TW200947997A - Method and apparatus for scheduling transmissions via an enhanced dedicated channel - Google Patents

Abstract

A method and apparatus for scheduling transmissions via an enhanced dedicated channel (E-DCH) are disclosed. A scheduled power is calculated for scheduled data flows. A remaining transmit power is calculated for the E-DCH transmission. A rate request message is generated, wherein the scheduled power, remaining transmit power and rate request message are used to select transport format combinations (TFCs) and multiplex data scheduled for the E-DCH transmission. The remaining transmit power is calculated by subtracting from a maximum allowed power the power of a dedicated physical data channel (DPDCH), a dedicated physical control channel (DPCCH), a high speed dedicated physical control channel (HS-DPCCH), an enhanced uplink dedicated physical control channel (E-DPCCH) and a power margin.

Description

200947997 VI. Description of the Invention: TECHNICAL FIELD OF THE INVENTION The present invention relates to a wireless communication system. More particularly, the present invention relates to an enhanced dedicated channel (E_DCH) scheduling method and apparatus. [Prior Art] The improved up key (UL) coverage, output and transmission latency methods are currently being investigated in the 3rd Generation Partnership Project (3GPP). To achieve these goals, Enhanced Uplink (EU) transmission has been proposed in the Third Generation Partnership Program, where the uplink resource (ie physical channel) control (ie scheduling and dispatching) is from the wireless network controller ( RN〇 is moved to Node B. Figure 1A shows a traditional WTRU (e.g., mobile station) 'Side Media Access Control (MAC) architecture. 无线 Wireless Transmit/Receive Unit Side Media Access Control The architecture 1 includes a media access control - es / media access control - e entity 1 〇 5, which contains different independent sub-layer entities within the media access control. Media access control _eS / _e Wei Ling (four) The result of how the domain access is divided into the wireless network of the thief. The result of the 1-line transmission/receiving unit side media access control architecture further includes a high-speed media access control entity, media access. (4) Magnetic 115... dedicated media access control (MAC-d) 120 and a media access control service access point (SAP) 125. Media access control ♦ 彳 115 115 can control access in addition to high-speed down key sharing channel (HS DSCH) 145 all shared transmission channels. Dedicated channel media storage The control 120 can control access to all dedicated transmission channels, media access control and media access control _hsU. Media access control - 1 can control access to the high speed downlink shared channel 145. 200947997 Media Access Control_es/ The media access control_e entity 105 can control the access enhanced dedicated channel 13', whereby the media access control-d 120 can access the enhanced dedicated channel via the connection 135 and the media access control SAP 125 can access the enhanced dedicated via the connection 140 Channel 130. Figure 1B shows the media access control interaction operation in the conventional WTRU in Figure 1A. As shown in Figure 1B, the GSM protocol data unit (PDU) is tied to the logical channel. Enter media access control. The media access control <header' data description indicator (DDI) block (6-bit) identifies the logical channel, media access control-d stream, and media access control protocol data unit size. The mapping table is transmitted on the Radio Resource Control (RRC) signal transmission to cause the WTRU to set the data description indicator value. The N field (6-bit fixed-size) is the number of consecutive media access control-d protocol data units corresponding to the same data description indicator value. Data Description Indicator Blocking Special Values are indicated No data is included in the remainder of the Media Access Control-e Agreement Data Unit. The Transmission Sequence Number (TSN) Block (6-bit) provides the transmission sequence number on the enhanced dedicated channel 130 shown in Figure 1A. The media access control-e-protocol data unit is forwarded to the hybrid automatic repeat request (H_ARQ) entity, which then forwards the media access control-e-protocol data unit to layer 1 for transmission in a transmission time segment (TTI) . An effective media access control architecture that enhances the scheduling of dedicated channel data transmissions is expected. SUMMARY OF THE INVENTION The present invention relates to an enhanced dedicated channel scheduling method and apparatus. The schedule power is calculated for the scheduled data stream. The remaining transmission power is calculated for enhanced dedicated channel transmission. The rate requirement message is generated, in which the scheduled power, and the remaining 200947997 transmission power and rate requirement messages are used to select the transmission type combinations (TFCs) and the multiplexed scheduled data used to enhance the transmission of the dedicated channel. The remaining transmission power is enhanced by extracting the dedicated physical data channel (DpDCH), the dedicated entity control channel (DPCCH), the high-speed dedicated entity control channel (hs_DPCCH), and the power of the uplink dedicated entity control channel (E_DpCCH) from the maximum allowed power. The power margin is deducted to calculate. [Embodiment] Hereinafter, the wireless transmitting/receiving unit "includes, but is not limited to, a User Equipment (UE)' mobile station, a fixed or mobile subscriber unit, a pager, or any other type of user operable in a wireless environment. Thereafter, what is referred to as a 'B Node' term includes, but is not limited to, a base station address controller, an access point, or any other interface device in a wireless environment. Thereafter, the "media access control -e" noun will be used in common to refer to the media access control -e and media access control. The features of the invention may be incorporated into an integrated circuit (1C) or configured in a circuit comprising multiple interconnected components. Figure 2 shows a wireless transmit/receive unit media access __e turn configured in accordance with the present invention. The non-sending/receiving unit media access control-e architecture 2G0 includes a schedule permission processing unit 21, a remaining transmission power calculation unit 215, and a rate request processing unit 220. The schedule license processing unit 210 can receive at least one schedule license from at least one wireless switch group (rls) and drive the current schedule license. Scheduling licenses can be used to enhance the exclusive channel 225 received from the service with primary and secondary identifiers (that is, the enhanced dedicated wireless network 200947997 temporary identifier (Ε-RNTI) is used It is determined whether the absolute license is primary or secondary) 'relative license 230 received from the service enhanced private channel radio link group or relative license 235 received from the non-service enhanced private channel radio link. The schedule permission processing unit 210 may output a signal 240 indicating the amount of scheduled power used in the enhanced transmission format combination selection and the multiplex function for scheduling the data medium access control-d stream. The amount of scheduled power can be identified as the ratio of the channel power to the dedicated entity. For example, if the dedicated entity controls the channel power to be p, the scheduled power amount has a ratio of 2 to the dedicated entity control channel power. The amount of scheduled power is 2P. Alternatively, the amount of scheduled power can be identified as being used to schedule transmission data to prevent transmission format combination selection and multiplex functions from paying attention to the maximum transmission power of the dedicated entity control channel power measurement. If the dedicated entity control channel power must be propagated to different entities within the media access control, then there is processing overhead due to its rapid change. Furthermore, synchronizing time points is complicated. Therefore, since other scheduling related functions require the current dedicated entity to control the channel power knowledge, it is preferable to only one of the media access control_e in mind that the dedicated entity controls the channel power. When the media access control-e entity 105 cites the media access control-e function, the schedule permission processing unit 21 can determine the current service x. The physical layer may provide an absolute grant 225 received from the AGCH, and the standard license will be received with a primary or secondary enhanced dedicated channel wireless network temporary identifier. The physical layer also provides a relative license 230' 235 that is received from each radio link group, the radio link group being a service enhanced dedicated channel radio link group or a non-service enhanced dedicated channel radio channel.绝# Licensing 200947997 rate = is sent as the ratio of the current channel-specific entity control channel power. Breaking the temporary identification of the wireless network with the main enhanced dedicated channel. It is necessary to re-set the current service license for the license 225. If the previously used secondary channel wireless network temporary identifier or permission setting is SX疋 zero, then the absolute permission received by the secondary enhanced private channel wireless network temporary identifier only validates the current service license. The relative license 230 from the non-service enhanced dedicated channel wireless key is to adjust the service license in steps or steps. Non-service enhanced dedicated channels The wireless link group's materials can only be used to reduce service licenses. When the relative grant from the non-service enhanced dedicated channel radio link group is received downwards, the hysteresis period is initiated while other relative grants are being ignored. The remaining transmission power calculation unit 215 can receive a signal 245 indicating the current dedicated entity control channel power estimated by the physical layer, indicating the dedicated channel transmission format combination selected by the media access control-d or the dedicated entity data estimated by the physical layer. The channel power signal is 25 〇, which can indicate the active signal 255 from the high-speed dedicated entity control channel from the real layer and the maximum allowable power (with power capacity) from the lower layer management entity (LLME) configured by the Radio Resource Controller (RRC). Signal 260. If the high-speed dedicated entity control channel is active, its power (and power from other channels) must be drawn from the maximum power to determine the remaining power. Based on the signals 245, 250, 255 and 260, the remaining transmission power calculation unit 215 can output a signal indicating the remaining transmission power (Premain) calculated according to the following equation (1): 265 : 200947997

Premain ~ Pallowed ~~ PDPDCH ~ PDPCCH ~~ PHS-DPCCH ~~ PE-DPCCH ~~

Margin; Equation (1) where Pdpcch ' PDPDCH ' PHS-DPCCH and pE DPCCH represent the power requirements of the dedicated entity control channel 'private entity data channel, the high speed dedicated entity control channel and the enhanced uplink dedicated entity control channel, respectively. The rate requirement processing unit 220 can monitor the triggering event of the rate requirement and trigger the scheduling information rate request when the triggering event occurs. Rate requirement processing unit 220 may provide logic to trigger rate requirements and logic to construct rate requirement message 270 containing rate requirement bits. When there is no current scheduling permission and is received when new data is mapped to the logical channel of the enhanced dedicated channel, the rate requirement can be triggered, and the higher priority and the last reported new data is received and mapped. To the logical channel of the enhanced dedicated channel 'when there is no current scheduling permission and the rate requirement is updated and periodically generated (which is configured by the radio resource controller), and when the serving radio link group acknowledgement (ACK) is not due to the previous When received by the transmission rate request, an updated rate requirement is generated. The rate requirement includes the total buffer occupancy of all scheduled media access control_d streams, the highest priority data buffer occupancy of any media access control_d stream, and the power remaining space available for enhanced dedicated channel transmission. Referring to Fig. 3, the media access control_e scheduling process 300 is explained as follows. The enhanced dedicated channel transmission time zone is monitored and it determines whether the scheduled information rate request triggers the occurrence and/or whether the enhanced enhanced dedicated channel material is available (step 302). If no rate request triggers or does not enhance the dedicated channel data, the process waits until the next pass 200947997 = inter-zone. If the decision to move the step is affirmative, whether there is available hybrid automatic repeat request processing (successive combination selection and enhanced dedicated channel data == repeated request processing availability. If there is no available missed automatic repeat == then the process 300 waits until The lower-transmission time section. If the mixing 5 is automatically repeated, the processing of the shirt is required to be used in the step tearing. The pre-scheduled permission and the remaining transmission power calculation are distributed by the processing unit to the remaining transmission power calculation unit ^3〇6). In the step, the media access control and e control function illuminate the schedule and enhance the transport format combination selection function to generate a media access control_e protocol data unit. In step 31, the media access control < protocol data unit is then forwarded to the available hybrid automatic repeat request processing with the unique power offset and retransmission maximum number. In a separate embodiment that satisfies the media access control-e-protocol data unit forming point requirements, the pre-calculation of the possible media access control_e protocol data unit that speeds up the forming process is utilized. When the media access control_e entity is required to perform enhanced dedicated channel transmission with the remaining power budget, the forming process searches the pre-formed media access control_e agreement data unit table (ie, its formed media access control-e protocol) The data unit header and the appropriate data block agreement data unit) provide ready-made information to the hybrid automatic repeat request/physical layer. There are several methods of performing this prior processing depending on the point of time requirements. Figure 4 shows an example of a pre-processed Media Access Control-e protocol data unit format configured in accordance with the present invention. Pre-Processed Media Access Control 200947997-e Protocol Data Unit Format contains power budgets for enhanced dedicated channels or equivalents. Fully formatted media access control - e-protocol data unit headers that best fit the budget or equivalent , Transmission Sequence Number (TSNs) and data block indicator list, schedule information and padding bits. The power budget for the enhanced dedicated channel contains several expected powers or equivalents based on the final transmission power and on the basis of this prediction. The Media Access Control-e Protocol Data Unit header is formatted based on this budget and the data priority on the same column. The fully formatted media access control-e-protocol data unit header is described in terms of logical channel prioritization, and is considered for scheduled and non-scheduled data and budget to describe the media access control-e protocol data unit. The header contains a data description indicator that describes the indicator terminator. The media access control including the transmission sequence number and the data index of the media access control-es_es protocol data unit description table column corresponds to the same column pre-formatted protocol data element header. If the schedule information exists, it can be associated with the Media Access Control_e agreement data unit. The padding bit indicates the number of bits at the end of the media access control-e protocol data unit for that particular suffix. Full formatting allows you to use some of the following information: Enhance the power budget for a dedicated channel or equivalent, and the data description indicator 'scheduled or non-scheduled. This type of list is based on data priority (10) for media access (4) collar (rhythm access control data says: month finger two 7°). 1 The rate budget is listed for the expected power budget. Identification 1 Association:: Rainbow represents media access control _d stream identification, logical channel: unit size. Scheduling or non-rowing indicates that the agreement is based on the power budget or scheduling power budget. Non-scheduled 11 200947997 The media access control-e agreement data can also be used together with the scheduling information. Although the features and elements of the present invention are described in a particular combination, the preferred features of the embodiments and the other features of the embodiments and/or other combinations of other features and components of the present invention are Use alone. BRIEF DESCRIPTION OF THE DRAWINGS The present invention can be understood in more detail from the following description of the preferred embodiments, in which: FIG. 1A shows the conventional wireless transmission/reception unit side media access control. FIG. Prior art media access control interaction operation in a WTRU; WTRU configured in accordance with the present invention; FIG. 2 shows meta-media access control - < Figure 3 is in accordance with the present invention The media access control_^ scheduling process flowchart; and FIG. 4 shows an example of a pre-processing control-e protocol data unit format configured in accordance with the present invention. [Main component symbol description] DCH dedicated channel DDI data description indication DPCCH dedicated entity control channel E enhanced DI> DCH dedicated entity data channel HS local speed DSCH downlink shared channel ID identifier HARQ hybrid automatic repeat request N field 12 200947997 LLME Lower management entity Opt selectable MAC media access control P power MAC-d dedicated channel media access control PCCH entity control channel PDU protocol data early element RLC wireless link control RLS wireless key group RRC radio resource control SAP media access control TFC transport format combination TSN transmission sequence number TTI transmission time segment wtru wireless transmission/reception unit 13

Claims (1)

200947997 VII. Patent application scope: 1. Scheduled Enhanced Media Access Control (MAC-e) device, including · Monitoring a Enhanced Downlink Control Channel (E-DCH) for a trigger; based on the trigger , stimulating a scheduling function and an enhanced transport format combination (E-TFC) selection function to generate a enhanced medium access control protocol data unit (PDU); and forwarding the MAC with a power offset and a maximum retransmission number The -ePDU is given to a Hybrid Automatic Repeat Requirement (H-ARQ) process. 2. A wireless transmit/receive unit comprising: a rate requirement processing unit configured to: monitor a enhanced downlink control channel (E-DCH) in one or more E-DCH transmission time segments (ττΐ) And determining whether a scheduled information rate request triggers the occurrence or presence of E-DCH data with an available license, the WTRU being configured to: condition that triggers the occurrence or absence of E-DCH data with available permissions at the rate request Next, wait for the next TTI; under the condition that the rate request triggers or there is E_Dci^ material with available licenses, 'Determining whether there is - available hybrid automatic repeating to post (New Zealand) processing; In the absence of available H- Under the condition of ARQ processing, wait until the next TTI; under the condition of the H_ARQ difference, request_current scheduling permission 14 200947997 and the remaining transmission power calculation; cite a scheduling function and a combination of enhanced transmission formats (Ε -TFC) selects a function and generates a Enhanced Media Access Control (MAC-e) Protocol Data Unit (PDU); and forwards the MAC-e PDU to the available H with a power offset and a maximum retransmission number -ARQ processing. 3. A Enhanced Media Access Control Protocol data unit (pDU^' contains: a power budget block for an enhanced lower key control channel (E_DCH); a MAC-ePDU header configured for adaptation The power budget; and a list of 'including the transmission sequence number (TSN) and the data block indicator, and the schedule information and the padding bits. 4. The MAC_e PDU as described in claim 3, wherein the The power budget of the E-DCH includes: an expected power level based on a final transmission power level; and a current possible power budget prediction. 5. The MAC-e PDU as described in claim 4, wherein The MAC-e PDU header is formatted based on the power budget and data priority. 6. The MAC-e PDU according to item 5 of the Shenjing patent scope, wherein the MAC-e PDU header includes: 15 200947997 Logical channel priority field; scheduled and non-scheduled data; a data description indicator (DDI); an N-bit, indicating continuous dedicated channel media access control (MAC-d) corresponding to a same DDI value The number of PDUs; and a DDI terminator. 16