KR101523973B1 - Device and method for transmitting and receiving resource allocation message in wireless communicating system - Google Patents

Abstract

The present invention relates to an apparatus and a method for processing an unacknowledged error transmission resource allocation message in a mobile communication system.

The UE's error correcting transmission resource allocation control apparatus includes a receiver for receiving and decoding a resource allocation message transmitted from a base station, a PDCCH processor for calculating an error by calculating the decoded signal, MAC PDU generation unit for transmitting the MAC PDU to the transmission and reception unit, and a MAC PDU generation unit for analyzing a transmission resource allocation message transmitted from the PDCCH processing unit to distinguish an unrecognized error transmission resource allocation message, And a controller for controlling the MAC PDU generator to prevent transmission from proceeding.

Physical Downlink Control Channel (PDCCH)

Description

TECHNICAL FIELD [0001] The present invention relates to a device and a method for transmitting and receiving a transmission resource allocation message in a mobile communication system,

The present invention relates to a method and apparatus for reducing waste of transmission resources due to an unrecognized error resource allocation by allowing a user to recognize a frequency error even when a resource allocation message for allocating a bandwidth for data transmission is received in a mobile communication system.

The Universal Mobile Telecommunication Service (UMTS) system is based on Global System for Mobile Communications (GSM) and General Packet Radio Services (GPRS), which are European mobile communication systems, and includes a Wideband Code Division Multiple Access CDMA ") is used as the third-generation asynchronous mobile communication system.

In the 3rd Generation Partnership Project (3GPP), which is in charge of standardization of UMTS, a discussion on LTE (Long Term Evolution) is underway as a next generation mobile communication system of UMTS system. LTE is a technology that implements high-speed packet-based communication with a transmission rate of up to 100 Mbps and aims to commercialize it in about 2010. Various schemes are being discussed for this purpose. For example, there are discussions to reduce the number of nodes located on the communication path by simplifying the structure of the network, and to approach the wireless protocols as much as possible to the wireless channel.

1 shows a structure of an LTE mobile communication system.

1, an Evolved Radio Access Network (hereinafter referred to as E-RAN) 110 and 112 includes an Evolved Node B (hereinafter, referred to as an ENB or Node B) 120 , 122, 124, 126 and 128, and an upper node (referred to as an Access Gateway) 130 and 132, respectively. A user equipment (UE) 101 is connected to an Internet Protocol (hereinafter referred to as IP) network by an E-RAN 110 or 112.

The ENBs 120-128 correspond to the existing Node B of the UMTS system. The ENB is connected to the UE 101 via a radio channel, and plays a more complex role than the existing Node B. In LTE, all user traffic, including real-time services such as Voice over IP (VoIP) via the Internet protocol, is serviced through a shared channel. Therefore, a device for collecting and scheduling situation information of UEs is needed. (120 to 128). One ENB typically controls multiple cells. In order to realize a transmission rate of up to 100 Mbps, LTE uses Orthogonal Frequency Division Multiplexing (OFDM) as a radio access technology in a bandwidth of up to 20 MHz. In addition, Adaptive Modulation and Coding (AMC) scheme is used to determine a modulation scheme and a channel coding rate in accordance with a channel state of a UE.

As shown in FIG. 2, the wireless protocols of the LTE system include Packet Data Convergence Protocols (PDCP) 205 and 240, RLC (Radio Link Control) 210 and RLC (Medium Access Control) 215 and 230. The PDCP (Packet Data Convergence Protocol) 205 and 240 are responsible for operations such as IP header compression / decompression and Radio Link Control (RLC) 210 and 235 are PDCP PDU Hereinafter, a packet output from a specific protocol layer device is referred to as a PDU of the protocol) is reconfigured to an appropriate size to perform an ARQ operation or the like. The MACs 215 and 230 are connected to a plurality of RLC layer devices configured in a terminal, multiplex RLC PDUs into MAC PDUs, and demultiplex RLC PDUs from MAC PDUs. The physical layers 220 and 225 perform channel coding and modulation of the upper layer data and transmit the OFDM symbols on a wireless channel or demodulate OFDM symbols received on a wireless channel, channel decoding, and transmit the OFDM symbols to an upper layer.

3 is a diagram illustrating a general reverse data transmission process.

In an LTE mobile communication system, a terminal reports the amount and type of data to be transmitted to a base station in order to transmit reverse data. This process is described in more detail below.

When reverse data is generated (315) in the terminal 305 where the buffer is empty at an arbitrary point in time, the terminal transmits a Scheduling Request signal on a predetermined reverse dedicated channel. The scheduling request signal is a signal for requesting allocation of a transmission resource to the base station by the 1-bit information. The base station can allocate a transmission resource for transmitting a scheduling request signal to the mobile station through a call setup process or the like. Upon receiving the scheduling request signal, the BS allocates an uplink resource to the MS (step 325), and the MS transmits a BS state report message using the allocated uplink resource (step 330). The buffer status report message includes information on the amount of data to be transmitted, priority, and the like. Upon receiving the buffer status report message, the BS refers to the buffer status of the UE and schedules the UE. For example, the UE allocates an uplink transmission resource to the UE at an appropriate time (340), and the UE transmits the MAC PDU containing the uplink data using the allocated uplink transmission resource (345). The above operation is repeated until the buffer of the terminal becomes empty. The terminal transmits information indicating that the buffer is empty together with transmitting the last data (350). The information may be, for example, a buffer status report message indicating that the amount of data to be transmitted is zero.

In the LTE mobile communication system, a transmission resource allocation message is transmitted to the UE through a control channel called PDCCH (Physical Downlink Control Channel). The transmission resource allocation message is divided into an uplink resource assignment message and a downlink resource assignment message. The transmission resource allocation message includes transmission resource information and Modulation Coding Scheme (MCS) information, and the terminal transmits data coded with the modulation scheme and the coding rate indicated in the MCS information through the transmission resource indicated in the transmission resource information send. The size of the data transmitted through the allocated transmission resource is derived from the allocated transmission resource amount and the MCS information.

Describing PDCCH in more detail, the PDCCH occupies a maximum of 3 OFDM symbols per 1 msec over the entire system bandwidth. Various types of control messages can be transmitted in various formats via the PDCCH, and the UE attempts to decode all possible types of control messages and all formats. Successful decoding is determined by a 16-bit CRC operation performed after masking the C-RNTI of the UE. In order to determine whether or not to allocate a transmission resource, the number of decoding attempts per 1 msec is usually about 20 times. Since the length of the CRC is 16 bits, a false positive occurs one time per decoding of 65536 probabilities, so that the UE can misidentify a transmission resource allocation message composed of erroneous information as an errorless message. An erroneous decoding success means that the CRC succeeds in the erroneous data due to the CRC error detection failure.

For convenience of explanation, a transmission resource allocation message with an erroneous erroneous error-free message is referred to as an unrecognized error transmission resource allocation message.

Upon receipt of the unrecognized error transmission resource allocation message, the UE incorrectly assumes that the unallocated transmission resource is allocated, and transmits data through the incorrect transmission resource. Is required.

  The present invention reduces the occurrence frequency of an unrecognized error transmission resource allocation message in a mobile communication system to reduce transmission resource waste due to an unrecognized error resource allocation.

A method for transmitting and receiving a transmission resource allocation message according to the present invention may be implemented by the first to sixth embodiments.

First, an apparatus and method for processing an unacknowledged resource allocation message according to the first embodiment of the present invention includes the steps of: determining whether a buffer of the UE is empty or a UE transmitting information indicating that the buffer is empty to the Node B, , It is determined that it is an unrecognized error transmission resource allocation message. Second, the second embodiment of the present invention manages a variable called a Node B-estimated buffer state, and upon receipt of an uplink resource assignment message, compares the size of data to be transmitted indicated by the assignment message with the Node B- And determines whether the uplink transmission resource allocation message is an incorrect transmission resource allocation message. Third, when an excessive padding bit is inserted into data to be transmitted, the third embodiment of the present invention determines that data transmission is based on an unacknowledged transmission resource allocation message and does not transmit data. Fourth, in order to reduce the probability of occurrence of an unrecognized error message for an uplink transmission resource allocation message indicating a data transmission of a predetermined size or greater or allocating more transmission resources than a predetermined reference, The UE transmits a predetermined uplink transmission resource allocation message before transmitting the uplink Tx allocation message satisfying the condition, and the UE transmits the uplink Tx allocation message in the reverse direction The transmission resource allocation message is determined to be an unacknowledged transmission resource allocation message. Fifth, the fifth embodiment of the present invention uses the same message as the second transmission resource allocation message as the first transmission resource allocation message. Sixth, according to a sixth embodiment of the present invention, a UE calculates a required transmission output upon reception of an uplink transmission resource allocation message, and when the requested transmission output exceeds a maximum transmission output of the UE by a predetermined reference or more, It is determined to be the acknowledged transmission resource allocation message, and the transmission resource allocation message is ignored.

The terminal apparatus for processing a transmission resource allocation message according to the first to sixth embodiments of the present invention performs a processing operation according to each of the following embodiments. In the case of the first embodiment, the UE determines whether the buffer is empty. If the buffer is empty, the UE ignores the uplink resource assignment message transmitted by the PDCCH processor. If the buffer is empty, And controls the transmission / reception unit and the MAC PDU generation unit such that the MAC PDU is transmitted according to the contents of the supplemental uplink transmission resource allocation message. Second, in the case of the second embodiment, the terminal manages the Node B-estimated BS state variable and compares the size of the MAC PDU to be transmitted with the BS estimated buffer state indicated in the uplink transmission resource allocation message delivered by the PDCCH processor, It determines whether the MAC PDU is a resource allocation message and controls the MAC PDU generation unit accordingly. Third, in the case of the third embodiment, when the rate of padding received in the MAC PDU generated by the MAC PDU generation unit exceeds a predetermined value, the terminal apparatus controls the MAC PDU generation unit and the transmission / reception unit so that the transmission of the MAC PDU is canceled. do. Fourth, in the case of the fourth embodiment, the terminal distinguishes the first transmission resource allocation message, the second transmission resource allocation message, and the general transmission resource allocation message, and the second transmission resource allocation message The message is determined to be an unrecognized error transmission resource allocation message. Fifth, in the case of the fifth embodiment, the terminal equals the second transmission resource allocation message and the general transmission resource allocation message, and transmits the same transmission resource allocation message to the second transmission resource allocation message Is determined to be an unrecognized error transmission resource allocation message. Sixth, in the case of the sixth embodiment of the present invention, the terminal apparatus distinguishes an unacknowledged error transmission resource allocation message using a transmission output. The transmission resource allocation message includes transmission resource information and MCS (Modulation Coding Scheme) information, and the UE transmits the coded data with the modulation scheme and coding rate indicated in the MCS information through the transmission resource indicated in the transmission resource information The terminal determines the transmission output of the data in consideration of the amount of transmission resources, the MCS level, the current channel status, and the like. If the requested transmission output exceeds the maximum transmission output of the terminal by a predetermined reference or more, It is determined to be the acknowledged transmission resource allocation message, and the transmission resource allocation message is ignored.

 The present invention reduces the transmission resource waste due to the unrecognized error resource allocation by allowing the mobile communication system to recognize the unrecognized error resource allocation message even when it occurs.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

The main idea of the present invention described below is to recognize an error in a transmission resource allocation message of a wireless system, and in particular, to provide an apparatus and a method for reducing the occurrence of unrecognized error transmission resources due to errors in a terminal or a system.

The first embodiment of the present invention proposes a method and apparatus for reducing the number of UEs decoding an uplink resource assignment message, thereby reducing the generation of unrecognized error transmission resources. In the first embodiment of the present invention, when processing an unacknowledged error transmission resource allocation message, if a terminal transmits information indicating that the buffer of the UE is empty or the buffer is empty to the Node B, the UE receives an uplink resource assignment message, It is judged as an unrecognized error transmission resource allocation message. That is, after transmitting the information indicating that the buffer state is empty or the buffer is empty to the base station, the UE does not decode the uplink resource assignment message or ignores the uplink resource assignment message even if the uplink resource assignment message is successfully decoded. For this, in the first embodiment, the UE determines whether the buffer is empty. If the buffer is empty, the UE ignores the uplink resource assignment message transmitted by the PDCCH processing unit. If the buffer is empty, the PDCCH process And controls the transmission / reception unit and the MAC PDU generation unit such that the MAC PDU is transmitted according to the contents of the supplemental uplink transmission resource allocation message.

In the second embodiment of the present invention, the base station does not allocate a transmission resource that can transmit more than the buffer size of the estimated terminal to the terminal. The UE manages a variable called a Node B-estimated buffer state. Upon receiving the uplink resource assignment message, the UE compares the size of the data to be transmitted indicated by the allocation message with the Node B-estimated buffer state, It is determined whether the message is a transmission resource allocation message. In order to achieve this, in the second embodiment, the MS manages the Node B-estimated BS state variable, compares the size of the MAC PDU to be transmitted and the BS estimated buffer state indicated in the uplink resource assignment message transmitted by the PDCCH processor, And controls the MAC PDU generation unit accordingly.

In the third embodiment of the present invention, when an excessive padding bit is inserted into data to be transmitted, the terminal determines that the data transmission is based on an unrecognized error transmission resource allocation message and does not transmit data. To this end, in the third embodiment, the UE controls the MAC PDU generation unit and the transmission / reception unit such that transmission of the MAC PDU is canceled when the ratio of the padding received in the MAC PDU generated by the MAC PDU generation unit exceeds a predetermined value.

In order to reduce the probability of occurrence of an unrecognized error message for an uplink transmission resource allocation message indicating a data transmission of a predetermined size or greater or allocating more transmission resources than a predetermined reference, the base station satisfies a predetermined condition The UE transmits a predetermined uplink transmission resource allocation message before transmitting the uplink transmission resource allocation message to the UE. The UE transmits the uplink transmission resource allocation message, which satisfies the predetermined condition, Message is determined to be an unrecognized error transmission resource allocation message. To this end, in the fourth embodiment, the UE distinguishes the first transmission resource allocation message, the second transmission resource allocation message, and the general transmission resource allocation message, and the second transmission resource allocation message in which the first transmission resource allocation message is not preceded, It is determined to be a perceived error transmission resource allocation message.

The fifth embodiment of the present invention uses the same message as the second transmission resource allocation message as the first transmission resource allocation message. To this end, in the fifth embodiment, the UE distinguishes a second transmission resource allocation message from a general transmission resource allocation message, and the second transmission resource allocation message having the same content is transmitted to the second transmission The resource allocation message is determined to be an unrecognized error transmission resource allocation message.

A sixth embodiment of the present invention relates to a method for distinguishing an unacknowledged error transmission resource allocation message using a transmission output. The transmission resource allocation message includes transmission resource information and MCS (Modulation Coding Scheme) information, and the UE transmits the coded data with the modulation scheme and coding rate indicated in the MCS information through the transmission resource indicated in the transmission resource information , And the terminal determines the transmission output of the data in consideration of the amount of transmission resources, the MCS level, the current channel status, and the like. In the normal case, the BS allocates a transmission resource and an MCS level such that the requested transmission output does not exceed the maximum transmission output of the MS, because the MS reports its available transmission output to the BS when the predetermined condition is satisfied. In other words, if the transmission resource is allocated or the MCS level is indicated so that the requested transmission output significantly exceeds the maximum transmission output of the UE, the transmission resource allocation message may be suspected to be an unacknowledged transmission resource allocation message. To this end, in the sixth embodiment of the present invention, when a request transmission output exceeds a maximum transmission output of a UE by a predetermined reference or more, the UE determines that the transmission resource allocation message is an unacknowledged error transmission resource allocation message, Ignore it.

≪ Embodiment 1 >

In the first embodiment of the present invention, a method and apparatus for reducing the number of UEs decoding an uplink transmission resource allocation message and reducing the occurrence of unrecognized error transmission resources are proposed.

The apparatus and method for processing an unrecognized error transmission resource allocation message according to the first embodiment of the present invention includes a step of transmitting an uplink transmission resource allocation message to a Node B that transmits information indicating that a buffer of the UE is empty, It is determined to be an unrecognized error transmission resource allocation message. Specifically, after transmitting the information indicating that the buffer state is empty or empty, the UE does not decode the uplink resource assignment message or ignores the uplink resource assignment message even if the uplink resource assignment message is successfully decoded.

4 is a diagram illustrating a terminal operation procedure according to the first embodiment of the present invention.

Referring to FIG. 4, the UE initially starts the process with the buffer empty. The state that the buffer is empty may be an example as follows. One is that the data is not stored in the buffer of the terminal and the other is the buffer that has successfully transmitted the information indicating that the buffer is empty and the data to be transmitted does not occur or the buffer The status report message may not be transmitted. The BS will not allocate the transmission resources to the MS in the buffer empty state. Accordingly, if the UE detects an empty state, the UE determines and ignores the message as an error transmission resource allocation message even if the UE successfully decodes the reverse transmission resource allocation message in step 410. Otherwise, And stops decoding the uplink resource assignment message.

As described above, various types of control messages are transmitted in various formats through the PDCCH. The UE performs blind decoding on all types of control messages and all formats to determine whether a control message is received. A UE with a buffer empty may not attempt blind decoding for a format associated with an uplink resource assignment message.

The MS proceeds to step 415 to check whether reverse data is generated. If the reverse data is not generated, the MS returns to step 410 and continues to ignore the reverse transmission resource allocation message even if it receives the reverse transmission resource allocation message. do. If it is determined in step 415 that the uplink data is generated, the UE transmits a scheduling request signal on a predetermined channel in step 420 and proceeds to step 425 to start processing the uplink resource assignment message. That is, after transmitting the scheduling request signal, the uplink data is transmitted using the allocated transmission resource without ignoring the received uplink resource assignment message.

When the UE receives the reverse transmission resource allocation message until the information indicating that the buffer is empty, the UE repeatedly transmits the reverse data using the allocated transmission resource, and the information indicating that the buffer is empty Once transferred, the buffer returns to an empty state. That is, in step 430, it is determined whether transmission of information indicating that the buffer is empty is completed. If not completed, the flow returns to step 425, and if it is completed, the flow returns to step 405.

The BS according to the first embodiment of the present invention allocates a very small transmission resource to the MS so that the BS can actively check the buffer status of the MS. In this case, even if the buffer is empty, the operation of the UE can be defined to process the uplink resource assignment message indicating the predetermined size of data transmission without ignoring it. For example, if there is a transmission resource to be allocated to the UE at a certain point of time, but all the UEs are in an empty state, the Node B allocates a transmission resource sufficient to transmit a buffer status report message to the UE, Can be obtained. For this, the UE may not ignore the reverse transmission resource allocation message indicating the data transmission of a predetermined size, for example, the size of the buffer status report message even if the buffer is empty. In this case, in step 410 of FIG. 4, the MS ignores all the uplink resource assignment messages except for the uplink resource assignment message indicating the predetermined size of data transmission. It is needless to say that the uplink transmission is performed according to the information stored in the message without ignoring the uplink transmission resource allocation message instructing the data transmission of the predetermined size.

≪ Embodiment 2 >

The base station does not allocate a transmission resource to the terminal that can transmit the buffer size of the terminal estimated by the base station. For example, if the base station estimates that x bytes of data are stored in an arbitrary terminal, it is normal for the terminal to allocate transmission resources so that the terminal transmits data of x bytes or less, Assigning is abnormal.

The second embodiment of the present invention manages a variable called a Node B-estimated buffer state, and upon receiving an uplink transmission resource allocation message, the UE compares the size of the data to be transmitted indicated by the allocation message with the Node B- And determines whether the resource allocation message is an error transmission resource allocation message. Specifically, if the base station estimates that x bytes of data are stored in an arbitrary terminal, if the terminal allocates a transmission resource to transmit data of x bytes or less, the base station determines that it is a normal resource allocation message, When a transmission resource is allocated to transmit data, it is determined to be an abnormal resource allocation message.

5 is a diagram illustrating a terminal operation procedure of the second embodiment, and FIGS. 6A and 6B are diagrams showing a structure of a buffer status report message.

Referring to FIGs. 5, 6A and 6B, upon receiving an uplink resource assignment message in step 505, the terminal detects it and proceeds to step 510 to analyze the size of the buffer and data to be transmitted. In step 510, the UE compares the size of the data to be transmitted indicated by the received uplink transmission resource allocation message with a value obtained by adding a predetermined value to the size of the estimated BS size. The Node B-estimated buffer size is a buffer size of the UE estimated by the BS, and is calculated based on the information stored in the most recently reported buffer status report message. The buffer status report message stores the buffer size of each terminal's logical channel group. Logical channels are composed of one per service and refer to a PDCP device and an RLC device configured to process data generated in a specific service. The logical channel group is a collection of logical channels having the same or similar characteristics and priorities. The buffer status of the terminal is reported for each logical channel group, and a maximum of four logical channel groups are configured in one terminal. The buffer status report message may contain buffer size information for one or four logical channel groups. When the buffer size information for one logical channel group is stored, the buffer status report message includes the logical channel group identifier 605 and the buffer size information 610 as shown in FIG. 6A. When buffer size information for four logical channel groups is received, the buffer status report message is composed of four buffer size information (615, 620, 625, 630 in FIG. 6), and the first buffer size information is shown in FIG. The second buffer size information is the buffer size of the logical channel group identifier 2, the third buffer size information is the buffer size of the logical channel group identifier 3, the fourth buffer size information is the logical channel group identifier of the logical channel group identifier 1, 4 indicates the buffer size. The buffer size information is an integer between 0 and 63, and each integer indicates a predetermined buffer size range. For example, the buffer size information 10 indicates that data between 100 bytes and 120 bytes is stored in the corresponding logical channel group of the terminal.

The UE estimates the Node B-estimated buffer size as shown in Equation (1).

Node B Estimate Buffer Size = total sum of buffer sizes received in the most recently transmitted buffer report message.

In Equation (1), the buffer size is the upper limit of the range indicated by the corresponding buffer size information. For example, an arbitrary terminal reports constants x ₁ , x ₂ , x ₃ , and x ₄ as buffer size information of the logical channel group 1, the logical channel group 2, the logical channel group 3, and the logical channel group 4, If the range of the buffer size indicated by the information is y ₁₁ to y ₁₂ , y ₂₁ to y ₂₂ , y ₃₁ to y ₃₂ , and y ₄₁ to y _42, then the size of the estimated BS is y ₁₂ , y _22, y _32, y _42, respectively. The UE can accurately maintain the estimated BS size by subtracting the amount of successfully transmitted data from the estimated BS size every time the MS successfully transmits the uplink data.

In step 510 of FIG. 5, a is a predetermined integer, and a normal uplink transmission resource allocation message is mistaken for an error transmission resource allocation message due to an error between the size of the Node B-estimated buffer managed by the UE and the actual BS estimated buffer size . If α is defined as a large value, the possibility of filtering out the unrecognized error transmission resource allocation message is lowered, but the likelihood that the normal transmission resource allocation message is misidentified as an error transmission resource allocation message is also lowered. Conversely, if α is defined as a small value, the probability of filtering out the unrecognized error transmission resource allocation message increases, but the likelihood that the normal transmission resource allocation message is misidentified as an error transmission resource allocation message also increases. may be a fixed value or may be a value obtained by multiplying a current base station estimated buffer size by a predetermined ratio.

It is abnormal to indicate that the base station should transmit data larger than the sum of the base station estimated buffer size and a. Accordingly, if the UE receives the uplink resource assignment message indicating that it should transmit data larger than a value obtained by adding? To the Node B-estimated buffer size in step 510, the UE proceeds to step 520, It is determined as an assignment message and the message is ignored. If it is detected in step 510 that the BS has received a reverse transmission resource allocation message to transmit data smaller than a value obtained by adding? To the size of the estimated BS size, the MS proceeds to step 515, And performs transmission.

≪ Third Embodiment >

In the third embodiment of the present invention, when an excessive padding bit is inserted into data to be transmitted, it is determined that the data transmission is based on an unrecognized error transmission resource allocation message and data is not transmitted.

FIG. 7 is a diagram illustrating an operation of a UE according to a third embodiment of the present invention, and FIG. 8 is a diagram illustrating a structure of a MAC PDU.

Referring to FIGS. 7 and 8, in step 705, when the UE receives the uplink resource assignment message, the UE proceeds to step 710 and configures an MAC PDU to be transmitted through the allocated transmission resource. As shown in FIG. 8, the MAC PDU 820 includes a MAC header 805, a payload 810, and a padding 815. In the MAC header 805, information such as the size of the payload and the identifier of the logical channel to which the payload belongs is stored. The payload 810 stores upper layer data, for example, an RLC PDU. If the size of the directed data is too large to store all the data in the MAC PDU 820 and the spare space remains, the terminal stores the padding bits 815 in the remaining space.

Upon completion of the configuration of the MAC PDU 820, the UE proceeds to step 715 and checks whether the total size of the configured MAC PDU is equal to or greater than a predetermined value C. [ At this time, if the size of the MAC PDU 820 is larger than C, the MS proceeds to step 720 and checks whether the MAC PDU 820 is triggered from an error transmission resource allocation message. At this time, if the size of the MAC PDU is smaller than C, the mobile station detects this in step 720, and proceeds to step 730 to transmit the MAC PDU using the allocated transmission resource. According to the size of the MAC PDU 820, the determination of whether or not to check the occurrence of an unrecognized error transmission resource allocation message may be disadvantageous in the case of the MAC PDU having a small size, Even though they are transmitted through unrecognized error transmission resources.

 In step 720, the MS checks if the ratio of the padding bits to the total MAC PDUs is equal to or greater than a predetermined value β. If the ratio of the padding bits is greater than or equal to β, the MS proceeds to step 725. At this time, if the ratio occupied by the padding bits is greater than or equal to the predetermined value?, It is highly likely that the associated uplink transmission resource allocation message is not a normal message but an unacknowledged error message. Therefore, the terminal ignores the associated uplink transmission resource allocation message in step 725. That is, the MAC PDU is discarded without being transmitted. In addition, if the ratio of the padding bits occupied by the padding bits is less than or equal to a predetermined value, since the associated uplink resource assignment message is likely to be a normal uplink resource assignment message, the MS proceeds to step 730 and transmits the MAC PDU through the allocated resources .

<Fourth Embodiment>

In order to reduce the probability of occurrence of an unrecognized error message for an uplink transmission resource allocation message indicating a data transmission of a predetermined size or greater or allocating more transmission resources than a predetermined reference, the base station satisfies a predetermined condition The UE transmits a predetermined uplink transmission resource allocation message before transmitting the uplink transmission resource allocation message to the UE. The UE transmits the uplink transmission resource allocation message, which satisfies the predetermined condition, Message is determined to be an unrecognized error transmission resource allocation message. For convenience of explanation, when a non-acknowledgment error occurs, a transmission resource allocation message having a large side effect is referred to as a second transmission resource allocation message. Also, a predetermined transmission resource allocation message transmitted to protect the second transmission resource allocation message from unrecognized error is referred to as a first transmission resource allocation message.

In the LTE mobile communication system, the reverse transmission resources are allocated in units of resource blocks. A resource block is a frequency-time resource of a predetermined size, and the entire transmission resource of one cell is divided into frequency-time of the predetermined size and then an identifier is assigned. The first transmission resource allocation message may be a transmission resource allocation message for instructing transmission of a MAC PDU having a predetermined size, for example. Or a transmission resource allocation message for allocating a predetermined reverse transmission resource. For example, a transmission resource allocation message indicating a predetermined Y-byte MAC PDU transmission or a transmission resource allocation message indicating a MAC PDU transmission through a predetermined RB K may be defined as a first transmission resource allocation message. K is an identifier of an arbitrary RB. The second transmission resource allocation message is a transmission resource allocation message having a large side effect when an unacknowledged error occurs as described above. For example, whether a certain transmission resource allocation message is a second transmission resource allocation message may be determined based on whether a size of a MAC PDU to which transmission is indicated through a corresponding transmission resource allocation message exceeds a predetermined reference size Z. [ Or whether the number of resource blocks allocated through the transmission resource allocation message exceeds a predetermined value Z`.

9 is a diagram showing the overall structure of a fourth embodiment of the present invention.

9, the base station 910 transmits a predetermined first transmission resource allocation message in step 915 before transmitting the second transmission resource allocation message to the terminal, And drives a timer T having a time. In this example, the first transmission resource allocation message is a transmission resource allocation message for instructing transmission of a MAC PDU having a size of Y bytes.

When the UE receives the first transmission resource allocation message transmitted from the Node B in step 915, the UE drives a timer T having a predetermined time as indicated by reference numeral 925 in FIG. 9, after the transmission of the first transmission resource allocation message is completed, the base station transmits a second transmission resource allocation message in step 920 of FIG. 9 before the T having the same setup time as the reference number 917 of FIG. 9 expires, It is determined that the second transmission resource assignment message is valid only when the T having the same setup time as reference numeral 925 is received before the expiration of the T, and the uplink transmission is performed according to the information stored in the transmission resource allocation message. However, when an unrecognized error transmission resource allocation message corresponding to the second transmission resource allocation message generated after the timer period (timer interval set as 925 in FIG. 9) elapses as set in step 930 of FIG. 9 occurs, The UE ignores the second transmission resource allocation message in step 935 because the first transmission resource allocation message for authenticating the second transmission resource allocation message is not received.

10 is a diagram illustrating an operation of a terminal according to a fourth embodiment of the present invention. Prior to performing the operation shown in FIG. 10, the UE acquires a value to be applied to the timer T, a first transmission resource allocation message criterion, and a second transmission resource allocation message criterion from the base station through a call setup process or the like.

Referring to FIG. 10, in step 1005, upon receiving an uplink resource assignment message in step 1005, the UE proceeds to step 1010 and determines whether the received uplink resource assignment message is a first resource assignment message. That is, when the UE receives the uplink resource assignment message, the UE checks whether information received in the uplink resource assignment message received satisfies the first resource assignment message. The reference of the first transmission resource allocation message may be, for example, the size of a MAC PDU to which a transmission resource allocation message indicates transmission or an identifier of an allocated RB. For example, if an uplink transmission resource allocation message indicates a transmission of a given MAC PDU with a size of Y bytes on the basis of a first transmission resource allocation message, the transmission resource allocation message is a first transmission resource allocation message.

If it is determined in step 1010 that the received uplink resource assignment message is a first resource assignment message, the terminal proceeds to step 1015 and proceeds to step 1035. In step 1035, And executes transmission.

If it is determined in step 1010 that the received uplink resource assignment message is not a first resource assignment message, the terminal proceeds to step 1020 and determines whether the received uplink resource assignment message is a second resource assignment message. That is, if the UE is not the first transmission resource allocation message, the UE checks whether information received in the received uplink transmission resource allocation message meets a second transmission resource allocation message criterion. The reference of the second transmission resource allocation message may be, for example, the size of a MAC PDU to which a transmission resource allocation message indicates transmission or the number of allocated RBs. For example, if an uplink transmission resource allocation message indicates transmission of a MAC PDU larger than a given Z byte on the basis of a second transmission resource allocation message, or allocates more resource blocks than a given Z` on the basis of the second transmission resource allocation message The transmission resource allocation message is a second transmission resource allocation message.

If it is determined in step 1020 that the received uplink transmission resource allocation message is a second transmission resource allocation message, the UE proceeds to step 1025 and checks whether T is being driven. If the timer T is in operation, it means that the first transmission resource allocation message has been received within a predetermined period from the reception of the second transmission resource allocation message. That is, The MS proceeds to step 1035 and terminates T and performs a reverse transmission and waits until a next reverse transmission resource allocation message is received. If T is not in operation in step 1025, it means that the first transmission resource allocation message for authenticating the second transmission resource allocation message has not been received. If the received second transmission resource allocation message is not an error transmission resource allocation message The MS proceeds to step 1030 and ignores the received uplink resource assignment message and waits until the next uplink resource assignment message is received.

<Fifth Embodiment>

The fifth embodiment of the present invention relates to the use of the same message as the second transmission resource allocation message in the first transmission resource allocation message.

11 is a diagram showing a terminal operation in the fifth embodiment. Prior to performing the operation shown in FIG. 11, the UE acquires a value to be applied to the timer T and a second transmission resource allocation message criterion from the base station through a call setup process or the like.

Referring to FIG. 11, in step 1105, upon receiving an uplink resource assignment message in step 1105, the UE proceeds to step 1110 and determines whether the received uplink resource assignment message is a second uplink resource assignment message. That is, the UE determines whether the information received in the received uplink Tx allocation message received by the received Tx resource allocation message meets a second Tx resource allocation message criterion. The reference of the second transmission resource allocation message may be, for example, the size of a MAC PDU to which a transmission resource allocation message indicates transmission or the number of allocated RBs. For example, if an uplink transmission resource allocation message indicates transmission of a MAC PDU larger than a given Z byte on the basis of a second transmission resource allocation message, or allocates more resource blocks than a given Z` on the basis of the second transmission resource allocation message The transmission resource allocation message is a second transmission resource allocation message.

In step 1140, the MS performs an uplink transmission using the allocated transmission resource and an uplink transmission resource allocation message in a waiting state until receiving the uplink transmission resource allocation message do.

If the UE receives the transmission resource allocation message satisfying the second transmission resource allocation message criterion, the UE proceeds to step 1115 and checks whether T is being driven. T means that the second transmission resource allocation message has been received in the near past. In other words, it means that the received second transmission resource allocation message is a real transmission resource allocation message. Therefore, The UE proceeds to step 1130. [

Therefore, if T is not in operation in step 1115, the received second transmission resource allocation message is not a substantial transmission resource allocation message, but a spare message transmitted prior to transmitting the second transmission resource allocation message, It means that the MS proceeds to step 1120. In step 1120, In step 1120, the UE drives T, and stores the content of the allocated second transmission resource allocation message, and then waits until it receives a new uplink transmission resource allocation message. Note that even if the UE receives the second transmission resource allocation message, it does not perform reverse transmission if T is not in operation.

If it is determined in step 1115 that the timer T is in operation, the UE determines in step 1130 whether the content of the received second transmission resource allocation message matches the content of the second transmission resource allocation message that caused the T to be driven . For example, it is checked whether the same transmission resource is allocated and the same MCS is indicated. If the determination result in step 1130 is YES, it means that the received second transmission resource allocation message is a substantial transmission resource allocation message. In step 1135, the terminal stops the currently operating T and proceeds to step 1140 to transmit an uplink transmission resource allocation message And performs reverse transmission in accordance with the contents of &lt; RTI ID = 0.0 &gt; If the determination result in step 1130 is false, it means that the UE has a high probability that the received second transmission resource allocation message is an error transmission resource allocation message, and the UE transmits the received second transmission resource allocation message And waits until a new transmission resource allocation message is received.

<Sixth Embodiment>

A sixth embodiment of the present invention relates to a method for distinguishing unacknowledged error transmission resource allocation messages using transmission power. The transmission resource allocation message includes transmission resource information and MCS (Modulation Coding Scheme) information, and the UE transmits the coded data with the modulation scheme and coding rate indicated in the MCS information through the transmission resource indicated in the transmission resource information , And the terminal determines the transmission output of the data in consideration of the amount of transmission resources, the MCS level, the current channel status, and the like. Briefly, the transmit power for arbitrary data is derived by:

Transmission output = MIN [Maximum transmission output of terminal, required transmission output]

Request transmission output = f (amount of transmission resource, MCS level, path loss)

In Equation (2), the requested transmission power is a proper transmission power to be applied when transmitting data coded at the MCS level indicated through the transmission resource allocated by the mobile station. The higher the MCS level, the higher the required transmission power, the higher the channel condition of the terminal, the higher the allocated transmission resources, and the higher the MCS level. If the BS allocates an excessive amount of transmission resources to the UE or indicates an excessively high MCS level, the requested transmission output may exceed the maximum transmission output of the UE, so that the transmission output of the UE may be lower than the requested transmission output. The probability increases.

In the normal case, the BS allocates a transmission resource and an MCS level such that the requested transmission output does not exceed the maximum transmission output of the MS, because the MS reports its available transmission output to the BS when the predetermined condition is satisfied. In other words, if the transmission resource is allocated or the MCS level is indicated so that the request transmission output significantly exceeds the maximum transmission output of the UE, the transmission resource allocation message may be suspected to be an unacknowledged transmission resource allocation message. In the embodiment, when the requested transmission output exceeds the maximum transmission output of the UE by a predetermined reference or more, the transmission resource allocation message is determined as an unacknowledged transmission resource allocation message and the transmission resource allocation message is ignored.

12 is a diagram showing a terminal operation procedure of the sixth embodiment of the present invention.

Referring to FIG. 12, in step 1205, when the UE receives an uplink resource assignment message, the UE detects the uplink resource assignment message and proceeds to step 1210 to calculate a request transmission output of a MAC PDU to be transmitted through the allocated transmission resource. As described above, the request transmission output is obtained by applying the amount of allocated transmission resources, the indicated MCS level, and the path loss of the terminal to a predetermined equation. In step 1215, the terminal compares the calculated required transmission output and the maximum transmission output of the terminal multiplied by gamma. If the requested transmission power is larger than the value obtained by multiplying the maximum transmission power of the terminal by?, The terminal proceeds to step 1225; Here, the? May be signaled to the UE in the call setup process, or a predetermined value may be used. In step 1225, since the requested transmission output significantly exceeds the maximum transmission output of the UE, the UE determines that the uplink transmission resource allocation message received in step 1205 is an incorrect transmission resource allocation message And ignore it. That is, the MS does not perform reverse transmission. In step 1220, it is determined that there is no reason to determine the uplink transmission resource allocation message received in step 1205 as an unacknowledged transmission resource allocation message. Therefore, the UE transmits an MAC PDU according to the uplink transmission resource allocation message And performs reverse transmission.

FIG. 13 is a block diagram of a terminal device that executes the first to sixth embodiments of the present invention.

The terminal apparatus includes an upper layer apparatus 1305, an MAC PDU generation unit 1310, a transceiver unit 1325, a controller 1320, a PDCCH processor 1330, and a radio resource controller 1335.

The terminal transceiver 1325 is a device that receives a PDCCH over a wireless channel and transmits / receives other traffic. The transceiver 1325 decodes a signal received via the PDCCH and transmits the decoded signal to the PDCCH processor 1330. The PDCCH processor 1330 masks the C-RNTI on the decoded signal transmitted from the transceiver 1325 and performs a CRC operation. And transmits a transmission resource allocation message determined as no error to the controller 1330. The controller 1330 controls the transceiver and the MAC PDU generator 1310 to transmit the MAC PDU of the indicated size through the allocated transmission resource through the transmission resource allocation message transmitted from the PDCCH processor 1330. The control unit 1330 further distinguishes the unrecognized error transmission resource allocation message using a predetermined scheme and controls the MAC PDU generation unit 1310 to prevent the reverse transmission from proceeding due to an unrecognized error transmission resource allocation message.

In more detail, the controller 1330 determines whether the buffer is empty. If the buffer is empty, the control unit 1330 ignores the reverse transmission resource allocation message transmitted by the PDCCH processor 1330, And controls the transceiver 1325 and the MAC PDU generator 1310 so that the MAC PDU is transmitted according to the contents of the uplink transmission resource allocation message transmitted by the PDCCH processor 1330. [ Second, in the second embodiment, the controller 1330 manages the Node B-estimated BS state variable and compares the size of the MAC PDU to be transmitted with the BS estimated buffer state indicated in the uplink transmission resource allocation message transmitted by the PDCCH processor 1330, Resource allocation message, and controls the MAC PDU generation unit 1310 according to the determination result. Third, in the third embodiment, when the rate of padding received in the MAC PDU generated by the MAC PDU generation unit 1310 exceeds a predetermined value, the controller 1320 controls the MAC PDU generation unit 1310 and the transmission / And controls the unit 1325. Fourth, in the fourth embodiment, the controller 1320 distinguishes the first transmission resource allocation message, the second transmission resource allocation message, and the general transmission resource allocation message, and the second transmission resource allocation message Is determined to be an unrecognized error transmission resource allocation message. Fifth, in the fifth embodiment, the controller 1320 distinguishes the second transmission resource allocation message from the general transmission resource allocation message, and the second transmission resource allocation message in which the same transmission resource allocation message is not received before the predetermined T It is determined that it is an unrecognized error transmission resource allocation message. Sixth, in the sixth embodiment, the MS calculates a required transmission output upon reception of an uplink transmission resource allocation message, and if a transmission resource is allocated or an MCS level is indicated such that the required transmission output significantly exceeds the maximum transmission output of the terminal, And determines the transmission resource allocation message as an unacknowledged transmission resource allocation message. At this time, if the request transmission output exceeds the maximum transmission output of the UE by a predetermined reference or more, the UE determines that the transmission resource allocation message is an unacknowledged transmission resource allocation message and ignores the transmission resource allocation message.

The MAC PDU generation unit 1220 composes data stored in the upper layer device 1305 into MAC PDUs and transmits the data to the transmission / reception unit 1325. At this time, the size of the MAC PDU is controlled by the control unit 1330. The upper layer device 1305 collectively refers to an RLC device or a PDCP device. The radio resource control unit recognizes parameters such as α, β, a timer value, a first transmission resource allocation message condition, a second transmission resource allocation message condition, etc.,

1 is a view showing an example of a structure of a next generation mobile communication system;

2 is a diagram showing a protocol stack of a next generation mobile communication system

3 is a diagram showing a general reverse data transmission process

4 is a diagram showing a terminal operation in an embodiment of the present invention

5 is a diagram showing a terminal operation of the second embodiment of the present invention

6 is a diagram showing the structure of a buffer status report message

Fig. 7 is a view showing the terminal operation in the third embodiment of the present invention

8 is a diagram showing the structure of a MAC PDU;

9 is a diagram showing the overall operation of the four embodiments of the present invention

FIG. 10 is a diagram showing a terminal operation in four embodiments of the present invention

11 is a diagram showing a terminal operation in the fifth embodiment of the present invention

12 is a diagram showing a terminal operation in the sixth embodiment of the present invention

13 is a view showing a terminal structure

Claims (2)

A receiving unit for receiving and decoding a transmission resource allocation message transmitted from a base station; A PDCCH processing unit for calculating the decoded transmission resource allocation message to determine whether an error occurs; An MAC PDU generation unit configured to transmit data stored in an upper layer device to MAC PDUs and transmit the MAC PDUs to a transceiver unit; And The MAC PDU generation unit analyzes the transmission resource allocation message transmitted from the PDCCH processing unit to distinguish the unrecognized error transmission resource allocation message and controls the MAC PDU generation unit such that the reverse transmission does not proceed according to the distinguished unacknowledged transmission resource allocation message And a control unit, Wherein the controller is configured to calculate a transmission resource allocation message based on the size of a ratio occupied by padding bits in transmission data indicated in the transmission resource allocation message, a size of transmission data indicated in the transmission resource allocation message, And distinguishes the unrecognized error transmission resource allocation message based on at least one of the required outputs. Receiving and decoding a transmission resource allocation message transmitted from a base station; Calculating the decoded transmission resource allocation message to determine whether an error occurs; Analyzing the transmission resource allocation message to identify an unacknowledged transmission resource allocation message; And And controlling generation of a MAC PDU so that a reverse transmission does not proceed according to the distinguished unacknowledged resource allocation message, The step of distinguishing the unrecognized error transmission resource allocation message may include: determining a size of a ratio occupied by padding bits in transmission data indicated in the transmission resource allocation message, a size of transmission data indicated in the transmission resource allocation message, And an output requested for data transmission determined based on an allocation message, and distinguishing the unrecognized error transmission resource allocation message based on at least one of outputs requested for data transmission determined based on the allocation message.

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