[go: up one dir, main page]

CN101034952A - Scheduling information transmission method of E-DCH - Google Patents

Scheduling information transmission method of E-DCH Download PDF

Info

Publication number
CN101034952A
CN101034952A CN 200610024560 CN200610024560A CN101034952A CN 101034952 A CN101034952 A CN 101034952A CN 200610024560 CN200610024560 CN 200610024560 CN 200610024560 A CN200610024560 A CN 200610024560A CN 101034952 A CN101034952 A CN 101034952A
Authority
CN
China
Prior art keywords
dch
scheduling information
information
order
cyclic redundancy
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CN 200610024560
Other languages
Chinese (zh)
Other versions
CN100574168C (en
Inventor
刘晟
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
XFusion Digital Technologies Co Ltd
Original Assignee
Huawei Technologies Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Huawei Technologies Co Ltd filed Critical Huawei Technologies Co Ltd
Priority to CNB2006100245606A priority Critical patent/CN100574168C/en
Publication of CN101034952A publication Critical patent/CN101034952A/en
Application granted granted Critical
Publication of CN100574168C publication Critical patent/CN100574168C/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Mobile Radio Communication Systems (AREA)
  • Detection And Prevention Of Errors In Transmission (AREA)

Abstract

本发明涉及移动通信技术,公开了一种E-DCH中调度信息传输方法,使得UE在单独传输SI时能提高无线链路性能。本发明中,在UE单独传输SI时,采用根据协议的固定设定或通过相关的高层协议消息通知的阶数小于24的CRC对SI进行编码后发送给Node B,Node B则根据协议的固定设定或通过相关的高层协议消息的通知使用相同阶数的CRC检测所接收到的SI是否正确。通过在高层协议RRC、NBAP和RNSAP中添加新的IE使得相关消息能够指示UE所使用的CRC的阶数。

The invention relates to mobile communication technology, and discloses a scheduling information transmission method in E-DCH, so that UE can improve wireless link performance when transmitting SI alone. In the present invention, when the UE transmits the SI alone, the SI is encoded by a CRC whose order is less than 24 according to the fixed setting of the protocol or notified by the relevant high-level protocol message, and then sent to the Node B, and the Node B then sends it to the Node B according to the fixed setting of the protocol. It is set or notified by the relevant high-level protocol message to use the same order of CRC to detect whether the received SI is correct. By adding new IEs in the high-level protocols RRC, NBAP and RNSAP, related messages can indicate the order of the CRC used by the UE.

Description

E-DCH scheduling information transmission method as in
Technology
The present invention relates to mobile communication technology, in particular E-DCH technology.
BACKGROUND
Third Generation Partnership Project (3rd Generation Partnership Project, referred to "3GPP") As an important field of mobile communications organizations to promote the third generation mobile communication (The Third Generation, Referred to as "3G") standardization technique, the earlier version of the protocol in order of the upstream and downstream operations Contained are based on the dedicated channel.
With the development of mobile communication technology, 3G technology is constantly to evolve. High Speed ​​Downlink Packet Access (High Speed ​​Downlink Packet Access, referred to as "HSDPA"), and High Speed ​​Uplink stars Group Access (High Speed ​​Uplink Packet Access, referred to "HSUPA") is a 3G technology An important evolution. HSDPA and HSUPA in the packet scheduling and retransmissions from the base station node (Node B) control.
Wherein, HSDPA High Speed ​​Downlink Packet Access as the technique was introduced in 2002 to the 3GPP Version 5 (Release 5, referred to "R5") version, and in the 3GPP version 6 (Release 6, Referred to as "R6") was carried out some improvements, it uses a shorter 2 milliseconds (ms) between the transmission time Compartment (Transmission Timing Interval, abbreviated "TTI"), to achieve fast adaptive control. In the physical layer using the adaptive coding and modulation (Adaptive Modulation and Coding, referred to "AMC") and hybrid automatic retransmission request (Hybrid Auto Repeat reQuest, referred to as "HARQ").
In order to realize the user device (User Equipment, referred to "UE") high-speed downlink data transfer Lose, HSDPA two new downlink physical channels and an uplink physical channel, they are used for Carrying user data speed physical downlink shared channel (High Speed ​​Physical Downlink Shared Channel, referred to as "HS-PDSCH"), for carrying the accompanying data channel demodulation HS-PDSCH Required for a high-speed downlink shared signaling control channel (High Speed ​​Shared Control Channel, Referred to "HS-SCCH"), as well as for carrying the UE acknowledgment / non-acknowledgment (ACK / NACK) And a channel quality indicator (Channel Quality Indicator, referred to as "CQI") such feedback information (FBI) The uplink dedicated physical control channel (High Speed ​​Dedicated Physical Control Channel, Abbreviated "HS-DPCCH"). Node B via HS-DPCCH informed whether the data is correctly received, If not, will initiate retransmission, or send new data. ...
In order to realize the user device (User Equipment, referred to "UE") high-speed downlink data transfer Lose, HSDPA two new downlink physical channels and an uplink physical channel, they are used for Carrying user data speed physical downlink shared channel (High Speed ​​Physical Downlink Shared Channel, referred to as "HS-PDSCH"), for carrying the accompanying data channel demodulation HS-PDSCH Required for a high-speed downlink shared signaling control channel (High Speed ​​Shared Control Channel, Referred to "HS-SCCH"), as well as for carrying the UE acknowledgment / non-acknowledgment (ACK / NACK) And a channel quality indicator (Channel Quality Indicator, referred to as "CQI") such feedback information (FBI) The uplink dedicated physical control channel (High Speed ​​Dedicated Physical Control Channel, Abbreviated "HS-DPCCH"). Node B via HS-DPCCH informed whether the data is correctly received, If not, will initiate retransmission, or send new data. ...
HARQ technology combines the forward error correction code and retransmission, for the E-DCH physical layer fast retransmit, And through the initial transmission and retransmission soft merger between the physical layer to improve decoding performance.
For high efficiency of UE uplink data transmission, E-DCH new addition of two uplink physical channels and Three downlink physical channels, which are used to carry user data uplink E-DCH Dedicated number According to the transport channel (E-DCH Dedicated Physical Data Channel, referred to as "E-DPDCH"), With the physical layer signaling for transmission, provide for the E-DPDCH demodulation accompanying uplink signaling E-DCH Dedicated Control Channel (E-DCH Dedicated Physical Control Channel, referred to "E-DPCCH"), is used to control the transmission rate of the UE uplink E-DCH Absolute Grant Channel (E-DCH Absolute Grant Channel, referred to as "E-AGCH") and E-DCH relative grant channel Channel (E-DCH Relative Grant Channel, referred to as the "E-RGCH"), and for indicating the uplink Process data is correct E-DCH retransmission indicator channel (E-DCH HARQ Indicator Channel, referred to as the "E-HICH"). ...
For high efficiency of UE uplink data transmission, E-DCH new addition of two uplink physical channels and Three downlink physical channels, which are used to carry user data uplink E-DCH Dedicated number According to the transport channel (E-DCH Dedicated Physical Data Channel, referred to as "E-DPDCH"), With the physical layer signaling for transmission, provide for the E-DPDCH demodulation accompanying uplink signaling E-DCH Dedicated Control Channel (E-DCH Dedicated Physical Control Channel, referred to "E-DPCCH"), is used to control the transmission rate of the UE uplink E-DCH Absolute Grant Channel (E-DCH Absolute Grant Channel, referred to as "E-AGCH") and E-DCH relative grant channel Channel (E-DCH Relative Grant Channel, referred to as the "E-RGCH"), and for indicating the uplink Process data is correct E-DCH retransmission indicator channel (E-DCH HARQ Indicator Channel, referred to as the "E-HICH"). ...
Specifically, RSN used to indicate the HARQ process in HARQ transmission redundancy version of each (Redundancy Version, referred to "RV"), to represent the transport process of the state. RSN 0 The transmission is initial transmission, the transmission is not 0 retransmission are: first retransmission RSN is 1, the second retransmission RSN is 2, then the subsequent retransmission RSN are three.
Specifically, RSN used to indicate the HARQ process in HARQ transmission redundancy version of each (Redundancy Version, referred to "RV"), to represent the transport process of the state. RSN 0 The transmission is initial transmission, the transmission is not 0 retransmission are: first retransmission RSN is 1, the second retransmission RSN is 2, then the subsequent retransmission RSN are three....
"Happy" bit reflects the UE for uplink packet scheduling Node B fast results "satisfactory Degrees "on the Node B control fast uplink packet scheduling with auxiliary role. According to 3GPP specifications TS25.321, if the UE has sufficient transmit power in the case, the total current E-DCH data sent Send buffer data in "Happy_Bit_Delay_Condition" time in accordance with the current service Authorization (Serving Grant, referred to "SG") but can not complete the send, it will "Happy" bit Is set to "Unhappy"; or "Happy" bit is set to "Happy".
This 10-bit information via second Reed Male (Reed-Muller) code for the channel coding, 30 bits, formed, for 2ms TTI mode 30 after the encoded bits in the E-DPCCH is A 2ms sub-frame for transmission; for 10ms TTI mode, the encoded bits after 30 In the E-DPCCH frame is a 10ms 2ms sub-frame 5 at the same time (that is repeated 5 times) pass Lose. E-DPCCH/E-DPDCH frame format shown in Figure 1, E-DPCCH in a 10ms frame packet With 15 slots, each time slot 3 a 2ms sub-frame, i.e. a 10ms frame includes 5 2ms Sub-frame. The E-DPCCH slot format shown in Table 1.
Slot Format # i # i slot format Channel Bit Rate (kbps) Channel bit rate (one thousand Bits per second) SF Spreading factor Bits / Frame Bits / frame Bits / Subframe Bits / sub-frame Bits / Slot Bits / slot N data
  0   15   256   150   30   10
Table 1
It can be seen, each slot can transmit E-DPCCH 10 bits, a sub-frame may 2ms Transfer 30 bits.
In the E-DCH and HSDPA, because the HARQ operation, thus the bit error rate than the physical layer Other high transmission channel, and, E-DCH and HSDPA are often large transport block transmitted to 2ms For example an E-DCH TTI, the maximum transport block size of 11484 bits.
Communication is often used in a cyclic redundancy check (Cyclic Redundancy Check, referred to "CRC") Code to detect the transmitted data block is correct, for example, in the ITU-T recommendation of 2048kbit / s (kilobits Special sec) of PCM (Pulse Code Modulation, Pulse Code Modulation)-based equipment used in group With a length of 4 CRC, wherein the CRC code with generator polynomial gCRC4(D)=D 4+ D 1+1. According to a cyclic redundancy check (Cyclic Redundancy Check, referred to "CRC") of the original Li, CRC checksum to detect 100% of all odd random bit errors, even almost all A random number of bit errors, and the length is less than or equal to n consecutive bit errors (also called burst error SE), where n is the order of the CRC generator polynomial.
In 3GPP, the addition to the HSDPA and E-DCH transport channel outside, 3GPP specifications TS 25.212 length allows the use of the CRC bits are 24,16,12 and 8, the specific use of the CRC Length is determined by the radio resource control (Radio Resource Control, abbreviated "RRC") semi-static transfer Information elements of transport format information (Information Element, abbreviated "IE") determined.
Also according to the 3GPP specification TS 25.212, the transmit side MAC-e PDU into the physical layer After the first attach a 24-bit CRC, the transport block prior to the HARQ process block error rate (Block Error Rate, referred to as "BLER") high, in order to reliably detect transmission errors, the use of Order of 24 of the CRC to reduce the probability of false negative errors. Then the channel coding, interleaving and Star Block diagram mapping operations.
However, there is no need to transmit user data transmission SI separate case:
(1) UE Node B is not allowed to send data state control, namely SG parameters "Zero_Grant" or all HARQ processes are in a non-active state;
(2) UE Node B is allowed to send data to the control state, that SG parameter is not equal to "Zero_Grant" and at least one HARQ process is active, but in a non-active HARQ Process and in the active HARQ processes certain TTI corresponding buffer has no data to send Send.
In these cases, too, the individual 18-bit in the SI transmitted in the physical layer 24 to form a Bit CRC code, and then by channel coding, interleaving and constellation mapping operation finally E-DPDCH transmission.
In practical applications, the above scheme has the following problem: UE is in a separate wireless link transmission SI Performance is poor.
The main reason for this situation, because after the CRC after the physical layer transmission block Interleaving process, when the transport block is large consecutive higher bit error probability, the higher The CRC coding order of consecutive bits can be detected errors, but for a separate 18-bit transfer SI reported cases, 24-bit vs. 18-bit CRC SI is still long, leading to increased CRC itself SI transmission BLER, while the wireless transmission efficiency is low, and thus the capacity of the uplink with a The limits specified.
SUMMARY OF THE INVENTION
In view of this, the main object of the present invention is to provide a scheduling information in E-DCH transmission method Method, the UE when the individual transmission SI improve the wireless link performance.
To achieve the above object, the present invention provides a scheduling information in E-DCH transmission method, including Contains the following steps:
The user equipment is sent to the base station node scheduling information transmitted alone, the use of order less than 24 Encoding cyclic redundancy check of the transmission scheduling information is encoded;
The base station node receives the encoded information of the scheduling by using the same encoding Order of cyclic redundancy check code of the scheduling information mode detector.
Wherein said user equipment in advance by one of the following messages notify the cycle used in the base station node Ring redundancy check in the order of coding:
RRC layer message, the radio link establishment request message, the radio link reconfiguration prepare message Or radio link reconfiguration request message.
In addition, in the method, the radio resource control layer protocol information element added for indicating Encoding the cyclic redundancy check in the order;
The radio resource control layer carrying the message by the new information element, notify the base station The cyclic redundancy check node in the order of coding.
In addition, in the method, the new information element to the information element "Scheduling Information Configuration "and" E-DCH reconfguration information "in the.
In addition, in the method, the base station node or wireless network subsystem application part in the Applications Additional information element for indicating a cyclic redundancy check in order of coding;
The radio link setup request message, the radio link reconfiguration prepare message, and the radio link reconfiguration By the request message carrying the new information elements, notifying the base node of said cyclic redundancy Encoding test in order.
In addition, in the method, the new information element to the information element "E-DPCH Information "in.
The user equipment and the base station node according to a predetermined protocol cyclic redundancy check code except order Number, for transmission of the scheduling information for a single cyclic redundancy check code or detected.
In addition, in the method, the order of less than 24 cyclic redundancy check the order of coding One of the following:
4、8、12、16。
In addition, in the method, further comprising the steps of:
Said user device by determining the transport block size determining that the user equipment to the base station node hair Whether to send scheduling information for a single transmission.
In addition, in the method, further comprising the steps of:
Said user equipment after cyclic redundancy check code of the scheduling information to perform channel coding, cross Organizations, and constellation diagram mapping operations.
Can be found by comparing the present invention according to the prior technology, the main difference being that in UE-SI transmission, the use of a fixed set under the agreement or through the relevant high-level protocol messages through Knowledge of the order of less than 24 CRC encodes the SI sent to the Node B, Node B under the agreement Proposed fixed settings or through the relevant high-level protocol messages using the same order of the notification of the CRC detection The SI received correctly. By level protocol RRC, the base station node Application Part (Node-B Application Part, referred to "NBAP") and Radio Network Subsystem (Radio Network Subsystem Application Part, referred to "RNSAP") to add new elements of information makes the relevant information to Used by the UE indicates the order of the CRC. ...
Can be found by comparing the present invention according to the prior technology, the main difference being that in UE-SI transmission, the use of a fixed set under the agreement or through the relevant high-level protocol messages through Knowledge of the order of less than 24 CRC encodes the SI sent to the Node B, Node B under the agreement Proposed fixed settings or through the relevant high-level protocol messages using the same order of the notification of the CRC detection The SI received correctly. By level protocol RRC, the base station node Application Part (Node-B Application Part, referred to "NBAP") and Radio Network Subsystem (Radio Network Subsystem Application Part, referred to "RNSAP") to add new elements of information makes the relevant information to Used by the UE indicates the order of the CRC. ...
BRIEF DESCRIPTION
Figure 1 is a prior art schematic diagram of a frame format E-DPCCH/E-DPDCH;
Figure 2 is a first embodiment of the present invention, E-DCH transmission method in a flowchart of SI.
Specific embodiments
The object of the present invention, technical solutions and advantages more clearly below with reference to the present Ming as described in further detail.
The present invention is a single SI of reports transmitted in the physical layer channel coding and multiplexing, allowing the Less than 24 bits using a CRC code checksum reported as SI, which, CRC coding order to Thought 16,12,8 or 4. On the order of 16, 12 or 8 for CRC coding, by the corresponding TS 25.212, respectively, given the generator polynomial is as follows:
g CRC16(D)=D 16+D 12+D 5+1;
g CRC12(D)=D 12+D 11+D 3+D 2+D+1;
g CRC8(D)=D 8+D 7+D 4+D 3+D+1。
Order of 4 to CRC coding, the generating polynomial is as follows:
g CRC4(D)=D 4+D 1+1
In addition to individual transport in the SI report can be fixed using the order number one 16,12,8 or 4 of the CRC In addition, it allows high-level protocols such as RRC, NBAP, RNSAP such flexibility to configure individual transport SI Reporting the E-DCH transport block CRC of the order. In this way, the UE is in a separate transmission SI, CRC coding can reasonably selected length, so long as a result of the CRC coding SI transmission BLER Increase. And, in a separate transmission SI short length used when the CRC coding, wireless transmission efficiency improves Rate, thereby effectively reducing the uplink interference system, help to optimize the uplink capacity of the system.
A first embodiment of the present invention, an E-DCH in the SI transmission method shown in Figure 2, UE and Node B According to the agreement fixed settings of the CRC for a separate order for CRC coding SI transmission, the order less than 24, 4,8,12, or 16 for one.
In step 201, according to the current protocol version, SI reported Ks = 18 bits in length. Accordingly, In the MAC layer MAC-e PDU into the physical layer, UE needs to transmit that determine the size of the transport block, The MAC-e PDU size is 18 bits, and if it is, the transport block is a single transmission SI, Go to Step 202; otherwise the transport block for a non-single transport block transmitted SI,, proceeds to step 203.
In step 202, UE using the protocol of the CRC fixed settings for individual transmission order of the CRC SI Encoding, for example, the order number is set to 8.
In step 203, UE 24 using the CRC order SI transmission of non-single transport block is encoded.
In step 204, the transport block CRC encoded added, UE specified by TS25.212 Process for the transmission block for channel coding, interleaving and constellation mapping and other operations, and then send the transport block To Node B.
In step 205, Node B fixed under the agreement set, the received transmission SI separate transmission With this order of less than 24 blocks fixed set the order of the CRC detection, for example, the UE in step 202 Used to set the order of 8, according to the setting, Node B using the same order of CRC code is 8; Node B for separate transmission received from non-SI transmission block 24, based on existing technology uses the CRC-order Testing.
The second embodiment of the present invention, an E-DCH in the SI transmission method in the first embodiment is basically the same, The only difference is that, by adding a new RRC IE "CRC Size for Standalone Scheduling Info (CRC alone scheduling information size) "is used to indicate the physical layer transmission order of use of the CRC, SI transmitted in a separate case, the report may be the order of 8, 12 or 16. And, UE through RRC IE message carrying the new Node B by the advance notice of the order of CRC used in the E-DPDCH single Independent Transmission SI report, Node B according to the RRC message transmitted with the UE using block CRC coding The same order of the CRC of the received transport blocks for testing.
Specifically, in the RRC protocol, defines a description of E-DPDCH channel parameters IE "E-DPDCH Info (E-DPDCH Info)" shown in Table 2, which contains the "Scheduling Information Configuration (scheduling information Configuration) "in IE TS25.331 the RRC under the existing agreement Yee, describes the E-DPDCH transmission parameters associated wireless SI: "Periodicity for Scheduling Info-no grant (scheduling information cycle - non-authorized) "," Periodicity for Scheduling Info-grant (tune Degree of information lifecycle - authorization) "and" Power Offet for Scheduling Info (scheduling information power offset). "
Will add IE "CRC Size for Standalone Scheduling Info" to add the IE "Scheduling Information Configuration ", add the IE type (Need) is mandatory (Mandatory Present, Abbreviation "MP"), which ranges from integer 0,4,8,12,16 or 24. This allows the RNC For creating, modifying, and other E-DPDCH channel operation at the same time, the flexibility to specify the E-DPDCH transmission alone SI input of the CRC used when reporting the order of, for example, typically of the order of l6, 12,8 or 4.
Information Element / Group name Information Element / Group Name Need Type Multi Other Type and reference Reference Type Semantics description Semantic Description Version Version
E-TFCI table index E-TFCI Table Index MP Required Integer (0 ... 1) Integer (0) Indicates which standardised E-TFCI TB size table shall be used Indicate the standard used The E-TFCI transmission block Size Table REL-6 Version 6
E-DCH minimum set E-TFCI E-DCH minimum set of E-TFCI MD There is lack of Provincial value A must Options Integer (0 ... 127) Integer (0 ... 127) See [15]; Absence means no E-DCH minimum set See [15], the default representation No E-DCH minimum set REL-6 Version 6
Reference E-TFCIs Reference E-TFCI MP Required 1 to 8 1 to 8 See [29] See [29] REL-6 Version 6
> Reference E-TFCI Reference E-TFCI MP Required Integer (0 ... 127) Integer (0 ... 127) REL-6 Version 6
> Reference E-TFCI power offset Reference E-TFCI power offset MP Required Integer (0 ... 29) Integer (0 ... 29) Refer to quantization of the power offset in [28] Reference [28] in the power Quantitative offset REL-6 Version 6
Maximum channelisation codes Maximum channelisation code MP Required Enumerated (sf64, sf32, sf16, sf8, sf4, 2sf4, 2sf2, 2sf2 and 2sf4) Enumerated (sf64, sf32, sf16, sf8, sf4, 2sf4, 2sf2, 2sf2 and 2sf4) REL-6 Version 6
  PL non-max MP Required Real (0.44-1.0 by step of 0.04) Real numbers (0.44-1.0, With 0.04 increments) As defined in [27] In [27] are defined REL-6 Version 6
Scheduling Information Configuration Configure the scheduling information MP Required REL-6 Version 6
> 2ms scheduled transmission grant HARQ process allocation 2ms scheduling transmissions authorized HARQ process allocation MD There is lack of Provincial value A must Options Bitstring (8) Bit stream (8) MAC-d PDUs belonging to MAC-d flows not configured with a "Max MAC-e PDU contents size "are only allowed to be transmitted in those processes for which the bit is set to "1". Do not configure the "Maximum MAC-e PDU payload Size "is MAC-d flow of MAC-d PDU, only This bit is set to 1 Permitted in these processes Transmission. Bit 0 corresponds to HARQ process 0, bit 1 corresponds to HARQ process 1, ..., Corresponds to 0 HARQ process 0, 1 Corresponds to the HARQ into Cheng 1, ...... Default value is: transmission in all HARQ processes is allowed.Bit 0 is the first / leftmost bit of the bit string. The default is: In all HARQ processes are allowed Xu transmission. 0 indicates ratio The first bit stream / Leftmost one ratio Special. ... MAC-d PDUs belonging to MAC-d flows not configured with a "Max MAC-e PDU contents size "are only allowed to be transmitted in those processes for which the bit is set to "1". Do not configure the "Maximum MAC-e PDU payload Size "is MAC-d flow of MAC-d PDU, only This bit is set to 1 Permitted in these processes Transmission. Bit 0 corresponds to HARQ process 0, bit 1 corresponds to HARQ process 1, ..., Corresponds to 0 HARQ process 0, 1 Corresponds to the HARQ into Cheng 1, ...... Default value is: transmission in all HARQ processes is allowed.Bit 0 is the first / leftmost bit of the bit string. The default is: In all HARQ processes are allowed Xu transmission. 0 indicates ratio The first bit stream / Leftmost one ratio Special. ...
> Serving Grant Service authorization OP Optional REL-6 Version 6
>> Serving Grant value Service authorization values MP Required Integer (0 ... 37, 38) Integer (0 ... 37, 38) (0 .. 37) indicates E-DCH serving grant index as defned in [15]; index 38 means zero grant. (0 ... 37) indicated E-DCH service authorization cord Introduced [15] in the set Righteousness; index 38 represents 0 Authorization. REL-6 Version 6
>> Primary / Secondary Grant Selector Basic / second authorization selector MP Required Enumerated ("Primary", "Secondary") Enumerated ("base This "," second ") Indicates whether the Serving Grant is received with a Primary E-RNTI or Secondary E-RNTI Indicates the received service Authorization is a basic E-RNTI or the second E-RNTI. REL-6 Version 6
3-Index-Step Threshold 3 - Index - step threshold MD There is lack of Provincial value A must Options Integer (0 ... 37) Integer (0 ... 37) Refers to an index in the "SG-Table" (see [15]). Reference "SG Table" Index (see [15]). Default value is 0. The default value is 0. REL-6 Version 6
2-Index-Step Threshold 2 - Index - step threshold MD There is lack of Provincial value A must Options Integer (0 ... 37) Integer (0 ... 37) Refers to an index in the "SG-Table" (see [15]). Reference "SG Table" Index (see [15]). Default value is 0. The default value is 0. REL-6 Version 6
NOTE: If the Periodicity is set to 4ms and the E-DCH TTI is set to 10ms, the UE shall interpret the periodicity value as 10ms. Note: If the cycle is set to 4ms and E-DCHTTI to 10ms, UE will 10ms as the period value.
Table 2
RRC protocol while also shown in Table 3 IE "E-DCH reconfiguration information (E-DCH reconfiguration information), "added the IE" CRC Size for Standalone Scheduling Info ".
Information Element / Group name Information Element / Group Name Need Type Multi Other Type and reference Reference Type Semantics description Semantic Description Version Version
E-DCH RL Info new serving cell The E-DCH serving cell Wireless New link information OP Optional
> Primary CPICH info Primary CPICH information MP Required Primary CPICH info 10.3.6.60 Primary CPICH letter Interest 10.3.6.60 Indicates scheduling E-DCH cell from the active set cells. Cell from the active set Indicated in the scheduling E-DCH cell. REL-6 Version 6
> E-AGCH Info E-AGCH information MP Required E-AGCH Info 10.3.6.100 E-AGCH information 10.3.6.100 REL-6 Version 6
> Serving Grant Service authorization OP Optional REL-6 Version 6
>> Serving Grant value Service authorization values MP Required Integer (0 ... 37, 38) Integer (0 ... 37, 38) (0 ... 37) indicates E-DCH serving grant index as defined in [15]; index 38 means zero grant. (0 ... 37) indicated E-DCH service authorization cord Introduced [15] in the set Righteousness; index 38 represents 0 Authorization. REL-6 Version 6
>> Primary / Secondary Grant Selector Basic / second authorization selector MP Required Enumerated ("Primary", "Secondary") Enumerated ("base This "," second ") Indicates whether the Serving Grant is received with a Primary E-RNTI or Secondary E-RNTI. Indicates the received service Authorization is a basic E-RNTI or the second E-RNTI. REL-6 Version 6
E-DPCCH/DPCCH Power Offset E-DPCCH/DPCCH power Offset OP Optional Integer (0 ... 8) Integer (0 ... 8) Refer to quantization of the power offset in [28]. Reference [28] in the power Quantitative offset REL-6 Version 6
……
Figure A20061002456000191
Information Element / Group name Information Element / Group Name Need Type Multi Other Type and reference Reference Type Semantics description Semantic Description Version Version
Select E-RGCH information serving E-DCH cell is added to the active set with this message Only when the E-DCH service Cell growth through this message Plus activation settings when Exists.
>> E-RGCH Information E-RGCH information E-RGCH Info 10.3.6.102 E-RGCH information 10.3.6.102 REL-6 Version 6
>> E-RGCH release indicator E-RGCH version indication REL-6 Version 6
E-DCH RL Info other cells Other cells E-DCH radio Link Information OP Optional 1 to <Max E-DC H RL> 1 to < Maximum E-DC H Wireless Link> This IE is not allowed to include information on a RL added by this message This message is not allowed for this IE Includes wireless link Information
> Primary CPICH info Initial CPICH information MP Required Primary CPICH info 10.3.6.60 The initial letter CPICH Interest 10.3.6.60 REL-6 Version 6
> CHOICE E-HICH Information Select E-HICH information OP Optional
>> E-HICH Information E-HICH information E-HICH Info 10.3.6.101 E-HICH information 10.3.6.101 REL-6 Version 6
>> E-HICH release indicator E-HICH version indication REL-6 Version 6
> CHOICE E-RGCH Information Select E-RGCH information OP Optional
>> E-RGCH Information E-RGCH information E-RGCH Info 10.3.6.102 E-RGCH information 10.3.6.102 REL-6 Version 6
>>E-RGCH release   REL-6
Information Element / Group name Information Element / Group Name Need Type Multi Other Type and reference Reference Type Semantics description Semantic Description Version Version
indicator E-RGCH version indication Version 6
Table 3
Third embodiment of the present invention, an E-DCH transmission method in the SI mode of the second embodiment is basically the same, The only difference is that, by NBAP / RNSAP increase the IE "CRC Size for Standalone Scheduling Info ", to inform the serving Node B of the UE used in the report of the SI order of CRC.
Among them, the NBAP / RNSAP involved in three E-DCH establish, modify and re-distribution of the news, The "RADIO LINK SETUP REQUEST (Radio Link Setup Request message)", "RADIO LINK RECONFIGURATION PREPARE (radio link reconfiguration prepare message), "and" RADIO LINK RECONFIGURATION REQUEST (radio link reconfiguration request message) ", which were three messages Contains an E-DCH is used to define the physical channel parameter IE "E-DPCH Information (E-DPCH Information). "
Will add IE "CRC Size for Standalone Scheduling Info" to add these messages IE "E-DPCH Information" in. Among them, the new IE add on "RADIO LINK SETUP REQUEST "message is shown in Table 4.
Figure A20061002456000221
Table 4
The new IE add on "RADIO LINK RECONFIGURATION PREPARE" message As shown in Table 5.
Figure A20061002456000231
IE / Group Name Information Element / Group Name Presence Choose Range Range IE Type and Reference Parameters information element Examination type Semantics Description Semantic Description Criticality Critical state Assigned Criticality Pro conferred Boundary value
To Delete E-DCH MAC-d flow Delete Optional Be Discard
Serving E-DCH RL E-DCH serving radio link O Optional   9.2.2.48B YES Be reject Discard
Table 5
Add IE added to the "RADIO LINK RECONFIGURATION REQUEST" message As shown in Table 6.
IE / Group Name Information Element / Group Name Presence Choose Range Range IE Type and Reference Information elements Reference Type Semantics Description Semantic Description Criticality Critical state Assigned Criticality Pro conferred Boundary value
E-DCH serving radio link Optional Be Discard
Table 6
The three different embodiments, can improve the efficiency of the wireless transmission. However, since the first real Embodiment does not pass RRC, NBAP signaling and RNSAP SI reports on individual transport CRC coding length Configuration, so efficiency will be slightly higher; latter two embodiments through RRC, NBAP and RNSAP SI signaling reports for individual transport CRC code length can be flexibly configured.
Although the present invention with reference to certain preferred embodiments, the present invention has been illustrated and Description, the person of ordinary skill in the art should understand that, in form and details may be made ​​of its Kinds of changes without departing from the spirit and scope of the invention.

Claims (10)

  1. A method of scheduling information in E-DCH transmission method characterized by comprising the steps of:
    The user equipment is sent to the base station node scheduling information transmitted alone, the use of order less than 24 Encoding cyclic redundancy check of the transmission scheduling information is encoded;
    The base station node receives the encoded information of the scheduling by using the same encoding Order of cyclic redundancy check code of the scheduling information mode detector.
  2. (2) as claimed in claim 1, wherein an E-DCH in the scheduling information transmission method, wherein Said user device notified in advance by one of the following messages used in the base station node cyclic redundancy Test in the order of coding:
    RRC layer message, the radio link establishment request message, the radio link reconfiguration prepare message Or radio link reconfiguration request message.
  3. 3 according to claim 2, wherein the E-DCH scheduling information transmission method, wherein The radio resource control layer protocol information element added for indicating the cyclic redundancy check coding Where the order;
    The radio resource control layer carrying the message by the new information element, notify the base station The cyclic redundancy check node in the order of coding.
  4. As claimed in claim 3, wherein the E-DCH in the scheduling information transmission method, wherein Add the new information element in the information element "Scheduling Information Configuration" And "E-DCH reconfiguration information" in the.
  5. 5 according to claim 2, wherein the E-DCH scheduling information transmission method, wherein In the base station node applications partially or Radio Network Subsystem Application Part information element added to indicate Encoding the cyclic redundancy check in the order;
    The radio link setup request message, the radio link reconfiguration prepare message, and the radio link reconfiguration By the request message carrying the new information elements, notifying the base node of said cyclic redundancy Encoding test in order.
  6. As claimed in claim 5 in the E-DCH scheduling information transmission method, wherein The information elements of the new information element added to the "E-DPCH Information" in the.
  7. As claimed in claim 1 in the E-DCH scheduling information transmission method, wherein
    The user equipment and the base station node according to a predetermined protocol order of the cyclic redundancy check, with The transmission of the scheduling information of the individual cyclic redundancy check code or detected.
  8. As claimed in claim 1 in the E-DCH scheduling information transmission method, wherein Of the order of less than 24 cyclic redundancy check coding order of one of the following:
    4、8、12、16。
  9. As claimed in any of claims 1 to 8 wherein a scheduling information in E-DCH transmission method, Characterized by further comprising the steps of:
    Said user device by determining the transport block size determining that the user equipment to the base station node hair Whether to send scheduling information for a single transmission.
  10. A process according to claim 9, wherein the scheduling information in E-DCH transmission method, wherein, Further comprising the steps of:
    Said user equipment after cyclic redundancy check code of the scheduling information to perform channel coding, cross Organizations, and constellation diagram mapping operations.
CNB2006100245606A 2006-03-09 2006-03-09 Dispatching information transmission method among the E-DCH Active CN100574168C (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CNB2006100245606A CN100574168C (en) 2006-03-09 2006-03-09 Dispatching information transmission method among the E-DCH

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CNB2006100245606A CN100574168C (en) 2006-03-09 2006-03-09 Dispatching information transmission method among the E-DCH

Publications (2)

Publication Number Publication Date
CN101034952A true CN101034952A (en) 2007-09-12
CN100574168C CN100574168C (en) 2009-12-23

Family

ID=38731277

Family Applications (1)

Application Number Title Priority Date Filing Date
CNB2006100245606A Active CN100574168C (en) 2006-03-09 2006-03-09 Dispatching information transmission method among the E-DCH

Country Status (1)

Country Link
CN (1) CN100574168C (en)

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2009082974A1 (en) * 2007-12-27 2009-07-09 Huawei Technologies Co., Ltd. An indicating method and device of data packet header
CN102315896A (en) * 2010-06-30 2012-01-11 重庆重邮信科通信技术有限公司 Monitoring type channel receiving method
CN101904127B (en) * 2007-12-20 2013-12-25 艾利森电话股份有限公司 Control of up link common E-DCH transmission
CN104869087A (en) * 2008-12-31 2015-08-26 联发科技股份有限公司 Channel interleaving method, channel interleaver and channel encoding device
WO2015176275A1 (en) * 2014-05-22 2015-11-26 华为技术有限公司 Data sending and receiving method and apparatus
WO2017011980A1 (en) * 2015-07-20 2017-01-26 华为技术有限公司 Information sending method and apparatus, and information receiving method and apparatus
CN106817205A (en) * 2015-11-27 2017-06-09 中兴通讯股份有限公司 Data in special physical data channel dispatching method and device
CN106888072A (en) * 2017-03-24 2017-06-23 宇龙计算机通信科技(深圳)有限公司 Data transmission method and device
WO2018072615A1 (en) * 2016-10-19 2018-04-26 上海朗帛通信技术有限公司 Method and apparatus for ue and base station using variable number of check bits
CN108352931A (en) * 2015-10-30 2018-07-31 高通股份有限公司 Cyclic redundancy check length management
WO2020168986A1 (en) * 2019-02-20 2020-08-27 华为技术有限公司 Data transmission method and apparatus

Cited By (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101904127B (en) * 2007-12-20 2013-12-25 艾利森电话股份有限公司 Control of up link common E-DCH transmission
WO2009082974A1 (en) * 2007-12-27 2009-07-09 Huawei Technologies Co., Ltd. An indicating method and device of data packet header
CN104869087B (en) * 2008-12-31 2019-08-30 寰发股份有限公司 Channel interleaving method, channel interleaver and channel coding device
CN104869087A (en) * 2008-12-31 2015-08-26 联发科技股份有限公司 Channel interleaving method, channel interleaver and channel encoding device
CN102315896A (en) * 2010-06-30 2012-01-11 重庆重邮信科通信技术有限公司 Monitoring type channel receiving method
CN102315896B (en) * 2010-06-30 2015-12-02 重庆重邮信科通信技术有限公司 A kind of monitoring class channel method of reseptance
WO2015176275A1 (en) * 2014-05-22 2015-11-26 华为技术有限公司 Data sending and receiving method and apparatus
CN105340207A (en) * 2014-05-22 2016-02-17 华为技术有限公司 Data sending and receiving method and apparatus
US10637610B2 (en) 2015-07-20 2020-04-28 Huawei Technologies Co., Ltd. Information sending method and apparatus, and information receiving method and apparatus
WO2017011980A1 (en) * 2015-07-20 2017-01-26 华为技术有限公司 Information sending method and apparatus, and information receiving method and apparatus
CN108352931A (en) * 2015-10-30 2018-07-31 高通股份有限公司 Cyclic redundancy check length management
CN108352931B (en) * 2015-10-30 2021-03-16 高通股份有限公司 Method and apparatus for cyclic redundancy check length management
US11457379B2 (en) 2015-10-30 2022-09-27 Qualcomm Incorporated Cyclic redundancy check length management
CN106817205A (en) * 2015-11-27 2017-06-09 中兴通讯股份有限公司 Data in special physical data channel dispatching method and device
CN106817205B (en) * 2015-11-27 2020-09-15 中兴通讯股份有限公司 Dedicated physical data channel data scheduling method and device
WO2018072615A1 (en) * 2016-10-19 2018-04-26 上海朗帛通信技术有限公司 Method and apparatus for ue and base station using variable number of check bits
CN107968696A (en) * 2016-10-19 2018-04-27 上海朗帛通信技术有限公司 A kind of method and apparatus in UE for variable check bit number, base station
CN106888072A (en) * 2017-03-24 2017-06-23 宇龙计算机通信科技(深圳)有限公司 Data transmission method and device
CN106888072B (en) * 2017-03-24 2020-02-21 宇龙计算机通信科技(深圳)有限公司 Data transmission method and device
WO2020168986A1 (en) * 2019-02-20 2020-08-27 华为技术有限公司 Data transmission method and apparatus

Also Published As

Publication number Publication date
CN100574168C (en) 2009-12-23

Similar Documents

Publication Publication Date Title
US12107690B2 (en) Autonomous transmission for extended coverage
CN101034952A (en) Scheduling information transmission method of E-DCH
JP5694410B2 (en) Method and apparatus for providing acknowledgment and assignment messages using a single channel
US8625601B2 (en) Method and apparatus for low-overhead packet data transmission and control of reception mode
EP1849330B1 (en) Method of transmitting/receiving mbms
CN1228939C (en) Signalling method for inserting media into control entity in block data communication system
US8489128B2 (en) Efficient transmission on a shared data channel for wireless communication
CN101193421B (en) Random access control method, system and device in cell forward access channel state
AU2007285802B2 (en) Method and apparatus for low-overhead packet data transmission and control of reception mode
CN1750450A (en) Method and apparatus for sending user equipment status information for uplink packet transmission
CN1471254A (en) Device and method for encoding and decoding channel quality identification information
CN1722652A (en) Method and device for changing transmission time interval based on hybrid automatic repeat request
CN1992579A (en) Apparatus and method for communicating high speed shared control channel in wideband wireless communication system
CN1893335A (en) Method for supporting multi-stage modulation by controlling high-speed down-converter grouped access system
CN1833379A (en) Mobile station device and receiving method
CN102571265B (en) Data transmission method and transmitting apparatus
CN101192878A (en) A control method, system and device for high-speed downlink packet access transmission
CN101399644A (en) Method, system and device for implementing hybrid automatic request retransmission feedback mechanism
CN100455043C (en) E-DCH data transmission method
CN1855758A (en) Transmission rate control, mobile platform and RF station
CN100561900C (en) Method for transmitting service signal through E-DCH
CN1691544A (en) Uplink Signaling Transmission Method for Uplink Channel Enhancement in Low Rate Code Division Multiple Access System
CN1630379A (en) Uplink Signaling Transmission Method for Uplink Channel Enhancement in Low Rate Code Division Multiple Access System
JP2009212874A (en) Base station device, mobile device, mobile communication system, and channel processing control method used therefor
CN1798444A (en) Method for transmitting down going scheduling information in use for time division duplexing system in low rate

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
TR01 Transfer of patent right

Effective date of registration: 20211222

Address after: 450046 Floor 9, building 1, Zhengshang Boya Plaza, Longzihu wisdom Island, Zhengdong New Area, Zhengzhou City, Henan Province

Patentee after: xFusion Digital Technologies Co., Ltd.

Address before: 518129 Bantian HUAWEI headquarters office building, Longgang District, Guangdong, Shenzhen

Patentee before: HUAWEI TECHNOLOGIES Co.,Ltd.

TR01 Transfer of patent right