithm to configure the physical channel. This core function 300 is signal independent and is illustrated in the third a and b diagrams. Function 300 begins with receiving a code group and an available time slot as input (step 302). The first coding group is selected (step 304) and it is determined whether the coding group is available for use in the cell (steps 306 and 308). If the selected code set is not available in the cell, then it is determined if there are more code groups to be checked (step 310). If there are more code groups, the next code group is selected (step 312) and the function continues at step 306. If there is no code group, this indicates a failure condition, the status flag is set to indicate no solution (step 314) and the function is terminated (step 316).

若該被選擇編碼組於胞元中可用(步驟308),則編碼合成傳輸頻道(CCTrCH)中之編碼組所需之資源單元係被計算(步驟318)。時間槽序列係被產生(步驟320),且第一時間槽序列係被選擇(步驟322)。下鏈或上鏈方向接著被決定(步驟 350)。若鏈結方向為下鏈,則嘗試指派現行下鏈編碼組進入現行時間槽序列中之可用時間槽(步驟352)。若鏈結方向為上鏈(步驟350),則嘗試指派現行上鏈編碼組進入現行時間槽序列中之可用時間槽(步驟354)。本發明替代實施例中(無圖示),步驟350可被刪除,且步驟352及354可被結合為單步驟來提供附帶最適化。 If the selected code group is available in the cell (step 308), the resource elements required to encode the code group in the composite transport channel (CCTrCH) are calculated (step 318). A time slot sequence is generated (step 320) and the first time slot sequence is selected (step 322). The lower chain or the winding direction is then determined (step 350). If the link direction is a downlink, an attempt is made to assign the current downlink code group to the available time slot in the current time slot sequence (step 352). If the link direction is up chained (step 350), an attempt is made to assign the current uplink code group to the available time slot in the current time slot sequence (step 354). In an alternate embodiment of the invention (not shown), step 350 can be deleted, and steps 352 and 354 can be combined into a single step to provide an incidental optimization.

嘗試指派現行編碼組至現行時間槽序列中之可用時間槽(步驟352,354)後,係決定指派解是否已被找到(步驟356),標示編碼組被成功指派至現行時間槽序列中之可用時間槽。若解被找到,則解之干擾信號編碼功率(ISCP)係被決定,而具有最低加權干擾信號編碼功率之解係被視為最佳解且被記錄(步驟358)。若解沒有被找到,則步驟358被跳過。 After attempting to assign the current code group to the available time slot in the current time slot sequence (steps 352, 354), it is determined whether the assignment solution has been found (step 356), indicating that the code group was successfully assigned to the current time slot sequence. Time slot. If the solution is found, the interfering signal coding power (ISCP) of the solution is determined, and the solution with the lowest weighted interfering signal coding power is considered to be the best solution and recorded (step 358). If the solution is not found, then step 358 is skipped.

接著,決定是否具有任何將被考慮之附加時間槽序列(步驟360)。若具有附加時間槽序列,則下一個時間槽序列係被選擇(步驟362),而功能繼續於步驟350。若無附加時間槽序列(步驟360),則決定最佳解是否已被找到(步驟364)。若最佳解沒有被找到,則功能繼續於呼叫功能中之點C(也就是步驟350被進入之功能)。若最佳解被找到,則狀態旗標係被設定標示成功指派(步驟366)且功能終止(步驟316)。 Next, a decision is made as to whether there are any additional time slot sequences to be considered (step 360). If there is an additional time slot sequence, the next time slot sequence is selected (step 362) and the function continues at step 350. If there is no additional time slot sequence (step 360), it is determined if the best solution has been found (step 364). If the best solution is not found, then the function continues at point C in the call function (i.e., the function that step 350 is entered). If the best solution is found, the status flag is set to indicate successful assignment (step 366) and the function terminates (step 316).

快速動態頻道配置呼叫允許控制(CAC)演算之過去實施中,功能352及354係為信號依賴。本發明中,這兩個功能係被修改成為信號獨立功能。被用於這兩個功能之相關功能亦被修改成為信號獨立功能。因為功能352,354之輸入係獨立於信號訊息(如輸入訊息),所以功能352,354可被其他無線資源管理程序使用。應注意上述快速動態頻道配置呼叫允許控制(CAC)演算實施係為例證且可被進一步最佳化。 In the past implementation of Fast Dynamic Channel Configuration Call Admission Control (CAC) calculus, functions 352 and 354 were signal dependent. In the present invention, these two functions are modified to be signal independent functions. The functions used for these two functions have also been modified to become signal independent functions. Because the inputs to functions 352, 354 are independent of signal messages (e.g., input messages), functions 352, 354 can be used by other RRC programs. It should be noted that the above described fast dynamic channel configuration call admission control (CAC) calculus implementation is exemplary and can be further optimized.

逸出 Escape

快速動態頻道配置逸出程序402之概觀400係被顯示於第四圖。快速動態頻道配置逸出程序402之主要功能係包含三個部份:事先編碼配置處理404,編碼配置處理406及事後編碼配置處理408。事先編碼配置處理404係開始於接收量測觸動信號410。具有兩個量測觸動信號,無線傳輸/接收單元(WTRU)量測信號及節點B量測觸動信號。無線傳輸/接收單元(WTRU)量測信號包含無線傳輸/接收單元(WTRU)識別及時間槽數列表,而節點B量測觸動信號包含時間槽數。逸出程序開始於接收無線傳輸/接收單元(WTRU)量測信號或節點B量測觸動信號。 An overview 400 of the fast dynamic channel configuration escape program 402 is shown in the fourth diagram. The main function of the fast dynamic channel configuration escape program 402 consists of three parts: a pre-encoding configuration process 404, an encoding configuration process 406, and a post-embler configuration process 408. The pre-coded configuration process 404 begins with receiving the measurement touch signal 410. There are two measurement touch signals, a wireless transmit/receive unit (WTRU) measurement signal and a node B measurement touch signal. The WTRU measurement signal includes a WTRU identification and time slot list, and the Node B measurement touch signal includes a time slot number. The escape procedure begins with receiving a WTRU measurement signal or a Node B measurement touch signal.

事先編碼配置處理404可從無線資源控制共享胞元資料庫412獲得節點B量測及無線傳輸/接收單元(WTRU)量測,從無線資源管理胞元資料庫416獲得胞元配置資訊,從無線資源管理無線傳輸/接收單元(WTRU)資料庫418獲得無線傳輸/接收單元(WTRU)性能資訊,決定將被重新指派之編碼合成傳輸頻道(CCTrCH),計算無線傳輸/接收單元(WTRU)路徑損失,決定將被重新指派之候選編碼組,及獲得可用時間槽之列表。事先編碼配置處理404可準備用於編碼配置處理406之輸入。 The pre-encoding configuration process 404 can obtain the Node B measurement and the WTRU measurement from the RRC shared cell repository 412, and obtain the cell configuration information from the RRC resource library 416, from the wireless A resource management wireless transmit/receive unit (WTRU) database 418 obtains WTRU performance information, determines a coded composite transmission channel (CCTrCH) to be reassigned, and calculates a wireless transmit/receive unit (WTRU) path loss. , determine the candidate code groups that will be reassigned, and get a list of available time slots. The pre-encoding configuration process 404 can prepare input for the encoding configuration process 406.

編碼配置處理406可檢查胞元中之編碼可用性,檢查候選時間槽之傳輸(Tx)功率,檢查其他時間槽之干擾信號編碼功率(ISCP)是否低於該候選時間槽之干擾信號編碼功率(ISCP),產生可用時間槽之時間槽序列,搜尋時間槽序列中之編碼組之指派解(藉由指派候選編碼組至可用時間槽),及選擇具有最低加權干擾信號編碼功率之解為最佳解。事後編碼配置處理408係負責將最新配置實體頻道記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫418中,及將實體頻道資訊填 入實體頻道重新配置要求訊息420中。 The encoding configuration process 406 can check the encoding availability in the cell, check the transmission (Tx) power of the candidate time slot, and check whether the interference signal coding power (ISCP) of the other time slots is lower than the interference signal coding power of the candidate time slot (ISCP). Generating a time slot sequence of available time slots, searching for an assigned solution of the coded group in the time slot sequence (by assigning candidate code groups to available time slots), and selecting the solution with the lowest weighted interference signal coding power as the optimal solution . The post-coding configuration process 408 is responsible for recording the latest configured physical channel in the WTRU data base 418 and filling in the physical channel information. The physical channel reconfiguration request message 420 is entered.

除了處理及資料庫間之資料交換,資料交換亦直接產生於處理間。無線傳輸/接收單元(WTRU)量測,節點B量測,胞元中之可用時間槽列表,候選編碼組及無線傳輸/接收單元(WTRU)性能資訊係從事先編碼配置處理404被傳送至編碼配置處理406。實體頻道資訊(各時間槽中之時間槽列表及頻道化編碼)係從編碼配置處理406被傳送至事後編碼配置處理408。 In addition to processing and data exchange between databases, data exchange is also directly generated in the processing room. WTRU measurement, Node B measurement, available time slot list in the cell, candidate code group and WTRU performance information are transmitted from the pre-encoding configuration process 404 to the code Configuration process 406. The physical channel information (time slot list and channelization code in each time slot) is transmitted from the code configuration process 406 to the post-code configuration process 408.

本發明中,快速動態頻道配置逸出演算402之功能係被調變為兩組功能:輸入為信號訊息部份之信號依賴功能,及輸入獨立於信號訊息之信號獨立功能。區分信號依賴功能及信號獨立功能之目的係為增加信號獨立功能之重複使用性。事先編碼配置處理404及事後編碼配置處理408之功能係為信號依賴功能。相對地,編碼配置處理406之功能係為信號獨立功能。信號獨立功能之重複使用性係高於信號依賴功能之重複使用性。本質上為信號依賴之特定功能係於本發明較佳實施例中從信號依賴被轉換為信號獨立,藉此增加被轉換功能之重複使用性。 In the present invention, the function of the fast dynamic channel configuration escape calculation 402 is modulated into two sets of functions: the input is a signal dependent function of the signal portion of the signal, and the signal independent function independent of the signal message is input. The purpose of distinguishing between signal-dependent functions and signal-independent functions is to increase the reusability of signal-independent functions. The functions of the pre-encoding configuration processing 404 and the post-coding configuration processing 408 are signal dependent functions. In contrast, the functionality of the encoding configuration process 406 is a signal independent function. The reusability of signal independent functions is higher than the reusability of signal dependent functions. The particular function that is inherently signal dependent is converted from signal dependent to signal independent in a preferred embodiment of the invention, thereby increasing the reusability of the converted function.

快速動態頻道配置逸出程序之功能流程圖係被顯示於第五a,b及六圖。第五a及b圖係顯示主逸出演算500之流程圖,係係藉由接收來自觸動信號之輸入而開始(步驟502)。無線資源管理胞元資料庫之入口識別係從無線資源管理胞元資料庫被檢索(步驟504)。無線傳輸/接收單元(WTRU)量測及節點B量測係從共享胞元資料庫被檢索(步驟506)。具有鏈結問題之時間槽鏈結方向係被決定(步驟508),而具有最差鏈結問題之時間槽係被定位。 The functional flow chart of the fast dynamic channel configuration escape program is shown in the fifth a, b and six diagrams. The fifth a and b diagrams show a flow chart of the primary escape calculation 500, which begins by receiving an input from the touch signal (step 502). The entry identification of the radio resource management cell database is retrieved from the radio resource management cell repository (step 504). The WTRU measurement and the Node B measurement are retrieved from the shared cell repository (step 506). The time slot link direction with the link problem is determined (step 508), and the time slot with the worst link problem is located.

將被重新指派之候選編碼合成傳輸頻道係基於逸出機構如何被觸動來決定(步驟510)。逸出程序被時間槽中無線 傳輸/接收單元(WTRU)之過高下鏈干擾信號編碼功率觸動時,此時間槽中之無線傳輸/接收單元(WTRU)編碼合成傳輸頻道(CCTrCH)係為將被重新指派之候選者。下鏈干擾信號編碼功率係藉由無線傳輸/接收單元(WTRU)來量測,且此例中,逸出程序係被無線傳輸/接收單元(WTRU)量測信號觸動。 The candidate coded composite transmission channel to be reassigned is determined based on how the escape mechanism is activated (step 510). The escape program is wireless in the time slot The WTRU-coded composite transmission channel (CCTrCH) in this time slot is a candidate to be reassigned when the transmission/receiving unit (WTRU)'s excessive downlink interference signal coding power is activated. The downlink interference signal coding power is measured by a WTRU, and in this example, the escape procedure is triggered by a WTRU measurement signal.

當逸出程序被時間槽中過高上鏈干擾信號編碼功率觸動時,具有編碼之編碼合成傳輸頻道(CCTrCH)係因最高信號干擾比加上路徑損失值而為將被重新指派之候選者。當逸出程序被節點B傳輸編碼功率觸動時,具有編碼之編碼合成傳輸頻道(CCTrCH)係因節點B傳輸編碼功率而為將被重新指派之候選者。上鏈干擾信號編碼功率及節點B傳輸編碼功率均藉由節點B來量測,且這兩例中,逸出程序係藉由節點B量測信號來觸動。 When the escape procedure is triggered by the excessively high uplink interference signal coding power in the time slot, the coded composite transmission channel (CCTrCH) with coding is the candidate to be reassigned due to the highest signal to interference ratio plus the path loss value. When the escape procedure is touched by the Node B transmission coding power, the coded composite transmission channel (CCTrCH) with the code is the candidate to be reassigned because the Node B transmits the coding power. Both the uplink interference signal coding power and the Node B transmission coding power are measured by the Node B, and in both cases, the escape procedure is triggered by the Node B measurement signal.

若無候選編碼合成傳輸頻道被找到(步驟512),則狀態旗標係被設定標示失敗情況(步驟514)且該程序終止(步驟516)。若候選編碼合成傳輸頻道被找到(步驟512),則無線傳輸/接收單元(WTRU)性能資訊係從無線資源管理無線傳輸/接收單元(WTRU)資料庫被檢索(步驟518)。無線傳輸/接收單元(WTRU)之路徑損失係被計算(步驟520),且將被重新指派之候選編碼組係被決定(步驟522)。候選編碼組係於此編碼組被移除自具有鏈結問題之時間槽之後基於被給定時間槽之被更新干擾信號編碼功率(ISCP)是否小於干擾信號編碼功率(ISCP)門檻,或被更新時間槽傳輸功率是否小於傳輸功率門檻來決定。此決定中,干擾信號編碼功率(ISCP)門檻及傳輸功率門檻係為設計參數。若無編碼組被重新指派(步驟524),則狀態旗標係被設定標示失敗情況(步驟514)且該程序終止(步驟516)。 If no candidate coded composite transmission channel is found (step 512), the status flag is set to indicate a failure condition (step 514) and the program terminates (step 516). If the candidate coded composite transmission channel is found (step 512), the wireless transmit/receive unit (WTRU) performance information is retrieved from the wireless resource management wireless transmit/receive unit (WTRU) database (step 518). The path loss of the WTRU is calculated (step 520) and the candidate coding set to be reassigned is determined (step 522). The candidate coding group is based on whether the updated Interference Signal Coding Power (ISCP) is less than the Interference Signal Coding Power (ISCP) threshold or is updated after the code group is removed from the time slot with the link problem. Whether the time slot transmission power is less than the transmission power threshold is determined. In this decision, the Interference Signal Coding Power (ISCP) threshold and the transmission power threshold are design parameters. If no code group is reassigned (step 524), the status flag is set to flag a failure condition (step 514) and the program terminates (step 516).

若具有被重新指派之編碼組(步驟524),則該被重新指派編碼之可用時間槽係從中央式資料庫被檢索(步驟526)。 若無可用時間槽(步驟528),則狀態旗標係被設定標示失敗情況(步驟514)且該程序終止(步驟516)。若有可用時間槽(步驟528),則實體頻道(時間槽及編碼)係被配置給編碼合成傳輸頻道(CCTrCH)(步驟530)。 If there is a reassigned code group (step 524), then the reassigned code available time slot is retrieved from the central repository (step 526). If no time slot is available (step 528), the status flag is set to indicate a failure condition (step 514) and the program terminates (step 516). If there is a time slot available (step 528), the physical channel (time slot and code) is configured for the coded composite transmission channel (CCTrCH) (step 530).

若實體頻道配置失敗(步驟532),則狀態旗標係被設定標示失敗情況(步驟514)且該程序終止(步驟516)。若資源配置成功(步驟532),則新實體頻道資訊係被記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫(步驟534)。只要最佳解被找到,則資源配置(步驟532)係被視為成功。實體頻道資訊係包含專用實體頻道時間槽資訊,重複期間值及重複長度值。專用實體頻道時間槽資訊係包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊係包含頻道化編碼,編碼使用狀態,專用實體頻道識別及編碼信號對干擾目標。 If the physical channel configuration fails (step 532), the status flag is set to flag a failure condition (step 514) and the program terminates (step 516). If the resource configuration is successful (step 532), the new entity channel information is recorded in a wireless resource management wireless transmit/receive unit (WTRU) database (step 534). As long as the best solution is found, the resource configuration (step 532) is considered successful. The physical channel information includes the dedicated physical channel time slot information, the repeat period value and the repeat length value. The dedicated physical channel time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding, coding usage status, dedicated physical channel identification and coding signals for interference targets.

實體頻道資訊亦被放置於實體頻道重新配置要求訊息中(步驟536),狀態旗標係被設定標示成功情況(步驟538)且該程序終止(步驟516)。實體頻道重新配置要求訊息係包含以下資訊:無線傳輸/接收單元(WTRU)識別,控制無線網路控制器識別,無線鏈結識別,無線資源控制交易識別,上鏈編碼合成傳輸頻道資訊,及下鏈編碼合成傳輸頻道資訊。 The physical channel information is also placed in the physical channel reconfiguration request message (step 536), the status flag is set to indicate a success (step 538) and the program terminates (step 516). The physical channel reconfiguration request message includes the following information: WTRU identification, control of wireless network controller identification, wireless link identification, RRC control transaction identification, uplink coded composite transmission channel information, and Chain coding synthesizes transmission channel information.

步驟530係有關呼叫快速動態頻道配置逸出程序來配置實體頻道之核心功能。此核心功能600係為信號獨立且被說明於第六及三a圖。功能600係以接收編碼組,可用時間槽及快速動態頻道配置類型指標為輸入來開始(步驟602)。第一編碼組係被選擇(步驟604),並決定胞元中是否具有該編碼組(步驟606及608)。若胞元中無被選擇編碼組(步驟608),則決定是否具有更多將被檢查之編碼組(步驟610)。若具有更多編碼組,則下一個編碼組係被選擇(步驟612)且功能繼續於步驟 606。若無更多編碼組(步驟610),則此標示失敗情況,狀態旗標係被設定標示無解(步驟314;第三b圖)且該功能終止(步驟316;第三b圖)。 Step 530 is to configure the core function of the physical channel with respect to the call fast dynamic channel configuration escape procedure. This core function 600 is signal independent and is illustrated in Figures 6 and 3a. Function 600 begins with receiving a code group, an available time slot, and a fast dynamic channel configuration type indicator as input (step 602). The first coding group is selected (step 604) and determines if the code group is present in the cell (steps 606 and 608). If there is no selected coding group in the cell (step 608), it is determined if there are more code groups to be examined (step 610). If there are more code groups, the next code group is selected (step 612) and the function continues at the step 606. If there are no more code groups (step 610), then this flag indicates a failure condition, the status flag is set to indicate no solution (step 314; third b picture) and the function terminates (step 316; third b picture).

若胞元中有被選擇編碼組(步驟608),則快速動態頻道配置類型係被檢查(步驟618)。快速動態頻道配置類型係基於如無線承載設立("RBSETUP"),逸出機構或背景干擾降低之不同無線資源管理功能。逸出程序中,快速動態頻道配置類型係被設定為"ESCAPE",且可被設定為以上步驟520之前之任何步驟。若快速動態頻道配置類型為"ESCAPE",則候選時間槽之傳輸功率係被檢查以決定其是否大於最小必須傳輸功率(步驟620)。若候選時間槽傳輸功率小於最小值(步驟622),則狀態旗標係被設定標示無解(步驟314)且該功能終止(步驟316;第三b圖)。 If there is a selected code group in the cell (step 608), the fast dynamic channel configuration type is checked (step 618). The fast dynamic channel configuration type is based on different radio resource management functions such as radio bearer setup ("RBSETUP"), egress mechanism or background interference reduction. In the escape procedure, the fast dynamic channel configuration type is set to "ESCAPE" and can be set to any step before step 520 above. If the fast dynamic channel configuration type is "ESCAPE", the transmission power of the candidate time slot is checked to determine if it is greater than the minimum required transmission power (step 620). If the candidate time slot transmission power is less than the minimum value (step 622), the status flag is set to indicate no solution (step 314) and the function is terminated (step 316; third b-picture).

若候選時間槽傳輸功率大於最小值(步驟622),則檢查以決定是否有任何時間槽具有較低報告鏈結問題之時間槽之干擾信號編碼功率(ISCP)(步驟624)。若無其他具有較低干擾信號編碼功率(ISCP)之時間槽(步驟626),則狀態旗標係被設定標示無解(步驟314;第三b圖)且該功能終止(步驟316;第三b圖)。 If the candidate time slot transmission power is greater than the minimum value (step 622), then check to determine if there are any time slots with interference signal coding power (ISCP) for the time slot with a lower reported link problem (step 624). If there are no other time slots with lower interfering signal coding power (ISCP) (step 626), the status flag is set to indicate no solution (step 314; third b picture) and the function terminates (step 316; third b)).

若具有較低干擾信號編碼功率(ISCP)之另一時間槽(步驟626)或若快速動態頻道配置類型為"RBSETUP"(步驟618),則編碼合成傳輸頻道(CCTrCH)中之編碼組所需資源單元係被計算(步驟640)。時間序列係被產生用於可用時間槽(步驟642),且第一時間序列係被選擇(步驟644)。如上述第三圖b,該方法繼續於步驟350。若快速動態頻道配置類型為"背景"所執行之步驟(步驟618)係被討論如下。 If there is another time slot with lower interference signal coding power (ISCP) (step 626) or if the fast dynamic channel configuration type is "RBSETUP" (step 618), then the code group in the composite transmission channel (CCTrCH) is required to be encoded. The resource unit is calculated (step 640). A time series is generated for the available time slots (step 642) and the first time series is selected (step 644). As in the third diagram b above, the method continues at step 350. The steps (step 618) performed if the fast dynamic channel configuration type is "background" are discussed below.

背景干擾降低 Background interference reduction

快速動態頻道配置背景干擾降低程序702之概觀700係被顯示於第七圖。快速動態頻道配置背景干擾降低程序702之主要功能係包含三部份:事先編碼配置處理704,編碼配置處理706及事後編碼配置處理708。事先編碼配置處理704係開始於接收背景計時觸動信號710。事先編碼配置處理704可獲得無線資源管理胞元資料庫716之入口識別,從無線資源控制共享胞元資料庫712獲得節點B量測,決定將被重新指派之編碼合成傳輸頻道(CCTrCH),計算無線傳輸/接收單元(WTRU)路徑損失,決定將被重新指派之候選時間槽(一上鏈時間槽及一下鏈時間槽),從無線資源管理胞元資料庫716檢索將被用於重新指派之可用時間槽之列表,決定兩方向中將被重新指派之候選編碼組,從無線資源管理無線傳輸/接收單元(WTRU)資料庫418獲得無線傳輸/接收單元(WTRU)性能資訊,及計算無線傳輸/接收單元(WTRU)路徑損失。 An overview 700 of the fast dynamic channel configuration background interference reduction procedure 702 is shown in the seventh diagram. The main function of the fast dynamic channel configuration background interference reduction program 702 is three parts: a prior encoding configuration process 704, an encoding configuration process 706, and a post-coding configuration process 708. The pre-coded configuration process 704 begins by receiving a background timing touch signal 710. The pre-encoding configuration process 704 can obtain the entry identification of the radio resource management cell repository 716, obtain the Node B measurement from the radio resource control shared cell repository 712, and determine the coded composite transmission channel (CCTrCH) to be reassigned, and calculate Wireless transmit/receive unit (WTRU) path loss, decision candidate time slots to be reassigned (a uplink time slot and a downlink time slot), retrieved from the RRC resource pool 716 will be used for reassignment A list of available time slots, determining candidate code sets to be reassigned in both directions, obtaining WTRU performance information from the WTRU data base 418, and calculating wireless transmissions / Receiver unit (WTRU) path loss.

編碼配置處理706可檢查胞元中之編碼可用性,檢查候選時間槽之傳輸(Tx)功率,搜尋時間槽序列之編碼組之指派解(藉由指派候選編碼組至可用時間槽),及選擇具有最低加權干擾信號編碼功率(ISCP)之解為最佳解。事後編碼配置處理708係負責將重新配置實體頻道記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫718中,及將實體頻道資訊填入實體頻道重新配置要求訊息720。 Encoding configuration process 706 can check the encoding availability in the cell, check the transmission (Tx) power of the candidate time slot, search for the assigned solution of the coded group of time slot sequences (by assigning the candidate code group to the available time slot), and select with The solution of the lowest weighted interference signal coding power (ISCP) is the optimal solution. The post-coding configuration process 708 is responsible for recording the reconfigured physical channel in the WTRU data base 718 and populating the physical channel information into the physical channel reconfiguration request message 720.

除了處理及資料庫間之資料交換,資料交換亦直接產生於處理間。無線傳輸/接收單元(WTRU)量測,節點B量測,胞元中之可用時間槽列表,候選編碼組及無線傳輸/接收單元(WTRU)性能資訊係從事先編碼配置處理704被傳送至編碼配置處理706。實體頻道資訊(各時間槽中之時間槽列表及頻道化編碼)係從編碼配置處理706被傳送至事後編碼配置處理 708。 In addition to processing and data exchange between databases, data exchange is also directly generated in the processing room. WTRU measurement, Node B measurement, available time slot list in the cell, candidate code group and WTRU performance information are transmitted from the pre-encoding configuration process 704 to the code Configuration process 706. The physical channel information (time slot list and channelization code in each time slot) is transmitted from the code configuration process 706 to the post-code configuration process. 708.

本發明中,快速動態頻道配置背景干擾降低程序702之功能係被調變為兩組功能:輸入為信號訊息部份之信號依賴功能,及輸入獨立於信號訊息之信號獨立功能。區分信號依賴功能及信號獨立功能之目的係為增加信號獨立功能之重複使用性。事先編碼配置處理704及事後編碼配置處理708之功能係為信號依賴功能。相對地,編碼配置處理706之功能係為信號獨立功能。因此,信號獨立功能之重複使用性係高於信號依賴功能之重複使用性。本質上為信號依賴之特定功能係於本發明較佳實施例中從信號依賴被轉換為信號獨立,藉此增加被轉換功能之重複使用性。 In the present invention, the function of the fast dynamic channel configuration background interference reduction program 702 is modulated into two sets of functions: the input is a signal dependent function of the signal portion of the signal, and the signal independent function independent of the signal message is input. The purpose of distinguishing between signal-dependent functions and signal-independent functions is to increase the reusability of signal-independent functions. The functions of the pre-encoding configuration processing 704 and the post-coding configuration processing 708 are signal dependent functions. In contrast, the functionality of the encoding configuration process 706 is a signal independent function. Therefore, the reusability of signal independent functions is higher than the reusability of signal dependent functions. The particular function that is inherently signal dependent is converted from signal dependent to signal independent in a preferred embodiment of the invention, thereby increasing the reusability of the converted function.

快速動態頻道配置背景干擾降低程序功能之流程圖係被顯示於第八a,b,六及三b圖。第八a及b圖係顯示背景干擾降低程序800主功能之流程圖,其係藉由檢索無線資源管理胞元資料庫之入口識別(步驟8O4)而開始(步驟8O2)。無線傳輸/接收單元(WTRU)量測及節點B量測係從共享胞元資料庫被檢索(步驟8O6)。重新指派之候選時間槽係基於時間槽測量因子而被決定一上鏈時間槽及一下鏈時間槽(步驟8O8)。具最低測量因子之時間槽係被選為重新指派之候選者。若無被重新指派之時間槽(步驟81O),則狀態旗標係被設定標示為失敗情況(步驟812)且程序終止(步驟814)。若具有被重新指派之時間槽(步驟81O),則鏈結方向係被設定為下鏈(步驟816)。應注意鏈結方向評估順序係任意的,無論上鏈或下鏈均可先被評估。 Fast Dynamic Channel Configuration The flow chart of the background interference reduction program function is shown in the eighth, a, b, six and three b diagrams. The eighth and a diagrams show a flow chart of the main function of the background interference reduction program 800, which is initiated by retrieving the entry identification of the radio resource management cell database (step 8O4) (step 8O2). The WTRU measurement and the Node B measurement are retrieved from the shared cell repository (step 8O6). The reassigned candidate time slot is determined based on the time slot measurement factor by a timed slot and a timed slot (step 8O8). The time slot with the lowest measurement factor is selected as the candidate for reassignment. If there is no time slot reassigned (step 81O), the status flag is set to indicate a failure condition (step 812) and the program terminates (step 814). If there is a time slot that is reassigned (step 81O), the link direction is set to the lower chain (step 816). It should be noted that the order of evaluation of the chain direction is arbitrary, and either the winding or the lower chain can be evaluated first.

被選擇鏈結方向之胞元中可用時間槽係被檢索(步驟818)。若無可用時間槽(步驟820),則狀態旗標係被設定標示為失敗情況(步驟812)且程序終止(步驟814)。若有可用時間槽(步驟820),則可用時間槽列表係被更新來排除候選時間槽(步 驟822)。將被重新指派之編碼組係基於編碼測量因子而被決定於候選時間槽中(步驟824)。具最低測量因子之編碼係被選為重新指派之候選者。若無被重新指派之編碼組(步驟826),則狀態旗標係被設定標示為失敗情況(步驟812)且程序終止(步驟814)。若具有被重新指派之編碼組(步驟826),則無線傳輸/接收單元(WTRU)性能資訊係從無線傳輸/接收單元(WTRU)資料庫被檢索(步驟828)。 The available time slots in the cells selected for the link direction are retrieved (step 818). If no time slot is available (step 820), the status flag is set to indicate a failure condition (step 812) and the program terminates (step 814). If there is a time slot available (step 820), the list of available time slots is updated to exclude candidate time slots (steps) Step 822). The coded group to be reassigned is determined in the candidate time slot based on the coding measurement factor (step 824). The code with the lowest measurement factor is chosen as the candidate for reassignment. If there is no reassigned code group (step 826), the status flag is set to indicate a failure condition (step 812) and the program terminates (step 814). If there is a reassigned code group (step 826), the WTRU performance information is retrieved from the WTRU library (step 828).

無線傳輸/接收單元(WTRU)之路徑損失係被計算(步驟830),而用於現行編碼合成傳輸頻道(CCTrCH)之實體頻道係被重新指派(步驟832)。若頻道重新指派失敗(步驟834),則狀態旗標係被設定標示為失敗情況(步驟812)且程序終止(步驟814)。若頻道重新指派成功(步驟834),則決定鏈結方向是否為現行上鏈(步驟836)。若鏈結方向為現行下鏈,則鏈結方向係被設定為上鏈(步驟838),且該方法繼續於步驟818。 The path loss of the WTRU is calculated (step 830), and the physical channel for the current coded composite transmission channel (CCTrCH) is reassigned (step 832). If the channel reassignment fails (step 834), the status flag is set to indicate a failure condition (step 812) and the program terminates (step 814). If the channel reassignment is successful (step 834), it is determined if the link direction is the current winding (step 836). If the link direction is the current downlink, the link direction is set to be uplink (step 838) and the method continues at step 818.

若現行鏈結方向為上鏈(步驟836),則決定將被重新指派之上鏈編碼合成傳輸頻道及下鏈編碼合成傳輸頻道是否屬於相同無線傳輸/接收單元(WTRU)(步驟840)。若將被重新指派之編碼合成傳輸頻道(CCTrCH)屬於不同無線傳輸/接收單元(WTRU),則旗標係被設定標示該兩不同無線傳輸/接收單元(WTRU)將被重新指派(步驟842)。若編碼合成傳輸頻道(CCTrCH)屬於相同無線傳輸/接收單元(WTRU)(步驟840)或旗標已被設定(步驟842),則實體頻道配置資訊係被記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫中(步驟844)。實體頻道資訊係包含專用實體頻道時間槽資訊,重複期間值,及重複長度值。專用實體頻道時間槽資訊係包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊係包含頻道化編碼,編碼使用狀態,專用實體頻道識別,及編碼信號干擾比目標。 If the current link direction is uplink (step 836), then it is determined whether the over-chain encoded composite transmission channel and the downlink encoded composite transmission channel will be re-assigned to the same WTRU (step 840). If the coded composite transmission channel (CCTrCH) to be reassigned belongs to a different WTRU, the flag is set to indicate that the two different WTRUs will be reassigned (step 842) . If the coded composite transmission channel (CCTrCH) belongs to the same WTRU (step 840) or the flag has been set (step 842), the physical channel configuration information is recorded in the RRC radio transmission/reception unit. In the (WTRU) database (step 844). The physical channel information includes the dedicated physical channel time slot information, the repeat period value, and the repeat length value. The dedicated physical channel time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding, coding usage status, dedicated physical channel identification, and coded signal interference ratio target.

實體頻道配置資訊亦被記錄至實體頻道重新配置要求訊息中(步驟846),狀態旗標係被設定標示"成功"(步驟848)且程序終止(步驟814)。若該旗標標示該兩無線傳輸/接收單元(WTRU)使編碼合成傳輸頻道(CCTrCH)被重新指派(步驟842),則用於該兩無線傳輸/接收單元(WTRU)之對應實體頻道資訊係被記錄(步驟844),且兩實體頻道重新配置要求訊息係被傳送(步驟846)。實體頻道重新配置要求訊息係包含以下資訊:無線傳輸/接收單元(WTRU)識別,控制無線網路控制器識別,無線鏈結識別,無線資源控制交易識別,上鏈編碼合成傳輸頻道資訊,及下鏈編碼合成傳輸頻道資訊。 The physical channel configuration information is also recorded in the physical channel reconfiguration request message (step 846), the status flag is set to indicate "success" (step 848) and the program terminates (step 814). If the flag indicates that the two WTRUs have re-assigned the coded composite transmission channel (CCTrCH) (step 842), the corresponding physical channel information system for the two WTRUs It is recorded (step 844) and the two physical channel reconfiguration request messages are transmitted (step 846). The physical channel reconfiguration request message includes the following information: WTRU identification, control of wireless network controller identification, wireless link identification, RRC control transaction identification, uplink coded composite transmission channel information, and Chain coding synthesizes transmission channel information.

步驟832係有關呼叫快速動態頻道配置背景干擾降低程序核心功能以重新配置實體頻道。此核心功能係為信號獨立且以第六及三b圖來說明。由於以下附帶步驟係以背景干擾降低程序來執行,所以功能600係以上述相同方式來操作。背景干擾降低程序中,快速動態頻道配置類型係被設定為"BACKGROUND",且其可以步驟832之前任何步驟來設定。若快速動態頻道配置類型為"BACKGROUND"(步驟618),則候選時間槽之傳輸功率係被檢查決定其是否大於最小所需傳輸功率(步驟63O)。若候選時間槽之傳輸功率小於最小值(步驟632),則狀態旗標係被設定標示無解(步驟314;第三b圖)且功能終止(步驟316;第三b圖)。若候選時間槽之傳輸功率大於最小傳輸功率(步驟632),則程序繼續於上述步驟640。 Step 832 is related to the call fast dynamic channel configuration background interference reduction program core function to reconfigure the physical channel. This core function is signal independent and illustrated in the sixth and third b-pictures. Since the following accompanying steps are performed with the background interference reduction program, the function 600 operates in the same manner as described above. In the background interference reduction procedure, the fast dynamic channel configuration type is set to "BACKGROUND", and it can be set at any step before step 832. If the fast dynamic channel configuration type is "BACKGROUND" (step 618), the transmission power of the candidate time slot is checked to determine if it is greater than the minimum required transmission power (step 63O). If the transmission power of the candidate time slot is less than the minimum value (step 632), the status flag is set to indicate no solution (step 314; third b-picture) and the function terminates (step 316; third b-picture). If the transmission power of the candidate time slot is greater than the minimum transmission power (step 632), then the process continues at step 640 above.

無線鏈結附加之呼叫允許控制(CAC) Wireless Link Attached Call Admission Control (CAC)

無線鏈結附加之呼叫允許控制(CAC)程序之概觀900係被顯示於第九圖。快速動態頻道配置呼叫允許控制(CAC)程序902之主功能係包含三部份:事先編碼配置處理904,編 碼配置處理906及事後編碼配置處理908。事先編碼配置處理904可從無線鏈結附加要求訊息910(此後為"要求訊息")讀取無線傳輸/接收單元(WTRU)量測,從無線資源控制共享胞元資料庫912讀取節點B量測,從無線資源管理無線傳輸/接收單元(WTRU)資料庫918檢索編碼合成傳輸頻道(CCTrCH)資訊,專用頻道資訊及無線傳輸/接收單元(WTRU)性能資訊。事先編碼配置處理904亦可從無線資源管理胞元資料庫916檢索新胞元中之可用時間槽列表,從無線資源管理無線傳輸/接收單元(WTRU)資料庫918獲得編碼合成傳輸頻道(CCTrCH)資料速率,及從操作及維護無線資源管理表資料庫914獲得編碼組。 An overview 900 of the wireless link-attached call admission control (CAC) procedure is shown in the ninth diagram. The main function of the Fast Dynamic Channel Configuration Call Admission Control (CAC) program 902 is three-part: pre-coding configuration processing 904, Code configuration processing 906 and post-coding configuration processing 908. The pre-encoding configuration process 904 can read the WTRU measurements from the wireless link attach request message 910 (hereinafter "request message") and the node B amount from the radio resource control shared cell repository 912. The coded composite transmission channel (CCTrCH) information, dedicated channel information, and WTRU performance information are retrieved from a radio resource management WTRU database 918. The pre-encoding configuration process 904 can also retrieve a list of available time slots in the new cell from the radio resource management cell repository 916, and obtain a coded composite transmission channel (CCTrCH) from the WTRU data base 918. The data rate, and the code group obtained from the operation and maintenance radio resource management table database 914.

編碼配置處理906可檢查新胞元中之編碼可用性,產生可用時間槽之時間槽序列,搜尋編碼組之最佳解(指派編碼組中之編碼至可用時間槽),及從無線資源管理胞元資料庫916中之編碼向量配置頻道化編碼。事後編碼配置處理908係負責更新無線資源管理胞元資料庫916中之編碼向量資訊,記錄新無線無線鏈結資訊及實體頻道資訊於無線資源管理無線傳輸/接收單元(WTRU)資料庫918中,及記錄編碼合成傳輸頻道(CCTrCH)資訊,專用頻道資訊,專用實體頻道資訊,上鏈干擾信號編碼功率資訊及功率控制資訊於無線鏈結附加回應訊息920。 Encoding configuration process 906 can check the encoding availability in the new cell, generate a time slot sequence of available time slots, search for the best solution for the code group (assign the code in the code group to the available time slot), and manage the cell from the radio resource The coding vector in the database 916 configures channelization coding. The post-coding configuration processing 908 is responsible for updating the coding vector information in the radio resource management cell database 916, and recording the new wireless radio link information and physical channel information in the radio resource management radio transmission/reception unit (WTRU) database 918. And recording coded composite transmission channel (CCTrCH) information, dedicated channel information, dedicated physical channel information, uplink interference signal coding power information and power control information in the wireless link additional response message 920.

除了處理及資料庫間之資料交換,資料交換亦可直接發生於處理之間。無線傳輸/接收單元(WTRU)量測,節點B量測,胞元中之可用時間槽列表,特定資料速率之編碼組列表及無線傳輸/接收單元(WTRU)性能資訊,係從事先編碼配置處理904被傳送至編碼配置處理906。實體頻道資訊(各時間槽中之時間槽列表及頻道化編碼)係從編碼配置處理906被傳送至事後編碼配置處理908。 In addition to processing and exchanging data between databases, data exchange can occur directly between processing. WTRU measurement, Node B measurement, list of available time slots in cells, code group list for specific data rates, and WTRU performance information, from pre-coding configuration processing 904 is passed to encoding configuration process 906. The physical channel information (time slot list and channelization code in each time slot) is transmitted from the code configuration process 906 to the post-code configuration process 908.

本發明中,無線鏈結附加之快速動態頻道配置呼叫允許控制(CAC)程序902之功能係被調變為兩組功能:輸入為信號訊息部份之信號依賴功能,及輸入獨立於信號訊息之信號獨立功能。分隔信號依賴功能及信號獨立功能之目的係增加信號獨立功能之重複使用性。事先編碼配置處理904及事後編碼配置處理908之功能係為信號依賴功能。相對地,編碼配置處理906之功能係為信號獨立功能。因此,信號獨立功能之重複使用性係高於信號依賴功能之重複使用性。本質上為信號依賴之特定功能係於本發明較佳實施例中從信號依賴被轉換為信號獨立,藉此增加被轉換功能之重複使用性。 In the present invention, the function of the fast dynamic channel configuration call admission control (CAC) program 902 attached to the wireless link is modulated into two sets of functions: the input is a signal dependent function of the signal message portion, and the input is independent of the signal message. Signal independent function. The purpose of separating the signal dependent function and the signal independent function is to increase the reusability of the signal independent function. The functions of the pre-encoding configuration processing 904 and the post-coding configuration processing 908 are signal dependent functions. In contrast, the functionality of the encoding configuration process 906 is a signal independent function. Therefore, the reusability of signal independent functions is higher than the reusability of signal dependent functions. The particular function that is inherently signal dependent is converted from signal dependent to signal independent in a preferred embodiment of the invention, thereby increasing the reusability of the converted function.

用於無線鏈結附加之快速動態頻道配置呼叫允許控制(CAC)程序功能之流程圖係被顯示於第十a-c圖,其顯示無線鏈結附加程序之快速動態頻道配置呼叫允許控制(CAC)之主介面功能1000。功能1000係開始於獲得無線鏈結附加要求訊息(步驟1002),及從該要求訊息擷取無線傳輸/接收單元(WTRU)識別,新無線鏈結識別及新胞元識別(步驟1004)。該要求訊息亦包含有或無無線傳輸/接收單元(WTRU)量測之新無線鏈結資訊。 A flow chart of the Fast Dynamic Channel Configuration Call Admission Control (CAC) program function for wireless link attachment is shown in the tenth ac diagram, which shows the Fast Dynamic Channel Configuration Call Admission Control (CAC) of the Wireless Link Attachment Program. The main interface function is 1000. The function 1000 begins with obtaining a wireless link attach request message (step 1002), and extracts WTRU identification, new wireless link identification, and new cell identification from the request message (step 1004). The request message also includes new wireless link information with or without wireless transmit/receive unit (WTRU) measurements.

無線資源管理胞元資料庫中之新胞元入口識別係被獲得(步驟1006)。新胞元之節點B量測係可從無線資源控制共享胞元資料庫獲得且被儲存於量測資料結構(步驟1008)。量測資料結構係被動態儲存於快速動態頻道配置呼叫允許控制(CAC)功能。當快速動態頻道配置呼叫允許控制(CAC)功能被跳出時,其係被建立於快速動態頻道配置呼叫允許控制(CAC)功能被呼叫及刪除時。節點B量測係包含共用量測及專用量測。節點B共用量測係包含上鏈干擾信號編碼功率資訊及下鏈傳輸載波功率。接著,舊胞元識別係基於無線傳輸/接收單元(WTRU)識別從無線資源管理無線傳輸/接收單元(WTRU)資 料庫被檢索;屬於舊胞元中之無線傳輸/接收單元(WTRU)無線鏈結中之編碼合成傳輸頻道(CCTrCH)資訊及專用頻道資訊係從無線資源管理無線傳輸/接收單元(WTRU)資料庫被檢索(步驟1010)。 A new cell entry identification in the radio resource management cell database is obtained (step 1006). The node B measurement system of the new cell can be obtained from the radio resource control shared cell database and stored in the measurement data structure (step 1008). The measurement data structure is dynamically stored in the Fast Dynamic Channel Configuration Call Admission Control (CAC) function. When the Fast Dynamic Channel Configuration Call Admission Control (CAC) function is popped out, it is established when the Fast Dynamic Channel Configuration Call Admission Control (CAC) function is called and deleted. The Node B measurement system includes a shared measurement and a dedicated measurement. The Node B shared measurement system includes the uplink interference signal coding power information and the downlink transmission carrier power. Next, the old cell identification is based on the WTRU identifying the WTRU from the radio resource management radio transmission/reception unit (WTRU). The repository is retrieved; the coded composite transmission channel (CCTrCH) information and the dedicated channel information in the wireless link/receiving unit (WTRU) wireless link in the old cell are from the radio resource management wireless transmit/receive unit (WTRU) data. The library is retrieved (step 1010).

接著,決定包含下鏈干擾信號編碼功率及下鏈主共用控制實體頻道被接收信號編碼功率(P-CCPCHRSCP)之無線傳輸/接收單元(WTRU)量測是否被包含於要求訊息中(步驟1012)。若無線傳輸/接收單元(WTRU)量測不被包含於要求訊息中,則服務類型係從無線資源管理無線傳輸/接收單元(WTRU)資訊被檢索(步驟1014),並檢查是否所有專用頻道均為非即時(步驟1016)。 Next, determining whether the WTRU measurement including the downlink interference signal coding power and the downlink main shared control entity channel received signal coding power (P-CCPCHRSCP) is included in the request message (step 1012) . If the WTRU measurement is not included in the request message, the service type is retrieved from the RRC information (step 1014) and checks if all dedicated channels are available. It is not immediate (step 1016).

若所有專用頻道均為非即時,則狀態旗標係被設定標示為失敗情況(步驟1018)且功能終止(步驟1020)。在此之失敗情況意指無足夠資訊來進一步處理功能。應注意僅所有即時之專用頻道非失敗情況;當無任何無線傳輸/接收單元(WTRU)量測及所有專用頻道均為即時時才達到失敗情況。若所有專用頻道均為非即時(步驟1016),則低速率暫時專用頻道係被配置給上鏈及下鏈編碼合成傳輸頻道(步驟1022)。頻道被配置後,決定資源配置是否成功(步驟1024)。若資源配置失敗,則狀態旗標係被設定標示為失敗情況(步驟1018)且功能終止(步驟1020)。若資源配置成功,則新無線鏈結資訊及實體頻道資訊係被記錄於無線資源管理無線傳輸/接收單元(WTRU)資料庫中,且編碼向量資訊係被更新於無線資源管理胞元資料庫中(步驟1026)。 If all of the dedicated channels are non-instant, the status flag is set to indicate a failure condition (step 1018) and the function terminates (step 1020). A failure here means that there is not enough information to further process the function. It should be noted that only all immediate dedicated channels are non-failed; failures are reached when there is no WTRU measurement and all dedicated channels are instantaneous. If all of the dedicated channels are non-instant (step 1016), the low rate temporary dedicated channel is configured for the uplink and downlink encoded composite transmission channels (step 1022). After the channel is configured, it is determined whether the resource configuration is successful (step 1024). If the resource configuration fails, the status flag is set to indicate a failure condition (step 1018) and the function terminates (step 1020). If the resource configuration is successful, the new wireless link information and the physical channel information are recorded in a wireless resource management wireless transmit/receive unit (WTRU) database, and the code vector information is updated in the wireless resource management cell database. (Step 1026).

被記錄資訊係包含新無線鏈結資訊及新無線資源控制交易識別。無線鏈結資訊係包含無線鏈結識別,胞元識別,上鏈編碼合成傳輸頻道資訊及下鏈編碼合成傳輸頻道資訊。編碼合成傳輸頻道(CCTrCH)資訊係包含編碼合成傳輸頻道 (CCTrCH)識別,編碼合成傳輸頻道(CCTrCH)狀態,編碼合成傳輸頻道(CCTrCH)信號干擾比目標,保證資料速率,允許資料速率及專用實體頻道資訊。專用實體頻道資訊係包含專用實體頻道時間槽資訊列表,重複期間值及重複長度值。專用實體頻道時間槽資訊係包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊係包含頻道化編碼,編碼使用狀態,專用實體頻道識別及編碼信號對干擾目標。 The recorded information contains new wireless link information and new wireless resource control transaction identification. The wireless link information includes wireless link identification, cell identification, uplink coded composite transmission channel information, and downlink coded composite transmission channel information. Coding and Synthetic Transport Channel (CCTrCH) information contains coded composite transmission channels (CCTrCH) identification, coded composite transmission channel (CCTrCH) state, coded composite transmission channel (CCTrCH) signal interference ratio target, guaranteed data rate, allowed data rate and dedicated physical channel information. The dedicated physical channel information includes a list of dedicated physical channel time slot information, repeat period values and repeat length values. The dedicated physical channel time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding, coding usage status, dedicated physical channel identification and coding signals for interference targets.

被更新編碼向量資訊係包含上鏈編碼向量資訊及下鏈編碼向量資訊。上鏈編碼向量資訊係包含編碼識別,編碼塊識別及編碼使用狀態。下鏈編碼向量資訊係包含編碼識別及編碼使用狀態。 The updated code vector information includes the uplink coded vector information and the downlink coded vector information. The uplink coding vector information includes code recognition, coding block identification and coding usage status. The downlink coding vector information includes code recognition and coding usage status.

若要求訊息中具有無線傳輸/接收單元(WTRU)量測(步驟1012),則無線傳輸/接收單元(WTRU)量測係從要求訊息被檢索且被局部儲存(步驟1032)。第一下鏈編碼合成傳輸頻道(CCTrCH)係被選擇(步驟1034),且無線傳輸/接收單元(WTRU)性能資訊係基於無線傳輸/接收單元(WTRU)識別,連結方向及舊胞元識別從無線資源管理無線傳輸/接收單元(WTRU)資料庫被檢索(步驟1036)。被選擇編碼合成傳輸頻道(CCTrCH)之服務類型係從無線資源管理無線傳輸/接收單元(WTRU)資料庫被獲得(步驟1038)。若服務類型為即時(步驟1040),則胞中之可用時間槽係被決定(步驟1042)。若無時間槽可用(步驟1044),則狀態旗標係被設定標示為失敗情況(步驟1018)且程序終止(步驟1020)。 If there is a wireless transmit/receive unit (WTRU) measurement in the request message (step 1012), the WTRU measurement is retrieved from the request message and stored locally (step 1032). The first downlink coded composite transmission channel (CCTrCH) is selected (step 1034), and the WTRU performance information is based on the WTRU identification, the connection direction and the old cell identification from A radio resource management wireless transmit/receive unit (WTRU) database is retrieved (step 1036). The service type of the selected coded composite transmission channel (CCTrCH) is obtained from the radio resource management wireless transmission/reception unit (WTRU) database (step 1038). If the service type is immediate (step 1040), the available time slot in the cell is determined (step 1042). If no time slot is available (step 1044), the status flag is set to indicate a failure condition (step 1018) and the program terminates (step 1020).

若新胞中具有可用時間槽(步驟1044),則舊胞元中此編碼合成傳輸頻道(CCTrCH)之最高要求資料速率係從無線資源管理無線傳輸/接收單元(WTRU)資料庫被檢索(步驟1046)。要求資料速率之編碼組係被獲得(步驟1048),且現行 編碼合成傳輸頻道(CCTrCH)之實體頻道(時間槽及編碼)係被配置且最佳解若被找到則被記錄(步驟1050)。步驟1050中之配置功能係被更詳細討論於第三a及b圖。若資源配置失敗(步驟1052),則狀態旗標係被設定標示為失敗情況(步驟1018)且程序終止(步驟1020)。 If there is a time slot available in the new cell (step 1044), the highest required data rate of the coded composite transmission channel (CCTrCH) in the old cell is retrieved from the WTRU data base (steps). 1046). A coding group requiring a data rate is obtained (step 1048) and is currently The physical channel (time slot and code) of the coded composite transmission channel (CCTrCH) is configured and the best solution is recorded if found (step 1050). The configuration functions in step 1050 are discussed in more detail in the third a and b diagrams. If the resource configuration fails (step 1052), the status flag is set to indicate a failure condition (step 1018) and the program terminates (step 1020).

若資源配置成功(步驟1052),則決定是否具有將被檢查之現行方向(下鏈或上鏈)中之附加編碼合成傳輸頻道。若具有將被檢查之附加編碼合成傳輸頻道,則下一個編碼合成傳輸頻道(CCTrCH)係被選擇(步驟1056),且程序繼續於步驟1038。若無將被檢查之附加編碼合成傳輸頻道(步驟1054),則決定上鏈編碼合成傳輸頻道是否已被檢查(步驟1058)。若上鏈編碼合成傳輸頻道尚未被檢查,則第一上鏈編碼合成傳輸頻道係被選擇(步驟1060),且程序繼續於步驟1036。若所有上鏈編碼合成傳輸頻道均已被考慮(步驟1058),則程序繼續如上述之步驟1026。 If the resource configuration is successful (step 1052), it is determined whether there is an additional coded composite transmission channel in the current direction (downlink or uplink) to be checked. If there is an additional coded composite transmission channel to be examined, the next coded composite transmission channel (CCTrCH) is selected (step 1056) and the process continues at step 1038. If there is no additional coded composite transmission channel to be checked (step 1054), it is determined if the uplink encoded composite transmission channel has been checked (step 1058). If the uplink encoded composite transmission channel has not been checked, the first uplink encoded composite transmission channel is selected (step 1060) and the process continues at step 1036. If all of the uplink encoded composite transmission channels have been considered (step 1058), then the program continues as in step 1026 above.

接著,具有最新配置實體頻道資訊,專用頻道資訊,上鏈時間槽干擾信號編碼功率(ISCP)資訊及功率控制資訊之編碼合成傳輸頻道(CCTrCH)資訊係被放入無線鏈結附加回應訊息中(步驟1028),狀態旗標係被設定標示為成功情況(步驟1030)且程序終止(步驟1020)。編碼合成傳輸頻道(CCTrCH)資訊係包含編碼合成傳輸頻道(CCTrCH)識別及專用實體頻道資訊。專用實體頻道資訊係包含時間槽資訊列表,重複期間及重複長度。專用實體頻道時間槽資訊係包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊係包含頻道化編碼及專用實體頻道識別。專用頻道資訊係包含多元指標及多元選擇指標。功率控制資訊係包含上鏈目標信號干擾比,最大上鏈目標信號干擾比,最小上鏈目標信號干擾比,啟始下鏈傳輸功率,最大下鏈傳輸功率及最小下鏈傳 輸功率。 Then, the coded composite transmission channel (CCTrCH) information with the latest configuration physical channel information, dedicated channel information, uplink time slot interference signal coding power (ISCP) information and power control information is placed in the wireless link additional response message ( In step 1028), the status flag is set to indicate a success condition (step 1030) and the program terminates (step 1020). The Coded Composite Transport Channel (CCTrCH) information includes Coded Synthetic Transport Channel (CCTrCH) identification and dedicated physical channel information. The dedicated physical channel information includes a list of time slot information, repetition period and repetition length. The dedicated physical channel time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding and dedicated physical channel identification. The dedicated channel information includes multiple indicators and multiple selection indicators. The power control information includes the uplink target signal-to-interference ratio, the maximum uplink target signal-to-interference ratio, the minimum uplink target signal-to-interference ratio, the start-down downlink transmission power, the maximum downlink transmission power, and the minimum downlink transmission. Power transmission.

若服務類型為非即時(步驟1040),則新胞中之可用時間槽係被決定(步驟1062)。若新胞中無時間槽可用(步驟1064),則狀態旗標係被設定標示為失敗情況(步驟1018)且程序終止(步驟1020)。 If the service type is non-instant (step 1040), the available time slot in the new cell is determined (step 1062). If no time slot is available in the new cell (step 1064), the status flag is set to indicate a failure condition (step 1018) and the program terminates (step 1020).

若新胞中具有可用時間槽(步驟1064),則所有適用於編碼合成傳輸頻道(CCTrCH)之資料速率係從無線資源管理無線傳輸/接收單元(WTRU)資料庫被檢索(步驟1066),且最高資料速率係被選擇(步驟1068)。用於被選擇資料速率之編碼組係被獲得(步驟1070),且用於本編碼合成傳輸頻道(CCTrCH)之一般暫時專用頻道係被配置且若最佳解被找到則被記錄(步驟1072)。應注意步驟1050及1072本質上相同;非即時服務中,專用頻道係暫時的。若資源配置失敗(步驟1074),則決定是否有將被檢查之額外資料速率(步驟1076)。若無將被檢查之其他資料速率,則狀態旗標係被設定標示為失敗情況(步驟1018)且程序終止(步驟1020)。若具有將被檢查之其他資料速率,則程序繼續如上述步驟1054。 If there is a time slot available in the new cell (step 1064), then all data rates applicable to the coded composite transmission channel (CCTrCH) are retrieved from the radio resource management wireless transmit/receive unit (WTRU) database (step 1066), and The highest data rate is selected (step 1068). A coding set for the selected data rate is obtained (step 1070), and a general temporary dedicated channel for the present coded composite transmission channel (CCTrCH) is configured and recorded if the best solution is found (step 1072) . It should be noted that steps 1050 and 1072 are essentially the same; in non-instant service, the dedicated channel is temporary. If the resource configuration fails (step 1074), it is determined if there is an additional data rate to be checked (step 1076). If there are no other data rates to be checked, the status flag is set to indicate a failure condition (step 1018) and the program terminates (step 1020). If there are other data rates to be checked, the program continues as in step 1054 above.

應注意步驟1034,1058及1060中任一方向(下鏈或上鏈)均可首先被執行。如上述,下鏈方向係優先於上鏈方向被檢查。若上鏈方向優先於下鏈方向被檢查,則功能1000將以相同方式操作。 It should be noted that either of the steps 1034, 1058 and 1060 (downlink or winding) can be performed first. As described above, the lower chain direction is checked in preference to the winding direction. If the winding direction is checked in preference to the downlink direction, function 1000 will operate in the same manner.

步驟1050及1072係有關呼叫快速動態頻道配置演算之頻道配置功能;此核心功能300係為信號獨立且以第三a及b圖相同方式操作。 Steps 1050 and 1072 are channel configuration functions for calling fast dynamic channel configuration calculations; this core function 300 is signal independent and operates in the same manner as the third a and b diagrams.

無線鏈結重新配置之呼叫允許控制(CAC) Call Forwarding Control (CAC) for Wireless Link Reconfiguration

無線鏈結重新配置之快速動態頻道配置呼叫允許控 制(CAC)程序1102之概觀1100係被顯示於第十一圖。快速動態頻道配置呼叫允許控制(CAC)控制程序1102係包含三部份:事先編碼配置處理1104,編碼配置處理1106及事後編碼配置處理1108。事先編碼配置處理1104可從無線鏈結重新配置預備訊息1110檢索無線傳輸/接收單元(WTRU)資訊及從無線資源管理無線傳輸/接收單元(WTRU)資料庫1118檢索無線傳輸/接收單元(WTRU)性能資訊。無線傳輸/接收單元(WTRU)量測及節點B量測係從無線資源控制共享胞元資料庫1112被檢索。可用時間槽列表係從無線資源管理胞元資料庫1116被獲得且編碼組係從操作及維護無線資源管理表資料庫1114被檢索。 Fast dynamic channel configuration call admission control for wireless link reconfiguration An overview 1100 of the CAC program 1102 is shown in FIG. The Fast Dynamic Channel Configuration Call Admission Control (CAC) control program 1102 includes three components: a pre-coding configuration process 1104, an encoding configuration process 1106, and a post-coding configuration process 1108. The pre-coding configuration process 1104 can retrieve wireless transmission/reception unit (WTRU) information from the wireless link reconfiguration preparation message 1110 and retrieve the wireless transmit/receive unit (WTRU) from the wireless resource management wireless transmit/receive unit (WTRU) database 1118. Performance information. The WTRU measurement and the Node B measurement are retrieved from the Radio Resource Control Shared Cell Library 1112. The list of available time slots is obtained from the radio resource management cell repository 1116 and the coded groups are retrieved from the operation and maintenance radio resource management table repository 1114.

編碼配置處理1106可檢查胞元中之可用編碼,產生時間槽序列,找尋編碼組之最佳解(指派編碼組中之編碼至可用時間槽,及從無線資源管理胞元資料庫1116中之編碼向量配置該集中式編碼)。事後編碼配置處理1108可更新無線資源管理胞元資料庫1116中之編碼向量資訊,記錄被配置實體頻道於無線資源管理無線傳輸/接收單元(WTRU)資料庫1118中,及記錄實體頻道參數及功率控制資訊於無線鏈結重新配置被妥訊息1120中。 Encoding configuration process 1106 can examine the available codes in the cells, generate a sequence of time slots, find the best solution for the code group (assign the code in the code group to the available time slot, and encode from the radio resource management cell library 1116) The vector is configured with this centralized encoding). The post-coding configuration processing 1108 may update the coding vector information in the radio resource management cell database 1116, record the configured entity channel in the radio resource management radio transmission/reception unit (WTRU) database 1118, and record the physical channel parameters and power. The control information is re-configured in the wireless link reconfiguration message 1120.

除了處理及資料庫間之資料交換,資料交換亦直接發生於處理之間。無線傳輸/接收單元(WTRU)量測,節點B量測,胞元中之可用時間槽列表,特定資料速率之編碼組列表及無線傳輸/接收單元(WTRU)性能資訊,係從事先編碼配置處理1104被傳送至編碼配置處理1106。實體頻道資訊(各時間槽中之時間槽列表及頻道化編碼)係從編碼配置處理1106被傳送至事後編碼配置處理1108。 In addition to processing and data exchange between databases, data exchange also occurs directly between processing. WTRU measurement, Node B measurement, list of available time slots in cells, code group list for specific data rates, and WTRU performance information, from pre-coding configuration processing 1104 is passed to encoding configuration process 1106. The physical channel information (time slot list and channelization code in each time slot) is transmitted from the code configuration process 1106 to the post-code configuration process 1108.

本發明中,無線鏈結重新配置之快速動態頻道配置呼叫允許控制(CAC)程序1102之功能係被調變為兩組功能: 輸入為信號訊息部份之信號依賴功能,及輸入獨立於信號訊息之信號獨立功能。分隔信號依賴功能及信號獨立功能之目的係增加信號獨立功能之重複使用性。事先編碼配置處理1104及事後編碼配置處理1108之功能係為信號依賴功能。相對地,編碼配置處理1106之功能係為信號獨立功能。應注意編碼配置處理1106之功能可藉由其他無線資源管理功能實施中之其他程序來重複使用。 In the present invention, the functionality of the Fast Dynamic Channel Configuration Call Admission Control (CAC) program 1102 for wireless link reconfiguration is modulated into two sets of functions: The input is the signal dependent function of the signal message part, and the signal independent function independent of the signal message. The purpose of separating the signal dependent function and the signal independent function is to increase the reusability of the signal independent function. The functions of the pre-encoding configuration processing 1104 and the post-coding configuration processing 1108 are signal dependent functions. In contrast, the functionality of the encoding configuration process 1106 is a signal independent function. It should be noted that the functionality of the code configuration process 1106 can be reused by other programs in other wireless resource management function implementations.

無線鏈結重新配置之快速動態頻道配置呼叫允許控制(CAC)程序功能之流程圖係被顯示於第十二及十三a-c圖。第十二圖顯示無線鏈結重新配置程序之快速動態頻道配置呼叫允許控制(CAC)之主要介面程序1200。程序1200係藉由獲得無線鏈結重新配置預備訊息(此後被稱為"預備訊息";步驟1202)來開始。預備訊息係包含編碼合成傳輸頻道(CCTrCH)資訊(有關將被附加或修改之編碼合成傳輸頻道(CCTrCH)),專用頻道資訊(有關將被附加或修改之專用頻道),具有或沒有無線傳輸/接收單元(WTRU)量測之無線鏈結資訊。無線傳輸/接收單元(WTRU)量測係包含下鏈干擾信號編碼功率及下鏈主共用控制實體頻道被接收信號編碼功率。無線傳輸/接收單元(WTRU)識別及無線鏈結識別係被擷取自預備訊息,而胞元識別係被擷取自無線傳輸/接收單元(WTRU)資料庫(步驟1204)。無線資源管理胞元資料庫之入口識別係接著被獲得(步驟1206)。 A flowchart of the Fast Dynamic Channel Configuration Call Admission Control (CAC) program function for wireless link reconfiguration is shown in Figures 12 and 13a-c. The twelfth figure shows the main interface program 1200 of the Fast Dynamic Channel Configuration Call Admission Control (CAC) of the Wireless Link Reconfiguration Procedure. The program 1200 begins by obtaining a wireless link reconfiguration preparation message (hereinafter referred to as "preparation message"; step 1202). The preparatory message consists of Coded Synthetic Transport Channel (CCTrCH) information (on the Coded Synthetic Transport Channel (CCTrCH) to be attached or modified), dedicated channel information (on the dedicated channel to be attached or modified), with or without wireless transmission / The wireless link information measured by the receiving unit (WTRU). The WTRU measurement system includes a downlink interference signal coding power and a downlink main shared control entity channel received signal coding power. The WTRU identification and the wireless link identification are retrieved from the prepared message, and the cell identification is retrieved from the WTRU library (step 1204). The entry identification system of the radio resource management cell database is then obtained (step 1206).

資料結構係被建立來局部儲存量測(步驟1208)。此量測資料結構係被動態儲存於快速動態頻道配置呼叫允許控制(CAC)功能中。其係被建立於快速動態頻道配置呼叫允許控制(CAC)功能被呼叫之後,且被刪除於快速動態頻道配置呼叫允許控制(CAC)功能被退出時。節點B量測接著從無線資源控制共享胞元資料庫被檢索且被局部儲存(步驟1210)。節點B量 測包含共用量測及專用量測。節點B量測包含上鏈干擾信號編碼功率及下鏈傳輸載波功率。節點B專用量測包含下鏈傳輸編碼功率。 The data structure is established to locally store the measurements (step 1208). This measurement data structure is dynamically stored in the Fast Dynamic Channel Configuration Call Admission Control (CAC) function. It is established after the Fast Dynamic Channel Configuration Call Admission Control (CAC) function is called and is deleted when the Fast Dynamic Channel Configuration Call Admission Control (CAC) function is exited. The Node B measurement is then retrieved from the RRC shared cell repository and stored locally (step 1210). Node B amount The measurement includes a shared measurement and a dedicated measurement. The Node B measurement includes the uplink interference signal coding power and the downlink transmission carrier power. The Node B dedicated measurement includes the downlink transmission coding power.

量測資料結構係包含胞元量測記錄列表。胞元量測記錄係包含胞元識別及時間槽量測記錄列表。時間槽量測記錄包含時間槽數,時間槽干擾信號編碼功率(ISCP),時間槽載波功率,及編碼量測記錄列表。編碼量測記錄包含無線傳輸/接收單元(WTRU)識別,無線鏈結識別,專用實體頻道識別及編碼傳輸功率。 The measurement data structure contains a list of cell measurement records. The cell measurement record contains a list of cell identification and time slot measurements. The time slot measurement record includes the number of time slots, time slot interference signal coding power (ISCP), time slot carrier power, and a list of code measurement records. The code measurement record includes WTRU identification, wireless link identification, dedicated physical channel identification, and coded transmission power.

若無線傳輸/接收單元(WTRU)量測被包含於預備訊息中(步驟1212),則無線傳輸/接收單元(WTRU)量測係從預備訊息被擷取且被局部儲存於量測資料結構中(步驟1214)。實體頻道接著被配置給將被附加或修改之編碼合成傳輸頻道(CCTrCH)(步驟1216)。無論編碼合成傳輸頻道(CCTrCH)將被附加或修改,應注意編碼配置程序(步驟1216)係相同。編碼配置程序將以下列第十三a-c圖做更詳細討論。若實體頻道配置成功(步驟1218),則狀態旗標係被設定標示為成功情況(步驟1220)且程序終止(步驟1222)。若實體頻道配置成功(步驟1218),則狀態旗標係被設定標示為成功情況(步驟1220)且程序終止(步驟1222)。 If the WTRU measurement is included in the preliminary message (step 1212), the WTRU measurement is retrieved from the preliminary message and stored locally in the measurement data structure. (Step 1214). The physical channel is then configured to a coded composite transmission channel (CCTrCH) to be appended or modified (step 1216). Regardless of whether the coded composite transmission channel (CCTrCH) will be appended or modified, it should be noted that the code configuration procedure (step 1216) is the same. The code configuration program will be discussed in more detail in the thirteenth a-c diagram below. If the physical channel configuration is successful (step 1218), the status flag is set to indicate a success condition (step 1220) and the program terminates (step 1222). If the physical channel configuration is successful (step 1218), the status flag is set to indicate a success condition (step 1220) and the program terminates (step 1222).

若無線傳輸/接收單元(WTRU)量測不被包含於預備訊息中(步驟1212),則決定是否所有專用頻道均為非即時(步驟1226)。若所有專用頻道均為即時,則狀態旗標係被設定標示為失敗情況(步驟1224)且程序終止(步驟1222)。若所有專用頻道均為非即時(步驟1228),則無線鏈結重新配置類型係被決定(步驟1230)。無線鏈結配置類型係基於無線鏈結中之編碼合成傳輸頻道(CCTrCH)來設定。若編碼合成傳輸頻道(CCTrCH)被附加,則無線鏈結配置類型係被設定"MODIFY(修改)"。 If the WTRU measurement is not included in the preliminary message (step 1212), then it is determined whether all of the dedicated channels are non-instant (step 1226). If all of the dedicated channels are instant, the status flag is set to indicate a failure condition (step 1224) and the program terminates (step 1222). If all of the dedicated channels are non-instant (step 1228), the wireless link reconfiguration type is determined (step 1230). The wireless link configuration type is set based on the coded composite transmission channel (CCTrCH) in the wireless link. If the coded composite transmission channel (CCTrCH) is attached, the wireless link configuration type is set to "MODIFY".

若無線鏈結配置類型為"MODIFY",則此標示為失敗情況,且狀態旗標係被設定標示為失敗情況(步驟1224)且程序終止(步驟1222)。該失敗情況標示無足夠資訊來儘一步處理要求。當無線鏈結配置類型為"MODIFY"且無線鏈結重新配置訊息不包含無線傳輸/接收單元(WTRU)量測時,則達到失敗情況。 If the wireless link configuration type is "MODIFY", then this is indicated as a failure condition, and the status flag is set to indicate a failure condition (step 1224) and the program terminates (step 1222). This failure condition indicates that there is not enough information to process the request as much as possible. A failure condition is reached when the wireless link configuration type is "MODIFY" and the wireless link reconfiguration message does not include wireless transmit/receive unit (WTRU) measurements.

若無線鏈結重新配置類型為"ADDITION",則低速率暫時專用頻道係被配置給將被附加之編碼合成傳輸頻道(步驟1232)。該程序繼續如上述步驟1218。 If the wireless link reconfiguration type is "ADDITION", the low rate temporary dedicated channel is configured for the coded composite transmission channel to be attached (step 1232). The program continues as in step 1218 above.

第十三a-c圖顯示頻道配置程序1300,其係藉由快速動態頻道配置呼叫允許控制(CAC)無線鏈結重新配置程序1200之步驟1216來使用。程序1300係開始於獲得預備訊息(步驟1302)及從預備訊息擷取無線傳輸/接收單元(WTRU)識別及無線鏈結識別(步驟1304)。 The thirteenth a-c diagram shows the channel configuration procedure 1300 for use by the fast dynamic channel configuration call admission control (CAC) wireless link reconfiguration procedure 1200 step 1216. The process 1300 begins with obtaining a preliminary message (step 1302) and extracting wireless carrier/receive unit (WTRU) identification and wireless link identification from the preliminary message (step 1304).

第一下鏈編碼合成傳輸頻道係被選擇(步驟1306),且無線傳輸/接收單元(WTRU)性能係從無線傳輸/接收單元(WTRU)資料庫被檢索(步驟1308)。被選擇編碼合成傳輸頻道(CCTrCH)之服務類型係被獲得(步驟1310),且若服務類型為即時(步驟1312),則用於胞元中之即時之可用時間槽係被決定(步驟1314)。若無可用時間槽(步驟1316),則此標示為失敗情況,且狀態旗標係被設定標示為失敗情況(步驟1318)且程序終止(步驟1322)。 The first downlink encoded composite transmission channel is selected (step 1306) and the WTRU performance is retrieved from the WTRU library (step 1308). The service type of the selected coded composite transmission channel (CCTrCH) is obtained (step 1310), and if the service type is immediate (step 1312), the available available time slot for the cell is determined (step 1314). . If no time slot is available (step 1316), then this is indicated as a failure condition, and the status flag is set to indicate a failure condition (step 1318) and the program terminates (step 1322).

若有可用時間槽(步驟1316),則被選擇編碼合成傳輸頻道之塊錯誤率(BLER)係被決定(步驟1322),且被要求資料速率係被計算(步驟1324)。被計算資料速率之編碼組係被獲得(步驟1326)且被選擇編碼合成傳輸頻道之實體頻道(時間槽及編碼)係被配置,而最佳解若被找到則被記錄(步驟1328)。步驟1328中之配置功能係被更詳細討論於以上第三a及b圖。 若資源配置失敗(步驟1330),則狀態旗標係被設定標示為失敗情況(步驟1318)且功能終止(步驟1320)。 If there is a time slot available (step 1316), the block error rate (BLER) of the selected coded composite transmission channel is determined (step 1322) and the requested data rate is calculated (step 1324). The encoded set of calculated data rates is obtained (step 1326) and the physical channel (time slot and code) selected to encode the composite transmission channel is configured, and the best solution is recorded if found (step 1328). The configuration functions in step 1328 are discussed in more detail in Figures 3a and b above. If the resource configuration fails (step 1330), the status flag is set to indicate a failure condition (step 1318) and the function terminates (step 1320).

若資源配置成功(步驟1330),則決定現行方向(下鏈或上鏈)中是否具有將被檢查之額外編碼合成傳輸頻道(步驟1332)。若具有將被檢查之額外編碼合成傳輸頻道,則現行方向中之下一個編碼合成傳輸頻道(CCTrCH)(步驟1334),且程序繼續於步驟1310。若無將被檢查之額外編碼合成傳輸頻道,則決定上鏈編碼合成傳輸頻道是否已被檢查(步驟1336)。若上鏈編碼合成傳輸頻道尚未被檢查,則第一上鏈編碼合成傳輸頻道係被選擇(步驟1338),且程序繼續於步驟1308。若所有上鏈編碼合成傳輸頻道均已被考慮(步驟1336),則無線傳輸/接收單元(WTRU)資訊及實體頻道資訊係被更新於無線資源管理無線傳輸/接收單元(WTRU)資料庫中,且編碼向量係被更新於無線資源管理胞元資料庫中(步驟1340)。 If the resource configuration is successful (step 1330), it is determined whether there is an additional coded composite transmission channel to be checked in the current direction (downlink or uplink) (step 1332). If there is an additional coded composite transmission channel to be examined, the next encoded intermediate transmission channel (CCTrCH) in the current direction (step 1334), and the process continues at step 1310. If there is no additional coded composite transmission channel to be checked, it is determined if the uplink encoded composite transmission channel has been checked (step 1336). If the uplink encoded composite transmission channel has not been checked, the first uplink encoded composite transmission channel is selected (step 1338) and the process continues at step 1308. If all of the uplink coded composite transmission channels have been considered (step 1336), the WTRU information and physical channel information are updated in a WTRU data base. And the code vector is updated in the radio resource management cell database (step 1340).

被更新無線傳輸/接收單元(WTRU)資訊係包含具有最新配置實體頻道資訊之上鏈編碼合成傳輸頻道資訊(用於將被附加或修改之編碼合成傳輸頻道(CCTrCH))及下鏈編碼合成傳輸頻道資訊(用於將被附加或修改之編碼合成傳輸頻道(CCTrCH))。編碼合成傳輸頻道資訊係包含編碼合成傳輸頻道(CCTrCH)識別,編碼合成傳輸頻道(CCTrCH)狀態,編碼合成傳輸頻道(CCTrCH)信號對干擾比率目標,保證資料速率,允許資料速率,及專用實體頻道資訊。專用實體頻道資訊包含專用實體頻道時間槽資訊列表,重複期間及重複長度。專用實體頻道時間槽資訊包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊包含頻道化編碼,編碼使用狀態,專用實體頻道識別及編碼信號對干擾目標。編碼向量資訊包含上鏈編碼向量資訊及下鏈編碼向量資訊。上鏈編碼向量資訊包含編碼識別,編碼塊標示及編碼使用 狀態。下鏈編碼向量資訊包含編碼識別及編碼使用狀態。 The updated WTRU information includes uplink coded composite transmission channel information (for coded composite transmission channel (CCTrCH) to be attached or modified) and downlink coded composite transmission with the latest configuration entity channel information. Channel information (for coded composite transmission channel (CCTrCH) to be attached or modified). The coded composite transmission channel information includes coded composite transmission channel (CCTrCH) identification, coded composite transmission channel (CCTrCH) state, coded composite transmission channel (CCTrCH) signal to interference ratio target, guaranteed data rate, allowed data rate, and dedicated physical channel. News. The dedicated entity channel information includes a list of dedicated physical channel time slot information, repetition period and repetition length. The dedicated physical channel time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding, coding usage status, dedicated physical channel identification and coding signals for interference targets. The coding vector information includes the uplink coding vector information and the downlink coding vector information. Up-chain coding vector information includes code recognition, coding block indication and coding use status. The downlink coding vector information includes code recognition and coding usage status.

實體頻道資訊及功率控制資訊接著被放入無線鏈結重新配置預備訊息(步驟1342),而狀態旗標係被設定標示為成功資源配置(步驟1344)且程序終止(步驟1320)。實體頻道資訊係包含時間槽資訊列表,重複期間及重複長度。時間槽資訊包含時間槽數,訓練序列移位及叢發類型,傳輸格式編碼指標呈現及編碼資訊列表。編碼資訊包含頻道化編碼及專用實體頻道識別。功率控制資訊包含啟始下鏈傳輸功率,最大下鏈傳輸功率,最小下鏈傳輸功率,最大上鏈信號對干擾比率及最小上鏈信號對干擾比率。本發明一實施中,單資料結構係被用於要求訊息及回應訊息,因為這兩訊息係包含許多共用資訊。 The physical channel information and power control information is then placed into the wireless link reconfiguration preparation message (step 1342), and the status flag is set to indicate successful resource configuration (step 1344) and the program terminates (step 1320). The physical channel information includes a list of time slot information, the repeat period and the repeat length. The time slot information includes the number of slots, the training sequence shift and the burst type, the transport format encoding indicator presentation and the encoded information list. The coding information includes channelization coding and dedicated physical channel identification. The power control information includes the start-down downlink transmission power, the maximum downlink transmission power, the minimum downlink transmission power, the maximum uplink signal-to-interference ratio, and the minimum uplink signal-to-interference ratio. In one implementation of the present invention, a single data structure is used for request messages and response messages because the two messages contain a lot of shared information.

若被選擇編碼合成傳輸頻道之服務類型係為非即時(步驟1312),則胞元中之非即時之可用時間槽係被決定(步驟1346)。若無可用時間槽(步驟1316),則此標示為失敗情況,且狀態旗標係被設定標示為失敗情況(步驟1318)且程序終止(步驟1322)。 If the type of service selected to encode the composite transmission channel is non-instant (step 1312), the non-instant available time slot in the cell is determined (step 1346). If no time slot is available (step 1316), then this is indicated as a failure condition, and the status flag is set to indicate a failure condition (step 1318) and the program terminates (step 1322).

若有可用時間槽(步驟1316),則被選擇編碼合成傳輸頻道之塊錯誤率(BLER)係被決定(步驟1322),且被要求資料速率係被計算(步驟1324)。被計算資料速率之編碼組係被獲得(步驟1326)且被選擇編碼合成傳輸頻道之實體頻道(時間槽及編碼)係被配置,而最佳解若被找到則被記錄(步驟1328)。步驟1328中之配置功能係被更詳細討論於以上第三a及b圖。若資源配置失敗(步驟1330),則狀態旗標係被設定標示為失敗情況(步驟1318)且功能終止(步驟1320)。若具有可用時間槽(步驟1348),則被選擇編碼合成傳輸頻道之塊錯誤率係被決定(步驟1350)。所有適用非即時服務之資料速率係被決定(步驟1352),且最高資料速率係被選擇(步驟1354)。被選擇資料速率之編碼組係被獲得(步驟1356),被選擇編碼合成傳輸頻道之 一般暫時專用頻道係被配置且最佳解若被找到則被記錄(步驟1358)。應注意,步驟1328及1538本質上相同;非即時服務中,專用頻道係為暫時。 If there is a time slot available (step 1316), the block error rate (BLER) of the selected coded composite transmission channel is determined (step 1322) and the requested data rate is calculated (step 1324). The encoded set of calculated data rates is obtained (step 1326) and the physical channel (time slot and code) selected to encode the composite transmission channel is configured, and the best solution is recorded if found (step 1328). The configuration functions in step 1328 are discussed in more detail in Figures 3a and b above. If the resource configuration fails (step 1330), the status flag is set to indicate a failure condition (step 1318) and the function terminates (step 1320). If there is an available time slot (step 1348), the block error rate of the selected coded composite transmission channel is determined (step 1350). The data rate for all applicable non-immediate services is determined (step 1352) and the highest data rate is selected (step 1354). A coded set of selected data rates is obtained (step 1356), selected to encode a composite transmission channel Typically the temporary dedicated channel is configured and the best solution is recorded if found (step 1358). It should be noted that steps 1328 and 1538 are essentially the same; in non-instant service, the dedicated channel is temporary.

若資源配置失敗(步驟1360),則決定是否具有將被檢查之額外資料速率(步驟1362)。若無其他將被檢查之資料速率,則狀態旗標係被設定標示為失敗情況(步驟1318)且程序終止(步驟1320)。若具有其他將被檢查之資料速率(步驟1362),則次高資料速率係被選擇(步驟1364),且程序繼續於步驟1356。若資料配置成功(步驟1360),則程序繼續如上述步驟1332。 If the resource configuration fails (step 1360), it is determined if there is an additional data rate to be checked (step 1362). If there are no other data rates to be checked, the status flag is set to indicate a failure condition (step 1318) and the program terminates (step 1320). If there are other data rates to be checked (step 1362), then the next highest data rate is selected (step 1364) and the process continues at step 1356. If the data configuration is successful (step 1360), the program continues as in step 1332 above.

應注意步驟1306,1336及1338,任一方向(下鏈或上鏈)係可首先被執行。如上述,下鏈方向係優先於上鏈方向被檢查。若上鏈優先於下鏈被檢查,則程序1300將以相同方式操作。 It should be noted that steps 1306, 1336 and 1338, either direction (lower or upper chain) may be performed first. As described above, the lower chain direction is checked in preference to the winding direction. If the winding is checked in preference to the lower chain, the program 1300 will operate in the same manner.

步驟1328及1358係有關呼叫快速動態頻道配置演算之頻道配置功能;此核心功能係為信號獨立且被說明於以上第三a及b圖。 Steps 1328 and 1358 are channel configuration functions for calling fast dynamic channel configuration calculus; this core function is signal independent and is illustrated in the above third a and b diagrams.

雖然較佳實施例係以使用分時雙工模式之第三代夥伴計劃(3GPP)寬頻分碼多重存取(W-CDMA)系統來說明,但實施例係可應用至任何混合分碼多重存取(CDMA)/分時多重存取(TDMA)通信系統。另外,通常使用如3GPPW-CDMA之建議分頻雙工(FDD)模式之光束形成之某些實施例係可應用至分碼多重存取系統。雖然本發明特定實施例已被顯示及說明,但只要不背離本發明範疇,熟練技術人士均可做許多修改及變異。以上說明提供例證且不限任何方式之特定發明。 Although the preferred embodiment is illustrated in a Third Generation Partnership Project (3GPP) Wideband Code Division Multiple Access (W-CDMA) system using time division duplex mode, embodiments can be applied to any hybrid code division multiple memory. Take (CDMA) / Time Division Multiple Access (TDMA) communication system. In addition, certain embodiments of beamforming, such as the proposed frequency division duplex (FDD) mode, such as 3GPP W-CDMA, are generally applicable to code division multiple access systems. While the invention has been shown and described with reference to the embodiments of the embodiments The above description provides specific examples of inventions that are illustrative and not limited in any way.

WTRU‧‧‧無線傳輸/接收單元 WTRU‧‧‧Wireless Transmission/Reception Unit

CCTrCH‧‧‧編碼合成傳輸頻道 CCTrCH‧‧‧Coded Synthetic Transmission Channel

Claims (15)

經配置用於實施快速動態頻道配置呼叫允許控制(CAC)的無線網路控制方法,該無線網路控制方法包括:一資料庫;一接收器,經配置用於接收啟始一呼叫允許控制的一要求訊息;一處理器,經配置用於處理該要求訊息且經配置用於從該資料庫獲得一可用時間槽的一列表以及一編碼組列表;該處理器更經配置用於將一編碼組分配給該可用時間槽以及用於將該編碼組分配儲存在該資料庫中;以及一傳輸器,經配置用於傳輸具有該編碼組分配的一回應訊息。 A wireless network control method configured to implement fast dynamic channel configuration call admission control (CAC), the wireless network control method comprising: a database; a receiver configured to receive a call admission control a request message; a processor configured to process the request message and configured to obtain a list of available time slots and a code group list from the database; the processor is further configured to encode A group is assigned to the available time slot and used to store the code group allocation in the database; and a transmitter configured to transmit a response message having the code group assignment. 如申請專利範圍第1項所述的無線網路控制器,其中該處理器經配置用於從該要求訊息中讀取一無線傳輸/接收單元(WTRU)量測、一WTRU編碼合成傳輸頻道資訊、一專用頻道資訊、以及一WTRU性能資訊。 The wireless network controller of claim 1, wherein the processor is configured to read a WTRU measurement, a WTRU coded composite transmission channel information from the request message. , a dedicated channel information, and a WTRU performance information. 如申請專利範圍第2項所述的無線網路控制器,其中該WTRU量測包括一下鏈干擾信號編碼功率。 The radio network controller of claim 2, wherein the WTRU measurement comprises a downlink interference signal coding power. 如申請專利範圍第1項所述的無線網路控制器,其中該處理器更經配置用於:檢查一胞元中的一編碼組的可用性;從該可用時間槽的列表產生一時間槽序列;以及指派一編碼組至一時間槽序列中的該可用時間槽以找尋一解,其中一成功指派為一解。 The wireless network controller of claim 1, wherein the processor is further configured to: check availability of a code group in a cell; generate a time slot sequence from the list of available time slots And assigning a code group to the available time slot in a time slot sequence to find a solution, one of which is successfully assigned as a solution. 如申請專利範圍第4項所述的無線網路控制器,其中該處理器更 經配置用於:計算用於該解的一干擾信號編碼功率(ISCP)值;以及選出具有一最低加權ISCP值的該解作為一最佳解。 The wireless network controller as described in claim 4, wherein the processor is further It is configured to: calculate an Interference Signal Coding Power (ISCP) value for the solution; and select the solution having a lowest weighted ISCP value as a best solution. 如申請專利範圍第1項所述的無線網路控制器,其中該資料庫經配置用於建立一無線傳輸/接收單元(WTRU)實體、記錄來自該要求訊息的一WTRU資訊、以及記錄一實體頻道資訊。 The wireless network controller of claim 1, wherein the database is configured to establish a wireless transmit/receive unit (WTRU) entity, record a WTRU information from the request message, and record an entity. Channel information. 如申請專利範圍第6項所述的無線網路控制器,其中,在該資料庫中記錄的該WTRU資訊包括:該WTRU識別;一交易識別;一無線鏈結資訊;一上鏈WTRU性能資訊,包括:每訊框的一時間槽最大數量;以及每時間槽的一上鏈實體頻道最大數量;以及一下鏈WTRU性能資訊,包括:每訊框的一時間槽最大數量;以及每時間槽的一下鏈實體頻道最大數量。 The wireless network controller of claim 6, wherein the WTRU information recorded in the database comprises: the WTRU identification; a transaction identification; a wireless link information; and an uplink WTRU performance information. The method includes: a maximum number of time slots per frame; and a maximum number of uplink physical channels per time slot; and a downlink WTRU performance information, including: a maximum number of time slots per frame; and a time slot per time slot The maximum number of physical channels in the chain. 如申請專利範圍第7項所述的無線網路控制器,其中該無線鏈結資訊包括:該無線鏈結識別;一胞元識別;一上鏈編碼合成傳輸頻道(CCTrCH)資訊;以及一下鏈CCTrCH資訊。 The wireless network controller of claim 7, wherein the wireless link information comprises: the wireless link identification; a cell identification; a uplink encoded combined transmission channel (CCTrCH) information; and a chain CCTrCH information. 如申請專利範圍第8項所述的無線網路控制器,其中該CCTrCH資訊包括: 一CCTrCH識別;一CCTrCH狀態;一CCTrCH信號干擾比目標;一保證資料速率;一允許資料速率;以及一專用實體頻道資訊。 The wireless network controller of claim 8, wherein the CCTrCH information comprises: A CCTrCH identification; a CCTrCH state; a CCTrCH signal interference ratio target; a guaranteed data rate; an allowed data rate; and a dedicated physical channel information. 如申請專利範圍第9項所述的無線網路控制器,其中該專用實體頻道資訊包括:一專用實體頻道時間槽資訊;一重複期間值;以及一重複長度值。 The wireless network controller of claim 9, wherein the dedicated physical channel information comprises: a dedicated physical channel time slot information; a repetition period value; and a repetition length value. 如申請專利範圍第10項所述的無線網路控制器,其中該專用實體頻道資訊包括:一時間槽數;一訓練序列移位及叢發類型;一傳輸格式編碼指標呈現;以及一編碼資訊。 The wireless network controller according to claim 10, wherein the dedicated physical channel information comprises: a time slot number; a training sequence shift and burst type; a transport format coding indicator presentation; and a coding information . 如申請專利範圍第11項所述的無線網路控制器,其中該編碼資訊包括:一頻道化編碼;一編碼使用狀態;一專用實體頻道識別;以及一編碼信號對干擾(SIR)目標。 The wireless network controller of claim 11, wherein the encoded information comprises: a channelization code; an encoding use state; a dedicated physical channel identification; and a coded signal pair interference (SIR) target. 如申請專利範圍第1項所述的無線網路控制器,其中該傳輸器包括該回應訊息中的一功率控制資訊以及一實體頻道資訊。 The wireless network controller of claim 1, wherein the transmitter includes a power control information and a physical channel information in the response message. 如申請專利範圍第13項所述的無線網路控制器,其中該功率控制資訊包括:一上鏈(UL)目標信號干擾比(SIR);一最大UL SIR;一最小UL SIR;一啟始下鏈(DL)傳輸功率;一最小DL傳輸功率;以及一最大允許UL傳輸功率。 The wireless network controller of claim 13, wherein the power control information comprises: a uplink (UL) target signal to interference ratio (SIR); a maximum UL SIR; a minimum UL SIR; Downlink (DL) transmission power; a minimum DL transmission power; and a maximum allowable UL transmission power. 如申請專利範圍第14項所述的無線網路控制器,其中該實體頻道資訊包括:一時間槽列表;以及各列表中的該頻道化編碼。 The wireless network controller of claim 14, wherein the physical channel information comprises: a time slot list; and the channelization code in each list.
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