Indian Patents. 271493:METHOD AND APPARATUS OF CONTROLLING TRANSMISSION OF DATA BLOCK

Title of Invention	METHOD AND APPARATUS OF CONTROLLING TRANSMISSION OF DATA BLOCK
Abstract	A method and apparatus for controlling a transmission of data blocks is provided by which data block transmission can be controlled more efficiently by measuring the RTT and setting a control timer value according to the measured RTT

Full Text	WO 2006/104341 1 PCT/KR2006/001139 METHOD AND APPARATUS OF CONTROLLING TRANSMISSION OF DATA BLOCK TECHNICAL FIELD [0001] The present invention relates to a method and apparatus for controlling transmission of a data block. Although the present invention is suitable for a wide scope of applications, it is particularly suitable for controlling data block transmission more efficiently by measuring round trip time (RTT) and setting a timer using the measured RTT. BACKGROUND ART [0002] FIG. 1 is a block diagram of a network structure of a universal mobile telecommunications system (UMTS). Referring to FIG. 1, the universal mobile telecommunications system (hereinafter, referred to as 'UMTS') includes a user equipment 1 (hereinafter, referred to as 'UE'), a UMTS terrestrial radio access network 2 (hereinafter, referred to as 'UTRAN') and a core network 3 (hereinafter, referred to as 'CN'). The UTRAN 2 includes at least one radio network sub-system 4 (hereinafter, referred to as 'RNS') and each RNS includes a radio network controller 5 (hereinafter, referred to as 'RNC') and at least one base station 6 (hereinafter, referred to as 'Node B') managed by the RNC. The Node B 6 includes at least one cell. [0003] FIG. 2 is an architectural diagram of UMTS radio protocol between a UE 1 and UTRAN 2. Referring to FIG. 2, the radio interface protocol horizontally includes a physical layer, a data link layer and a network layer and the radio interface WO 2006/104341 2 PCT/KR2006/001139 protocol vertically includes a user plane for data information transfer and a control plane for signaling transfer. The protocol layers in FIG, 2 can be divided into L1 (first layer), L2 (second layer), and L3 (third layer) based on lower three layers of the open system interconnection (OSI) standard model widely known in the communications systems. The radio protocol layers exist as pairs in both the UE 1 and UTRAN 2 to facilitate data transmission in the radio section. [0004] The physical layer as the first layer provides an information transfer service to an upper layer using physical channels. The physical layer is connected to a medium access control (MAC) layer above the physical layer via transport channels through which data are transferred between the medium access control layer and the physical layer. The transport channels are classified as dedicated transport channels and common transport channels according to whether or not a channel is shared. Data is transmitted between different physical layers, and more particularly, between the physical layer of a transmitting side and the physical layer of a receiving side via physical channels. [0005] The medium access control (MAC) layer of the second layer provides services to a radio link control (hereinafter abbreviated RLC) layer above the MAC layer via logical channels. The RLC layer of the second layer supports reliable data transfer and is operative in segmentation and concatenation of RLC service data units (SDUs) sent down from an upper layer. [0006] The MAC layer and the physical layer exchange data via the transport channel. The second layer (L2) includes a MAC layer, a radio link control (RLC) layer, WO 2006/104341 3 PCT/KR2006/001139 a broadcast/multicast control (BMC) layer and a packet data convergence protocol (PDCP) layer. [0007] The MAC layer handles mapping between logical channels and transport channels and provides allocation of the MAC parameters for allocation and re-allocation of radio resources. The MAC layer is connected to an upper layer, called the radio link control (RLC) layer, via a logical channel, [0008] Various logical channels are provided according to the type of information transmitted. In general, a control channel is used to transmit information of the control plane and a traffic channel is used to transmit information of the user plane. [0009] The MAC layer is connected to the physical layer by transport channels and can be divided into a MAC-b sub-layer, a MAC-d sub-layer, a MAC-c/sh sub-layer, a MAC-hs sub-layer and a MAC-e sublayer. The division of the MAC is according to the type of transport channel being managed. [0010] The MAC-b sub-layer manages a BCH (Broadcast Channel), which is a transport channel handling the broadcasting of system information. The MAC-c/sh sub- layer manages a common transport channel, such as a forward access channel (FACH) or a downlink shared channel (DSCH), which is shared by a plurality of terminals, or in the uplink the Radio Access Channel (RACH). The MAC-d sub-layer manages a dedicated channel (DCH), which is a dedicated transport channel for a specific terminal. The MAC-hs sublayer manages a transport channel HS-DSCH (high speed downlink shared channel) for high speed data transfer to support the high speed data transfer in downlink and uplink. The MAC-e sublayer manages a transport channel E-DCH (enhanced dedicated channel) for uplink data transfer. WO 2006/104341 4 PCT/KR2006/001139 [0011] The radio link control (hereinafter abbreviated 'RLC') layer supports a guarantee of quality of service (hereinafter abbreviated 'QoS') of each radio bearer and also controls the transfer of corresponding data. The RLC layer leaves one independent RLC entity at each RB to guarantee intrinsic QoS of the RB. Three RLC modes are provided to support various QoS; a transparent mode (hereinafter abbreviated 'TM'), an unacknowledged mode (hereinafter abbreviated 'UM') and an acknowledged mode (hereinafter abbreviated 'AM'). [0012] The RLC also facilitates adjusting a data size to enable a lower layer to transfer data to a radio section. To facilitate an adjusted data size, the RLC segments and concatenates data received from an upper layer. [0013] The PDCP layer is located above the RLC layer and facilitates transferring data using IP packets, such as IPv4 or IPv6, efficiently in a radio section having a relatively small bandwidth. Toward this end, the PDCP layer performs header compression, a function by which mandatory data header information is transferred to increase transport efficiency in a radio section. [0014] Since header compression is a basic function of the PDCP layer, the PDCP layer exists only in a packet service domain (hereinafter abbreviated 'PS domain'). Furthermore, one PDCP entity exists for each RB in order to provide an effective header compression function to each PS service. [0015] The BMC (broadcast/multicast control) layer is located above the RLC layer. The BMC layer schedules a cell broadcast message and performs broadcasting to UEs located in a specific cell. WO 2006/104341 5 PCT/KR2006/001139 [0016] A radio resource control (RRC) layer located on the lowest part of the third layer is defined in the control plane only and controls the logical channels, the transport channels, and the physical channels with configuration, reconfiguration, and release of radio bearers (RBs). A RB is a logical path provided by the first and second layers for the data transfer between the UE 1 and the UTRAN 2. Generally, configuring an RB refers to defining the characteristics of protocol layers and channels necessary for providing a specific service and is to establish respective specific parameters and operational methods for them. [0017] Basic functions of the RLC layer are to guarantee QoS of each RB and a corresponding data transfer. Since an RB service is a service that the second layer provides to an upper layer, the entire second layer affects QoS. However, the RLC layer has the greatest effect on QoS. [0018] The RLC layer provides an independent RLC entity at each RB to guarantee the intrinsic QoS of aa RB and provides three modes, specifically TM, UM and AM. Since the three RLC modes differ from one another in the supported QoS, their operational methods are different as well as their detailed functions. Therefore, the RLC operational mode must be considered. [0019] TM RLC is a mode in which no overhead is attached to an RLC service data unit (hereinafter abbreviated 'SDU') that is delivered from a higher layer in configuring an RLC protocol data unit (hereinafter abbreviated TDU'). Since the RLC transmits the SDU transparently, it is called TM RLC. [0020] Due to these transparent characteristics, the TM RLC plays various roles in user and control planes. In the user plane, the TM RLC performs real-time circuit WO 2006/104341 6 PCT/KR2006/001139 data transfer, such as voice or streaming data, in a circuit service domain (hereinafter abbreviated 'CS domain') since data processing time within RLC is short. In the control plane, the RLC controls uplink transmission of RRC messages from an unspecific UE or downlink transmission of RRC messages broadcast from all UEs with a cell since there is no overhead within the RLC. [0021] Unlike the transparent mode, a non-transparent mode is a mode in which overhead is added in the RLC. Non-transparent modes are classified into an unacknowledged mode (UM), having no acknowledgement for the transmitted data, and an acknowledged mode (AM), having acknowledgement for the transmitted data. [0022] By attaching a PDU header including a sequence number (hereinafter abbreviated 'SN') to each PDU, UM RLC enables a receiving side to determine which PDU is lost in the course of transmission. Due to this characteristic, the UM RLC primarily performs transmission of real-time packet data, such as broadcast/multicast data transmission, voice of PS domain, (such as, VoIP) and streaming data in the user plane or transmission of RRC messages transmitted to a specific UE or specific UE group within a cell in control plane that require no acknowledgement. [0023] AM RLC is a non-transparent mode that configures PDUs by attaching a PDU header, including an SN, as in UM RLC. However, AM RLC differs from UM RLC in that a receiving side acknowledges the PDUs transmitted by a transmitting side. [0024] The receiving side acknowledges PDU reception in the AM RLC because the transmitting side can request retransmission of a PDU that is not received by the receiving side. The retransmission function is the most outstanding feature of the AM RLC. WO 2006/104341 7 PCT/KR2006/001139 [0025] An object of the AM RLC is to guarantee error-free data transmission through retransmission. Due to this characteristic, the AM RLC primarily controls transmission of non-real-time packet data, such as TCP/IP of PS domain in the user plane, or transmission of RRC messages transmitted to a specific UE within a cell in control plane for which acknowledgment is mandatory. [0026] TM or DM RLC is used for uni-directional communications, whereas AM RLC is used for bi-directional communications due to the feedback from a receiving side in AM RLC. Since bi-directional communications are primarily used for point-to-point communications, AM RLC uses only a dedicated logical channel. Therefore, one RLC entity includes a transmission or reception structure in TM or UM RLC, whereas a transmitting side and a receiving side exist within one RLC entity in AM RLC. [0027] The complexity of AM RLC is due to the retransmission function. The AM RLC includes a retransmission buffer for retransmission management as well as a transmitting/receivtng buffer and performs various functions. The various functions may be related to a transmitting/receiving window for flow control, polling when a transmitting side requests status information from a corresponding RLC entity of a receiving side, status reporting in order that a receiving side may report its buffer status to a corresponding RLC entity of a transmitting side, status PDU for carrying status information and piggybacking by inserting a status PDU in a data PDU to increase data transfer efficiency. [0028] A reset PDU is required in order to request the resetting of all operations and parameters of an AM RLC entity of the other side if an AM RLC entity discovers a WO 2006/104341 8 PCT/KR2006/001139 critical error during the course of operation, A reset ACK PDU is required for response to the reset PDU. [0029] To support these functions, an AM RLC needs various protocol parameters, status variables and a timer. PDUs used for data transfer control in status information reporting, status PDUs and reset PDUs are called control PDUs and PDUs used for delivery of user data are called data PDUs. [0030] Specifically, PDUs used by an AM RLC may be classified into two types. A first type is a data PDU and a second type is a control PDU. Control PDUs include status PDU, piggybacked status PDUs, reset PDUs and reset ACK PDUs. [0031] As mentioned previously control PDUs are used for a reset procedure. The reset procedure is used in response to an error condition during operation of an AM RLC. [0032] For example, an error condition may result if mutually used sequence numbers are different from each other or a PDU or an SDU transmission fails in excess of a count limit. Through the reset procedure, an AM RLC of a receiving side and an AM RLC of a transmitting side reset environmental variables and then communications are re-enabled. [0033] Once an AM RLC entity, such as an AM RLC of a transmitting side, decides to initiate a reset procedure, a currently used transmitting direction hyper frame number (hereinafter abbreviated 'HFN') value is included in a reset PDU and the reset PDU is transmitted to the corresponding AM RLC entity on the other side, such as an AM RLC of a receiving side. The AM RLC of the receiving side, having received the WO 2006/104341 9 PCT/KR2006/001139 reset PDU, re-establishes an HFN value of its receiving direction and then resets environmental variables, such as a sequence number. [0034] Subsequently, the AM RLC of the receiving side includes its transmitting direction HFN in a reset ACK PDU and then transmits the reset ACK PDU to the AM RLC of the transmitting side. Upon receiving the reset ACK PDU, the AM RLC of the transmitting side re-establishes its receiving direction HFN value and then resets environmental variables. [0035] FIG. 3 illustrates the structure of an AM RLC PDU. As illustrated in FIG. 3, an AM RLC PDU is used when an AM RLC entity attempts to transmit user data or piggybacked status information anci a polling bit. A user data portion is configured as an 8-bit integer multiplication and an AM RLC PDU header is constructed with a 2-octet sequence number. The header part of an AM RLC PDU includes a length indicator. [0036] FIG. 4 illustrates the structure of a status PDU. As illustrated in FIG. 4, a status PDU includes different types of SUFIs (super fields). The status PDU size is variable, but is limited to a size of the largest RLC PDU of a logical channel carrying the status PDU. [0037] The SUFI is utilized to identify what type of AM RLC PDU is received at a receiving side or what type of AM RLC PDU is not received at the receiving side. The SUFI consists of three parts that indicate type, length and value. [0038] FIG. 5 illustrates the structure of a piggybacked status PDU. As illustrated in FIG. 5, the structure of a piggybacked status PDU, while similar to that of a status PDU, differs in that a reserved bit (R2) replaces the D/C field. The piggybacked WO 2006/104341 10 PCT/KR2006/001139 status PDU is inserted if there is sufficient space in an AM RLC PDU. The PDU type value may be fixed at' 000'. [0039] FIG. 6 illustrates the structure of a reset ACK PDU. As illustrated in FIG. 6, a reset PDU includes a 1-bit sequence number (RSN). A reset ACK PDU is transmitted in response to a received reset PDU by including the RSN contained in the received reset PDU. [0040] The 'D/C field' indicates whether a corresponding PDU is a control PDU or a data PDU. The TDU Type' indicates a type of the control PDU and, specifically, whether a corresponding PDU is a reset PDU or a status PDU. The 'Sequence Number' value indicates sequence number information of an AM RLC PDU. [0041] The 'Polling Bit' value is set when a request for a status report is made to a receiving side. The 'Extension bit (E)' value indicates whether a next octet is a length indicator. The 'Reserved bit (R1)' value is used for a reset PDU or a reset ACK PDU and is coded as '000'. The 'Header Extension Bit (HE)' value indicates whether a next octet is a length indicator or data. The 'Length Indicator' value indicates a location of a boundary if a boundary exists between different SDUs within a data part of a PDU. The 'PAD' part is a padding area and is not used in an AM RLC PDU. [0042] A method of reducing reception error in an AM RLC entity is explained as follows. Unlike an UM RLC or TM RLC, error-free data transmission is important for an AM RLC. [0043] Specifically, if a receiving side fails to successfully receive an AM RLC PDU transmitted by a transmitting side, the transmitting side keeps transmitting the AM RLC PDUs until they are successfully received. The receiving side informs the WO 2006/104341 11 PCT/KR2006/001139 transmitting side of reception or failure of the AM RLC PDUs. Included in the information is a status PDU or a piggybacked status PDU. [0044] FIG. 7 is a flowchart illustrating a conventional AM RLC PDU transmitting method according to a first example. As illustrated in FIG. 7, a transmitting side RLC transmits a first AM RLC PDU, a second AM RLC PDU and a third AM RLC PDU. [0045] Assuming that the second AM RLC PDU is lost during transmission, a receiving side RLC is unable to receive the second AM RLC PDU. Therefore, the receiving side RLC determines that the second AM RLC PDU is lost and informs the transmitting side, via a status PDU, that the second AM RLC PDU was not received. [0046] The transmitting side retransmits the second AM RLC PDU in response to the status PDU received from the receiving side. If the receiving side successfully receives the retransmitted second AM RLC PDU, the AM RLC PDU transmitting process is terminated. [0047] As illustrated in FIG. 7, the receiving side transmits the status PDU if an AM RLC PDU is not received, if the transmitting side polls the receiving side AM RLC PDU or if a receiving side transmission interval timer (Timer_Status jperiodic) expires. The transmission interval timer (Timer_Status_periodic) is provided to enable the receiving side to send a status PDU periodically and the receiving side transmits the status PDU each time the transmission interval timer (Timer_Status_periodic) expires. [0048] However, the status PDU includes no data, but rather only control information. Unlike an AM RLC PDU, which includes data, the status PDU lowers a WO 2006/104341 12 PCT/KR2006/001139 real data rate. Therefore, to prevent the status PDU from being sent too frequently, a timer, such as a transmission prohibit interval (Timer_Status_Prohibit) timer, is utilized. [0049] The transmission prohibit interval (Timer_Status_Prohibit) timer is initialized each time the receiving side transmits the status PDU. While the transmission prohibit interval (TimerJ5tatus_Prohibit) timer is active, the receiving side is prevented from transmitting a status PDU. [0050] FIG. 8 is a flowchart illustrating a conventional AM RLC PDU transmitting method according to a second example. As illustrated in FIG. 8, the receiving side determines that a second AM RLC PDU was lost and initiates a transmission interval timer (Timer _Status_periodic) and a transmission prohibit interval timer (Timer_status_Prohibit) while transmitting a status PDU. [0051] Upon receiving a fifth AM RLC PDU, the receiving side determines that a fourth AM RLC PDU was lost. However, since the transmission prohibit interval timer (Timer__status _Prohibit) has not expired, the receiving side does not transmit the status PDU despite having determined that a second PDU was lost. [0052] Also as illustrated in FIG. 8, a re-transmission of the second AM RLC PDU fails as well. However, the receiving side is unable to determine whether the second AM RLC PDU was retransmitted from the transmitting side. The retransmitted second AM RLC PDU may have been lost or the status PDU previously sent by the receiving side to indicate loss at the second AM RLC PDU may have been lost and not delivered to the transmitting side. Therefore, the receiving side again sends the status PDU to the transmitting side to indicate loss of the second AM RLC PDU. WO 2006/104341 13 PCT/KR2006/001139 [0053] The transmission prohibit interval tinier (Timer_Starus_prohibit) determines an interval for retransmitting the status PDU. In the previous example, if the transmission prohibit interval timer (Timer_Status_prohibit) expires, the receiving side immediately transmits the status PDU to the transmitting side again. [0054] Since the transmission prohibit interval timer (Timer_Status_prohibit) expires, there is no limitation on the AM RLC transmitting the status PDU. Upon receiving the retransmitted status PDU, the transmitting side retransmits the second AM RLC PDU one again time. Therefore, the receiving side can receive data without error in operation of the AM RLC. [0055] FIG. 9 illustrates a conventional AM RLC PDU transmitting method according to a third example. As illustrated in FIG. 9, it is assumed that there is no transmission prohibit interval timer (Timer_Status_rohibit) and that a transmission interval timer (Timer_Status_periodic) is set to a very short value. [0056] A receiving side again sends a status PDU indicating loss of the second AM RLC PDU before receiving the retransmitted second AM RLC PDU from a transmitting side. Therefore, the transmitting side decides that the retransmitted second AM RLC PDU was also lost in transmission and retransmits the second AM RLC PDU once more. However, if the receiving side successfully receives the first retransmission of the second AM RLC PDU, the second retransmission of the second AM RLC PDU unnecessarily wastes radio resources. [0057] On the other hand, if the transmission interval timer (Timer__Status__periodic) is set to too long a value, a delay before the transmitting side WO 2006/104341 14 PCT/KR2006/001139 attempts the retransmission is increased. Due to the increased delay, QoS (quality of service) is degraded. [0058] If a value of the transmission interval timer (Timer_Status_periodic) or transmission prohibit interval timer (Timer_status_Prohibit) is set closer to a time required for a transmitting side of a UE to receive a corresponding status response after having sent an AM RLC PDU to a receiving side, system performance can be enhanced. Such a time required for the transmitting to receive a corresponding status response back from the receiving side is called a round-trip time (hereinafter abbreviated 'RTT'). [0059] In conventional methods, a value of a transmission interval timer (Timer_Status_periodic) or a transmission prohibit interval timer (Timer_status_Prohibit) is determined when a UE and a serving RNC (hereinafter abbreviated 'SRNC') first configure a RB and the value is unilaterally selected by the SRNC. However, since the SRNC has no measurement value for data transmission of an AM RLC to a UE, the SRNC is unable to select a correct RTT value. Therefore, the value of the transmission interval timer (Timer_Status_periodic) or transmission prohibit interval timer (Timer_status_Prohibit) cannot be set to a correct value. [0060] Furthermore, since a UE keeps moving between cells and since a processor load of the UE or base station fluctuates, an RTT value varies. Therefore, it is necessary to keep updating the value of the transmission interval timer (Timer_Status_periodic) or transmission prohibit interval timer (Tnner_status_Prohibit). However, these values are determined by the RRC of the SRNC and provided to the RRC of a UE and the RRC of the UE informs the RLC of the UE of the values to use. WO 2006/104341 15 PCT/KR2006/0O1139 [0061] Moreover, signaling between the RECs takes a lot of time and the timer values are basic attributes of an RB. Therefore, whenever these values are changed, a complicated RB reconfiguration process is required. As a result, an incorrect value of the transmission interval timer (Timer_Status_periodic) or transmission prohibit interval timer (Trmer_status_Prohibit) degrades RLC performance and the conventional signaling using the RRC limits the RLC performance as well. [0062] Therefore, there is a need for a system for controlling data block transmission more efficiently by measuring round trip time (RTT) and setting a timer using the measured RTT. The present invention addresses this and other needs. DISCLOSURE OF THE INVENTION [0063] Features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings. [0064] Accordingly, the present invention is directed to a method for controlling transmission of data blocks that substantially obviates one or more problems due to limitations and disadvantages of conventional methods. An object of the present invention is to provide a method and apparatus for controlling a transmission of data blocks by which data block transmission can be controlled more efficiently by measuring the RTT and setting a control timer value according to the measured RTT. WO 2006/104341 16 PCT/KR2006/001139 [0065] In one aspect of the present invention, a method of controlling data block transmission in a wireless communication system is provided. The method includes transmitting a round trip time measurement request to a receiving device, the round trip time measurement request including a first identifier, receiving a round trip time measurement response from the receiving device in response to the round trip time measurement request, the round trip time measurement response including a second identifier and detenrrining a round trip time based on a transmission time of the round trip time measurement request and a reception time of the round trip time measurement response, wherein the round trip time includes a processing delay for processing the round trip time measurement request and round trip time measurement response. [0066] It is contemplated that the method further includes determining either a data block retransmission prohibit interval and/or a data block retransmission interval according to the round trip time, the data block retransmission prohibit interval for preventing the sending of a data block retransmission request to resend a data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend a data block. It is further contemplated that the method further includes periodically transmitting a data block retransmission request until receipt of a data block is acknowledged such that the time between successive data block retransmission requests is as least as great as the round trip time. [0067] It is contemplated that the data block includes an acknowledgement mode radio link control protocol data unit. It is further contemplated that the first identifier is the same as the second identifier. Preferably, the first and second identifiers are sequence numbers. WO 2006/104341 17 PCT/KR2006/001139 [0068] It is contemplated that the method further includes determining the round trip time only when the first identifier is the same as the second identifier. It is further contemplated that the method further includes determining either a round trip time transmission prohibit interval and/or a round trip time transmission interval according to the round trip time, the round trip time transmission prohibit interval for preventing transmission of a next round trip time measurement request and the round trip time transmission interval for initiating transmission of a next round trip time measurement request. [0069] It is contemplated that the method further includes determining a waiting interval according to the round trip time, the waiting interval for initiating retransmission of the round trip time measurement request if the round trip time measurement response is not received. It is further contemplated that the method further includes increasing the waiting interval each time the round trip time measurement request is retransmitted. [0070] It is contemplated that the method further includes incrementing a value of the first identifier each time the round trip time measurement request is retransmitted. It is further contemplated that the method further includes incrementing a retransmission count each time the round trip time measurement request is retransmitted and no longer retransmitting the round trip time measurement request if the count reaches a predetermined value before the round trip time measurement response is received. [0071] It is contemplated that the method further includes including the transmission time of the round trip time measurement request in the round trip time WO 2006/104341 18 PCT/KR2006/001139 measurement request. It is further contemplated that the round trip time measurement response further includes the transmission time of the round trip time measurement response. [0072] It is contemplated that determining the round trip time includes calculating a difference between the transmission time in the round trip time measurement response and the reception time of the round trip time measurement response. It is further contemplated that the transmission time of the round trip time measurement request includes either a system frame number and/or a connection frame number. [0073] It is contemplated that the method further includes including the round trip time measurement request in either a status PDU or a piggybacked status PDU and the round trip time measurement response in cither a status PDU or a piggybacked status PDU. It is further contemplated that determining the round trip time includes computing an average of a plurality of round trip times determined based on the transmission times of a plurality of round trip time measurement requests and the reception times of a plurality of round trip time measurement responses. [0074] It is contemplated that transmitting the round trip time measurement request includes transmitting a plurality of round trip time measurement requests consecutively, each of the plurality of round trip time measurement requests having the same first identifier. It is further contemplated that receiving the round trip time measurement response includes receiving a plurality of round trip time measurement responses consecutively, each of the plurality of round trip time measurement responses WO 2006/104341 19 PCT/KR2006/001139 having the same second identifier. Preferably, the wireless communication system supports a data receipt acknowledgement from the receiving device. [0075] In another aspect of the present invention, a method of controlling data block transmission in a wireless communication system is provided. The method includes transmitting a data block to a receiving device and retransmitting the data block to the receiving device if receipt of the data block is not acknowledged by the receiving device, wherein retransmission of the data block is according to a round trip time that is updated periodically by transmitting a round trip time measurement request including a first identifier to the receiving device, receiving a round trip time measurement response including a second identifier from the receiving device and determining a difference between a transmission time of the round trip time measurement request and a reception time of the round trip time measurement response in consideration of a processing delay for processing the round trip time measurement request and round trip time measurement response. [0076] It is contemplated that the method further includes the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if no response is received within a predetermined time interval after transmission of the status word. It is further contemplated that the method iurtiier includes the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if no response is received after a number of retransmissions of the status word that exceeds a predetermined number. WO 2006/104341 20 PCT/KR2006/001139 [0077] It is contemplated that the method further includes the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if the data block is received after transmission the status word, the data block received within a time interval that is shorter than a previously determined round trip time, the time interval representing a time between a previous transmission of the data block and a subsequent retransmission of the data block. It is further contemplated that the method further includes updating either a data block retransmission prohibit interval and/or a data block retransmission interval according to the round trip time, the data block retransmission prohibit interval for preventing the sending a data block retransmission request to resend the data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend the data block. [0078] It is contemplated that the data block includes an acknowledgement mode radio link control protocol data unit. It is further contemplated that the first and sedond identifiers are sequence numbers. [0079] It is contemplated that the round trip time is updated only when the first identifier is the same as the second identifier. It is further contemplated that the round trip time is periodically updated according to either a round trip time transmission prohibit interval and/or a round trip time transmission interval, the round trip time transmission prohibit interval and round trip time transmission interval based on a previously determined round trip time, the round trip time transmission prohibit interval WO 2006/104341 21 PCT/KR2006/001139 for preventing a next round trip time update and the round trip time transmission interval for initiating a next round trip time update. [0080] In another aspect of the present invention, a communication apparatus for controlling data block transmission in a wireless communication system is provided, The apparatus includes a transmitting unit adapted to transmit RF signals including a round trip time measurement request to a receiving device, the round trip time measurement request including a first identifier, a receiving unit adapted to receive RF signals including a round trip time measurement response from the receiving device in response to the round trip time measurement request, the round trip time measurement response including a second identifier and a processing unit adapted to determine a round trip time based on a transmission time of the round trip time measurement request and a reception time of the round trip time measurement response, wherein the round trip time includes a processing delay for processing the round trip time measurement request and round trip time measurement response. [0081] It is contemplated that the processing unit is further adapted to determine either a data block retransmission prohibit interval and/or a data block retransmission interval according to the round trip time, the data block retransmission prohibit interval for preventing the sending of a data block retransmission request to resend a data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend a data block. It is further contemplated that the processing unit is further adapted to control the transmitting unit to periodically transmit a data block retransmission request until receipt of a data block is WO 2006/104341 22 PCT/KR2006/001139 acknowledged such that the time between successive data block retransmission requests is as least as great as the round trip time. [0082] It is contemplated that the processing unit is further adapted to set the first identifier as a sequence number. It is further contemplated that the processing unit is further adapted to determine the round trip time only when the first identifier is the same as the second identifier. [0083] It is contemplated that the processing unit is further adapted to determine either a round trip time measurement prohibit interval and/or a round trip time measurement transmission interval according to the round trip time and to control the transmitting unit such that transmission of a next round trip time measurement request is prevented according to the round trip time measurement prohibit interval and transmission of a next round trip time measurement request is initiated according to the round trip time measurement transmission interval. It is further contemplated that the processing unit is further adapted to determine a waiting interval according to the round trip time and to control the transmitting unit such that retransmission of the round trip time measurement request is initiated according to the waiting interval if the round trip time measurement response is not received. [0084] It is contemplated that the processing unit is further adapted to increase the waiting interval each time the round trip time measurement request is retransmitted. It is further contemplated that the processing unit is farther adapted to increment a value of the first identifier each time the round trip time measurement request is retransmitted. [0085] It is contemplated that the processing unit is further adapted to increment a retransmission count each time the round trip time measurement request is WO 2006/104341 23 PCT/KR2006/001139 retransmitted and control the transmitting unit such that the round trip time measurement request is no longer retransmitted if the count reaches a predetermined value before the round trip time measurement response is received. It is further contemplated that the processing unit is further adapted to include the transmission time of the round trip time measurement request in the round trip time measurement request. [0086] It is contemplated that the processing unit is further adapted to determine the round trip time by calculating a difference between a transmission time in the round trip time measurement response and the reception time of the round trip time measurement response. It is further contemplated that the processing unit is further adapted to include the round trip time measurement request in either a status PDU or a piggybacked status PDU and to extract the round trip time measurement response from either a status PDU or a piggybacked status PDU. [0087] It is contemplated that the processing unit is further adapted to determine the round trip time by computing an average of a plurality of round trip times determined based on the transmission times of a plurality of round trip time measurement requests and the reception times of a plurality of round trip time measurement responses. It is further contemplated that the processing unit is further adapted to control the transmitting unit to transmit a plurality of round trip time measurement requests consecutively, each of the plurality of round trip time measurement requests having the same first identifier. [0088] It is contemplated that the processing unit is further adapted to process a plurality of consecutively received round trip time measurement responses, each of the plurality of round trip time measurement responses having the same second identifier. WO 2006/104341 24 PCT/KR2006/001139 It is further contemplated that the wireless communication system supports a data receipt acknowledgement from the receiving device. [0089] In another aspect of the present invention, a method of controlling data block transmission in a wireless communication system is provided. The method includes receiving around trip time measurement request from a transmitting device, the round trip time measurement request including a first identifier and transmitting a round trip time measurement response to the receiving device in response to the round trip time measurement request, the round trip time measurement response including a second identifier. [0090] It is contemplated that the data block includes an acknowledgement mode radio link control protocol data unit. It is further contemplated that the first identifier is the same as the second identifier. Preferably, the first and second identifiers are sequence numbers. [0091] It is contemplated that the round trip time measurement request further includes the transmission time of the round trip time measurement request. It is further contemplated that the transmission time of the round trip time measurement request includes either a system frame number and/or a connection frame number. [0092] It is contemplated that the method further includes including the transmission time of the round trip time measurement response in the round trip time measurement response. It is further contemplated that the round trip time measurement request is included in either a status PDU or a piggybacked status PDU and the round trip time measurement response is included in either a status PDU or a piggybacked status PDU. WO 2006/104341 25 PCT/KR2006/001139 [0093] It is contemplated that receiving the round trip time measurement request includes receiving a plurality of round trip time measurement requests consecutively, each of the plurality of round trip time measurement requests having the same first identifier. It is further contemplated that transmitting the round trip time measurement response includes transmitting a plurality of round trip time measurement responses consecutively, each of the plurality of round trip time measurement responses having the same second identifier. Preferably, the wireless communication system supports a data receipt acknowledgement from the receiving device. [0094] In another aspect of the present invention, a communication apparatus for controlling data block transmission in a wireless communication system is provided. The apparatus includes a receiving unit adapted to receive RF signals including a round trip time measurement request from a transmitting device, the round trip time measurement request including a first identifier and a transmitting unit adapted to transmit RF signals including a round trip time measurement response to the transmitting device in response to the round trip time measurement request, the round trip time measurement response including a second identifier. [0095] It is contemplated that the processing unit is further adapted to control the transmitting unit to periodically transmit a data block retransmission request until receipt of a data block is acknowledged such that the time between successive data block retransmission requests is as least as great as a determined round trip time. It is further contemplated that the processing unit is further adapted to set the second identifier as a sequence number. WO 2006/104341 26 PCT/KR2006/001139 [0096] It is contemplated that the processing unit is further adapted to include the transmission time of the round trip, time measurement response in the round trip time measurement response. It is further contemplated that the processing unit is further adapted to extract the round trip time measurement request from either a status PDU or a piggybacked status PDU and to include the round trip time measurement response in either a status PDU or a piggybacked status PDU, [0097] It is contemplated that the processing unit is further adapted to control the transmitting unit to transmit a plurality of round trip time measurement responses consecutively, each of the plurality of round trip time measurement responses having the same second identifier. It is further contemplated that the processing unit is further adapted to process a plurality of consecutively received round trip time measurement requests, each of the plurality of round trip time measurement requests having the same first identifier. Preferably, the wireless communication system supports a data receipt acknowledgement frorn the receiving device. [0098] Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. [0099] These and other embodiments will also become readily apparent to those skilled in the art from the following detailed description of the embodiments having WO 2006/104341 27 PCT/KR2006/001139 reference to the attached figures, the invention not being limited to any particular embodiments disclosed. BRIEF DESCRIPTION OF THE DRAWINGS [00100] The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention. Features, elements, and aspects of the invention that are referenced by the same numerals in different figures represent the same, equivalent, or similar features, elements, or aspects in accordance with one or more embodiments. [00101] FIG. 1 is a block diagram of a network structure of UMTS (universal mobile telecommunications system); [00102] FIG 2 is a diagram of architecture of UMTS radio protocol; [00103] FIG 3 is a structural diagram of AM RLC PDU; [00104] FIG 4 is a structural diagram of status PDU; [00105] FIG 5 is a structural diagram of a piggybacked status PDU; [00106] FIG 6 is a structural diagram of Reset ACK PDU; [00107] FIG 7 is a flowchart of a first example of a conventional AM RLC PDU transmitting method. [00108] FIG 8 is a second example of a conventional AM RLC PDU WO 2006/104341 28 PCT/KR2006/001139 [00109] FIG 9 is a third exampl e of a conventional AM RLC PDU transmitting method. [00110] FIG 10 is a flowchart of an RTT measuring and setting method according to one embodiment of the present invention. [00111] FIG. 11 is a diagram of an RTT measurement response (SUFI) according to one embodiment of the present invention. BEST MOPE FOR CARRYING OUT THE INVENTION [00112] The present invention relates to an apparatus and method for controlling a transmission of data blocks by which data block transmission can be controlled more efficiently by measuring the RTT and setting a control timer value according to the measured RTT. Although the present invention is illustrated with respect to a mobile communication device, it is contemplated that the present invention may be utilized anytime it is desired to more efficiently control a transmission of data blocks by measuring a round trip time and setting a control timer value according to the measured time. [00113] Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. [00114] The present invention enables an AM RLC entity to operate with an optimal transmission interval timer (timer_Status__periodic) value and an optimal WO 2006/104341 29 PCT/KR2006/001139 transmission prohibit interval timer (Timer_status_Prohibit) value, thereby providing a service more efficiently by increasing the data rate. The present invention provides a method to enable an RLC entity to measure a round-trip time (RTT) value and set a transmission interval timer (timer_Status_periodic) value and a transmission prohibit interval timer (Timer_status_Prohibit) value using the measured RTT value, [00115] An AM RNC uses a status PDU or piggybacked status PDU to measure an RTT value. Specifically, an AM RLC attempting to measure the RTT sends a message requesting RTT measurement to an AM RLC of the other side. An AM RLC entity, having received the message, transmits a corresponding response. [00116] The requesting AM RLC uses the status PDU or the piggybacked status PDU to send the RTT measurement request message. Specifically, the AM RLC includes the RTT measurement request (SUFI) in a transmitted status PDU or piggybacked status PDU. [00117] The AM RLC of the other side uses the status PDU or the piggybacked status PDU to transmit an RTT measurement response message in response to the RTT measurement request message. Specifically, the AM RLC includes the RTT measurement response SUFI in a transmitted status PDU or a piggybacked status PDU. [00118] Since the RTT measurement request or response message is transmitted through a radio section, it may be lost in the radio section. Therefore, for more accurate RTT measurement, a sequence number is attached to the AM RLC PDU that includes the RTT measurement request so that a measuring side can identify the RTT measurement response message. WO 2006/104341 30 PCT/KR2006/001139 [00119] The requesting AM RLC attaches a sequence number to each RTT measurement request message. Upon receiving the RTT measurement response message, the requesting AM RLC processes the RTT measurement response message if a value equal to the sequence number that was sent by the AM RLC is received. If an RTT measurement response message including a value different from the sequence number that was sent by the AM RLC is received, the requesting AM RLC deletes the message or does not process the message. [00120] The requesting AM RLC records a time at which each RTT measurement request message is transmitted. Each time an RTT measurement request message is received, the measuring AM RLC checks the sequence number included in the RTT measurement request message. Upon sending an RTT measurement response message, the measuring AM RLC includes a value equal to the sequence number from the RTT request message in the RTT measurement response message. [00121] To measure a real RTT value, the requesting AM RLC waits for an RTT measurement response message after sending an RTT measurement request message. Upon receiving the RTT measurement response message, the requesting AM RLC checks a sequence number included in the received RTT measurement response message. [00122] If the sequence number is equal to the sequence number previously sent by the AM RNC in the RTT measurement request message, the AM RNC determines a difference between the time the RTT measurement response message was received and the time the RTT measurement request message was sent The AM RNC then uses the determined difference as a measured RTT value. WO 2006/104341 31 PCT/KR2006/001139 [00123] The requesting AM RLC executes the RTT measurement process several times to increase reliability of the measurement and to remove variable factors in measurement The AM RLC determines an average of the measured RTT values for use as an estimated value of real RTT. By determining an average value, a UE can use a number of samples as indicated by a base station. [00124] Subsequently, the requesting AM RNC can set the estimated RTT as a transmission prohibit interval timer (Timer _status_Prohibit) value or a transmission interval timer (Timer_Starus_periodic) value. Alternately, the requesting AM RNC may set the transmission prohibit interval timer (Timer_status_Prohibit) value or transmission interval timer (Timer_Status_periodic) value by processing the estimated RTT according to parameters indicated by a base station. [00125] FIG. 10 illustrates a flowchart of an RTT measuring and setting method according to one embodiment of the present invention. As illustrated in FIG. 10, once a transmitting side initiates an RTT measurement (S101), an RTT measurement request message is created and a sequence number is included in the message and recorded in a transmitting side memory (S102). The created RTT measurement request message is transmitted to a receiving side and a time at which the RTT measurement request message is transmitted is recorded in the transmitting side memory (S1 03). [00126] A receiving side, upon receiving the RTT measurement request message transmitted by the transmitting side (S104), transmits an RTT measurement response message to the transmitting side (S106). After transmitting the RTT measurement request message, the transmitting side waits for an RTT measurement response message (S107). Upon receiving the RTT measurement response message, the transmitting side WO 2006/104341 32 PCT/KR2006/001139 records a reception time of the RTT measurement response message in the transmitting side memory (S108). [00127] The transmitting side checks a sequence number included in the received RTT measurement response message (S109). If the sequence number in the RTT measurement response message is equal to the sequence number in the transmitted RTT measurement request message, the RTT is calculated using the recorded transmission time and the recorded reception time (S110). [00128] However, for accurate RTT measurement, the receiving side AM RLC must send an RTT measurement response immediately upon receiving an RTT measurement request. In order to accomplish this, an RTT measurement response message can be immediately transmitted without previously set limitations, such as a transmission prohibit interval timer (Timer_status_Prohibit). Furthermore, for more effective measurement, the transmitting side AM RLC can be free from previously set limitations with regard to sending an RTT measurement request. [00129] FIG. 11 illustrates an RTT measurement response SUFI according to one embodiment of the present invention. As illustrated in FIG 10 and FIG 11, 'TYPE' is an identifier to identify various types of SUFIs and ' Sequence Number' indicates an RTT measurement response SUFI corresponding to an RTT measurement request SUFI [00130] Unlike a status PDU, a pi ggybacked status PDU, which replaces padding of an AM RLC PDU, has no additional overhead. Therefore, to reduce overhead due to the RTT measurement request message, the RTT measurement request message can be included only in a piggybacked status PDU. WO 2006/104341 33 PCT/KR2006/001139 [00131] However, if RTT measurements are performed too frequently, system performance may be affected. To reduce the effect upon system performance, a network can restrict RTT measurements performed by an AM entity. In order to restrict RTT measurements, an RTT measurement prohibit interval timer can be used. Specifically, after an RTT measurement request has been sent or after an RTT measurement process has been completed, the AM entity initiates the RTT measurement prohibit interval timer. A UE is unable to initiate a new RTT measurement process until the RTT measurement prohibit interval timer expires. [00132] To increase accuracy of the RTT measurement process, an AM entity can send an RTT measurement request message and an RTT measurement response message consecutively. In this way, the probability of losing each message in a radio section is lowered and sequence numbers of the consecutively sent messages are equal to each other. The number of the consecutively sent messages can be determined by the network and indicated to a UE. [00133] If an AM entity periodically performs the RTT measurement, it can be prevent a difference between an actual RTT value and an RTT value determined by a UE from deviating considerably. For periodically performing the RTT measurement, an RTT measurement period timer (periodic timer) is defined. A network can inform a UE of a value of the RTT measurement prohibit interval timer and a value of the RTT measurement period timer (periodic timer). [00134] An AM entity initiates the RTT measurement period timer (periodic timer). Whenever the RTT measurement period timer (periodic timer) expires, the AM entity initiates the RTT measurement process. Each time the RTT measurement process WO 2006/104341 27 PCT/KR2006/001139 is completed, the AM entity activates the RTT measurement period timer (periodic timer) again. [00135] Since the RTT measurement request message or the RTT measurement response message can be lost in the radio section, the RTT measurement response message may not arrive at the side having made the request for the RTT measurement. An RTT measurement waiting timer can be defined to prevent a side having sent an RTT measurement request message from awaiting the RTT measurement response message indefinitely. [00136] After transmitting an RTT measurement response message, the AM entity activates the RTT measurement waiting timer. If the RTT measurement response message is not received before the RTT measurement waiting timer expires, the AM entity sends the RTT measurement request message again. This retransmission process cannot be repeated indefinitely. To restrict the retransmission process, a count limit of RTT measurement request retransmissions can be set. [00137] In order to remove ambiguity of each retransmission, a sequence number can be changed each time the RTT measurement request is retransmitted. The sequence number can simply be incremented by' 1' each time the RTT measurement request is retransmitted. To increase efficiency, each time the RTT measurement request is retransmitted, a value of the RTT measurement waiting timer is increased to accommodate a change of a lower layer. [00138] If an AM PDU is not received by an AM entity, the AM entity transmits a status PDU. If a correspondiag response is not received within a uniform duration or if a transmission count of the status PDU indicating that a specific AM PDU is not WO 2006/104341 35 PCT/KR2006/001139 received exceeds a predetermined value, the AM entity executes the RTT measurement process. Furthermore, if an AM PDU that is indicated as not having been received in the status PDU arrives within a time that is shorter than a previously measured RTT value or a time that is shorter than the transmission prohibit interval timer (Tirner_status_Probibit) value, the AM entity executes the RTT measurement process. Furthermore, [00139] Whenever the RTT value is updated, the AM entity updates an associated timer value. The AM entity can appropriately set values associated with polling, such as a polling timer (Timer poll) or a polling prohibit interval timer (Timer_Poll_prohibit). [00140] The AM entity can also include the time of message transmission when transmitting an RTT measurement request message. In this way, the time included in the RTT measurement request message is a time that can be determined by the AM entities of both sides. Furthermore, the time included can be a system frame number (hereinafter abbreviated 'SFN') as a time reference applied to all UEs located within one cell or a connection frame number (hereinafter abbreviated 'CFN') managed in common by one UE and one SRNC. [00141 ] Therefore, one side, having received the RTT measurement request message, can obtain the transmission time in one direction using the difference between the time included in the message and the time at which the message was received. Similarly, if the time of transmission of the RTT measurement response message is included in the response message, the side receiving the RTT measurement response message can calculate a portion of RTT using the difference between the time the WO 2006/104341 36 PCT/KR2006/001139 message was received and the time included in the message. The RTT can then be found by multiplying the measured time by' 2'. [00142] Accordingly, the present invention sets a control timer by measuring an RTT value, thereby transmitting data blocks more efficiently, [00143] It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. Thus, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. 100144] As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, unless otherwise specified, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the metes and bounds of the claims, or equivalence of such metes and bounds are therefore intended to be embraced by the appended claims. [00145] The foregoing embodiments and advantages are merely exemplary and are not to be construed as limiting the present invention. The present teaching can be readily applied to other types of apparatuses. The description of the present invention is intended to be illustrative, and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those skilled in the art. In the claims, means-plus-function clauses are intended to cover the structure described herein as WO 2006/104341 37 PCT/KR2006/001139 performing the recited function and not only structural equivalents but also equivalent structures. INDERSTRIAL APPLICABILITY [00146] The present invention can be applied to a mobile communication system. WO 2006/104341 38 PCT/KR2006/001139 What is claimed is: 1. A method of controlling data block transmission in a wireless communication system, the method comprising: transmitting a round trip time measurement request to a receiving device, the round trip time measurement request comprising a first identifier; receiving a round trip time measurement response from the receiving device in response to trie round trip time measurement request, the round trip time measurement response comprising a second identifier; and determining a round trip time based on a transmission time of the round trip time measurement request and a reception time of the round trip time measurement response, wherein the round trip time comprises a processing delay for processing the round trip time measurement request and round trip time measurement response. 2. The method of claim 1, further comprising determining at least one of a data block retransmission prohibit interval and a data block retransmission interval according to the round trip time, the data block retransmission prohibit interval for preventing the sending of a data block retransmission request to resend a data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend a data block. WO 2006/104341 PCT/KR2006/001139 39 3. The method of claim 1, further comprising periodically transmitting a data block retransmission request until receipt of a data block is acknowledged such that the time between successive data block retransmission requests is as least as great as the round trip time. 4. The method of claim 1, wherein the data block comprises an acknowledgement mode radio link control protocol data unit. 5. The method of claim 1, wherein the first identifier is the same as the second identifier. 6. The method of claim 1, wherein the first and second identifiers are sequence numbers. 7. The method of claim 1, further comprising determining the round trip time only when the first identifier is the same as the second identifier. 8. The method of claim 1, further comprising determining at least one of a round trip time transmission prohibit interval and a round trip time transmission interval according to the round trip time, the round trip time transmission prohibit interval for preventing transmission of a next round trip time measurement request and the round trip time transmission interval for initiating transmission of a next round trip time measurement request. WO 2006/104341 PCT/KR2006/001139 40 9. The method of claim 1, wherein the transmission time of the round trip time measurement request comprises at least one of a system frame number and a connection frame number. 10. The method of claim 1, further comprising including the round trip time measurement request in one of a status PDU and a piggybacked status PDU and wherein the round trip time measurement response is included in one of a status PDU and a piggybacked status PDU. 11. The method of claim 1, wherein the wireless communication system supports a data receipt acknowledgement from the receiving device. 12. A method of controlling data block transmission in a wireless communication system, the method comprising: transmitting a data block to a receiving device; and retransmitting the data block to the receiving device if receipt of the data block is not acknowledged by the receiving device, wherein retransmission of the data block is according to a round trip time that is updated periodically by transmitting a round trip time measurement request comprising a first identifier to the receiving device, receiving a round trip time measurement response comprising a second identifier from the receiving device and determining a difference between a transmission time of the round trip time measurement request and a reception WO 2006/104341 PCT/KR2006/001139 41 time of the round trip time measurement response in consideration of a processing delay for processing the round trip time measurement request and round trip time measurement response. 13. The method of claim 12, further comprising the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if no response is received within a predetermined time interval after transmission of the status word. 14. The method of claim 12, further comprising the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if no response is received after a number of retransmissions of the status word that exceeds a predetermined number. 15. The method of claim 12, further comprising the receiving device transmitting a status word, the status word indicating that the data block was not received and wherein updating of the round trip time is initiated by the receiving device if the data block is received after transmission the status word, the data block received within a time interval that is shorter than a previously determined round trip time, the time interval WO 2006/104341 PCT/KR2006/001139 42 representing a time between a previous transmission of the data block and a subsequent retransmission of the data block. 16. The method of claim 12, further comprising updating at least one of a data block retransmission prohibit interval and a data block retransmission interval according to the round trip time, the data block retransmission prohibit interval for preventing the sending a data block retransmission request to resend the data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend the data block. 17. The method of claim 12, wherein the data block comprises an acknowledgement mode radio link control protocol data unit. 18. The method of claim 12, wherein the first and second identifiers are sequence numbers. 19. The method of claim 12, wherein the round trip time is updated only when die first identifier is the same as the second identifier. 20. The method of claim 12, wherein the round trip time is periodically updated according to at least one of a round trip time transmission prohibit interval and a round trip time transmission interval, the round trip time transmission prohibit interval and round trip WO 2006/104341 PCT/KR2006/001139 43 time transmission interval based on a previously determined round trip time, the round trip time transmission prohibit interval for preventing a next round trip time update and the round trip time transmission interval for initiating a next round trip time update. 21. A communication apparatus for controlling data block transmission in a wireless communication system, the apparatus comprising: a transmitting unit adapted to transmit RF signals comprising a round trip time measurement request to a receiving device, the round trip time measurement request comprising a first identifier; a receiving unit adapted to receive RF signals comprising a round trip time measurement response from the receiving device in response to the round trip time measurement request, the round trip time measurement response comprising a second identifier; and a processing unit adapted to determine a round trip time based on a transmission time of the round trip time measurement request and a reception time of the round trip time measurement response, wherein the round trip time comprises a processing delay for processing the round trip time measurement request and round trip time measurement response. 22. The apparatus of claim 21, wherein the processing unit is further adapted to determine at least one of a data block retransmission prohibit interval and a data block retransmission interval according to the round trip time, the data block retransmission WO 2006/104341 PCT/KR2006/001139 44 prohibit interval for preventing the sending of a data block retransmission request to resend a data block and the data block retransmission interval for initiating the sending of a data block retransmission request to resend a data block. 23. The apparatus of claim 21, wherein the processing unit is further adapted to control the transmitting unit to periodically transmit a data block retransmission request until receipt of a data block is acknowledged such that the time between successive data block retransmission requests is as least as great as the round trip time. 24. The apparatus of claim 21, wherein the processing unit is further adapted to set the first identifier as a sequence number. 25. The apparatus of claim 21, wherein the processing unit is further adapted to determine the round trip time only when the first identifier is the same as the second identifier. 26. The apparatus of claim 21, wherein the processing unit is further adapted to determine at least one of a round trip time measurement prohibit interval and a round trip time measurement transmission interval according to the round trip time and to control the transmitting unit such that transmission of a next round trip time measurement request is prevented according to the round trip time measurement prohibit interval and transmission WO 2006/104341 PCT/KR2006/001139 45 of a next round trip time measurement request is initiated according to the round trip time measurement transmission interval. 27. The apparatus of claim 21, wherein the processing unit is further adapted to include the transmission time of the round trip time measurement request in the round trip time measurement request. 28. The apparatus of claim 21, wherein the processing 'unit is further adapted to determine the round trip time hy calculating a difference between a transmission time in the round trip time measurement response and the reception time of the round trip time measurement response. 29. The apparatus of claim 21, wherein the processing unit is further adapted to include the round trip time measurement request in one of a status PDU and a piggybacked status PDU and to extract the round trip time measurement response from one of a status PDU and a piggybacked status PDU. 30. The apparatus of claim 21, wherein the processing unit is further adapted to determine the round trip time by computing an average of a plurality of round trip times determined based on the transmission times of a plurality of round trip time measurement requests and the reception times of a plurality of round trip time measurement responses. WO 2006/104341 PCT/KR2006/001139 46 31. The apparatus of claim 21, wherein the processing unit is further adapted to control the transmitting unit to transmit a plurality of round trip time measurement requests consecutively, each of the plurality of round trip time measurement requests having the same first identifier. 32. The apparatus of claim 21, wherein the processing unit is further adapted to process a plurality of consecutively received round trip time measurement responses, each of the plurality of round trip time measurement responses having the same second identifier. 33. The apparatus of claim 21, wherein the wireless communication system supports a data receipt acknowledgement from the receiving device. 34. A method of controlling data "block transmission in a wireless communication system, the method comprising: receiving a round trip time measurement request from a transmitting device, the round trip time measurement request comprising a first identifier; and transmitting a round trip time measurement response to the receiving device in response to the round trip time measurement request, the round trip time measurement response comprising a second identifier. 35. The method of claim 34, wherein the data block comprises an acknowledgement mode radio link control protocol data unit. WO 2006/104341 PCT/KR2006/001139 47 36. The method of claim 34, wherein the first identifier is the same as the second identifier. 37. The method of claim 34, wherein the first and second identifiers are sequence numbers. 38. The method of claim 34, wherein the round trip time measurement request further comprises the transmission time of the round trip time measurement request. 39. The method of claim 38, wherein the transmission time of the round trip time measurement request comprises at least one of a system frame number and a connection frame number. 40. The method of claim 34, further comprising including the transmission time of the round trip time measurement response in the round trip time measurement response. 41. The method of claim 34, wherein the round trip time measurement request is included in one of a status PDU and a piggybacked status PDU and further comprising including the round trip time measurement response in one of a status PDU and a piggybacked status PDU. WO 2006/104341 . PCT/KR2006/001139 48 42. The method of claim 34, wherein receiving the round trip time measurement request comprises receiving a plurality of round trip rime measurement requests consecutively, each of the plurality of round trip time measurement requests having the same first identifier. 43. The method of claim 34, wherein transmitting the round tip time measurement response comprises transmitting a plurality of round trip time measurement responses consecutively, each of the plurality of round trip time measurement responses having the same second identifier. 44. The method of claim 34, wherein the wireless communication system supports a data receipt acknowledgement from the receiving device. 45. A communication apparatus for controlling data block transmission in a wireless communication system, the apparatus comprising: a receiving unit adapted to receive RF signals comprising a round trip time measurement request from a transmitting device, the round trip time measurement request comprising a first identifier; and a transmitting unit adapted to transmit RF signals comprising a round trip time measurement response to the transmitting device in response to the round trip time measurement request, the round trip time measurement response comprising a second identifier. WO 2006/104341 PCT/KR2006/001139 49 46. The apparatus of claim 45, wherein the processing unit is further adapted to control the transmitting unit to periodically transmit a data block retransmission request until receipt of a data block is acknowledged such that the time between successive data "block retransmission requests is as least as great as a determined round trip time. 47. The apparatus of claim 45, wherein the processing unit is further adapted to set the second identifier as a sequence number. 48. The apparatus of claim 45, wherein the processing unit is further adapted to include the transmission time of the round trip time measurement response in the round trip time measurement response. 49. The apparatus of claim 45, wherein the processing unit is further adapted to extract the round trip time measurement request from one of a status PDU and a piggybacked status PDU and to include the round trip time measurement response in one of a status PDU and a piggybacked status PDU. 50. The apparatus of claim 45, wherein the processing unit is further adapted to control the transmitting unit to transmit a plurality of round trip tune measurement responses consecutively, each of the plurality of round trip time measurement responses having the same second identifier. WO 2006/104341 PCT/KR2006/001139 50 51. The apparatus of claim 45, wherein the processing unit is further adapted to process a plurality of consecutively received round trip time measurement requests, each of the plurality of round trip time measurement requests having the same first identifier, 52. The apparatus of claim 45, wherein the wireless communication system supports a data receipt acknowledgement from the receiving device. A method and apparatus for controlling a transmission of data blocks is provided by which data block transmission can be controlled more efficiently by measuring the RTT and setting a control timer value according to the measured RTT

Full Text

WO 2006/104341 1 PCT/KR2006/001139

METHOD AND APPARATUS OF CONTROLLING TRANSMISSION
OF DATA BLOCK
TECHNICAL FIELD
[0001] The present invention relates to a method and apparatus for controlling
transmission of a data block. Although the present invention is suitable for a wide
scope of applications, it is particularly suitable for controlling data block transmission
more efficiently by measuring round trip time (RTT) and setting a timer using the
measured RTT.
BACKGROUND ART
[0002] FIG. 1 is a block diagram of a network structure of a universal mobile
telecommunications system (UMTS). Referring to FIG. 1, the universal mobile
telecommunications system (hereinafter, referred to as 'UMTS') includes a user
equipment 1 (hereinafter, referred to as 'UE'), a UMTS terrestrial radio access network
2 (hereinafter, referred to as 'UTRAN') and a core network 3 (hereinafter, referred to as
'CN'). The UTRAN 2 includes at least one radio network sub-system 4 (hereinafter,
referred to as 'RNS') and each RNS includes a radio network controller 5 (hereinafter,
referred to as 'RNC') and at least one base station 6 (hereinafter, referred to as 'Node
B') managed by the RNC. The Node B 6 includes at least one cell.
[0003] FIG. 2 is an architectural diagram of UMTS radio protocol between a
UE 1 and UTRAN 2. Referring to FIG. 2, the radio interface protocol horizontally
includes a physical layer, a data link layer and a network layer and the radio interface

WO 2006/104341 2 PCT/KR2006/001139
protocol vertically includes a user plane for data information transfer and a control
plane for signaling transfer. The protocol layers in FIG, 2 can be divided into L1 (first
layer), L2 (second layer), and L3 (third layer) based on lower three layers of the open
system interconnection (OSI) standard model widely known in the communications
systems. The radio protocol layers exist as pairs in both the UE 1 and UTRAN 2 to
facilitate data transmission in the radio section.
[0004] The physical layer as the first layer provides an information transfer
service to an upper layer using physical channels. The physical layer is connected to a
medium access control (MAC) layer above the physical layer via transport channels
through which data are transferred between the medium access control layer and the
physical layer. The transport channels are classified as dedicated transport channels and
common transport channels according to whether or not a channel is shared. Data is
transmitted between different physical layers, and more particularly, between the
physical layer of a transmitting side and the physical layer of a receiving side via
physical channels.
[0005] The medium access control (MAC) layer of the second layer provides
services to a radio link control (hereinafter abbreviated RLC) layer above the MAC
layer via logical channels. The RLC layer of the second layer supports reliable data
transfer and is operative in segmentation and concatenation of RLC service data units
(SDUs) sent down from an upper layer.
[0006] The MAC layer and the physical layer exchange data via the transport
channel. The second layer (L2) includes a MAC layer, a radio link control (RLC) layer,

WO 2006/104341 3 PCT/KR2006/001139
a broadcast/multicast control (BMC) layer and a packet data convergence protocol
(PDCP) layer.
[0007] The MAC layer handles mapping between logical channels and transport
channels and provides allocation of the MAC parameters for allocation and re-allocation
of radio resources. The MAC layer is connected to an upper layer, called the radio link
control (RLC) layer, via a logical channel,
[0008] Various logical channels are provided according to the type of
information transmitted. In general, a control channel is used to transmit information of
the control plane and a traffic channel is used to transmit information of the user plane.
[0009] The MAC layer is connected to the physical layer by transport channels
and can be divided into a MAC-b sub-layer, a MAC-d sub-layer, a MAC-c/sh sub-layer,
a MAC-hs sub-layer and a MAC-e sublayer. The division of the MAC is according to
the type of transport channel being managed.
[0010] The MAC-b sub-layer manages a BCH (Broadcast Channel), which is a
transport channel handling the broadcasting of system information. The MAC-c/sh sub-
layer manages a common transport channel, such as a forward access channel (FACH)
or a downlink shared channel (DSCH), which is shared by a plurality of terminals, or in
the uplink the Radio Access Channel (RACH). The MAC-d sub-layer manages a
dedicated channel (DCH), which is a dedicated transport channel for a specific terminal.
The MAC-hs sublayer manages a transport channel HS-DSCH (high speed downlink
shared channel) for high speed data transfer to support the high speed data transfer in
downlink and uplink. The MAC-e sublayer manages a transport channel E-DCH
(enhanced dedicated channel) for uplink data transfer.

WO 2006/104341 4 PCT/KR2006/001139
[0011] The radio link control (hereinafter abbreviated 'RLC') layer supports a
guarantee of quality of service (hereinafter abbreviated 'QoS') of each radio bearer and
also controls the transfer of corresponding data. The RLC layer leaves one independent
RLC entity at each RB to guarantee intrinsic QoS of the RB. Three RLC modes are
provided to support various QoS; a transparent mode (hereinafter abbreviated 'TM'), an
unacknowledged mode (hereinafter abbreviated 'UM') and an acknowledged mode
(hereinafter abbreviated 'AM').
[0012] The RLC also facilitates adjusting a data size to enable a lower layer to
transfer data to a radio section. To facilitate an adjusted data size, the RLC segments
and concatenates data received from an upper layer.
[0013] The PDCP layer is located above the RLC layer and facilitates
transferring data using IP packets, such as IPv4 or IPv6, efficiently in a radio section
having a relatively small bandwidth. Toward this end, the PDCP layer performs header
compression, a function by which mandatory data header information is transferred to
increase transport efficiency in a radio section.
[0014] Since header compression is a basic function of the PDCP layer, the
PDCP layer exists only in a packet service domain (hereinafter abbreviated 'PS
domain'). Furthermore, one PDCP entity exists for each RB in order to provide an
effective header compression function to each PS service.
[0015] The BMC (broadcast/multicast control) layer is located above the RLC
layer. The BMC layer schedules a cell broadcast message and performs broadcasting to
UEs located in a specific cell.

WO 2006/104341 5 PCT/KR2006/001139
[0016] A radio resource control (RRC) layer located on the lowest part of the
third layer is defined in the control plane only and controls the logical channels, the
transport channels, and the physical channels with configuration, reconfiguration, and
release of radio bearers (RBs). A RB is a logical path provided by the first and second
layers for the data transfer between the UE 1 and the UTRAN 2. Generally, configuring
an RB refers to defining the characteristics of protocol layers and channels necessary for
providing a specific service and is to establish respective specific parameters and
operational methods for them.
[0017] Basic functions of the RLC layer are to guarantee QoS of each RB and a
corresponding data transfer. Since an RB service is a service that the second layer
provides to an upper layer, the entire second layer affects QoS. However, the RLC layer
has the greatest effect on QoS.
[0018] The RLC layer provides an independent RLC entity at each RB to
guarantee the intrinsic QoS of aa RB and provides three modes, specifically TM, UM
and AM. Since the three RLC modes differ from one another in the supported QoS,
their operational methods are different as well as their detailed functions. Therefore, the
RLC operational mode must be considered.
[0019] TM RLC is a mode in which no overhead is attached to an RLC service
data unit (hereinafter abbreviated 'SDU') that is delivered from a higher layer in
configuring an RLC protocol data unit (hereinafter abbreviated TDU'). Since the RLC
transmits the SDU transparently, it is called TM RLC.
[0020] Due to these transparent characteristics, the TM RLC plays various roles
in user and control planes. In the user plane, the TM RLC performs real-time circuit

WO 2006/104341 6 PCT/KR2006/001139

data transfer, such as voice or streaming data, in a circuit service domain (hereinafter
abbreviated 'CS domain') since data processing time within RLC is short. In the control
plane, the RLC controls uplink transmission of RRC messages from an unspecific UE or
downlink transmission of RRC messages broadcast from all UEs with a cell since there
is no overhead within the RLC.
[0021] Unlike the transparent mode, a non-transparent mode is a mode in which
overhead is added in the RLC. Non-transparent modes are classified into an
unacknowledged mode (UM), having no acknowledgement for the transmitted data, and
an acknowledged mode (AM), having acknowledgement for the transmitted data.
[0022] By attaching a PDU header including a sequence number (hereinafter
abbreviated 'SN') to each PDU, UM RLC enables a receiving side to determine which
PDU is lost in the course of transmission. Due to this characteristic, the UM RLC
primarily performs transmission of real-time packet data, such as broadcast/multicast
data transmission, voice of PS domain, (such as, VoIP) and streaming data in the user
plane or transmission of RRC messages transmitted to a specific UE or specific UE
group within a cell in control plane that require no acknowledgement.
[0023] AM RLC is a non-transparent mode that configures PDUs by attaching a
PDU header, including an SN, as in UM RLC. However, AM RLC differs from UM
RLC in that a receiving side acknowledges the PDUs transmitted by a transmitting side.
[0024] The receiving side acknowledges PDU reception in the AM RLC
because the transmitting side can request retransmission of a PDU that is not received
by the receiving side. The retransmission function is the most outstanding feature of the
AM RLC.

WO 2006/104341 7 PCT/KR2006/001139
[0025] An object of the AM RLC is to guarantee error-free data transmission
through retransmission. Due to this characteristic, the AM RLC primarily controls
transmission of non-real-time packet data, such as TCP/IP of PS domain in the user
plane, or transmission of RRC messages transmitted to a specific UE within a cell in
control plane for which acknowledgment is mandatory.
[0026] TM or DM RLC is used for uni-directional communications, whereas
AM RLC is used for bi-directional communications due to the feedback from a
receiving side in AM RLC. Since bi-directional communications are primarily used for
point-to-point communications, AM RLC uses only a dedicated logical channel.
Therefore, one RLC entity includes a transmission or reception structure in TM or UM
RLC, whereas a transmitting side and a receiving side exist within one RLC entity in
AM RLC.
[0027] The complexity of AM RLC is due to the retransmission function. The
AM RLC includes a retransmission buffer for retransmission management as well as a
transmitting/receivtng buffer and performs various functions. The various functions may
be related to a transmitting/receiving window for flow control, polling when a
transmitting side requests status information from a corresponding RLC entity of a
receiving side, status reporting in order that a receiving side may report its buffer status
to a corresponding RLC entity of a transmitting side, status PDU for carrying status
information and piggybacking by inserting a status PDU in a data PDU to increase data
transfer efficiency.
[0028] A reset PDU is required in order to request the resetting of all operations
and parameters of an AM RLC entity of the other side if an AM RLC entity discovers a

WO 2006/104341 8 PCT/KR2006/001139

critical error during the course of operation, A reset ACK PDU is required for response
to the reset PDU.
[0029] To support these functions, an AM RLC needs various protocol
parameters, status variables and a timer. PDUs used for data transfer control in status
information reporting, status PDUs and reset PDUs are called control PDUs and PDUs
used for delivery of user data are called data PDUs.
[0030] Specifically, PDUs used by an AM RLC may be classified into two
types. A first type is a data PDU and a second type is a control PDU. Control PDUs
include status PDU, piggybacked status PDUs, reset PDUs and reset ACK PDUs.
[0031] As mentioned previously control PDUs are used for a reset procedure.
The reset procedure is used in response to an error condition during operation of an AM
RLC.
[0032] For example, an error condition may result if mutually used sequence
numbers are different from each other or a PDU or an SDU transmission fails in excess
of a count limit. Through the reset procedure, an AM RLC of a receiving side and an
AM RLC of a transmitting side reset environmental variables and then communications
are re-enabled.
[0033] Once an AM RLC entity, such as an AM RLC of a transmitting side,
decides to initiate a reset procedure, a currently used transmitting direction hyper frame
number (hereinafter abbreviated 'HFN') value is included in a reset PDU and the reset
PDU is transmitted to the corresponding AM RLC entity on the other side, such as an
AM RLC of a receiving side. The AM RLC of the receiving side, having received the

WO 2006/104341 9 PCT/KR2006/001139
reset PDU, re-establishes an HFN value of its receiving direction and then resets
environmental variables, such as a sequence number.
[0034] Subsequently, the AM RLC of the receiving side includes its
transmitting direction HFN in a reset ACK PDU and then transmits the reset ACK PDU
to the AM RLC of the transmitting side. Upon receiving the reset ACK PDU, the AM
RLC of the transmitting side re-establishes its receiving direction HFN value and then
resets environmental variables.
[0035] FIG. 3 illustrates the structure of an AM RLC PDU. As illustrated in
FIG. 3, an AM RLC PDU is used when an AM RLC entity attempts to transmit user
data or piggybacked status information anci a polling bit. A user data portion is
configured as an 8-bit integer multiplication and an AM RLC PDU header is
constructed with a 2-octet sequence number. The header part of an AM RLC PDU
includes a length indicator.
[0036] FIG. 4 illustrates the structure of a status PDU. As illustrated in FIG. 4,
a status PDU includes different types of SUFIs (super fields). The status PDU size is
variable, but is limited to a size of the largest RLC PDU of a logical channel carrying
the status PDU.
[0037] The SUFI is utilized to identify what type of AM RLC PDU is received
at a receiving side or what type of AM RLC PDU is not received at the receiving side.
The SUFI consists of three parts that indicate type, length and value.
[0038] FIG. 5 illustrates the structure of a piggybacked status PDU. As
illustrated in FIG. 5, the structure of a piggybacked status PDU, while similar to that of
a status PDU, differs in that a reserved bit (R2) replaces the D/C field. The piggybacked

WO 2006/104341 10 PCT/KR2006/001139
status PDU is inserted if there is sufficient space in an AM RLC PDU. The PDU type
value may be fixed at' 000'.
[0039] FIG. 6 illustrates the structure of a reset ACK PDU. As illustrated in
FIG. 6, a reset PDU includes a 1-bit sequence number (RSN). A reset ACK PDU is
transmitted in response to a received reset PDU by including the RSN contained in the
received reset PDU.
[0040] The 'D/C field' indicates whether a corresponding PDU is a control
PDU or a data PDU. The TDU Type' indicates a type of the control PDU and,
specifically, whether a corresponding PDU is a reset PDU or a status PDU. The
'Sequence Number' value indicates sequence number information of an AM RLC PDU.
[0041] The 'Polling Bit' value is set when a request for a status report is made
to a receiving side. The 'Extension bit (E)' value indicates whether a next octet is a
length indicator. The 'Reserved bit (R1)' value is used for a reset PDU or a reset ACK
PDU and is coded as '000'. The 'Header Extension Bit (HE)' value indicates whether a
next octet is a length indicator or data. The 'Length Indicator' value indicates a location
of a boundary if a boundary exists between different SDUs within a data part of a PDU.
The 'PAD' part is a padding area and is not used in an AM RLC PDU.
[0042] A method of reducing reception error in an AM RLC entity is explained
as follows. Unlike an UM RLC or TM RLC, error-free data transmission is important
for an AM RLC.
[0043] Specifically, if a receiving side fails to successfully receive an AM RLC
PDU transmitted by a transmitting side, the transmitting side keeps transmitting the AM
RLC PDUs until they are successfully received. The receiving side informs the

WO 2006/104341 11 PCT/KR2006/001139
transmitting side of reception or failure of the AM RLC PDUs. Included in the
information is a status PDU or a piggybacked status PDU.
[0044] FIG. 7 is a flowchart illustrating a conventional AM RLC PDU
transmitting method according to a first example. As illustrated in FIG. 7, a transmitting
side RLC transmits a first AM RLC PDU, a second AM RLC PDU and a third AM
RLC PDU.
[0045] Assuming that the second AM RLC PDU is lost during transmission, a
receiving side RLC is unable to receive the second AM RLC PDU. Therefore, the
receiving side RLC determines that the second AM RLC PDU is lost and informs the
transmitting side, via a status PDU, that the second AM RLC PDU was not received.
[0046] The transmitting side retransmits the second AM RLC PDU in response
to the status PDU received from the receiving side. If the receiving side successfully
receives the retransmitted second AM RLC PDU, the AM RLC PDU transmitting
process is terminated.
[0047] As illustrated in FIG. 7, the receiving side transmits the status PDU if an
AM RLC PDU is not received, if the transmitting side polls the receiving side AM RLC
PDU or if a receiving side transmission interval timer (Timer_Status jperiodic) expires.
The transmission interval timer (Timer_Status_periodic) is provided to enable the
receiving side to send a status PDU periodically and the receiving side transmits the
status PDU each time the transmission interval timer (Timer_Status_periodic) expires.
[0048] However, the status PDU includes no data, but rather only control
information. Unlike an AM RLC PDU, which includes data, the status PDU lowers a

WO 2006/104341 12 PCT/KR2006/001139
real data rate. Therefore, to prevent the status PDU from being sent too frequently, a
timer, such as a transmission prohibit interval (Timer_Status_Prohibit) timer, is utilized.
[0049] The transmission prohibit interval (Timer_Status_Prohibit) timer is
initialized each time the receiving side transmits the status PDU. While the transmission
prohibit interval (TimerJ5tatus_Prohibit) timer is active, the receiving side is prevented
from transmitting a status PDU.
[0050] FIG. 8 is a flowchart illustrating a conventional AM RLC PDU
transmitting method according to a second example. As illustrated in FIG. 8, the
receiving side determines that a second AM RLC PDU was lost and initiates a
transmission interval timer (Timer _Status_periodic) and a transmission prohibit interval
timer (Timer_status_Prohibit) while transmitting a status PDU.
[0051] Upon receiving a fifth AM RLC PDU, the receiving side determines that
a fourth AM RLC PDU was lost. However, since the transmission prohibit interval
timer (Timer__status _Prohibit) has not expired, the receiving side does not transmit the
status PDU despite having determined that a second PDU was lost.
[0052] Also as illustrated in FIG. 8, a re-transmission of the second AM RLC
PDU fails as well. However, the receiving side is unable to determine whether the
second AM RLC PDU was retransmitted from the transmitting side. The retransmitted
second AM RLC PDU may have been lost or the status PDU previously sent by the
receiving side to indicate loss at the second AM RLC PDU may have been lost and not
delivered to the transmitting side. Therefore, the receiving side again sends the status
PDU to the transmitting side to indicate loss of the second AM RLC PDU.

WO 2006/104341 13 PCT/KR2006/001139
[0053] The transmission prohibit interval tinier (Timer_Starus_prohibit)
determines an interval for retransmitting the status PDU. In the previous example, if the
transmission prohibit interval timer (Timer_Status_prohibit) expires, the receiving side
immediately transmits the status PDU to the transmitting side again.
[0054] Since the transmission prohibit interval timer (Timer_Status_prohibit)
expires, there is no limitation on the AM RLC transmitting the status PDU. Upon
receiving the retransmitted status PDU, the transmitting side retransmits the second AM
RLC PDU one again time. Therefore, the receiving side can receive data without error
in operation of the AM RLC.
[0055] FIG. 9 illustrates a conventional AM RLC PDU transmitting method
according to a third example. As illustrated in FIG. 9, it is assumed that there is no
transmission prohibit interval timer (Timer_Status_rohibit) and that a transmission
interval timer (Timer_Status_periodic) is set to a very short value.
[0056] A receiving side again sends a status PDU indicating loss of the second
AM RLC PDU before receiving the retransmitted second AM RLC PDU from a
transmitting side. Therefore, the transmitting side decides that the retransmitted second
AM RLC PDU was also lost in transmission and retransmits the second AM RLC PDU
once more. However, if the receiving side successfully receives the first retransmission
of the second AM RLC PDU, the second retransmission of the second AM RLC PDU
unnecessarily wastes radio resources.
[0057] On the other hand, if the transmission interval timer
(Timer__Status__periodic) is set to too long a value, a delay before the transmitting side

WO 2006/104341 14 PCT/KR2006/001139
attempts the retransmission is increased. Due to the increased delay, QoS (quality of
service) is degraded.
[0058] If a value of the transmission interval timer (Timer_Status_periodic) or
transmission prohibit interval timer (Timer_status_Prohibit) is set closer to a time
required for a transmitting side of a UE to receive a corresponding status response after
having sent an AM RLC PDU to a receiving side, system performance can be enhanced.
Such a time required for the transmitting to receive a corresponding status response
back from the receiving side is called a round-trip time (hereinafter abbreviated 'RTT').
[0059] In conventional methods, a value of a transmission interval timer
(Timer_Status_periodic) or a transmission prohibit interval timer
(Timer_status_Prohibit) is determined when a UE and a serving RNC (hereinafter
abbreviated 'SRNC') first configure a RB and the value is unilaterally selected by the
SRNC. However, since the SRNC has no measurement value for data transmission of an
AM RLC to a UE, the SRNC is unable to select a correct RTT value. Therefore, the
value of the transmission interval timer (Timer_Status_periodic) or transmission
prohibit interval timer (Timer_status_Prohibit) cannot be set to a correct value.
[0060] Furthermore, since a UE keeps moving between cells and since a
processor load of the UE or base station fluctuates, an RTT value varies. Therefore, it is
necessary to keep updating the value of the transmission interval timer
(Timer_Status_periodic) or transmission prohibit interval timer (Tnner_status_Prohibit).
However, these values are determined by the RRC of the SRNC and provided to the
RRC of a UE and the RRC of the UE informs the RLC of the UE of the values to use.

WO 2006/104341 15 PCT/KR2006/0O1139
[0061] Moreover, signaling between the RECs takes a lot of time and the timer
values are basic attributes of an RB. Therefore, whenever these values are changed, a
complicated RB reconfiguration process is required. As a result, an incorrect value of
the transmission interval timer (Timer_Status_periodic) or transmission prohibit interval
timer (Trmer_status_Prohibit) degrades RLC performance and the conventional
signaling using the RRC limits the RLC performance as well.
[0062] Therefore, there is a need for a system for controlling data block
transmission more efficiently by measuring round trip time (RTT) and setting a timer
using the measured RTT. The present invention addresses this and other needs.
DISCLOSURE OF THE INVENTION
[0063] Features and advantages of the invention will be set forth in the
description which follows, and in part will be apparent from the description, or may be
learned by practice of the invention. The objectives and other advantages of the
invention will be realized and attained by the structure particularly pointed out in the
written description and claims hereof as well as the appended drawings.
[0064] Accordingly, the present invention is directed to a method for
controlling transmission of data blocks that substantially obviates one or more problems
due to limitations and disadvantages of conventional methods. An object of the present
invention is to provide a method and apparatus for controlling a transmission of data
blocks by which data block transmission can be controlled more efficiently by
measuring the RTT and setting a control timer value according to the measured RTT.

WO 2006/104341 16 PCT/KR2006/001139
[0065] In one aspect of the present invention, a method of controlling data
block transmission in a wireless communication system is provided. The method
includes transmitting a round trip time measurement request to a receiving device, the
round trip time measurement request including a first identifier, receiving a round trip
time measurement response from the receiving device in response to the round trip time
measurement request, the round trip time measurement response including a second
identifier and detenrrining a round trip time based on a transmission time of the round
trip time measurement request and a reception time of the round trip time measurement
response, wherein the round trip time includes a processing delay for processing the
round trip time measurement request and round trip time measurement response.
[0066] It is contemplated that the method further includes determining either a
data block retransmission prohibit interval and/or a data block retransmission interval
according to the round trip time, the data block retransmission prohibit interval for
preventing the sending of a data block retransmission request to resend a data block and
the data block retransmission interval for initiating the sending of a data block
retransmission request to resend a data block. It is further contemplated that the method
further includes periodically transmitting a data block retransmission request until
receipt of a data block is acknowledged such that the time between successive data
block retransmission requests is as least as great as the round trip time.
[0067] It is contemplated that the data block includes an acknowledgement
mode radio link control protocol data unit. It is further contemplated that the first
identifier is the same as the second identifier. Preferably, the first and second identifiers
are sequence numbers.

WO 2006/104341 17 PCT/KR2006/001139
[0068] It is contemplated that the method further includes determining the
round trip time only when the first identifier is the same as the second identifier. It is
further contemplated that the method further includes determining either a round trip
time transmission prohibit interval and/or a round trip time transmission interval
according to the round trip time, the round trip time transmission prohibit interval for
preventing transmission of a next round trip time measurement request and the round
trip time transmission interval for initiating transmission of a next round trip time
measurement request.
[0069] It is contemplated that the method further includes determining a
waiting interval according to the round trip time, the waiting interval for initiating
retransmission of the round trip time measurement request if the round trip time
measurement response is not received. It is further contemplated that the method
further includes increasing the waiting interval each time the round trip time
measurement request is retransmitted.
[0070] It is contemplated that the method further includes incrementing a value
of the first identifier each time the round trip time measurement request is retransmitted.
It is further contemplated that the method further includes incrementing a
retransmission count each time the round trip time measurement request is retransmitted
and no longer retransmitting the round trip time measurement request if the count
reaches a predetermined value before the round trip time measurement response is
received.
[0071] It is contemplated that the method further includes including the
transmission time of the round trip time measurement request in the round trip time

WO 2006/104341 18 PCT/KR2006/001139
measurement request. It is further contemplated that the round trip time measurement
response further includes the transmission time of the round trip time measurement
response.
[0072] It is contemplated that determining the round trip time includes
calculating a difference between the transmission time in the round trip time
measurement response and the reception time of the round trip time measurement
response. It is further contemplated that the transmission time of the round trip time
measurement request includes either a system frame number and/or a connection frame
number.
[0073] It is contemplated that the method further includes including the round
trip time measurement request in either a status PDU or a piggybacked status PDU and
the round trip time measurement response in cither a status PDU or a piggybacked
status PDU. It is further contemplated that determining the round trip time includes
computing an average of a plurality of round trip times determined based on the
transmission times of a plurality of round trip time measurement requests and the
reception times of a plurality of round trip time measurement responses.
[0074] It is contemplated that transmitting the round trip time measurement
request includes transmitting a plurality of round trip time measurement requests
consecutively, each of the plurality of round trip time measurement requests having the
same first identifier. It is further contemplated that receiving the round trip time
measurement response includes receiving a plurality of round trip time measurement
responses consecutively, each of the plurality of round trip time measurement responses

WO 2006/104341 19 PCT/KR2006/001139
having the same second identifier. Preferably, the wireless communication system
supports a data receipt acknowledgement from the receiving device.
[0075] In another aspect of the present invention, a method of controlling data
block transmission in a wireless communication system is provided. The method
includes transmitting a data block to a receiving device and retransmitting the data
block to the receiving device if receipt of the data block is not acknowledged by the
receiving device, wherein retransmission of the data block is according to a round trip
time that is updated periodically by transmitting a round trip time measurement request
including a first identifier to the receiving device, receiving a round trip time
measurement response including a second identifier from the receiving device and
determining a difference between a transmission time of the round trip time
measurement request and a reception time of the round trip time measurement response
in consideration of a processing delay for processing the round trip time measurement
request and round trip time measurement response.
[0076] It is contemplated that the method further includes the receiving device
transmitting a status word, the status word indicating that the data block was not
received and wherein updating of the round trip time is initiated by the receiving device
if no response is received within a predetermined time interval after transmission of the
status word. It is further contemplated that the method iurtiier includes the receiving
device transmitting a status word, the status word indicating that the data block was not
received and wherein updating of the round trip time is initiated by the receiving device
if no response is received after a number of retransmissions of the status word that
exceeds a predetermined number.

WO 2006/104341 20 PCT/KR2006/001139
[0077] It is contemplated that the method further includes the receiving device
transmitting a status word, the status word indicating that the data block was not
received and wherein updating of the round trip time is initiated by the receiving device
if the data block is received after transmission the status word, the data block received
within a time interval that is shorter than a previously determined round trip time, the
time interval representing a time between a previous transmission of the data block and
a subsequent retransmission of the data block. It is further contemplated that the
method further includes updating either a data block retransmission prohibit interval
and/or a data block retransmission interval according to the round trip time, the data
block retransmission prohibit interval for preventing the sending a data block
retransmission request to resend the data block and the data block retransmission
interval for initiating the sending of a data block retransmission request to resend the
data block.
[0078] It is contemplated that the data block includes an acknowledgement
mode radio link control protocol data unit. It is further contemplated that the first and
sedond identifiers are sequence numbers.
[0079] It is contemplated that the round trip time is updated only when the first
identifier is the same as the second identifier. It is further contemplated that the round
trip time is periodically updated according to either a round trip time transmission
prohibit interval and/or a round trip time transmission interval, the round trip time
transmission prohibit interval and round trip time transmission interval based on a
previously determined round trip time, the round trip time transmission prohibit interval

WO 2006/104341 21 PCT/KR2006/001139
for preventing a next round trip time update and the round trip time transmission
interval for initiating a next round trip time update.
[0080] In another aspect of the present invention, a communication apparatus
for controlling data block transmission in a wireless communication system is provided,
The apparatus includes a transmitting unit adapted to transmit RF signals including a
round trip time measurement request to a receiving device, the round trip time
measurement request including a first identifier, a receiving unit adapted to receive RF
signals including a round trip time measurement response from the receiving device in
response to the round trip time measurement request, the round trip time measurement
response including a second identifier and a processing unit adapted to determine a
round trip time based on a transmission time of the round trip time measurement request
and a reception time of the round trip time measurement response, wherein the round
trip time includes a processing delay for processing the round trip time measurement
request and round trip time measurement response.
[0081] It is contemplated that the processing unit is further adapted to
determine either a data block retransmission prohibit interval and/or a data block
retransmission interval according to the round trip time, the data block retransmission
prohibit interval for preventing the sending of a data block retransmission request to
resend a data block and the data block retransmission interval for initiating the sending
of a data block retransmission request to resend a data block. It is further contemplated
that the processing unit is further adapted to control the transmitting unit to periodically
transmit a data block retransmission request until receipt of a data block is

WO 2006/104341 22 PCT/KR2006/001139
acknowledged such that the time between successive data block retransmission requests
is as least as great as the round trip time.
[0082] It is contemplated that the processing unit is further adapted to set the
first identifier as a sequence number. It is further contemplated that the processing unit
is further adapted to determine the round trip time only when the first identifier is the
same as the second identifier.
[0083] It is contemplated that the processing unit is further adapted to
determine either a round trip time measurement prohibit interval and/or a round trip
time measurement transmission interval according to the round trip time and to control
the transmitting unit such that transmission of a next round trip time measurement
request is prevented according to the round trip time measurement prohibit interval and
transmission of a next round trip time measurement request is initiated according to the
round trip time measurement transmission interval. It is further contemplated that the
processing unit is further adapted to determine a waiting interval according to the round
trip time and to control the transmitting unit such that retransmission of the round trip
time measurement request is initiated according to the waiting interval if the round trip
time measurement response is not received.
[0084] It is contemplated that the processing unit is further adapted to increase
the waiting interval each time the round trip time measurement request is retransmitted.
It is further contemplated that the processing unit is farther adapted to increment a value
of the first identifier each time the round trip time measurement request is retransmitted.
[0085] It is contemplated that the processing unit is further adapted to
increment a retransmission count each time the round trip time measurement request is

WO 2006/104341 23 PCT/KR2006/001139
retransmitted and control the transmitting unit such that the round trip time
measurement request is no longer retransmitted if the count reaches a predetermined
value before the round trip time measurement response is received. It is further
contemplated that the processing unit is further adapted to include the transmission time
of the round trip time measurement request in the round trip time measurement request.
[0086] It is contemplated that the processing unit is further adapted to
determine the round trip time by calculating a difference between a transmission time in
the round trip time measurement response and the reception time of the round trip time
measurement response. It is further contemplated that the processing unit is further
adapted to include the round trip time measurement request in either a status PDU or a
piggybacked status PDU and to extract the round trip time measurement response from
either a status PDU or a piggybacked status PDU.
[0087] It is contemplated that the processing unit is further adapted to
determine the round trip time by computing an average of a plurality of round trip times
determined based on the transmission times of a plurality of round trip time
measurement requests and the reception times of a plurality of round trip time
measurement responses. It is further contemplated that the processing unit is further
adapted to control the transmitting unit to transmit a plurality of round trip time
measurement requests consecutively, each of the plurality of round trip time
measurement requests having the same first identifier.
[0088] It is contemplated that the processing unit is further adapted to process a
plurality of consecutively received round trip time measurement responses, each of the
plurality of round trip time measurement responses having the same second identifier.

WO 2006/104341 24 PCT/KR2006/001139
It is further contemplated that the wireless communication system supports a data
receipt acknowledgement from the receiving device.
[0089] In another aspect of the present invention, a method of controlling data
block transmission in a wireless communication system is provided. The method
includes receiving around trip time measurement request from a transmitting device,
the round trip time measurement request including a first identifier and transmitting a
round trip time measurement response to the receiving device in response to the round
trip time measurement request, the round trip time measurement response including a
second identifier.
[0090] It is contemplated that the data block includes an acknowledgement
mode radio link control protocol data unit. It is further contemplated that the first
identifier is the same as the second identifier. Preferably, the first and second identifiers
are sequence numbers.
[0091] It is contemplated that the round trip time measurement request further
includes the transmission time of the round trip time measurement request. It is further
contemplated that the transmission time of the round trip time measurement request
includes either a system frame number and/or a connection frame number.
[0092] It is contemplated that the method further includes including the
transmission time of the round trip time measurement response in the round trip time
measurement response. It is further contemplated that the round trip time measurement
request is included in either a status PDU or a piggybacked status PDU and the round
trip time measurement response is included in either a status PDU or a piggybacked
status PDU.

WO 2006/104341 25 PCT/KR2006/001139
[0093] It is contemplated that receiving the round trip time measurement
request includes receiving a plurality of round trip time measurement requests
consecutively, each of the plurality of round trip time measurement requests having the
same first identifier. It is further contemplated that transmitting the round trip time
measurement response includes transmitting a plurality of round trip time measurement
responses consecutively, each of the plurality of round trip time measurement responses
having the same second identifier. Preferably, the wireless communication system
supports a data receipt acknowledgement from the receiving device.
[0094] In another aspect of the present invention, a communication apparatus
for controlling data block transmission in a wireless communication system is provided.
The apparatus includes a receiving unit adapted to receive RF signals including a round
trip time measurement request from a transmitting device, the round trip time
measurement request including a first identifier and a transmitting unit adapted to
transmit RF signals including a round trip time measurement response to the
transmitting device in response to the round trip time measurement request, the round
trip time measurement response including a second identifier.
[0095] It is contemplated that the processing unit is further adapted to control
the transmitting unit to periodically transmit a data block retransmission request until
receipt of a data block is acknowledged such that the time between successive data
block retransmission requests is as least as great as a determined round trip time. It is
further contemplated that the processing unit is further adapted to set the second
identifier as a sequence number.

WO 2006/104341 26 PCT/KR2006/001139
[0096] It is contemplated that the processing unit is further adapted to include
the transmission time of the round trip, time measurement response in the round trip time
measurement response. It is further contemplated that the processing unit is further
adapted to extract the round trip time measurement request from either a status PDU or
a piggybacked status PDU and to include the round trip time measurement response in
either a status PDU or a piggybacked status PDU,
[0097] It is contemplated that the processing unit is further adapted to control
the transmitting unit to transmit a plurality of round trip time measurement responses
consecutively, each of the plurality of round trip time measurement responses having
the same second identifier. It is further contemplated that the processing unit is further
adapted to process a plurality of consecutively received round trip time measurement
requests, each of the plurality of round trip time measurement requests having the same
first identifier. Preferably, the wireless communication system supports a data receipt
acknowledgement frorn the receiving device.
[0098] Additional features and advantages of the invention will be set forth in
the description which follows, and in part will be apparent from the description, or may
be learned by practice of the invention. It is to be understood that both the foregoing
general description and the following detailed description of the present invention are
exemplary and explanatory and are intended to provide further explanation of the
invention as claimed.
[0099] These and other embodiments will also become readily apparent to those
skilled in the art from the following detailed description of the embodiments having

WO 2006/104341 27 PCT/KR2006/001139
reference to the attached figures, the invention not being limited to any particular
embodiments disclosed.
BRIEF DESCRIPTION OF THE DRAWINGS
[00100] The accompanying drawings, which are included to provide a further
understanding of the invention and are incorporated in and constitute a part of this
specification, illustrate embodiments of the invention and together with the description
serve to explain the principles of the invention. Features, elements, and aspects of the
invention that are referenced by the same numerals in different figures represent the
same, equivalent, or similar features, elements, or aspects in accordance with one or
more embodiments.
[00101] FIG. 1 is a block diagram of a network structure of UMTS (universal
mobile telecommunications system);
[00102] FIG 2 is a diagram of architecture of UMTS radio protocol;
[00103] FIG 3 is a structural diagram of AM RLC PDU;
[00104] FIG 4 is a structural diagram of status PDU;
[00105] FIG 5 is a structural diagram of a piggybacked status PDU;
[00106] FIG 6 is a structural diagram of Reset ACK PDU;
[00107] FIG 7 is a flowchart of a first example of a conventional AM RLC PDU
transmitting method.
[00108] FIG 8 is a second example of a conventional AM RLC PDU

WO 2006/104341 28 PCT/KR2006/001139
[00109] FIG 9 is a third exampl e of a conventional AM RLC PDU transmitting
method.
[00110] FIG 10 is a flowchart of an RTT measuring and setting method
according to one embodiment of the present invention.
[00111] FIG. 11 is a diagram of an RTT measurement response (SUFI) according
to one embodiment of the present invention.
BEST MOPE FOR CARRYING OUT THE INVENTION
[00112] The present invention relates to an apparatus and method for controlling
a transmission of data blocks by which data block transmission can be controlled more
efficiently by measuring the RTT and setting a control timer value according to the
measured RTT. Although the present invention is illustrated with respect to a mobile
communication device, it is contemplated that the present invention may be utilized
anytime it is desired to more efficiently control a transmission of data blocks by
measuring a round trip time and setting a control timer value according to the measured
time.
[00113] Reference will now be made in detail to the preferred embodiments of
the present invention, examples of which are illustrated in the accompanying drawings.
Wherever possible, the same reference numbers will be used throughout the drawings to
refer to the same or like parts.
[00114] The present invention enables an AM RLC entity to operate with an
optimal transmission interval timer (timer_Status__periodic) value and an optimal

WO 2006/104341 29 PCT/KR2006/001139
transmission prohibit interval timer (Timer_status_Prohibit) value, thereby providing a
service more efficiently by increasing the data rate. The present invention provides a
method to enable an RLC entity to measure a round-trip time (RTT) value and set a
transmission interval timer (timer_Status_periodic) value and a transmission prohibit
interval timer (Timer_status_Prohibit) value using the measured RTT value,
[00115] An AM RNC uses a status PDU or piggybacked status PDU to measure
an RTT value. Specifically, an AM RLC attempting to measure the RTT sends a
message requesting RTT measurement to an AM RLC of the other side. An AM RLC
entity, having received the message, transmits a corresponding response.
[00116] The requesting AM RLC uses the status PDU or the piggybacked status
PDU to send the RTT measurement request message. Specifically, the AM RLC
includes the RTT measurement request (SUFI) in a transmitted status PDU or
piggybacked status PDU.
[00117] The AM RLC of the other side uses the status PDU or the piggybacked
status PDU to transmit an RTT measurement response message in response to the RTT
measurement request message. Specifically, the AM RLC includes the RTT
measurement response SUFI in a transmitted status PDU or a piggybacked status PDU.
[00118] Since the RTT measurement request or response message is transmitted
through a radio section, it may be lost in the radio section. Therefore, for more accurate
RTT measurement, a sequence number is attached to the AM RLC PDU that includes
the RTT measurement request so that a measuring side can identify the RTT
measurement response message.

WO 2006/104341 30 PCT/KR2006/001139
[00119] The requesting AM RLC attaches a sequence number to each RTT
measurement request message. Upon receiving the RTT measurement response message,
the requesting AM RLC processes the RTT measurement response message if a value
equal to the sequence number that was sent by the AM RLC is received. If an RTT
measurement response message including a value different from the sequence number
that was sent by the AM RLC is received, the requesting AM RLC deletes the message
or does not process the message.
[00120] The requesting AM RLC records a time at which each RTT
measurement request message is transmitted. Each time an RTT measurement request
message is received, the measuring AM RLC checks the sequence number included in
the RTT measurement request message. Upon sending an RTT measurement response
message, the measuring AM RLC includes a value equal to the sequence number from
the RTT request message in the RTT measurement response message.
[00121] To measure a real RTT value, the requesting AM RLC waits for an RTT
measurement response message after sending an RTT measurement request message.
Upon receiving the RTT measurement response message, the requesting AM RLC
checks a sequence number included in the received RTT measurement response
message.
[00122] If the sequence number is equal to the sequence number previously sent
by the AM RNC in the RTT measurement request message, the AM RNC determines a
difference between the time the RTT measurement response message was received and
the time the RTT measurement request message was sent The AM RNC then uses the
determined difference as a measured RTT value.

WO 2006/104341 31 PCT/KR2006/001139
[00123] The requesting AM RLC executes the RTT measurement process several
times to increase reliability of the measurement and to remove variable factors in
measurement The AM RLC determines an average of the measured RTT values for use
as an estimated value of real RTT. By determining an average value, a UE can use a
number of samples as indicated by a base station.
[00124] Subsequently, the requesting AM RNC can set the estimated RTT as a
transmission prohibit interval timer (Timer _status_Prohibit) value or a transmission
interval timer (Timer_Starus_periodic) value. Alternately, the requesting AM RNC may
set the transmission prohibit interval timer (Timer_status_Prohibit) value or
transmission interval timer (Timer_Status_periodic) value by processing the estimated
RTT according to parameters indicated by a base station.
[00125] FIG. 10 illustrates a flowchart of an RTT measuring and setting method
according to one embodiment of the present invention. As illustrated in FIG. 10, once a
transmitting side initiates an RTT measurement (S101), an RTT measurement request
message is created and a sequence number is included in the message and recorded in a
transmitting side memory (S102). The created RTT measurement request message is
transmitted to a receiving side and a time at which the RTT measurement request
message is transmitted is recorded in the transmitting side memory (S1 03).
[00126] A receiving side, upon receiving the RTT measurement request message
transmitted by the transmitting side (S104), transmits an RTT measurement response
message to the transmitting side (S106). After transmitting the RTT measurement
request message, the transmitting side waits for an RTT measurement response message
(S107). Upon receiving the RTT measurement response message, the transmitting side

WO 2006/104341 32 PCT/KR2006/001139
records a reception time of the RTT measurement response message in the transmitting
side memory (S108).
[00127] The transmitting side checks a sequence number included in the received
RTT measurement response message (S109). If the sequence number in the RTT
measurement response message is equal to the sequence number in the transmitted RTT
measurement request message, the RTT is calculated using the recorded transmission
time and the recorded reception time (S110).
[00128] However, for accurate RTT measurement, the receiving side AM RLC
must send an RTT measurement response immediately upon receiving an RTT
measurement request. In order to accomplish this, an RTT measurement response
message can be immediately transmitted without previously set limitations, such as a
transmission prohibit interval timer (Timer_status_Prohibit). Furthermore, for more
effective measurement, the transmitting side AM RLC can be free from previously set
limitations with regard to sending an RTT measurement request.
[00129] FIG. 11 illustrates an RTT measurement response SUFI according to one
embodiment of the present invention. As illustrated in FIG 10 and FIG 11, 'TYPE' is an
identifier to identify various types of SUFIs and ' Sequence Number' indicates an RTT
measurement response SUFI corresponding to an RTT measurement request SUFI
[00130] Unlike a status PDU, a pi ggybacked status PDU, which replaces
padding of an AM RLC PDU, has no additional overhead. Therefore, to reduce
overhead due to the RTT measurement request message, the RTT measurement request
message can be included only in a piggybacked status PDU.

WO 2006/104341 33 PCT/KR2006/001139
[00131] However, if RTT measurements are performed too frequently, system
performance may be affected. To reduce the effect upon system performance, a network
can restrict RTT measurements performed by an AM entity. In order to restrict RTT
measurements, an RTT measurement prohibit interval timer can be used. Specifically,
after an RTT measurement request has been sent or after an RTT measurement process
has been completed, the AM entity initiates the RTT measurement prohibit interval
timer. A UE is unable to initiate a new RTT measurement process until the RTT
measurement prohibit interval timer expires.
[00132] To increase accuracy of the RTT measurement process, an AM entity
can send an RTT measurement request message and an RTT measurement response
message consecutively. In this way, the probability of losing each message in a radio
section is lowered and sequence numbers of the consecutively sent messages are equal
to each other. The number of the consecutively sent messages can be determined by the
network and indicated to a UE.
[00133] If an AM entity periodically performs the RTT measurement, it can be
prevent a difference between an actual RTT value and an RTT value determined by a
UE from deviating considerably. For periodically performing the RTT measurement, an
RTT measurement period timer (periodic timer) is defined. A network can inform a UE
of a value of the RTT measurement prohibit interval timer and a value of the RTT
measurement period timer (periodic timer).
[00134] An AM entity initiates the RTT measurement period timer (periodic
timer). Whenever the RTT measurement period timer (periodic timer) expires, the AM
entity initiates the RTT measurement process. Each time the RTT measurement process

WO 2006/104341 27 PCT/KR2006/001139
is completed, the AM entity activates the RTT measurement period timer (periodic
timer) again.
[00135] Since the RTT measurement request message or the RTT measurement
response message can be lost in the radio section, the RTT measurement response
message may not arrive at the side having made the request for the RTT measurement.
An RTT measurement waiting timer can be defined to prevent a side having sent an
RTT measurement request message from awaiting the RTT measurement response
message indefinitely.
[00136] After transmitting an RTT measurement response message, the AM
entity activates the RTT measurement waiting timer. If the RTT measurement response
message is not received before the RTT measurement waiting timer expires, the AM
entity sends the RTT measurement request message again. This retransmission process
cannot be repeated indefinitely. To restrict the retransmission process, a count limit of
RTT measurement request retransmissions can be set.
[00137] In order to remove ambiguity of each retransmission, a sequence number
can be changed each time the RTT measurement request is retransmitted. The sequence
number can simply be incremented by' 1' each time the RTT measurement request is
retransmitted. To increase efficiency, each time the RTT measurement request is
retransmitted, a value of the RTT measurement waiting timer is increased to
accommodate a change of a lower layer.
[00138] If an AM PDU is not received by an AM entity, the AM entity transmits
a status PDU. If a correspondiag response is not received within a uniform duration or if
a transmission count of the status PDU indicating that a specific AM PDU is not

WO 2006/104341 35 PCT/KR2006/001139
received exceeds a predetermined value, the AM entity executes the RTT measurement
process. Furthermore, if an AM PDU that is indicated as not having been received in
the status PDU arrives within a time that is shorter than a previously measured RTT
value or a time that is shorter than the transmission prohibit interval timer
(Tirner_status_Probibit) value, the AM entity executes the RTT measurement process.
Furthermore,
[00139] Whenever the RTT value is updated, the AM entity updates an
associated timer value. The AM entity can appropriately set values associated with
polling, such as a polling timer (Timer poll) or a polling prohibit interval timer
(Timer_Poll_prohibit).
[00140] The AM entity can also include the time of message transmission when
transmitting an RTT measurement request message. In this way, the time included in the
RTT measurement request message is a time that can be determined by the AM entities
of both sides. Furthermore, the time included can be a system frame number (hereinafter
abbreviated 'SFN') as a time reference applied to all UEs located within one cell or a
connection frame number (hereinafter abbreviated 'CFN') managed in common by one
UE and one SRNC.
[00141 ] Therefore, one side, having received the RTT measurement request
message, can obtain the transmission time in one direction using the difference between
the time included in the message and the time at which the message was received.
Similarly, if the time of transmission of the RTT measurement response message is
included in the response message, the side receiving the RTT measurement response
message can calculate a portion of RTT using the difference between the time the

WO 2006/104341 36 PCT/KR2006/001139
message was received and the time included in the message. The RTT can then be found
by multiplying the measured time by' 2'.
[00142] Accordingly, the present invention sets a control timer by measuring an
RTT value, thereby transmitting data blocks more efficiently,
[00143] It will be apparent to those skilled in the art that various modifications
and variations can be made in the present invention without departing from the spirit or
scope of the inventions. Thus, it is intended that the present invention covers the
modifications and variations of this invention provided they come within the scope of
the appended claims and their equivalents.
100144] As the present invention may be embodied in several forms without
departing from the spirit or essential characteristics thereof, it should also be understood
that the above-described embodiments are not limited by any of the details of the
foregoing description, unless otherwise specified, but rather should be construed
broadly within its spirit and scope as defined in the appended claims, and therefore all
changes and modifications that fall within the metes and bounds of the claims, or
equivalence of such metes and bounds are therefore intended to be embraced by the
appended claims.
[00145] The foregoing embodiments and advantages are merely exemplary and
are not to be construed as limiting the present invention. The present teaching can be
readily applied to other types of apparatuses. The description of the present invention is
intended to be illustrative, and not to limit the scope of the claims. Many alternatives,
modifications, and variations will be apparent to those skilled in the art. In the claims,
means-plus-function clauses are intended to cover the structure described herein as

WO 2006/104341 37 PCT/KR2006/001139
performing the recited function and not only structural equivalents but also equivalent
structures.
INDERSTRIAL APPLICABILITY
[00146] The present invention can be applied to a mobile communication system.

WO 2006/104341 38 PCT/KR2006/001139
What is claimed is:
1. A method of controlling data block transmission in a wireless
communication system, the method comprising: transmitting a round trip time
measurement request to a receiving device, the round trip time measurement request
comprising a first identifier;
receiving a round trip time measurement response from the receiving device in
response to trie round trip time measurement request, the round trip time measurement
response comprising a second identifier; and
determining a round trip time based on a transmission time of the round trip time
measurement request and a reception time of the round trip time measurement response,
wherein the round trip time comprises a processing delay for processing the round trip time
measurement request and round trip time measurement response.
2. The method of claim 1, further comprising determining at least one of a data
block retransmission prohibit interval and a data block retransmission interval according to
the round trip time, the data block retransmission prohibit interval for preventing the
sending of a data block retransmission request to resend a data block and the data block
retransmission interval for initiating the sending of a data block retransmission request to
resend a data block.

WO 2006/104341 PCT/KR2006/001139
39
3. The method of claim 1, further comprising periodically transmitting a data
block retransmission request until receipt of a data block is acknowledged such that the
time between successive data block retransmission requests is as least as great as the round
trip time.
4. The method of claim 1, wherein the data block comprises an
acknowledgement mode radio link control protocol data unit.
5. The method of claim 1, wherein the first identifier is the same as the second
identifier.
6. The method of claim 1, wherein the first and second identifiers are sequence
numbers.
7. The method of claim 1, further comprising determining the round trip time
only when the first identifier is the same as the second identifier.
8. The method of claim 1, further comprising determining at least one of a
round trip time transmission prohibit interval and a round trip time transmission interval
according to the round trip time, the round trip time transmission prohibit interval for
preventing transmission of a next round trip time measurement request and the round trip
time transmission interval for initiating transmission of a next round trip time measurement
request.

WO 2006/104341 PCT/KR2006/001139
40
9. The method of claim 1, wherein the transmission time of the round trip time
measurement request comprises at least one of a system frame number and a connection
frame number.
10. The method of claim 1, further comprising including the round trip time
measurement request in one of a status PDU and a piggybacked status PDU and wherein
the round trip time measurement response is included in one of a status PDU and a
piggybacked status PDU.
11. The method of claim 1, wherein the wireless communication system
supports a data receipt acknowledgement from the receiving device.
12. A method of controlling data block transmission in a wireless
communication system, the method comprising:
transmitting a data block to a receiving device; and
retransmitting the data block to the receiving device if receipt of the data block is
not acknowledged by the receiving device,
wherein retransmission of the data block is according to a round trip time that is
updated periodically by transmitting a round trip time measurement request comprising a
first identifier to the receiving device, receiving a round trip time measurement response
comprising a second identifier from the receiving device and determining a difference
between a transmission time of the round trip time measurement request and a reception

WO 2006/104341 PCT/KR2006/001139
41
time of the round trip time measurement response in consideration of a processing delay for
processing the round trip time measurement request and round trip time measurement
response.
13. The method of claim 12, further comprising the receiving device
transmitting a status word, the status word indicating that the data block was not received
and wherein updating of the round trip time is initiated by the receiving device if no
response is received within a predetermined time interval after transmission of the status
word.
14. The method of claim 12, further comprising the receiving device
transmitting a status word, the status word indicating that the data block was not received
and wherein updating of the round trip time is initiated by the receiving device if no
response is received after a number of retransmissions of the status word that exceeds a
predetermined number.
15. The method of claim 12, further comprising the receiving device
transmitting a status word, the status word indicating that the data block was not received
and wherein updating of the round trip time is initiated by the receiving device if the data
block is received after transmission the status word, the data block received within a time
interval that is shorter than a previously determined round trip time, the time interval

WO 2006/104341 PCT/KR2006/001139
42
representing a time between a previous transmission of the data block and a subsequent
retransmission of the data block.
16. The method of claim 12, further comprising updating at least one of a data
block retransmission prohibit interval and a data block retransmission interval according to
the round trip time, the data block retransmission prohibit interval for preventing the
sending a data block retransmission request to resend the data block and the data block
retransmission interval for initiating the sending of a data block retransmission request to
resend the data block.
17. The method of claim 12, wherein the data block comprises an
acknowledgement mode radio link control protocol data unit.
18. The method of claim 12, wherein the first and second identifiers are
sequence numbers.
19. The method of claim 12, wherein the round trip time is updated only when
die first identifier is the same as the second identifier.
20. The method of claim 12, wherein the round trip time is periodically updated
according to at least one of a round trip time transmission prohibit interval and a round trip
time transmission interval, the round trip time transmission prohibit interval and round trip

WO 2006/104341 PCT/KR2006/001139
43
time transmission interval based on a previously determined round trip time, the round trip
time transmission prohibit interval for preventing a next round trip time update and the
round trip time transmission interval for initiating a next round trip time update.
21. A communication apparatus for controlling data block transmission in a
wireless communication system, the apparatus comprising:
a transmitting unit adapted to transmit RF signals comprising a round trip time
measurement request to a receiving device, the round trip time measurement request
comprising a first identifier;
a receiving unit adapted to receive RF signals comprising a round trip time
measurement response from the receiving device in response to the round trip time
measurement request, the round trip time measurement response comprising a second
identifier; and
a processing unit adapted to determine a round trip time based on a transmission
time of the round trip time measurement request and a reception time of the round trip time
measurement response, wherein the round trip time comprises a processing delay for
processing the round trip time measurement request and round trip time measurement
response.
22. The apparatus of claim 21, wherein the processing unit is further adapted to
determine at least one of a data block retransmission prohibit interval and a data block
retransmission interval according to the round trip time, the data block retransmission

WO 2006/104341 PCT/KR2006/001139
44
prohibit interval for preventing the sending of a data block retransmission request to resend
a data block and the data block retransmission interval for initiating the sending of a data
block retransmission request to resend a data block.
23. The apparatus of claim 21, wherein the processing unit is further adapted to
control the transmitting unit to periodically transmit a data block retransmission request
until receipt of a data block is acknowledged such that the time between successive data
block retransmission requests is as least as great as the round trip time.
24. The apparatus of claim 21, wherein the processing unit is further adapted to
set the first identifier as a sequence number.
25. The apparatus of claim 21, wherein the processing unit is further adapted to
determine the round trip time only when the first identifier is the same as the second
identifier.
26. The apparatus of claim 21, wherein the processing unit is further adapted to
determine at least one of a round trip time measurement prohibit interval and a round trip
time measurement transmission interval according to the round trip time and to control the
transmitting unit such that transmission of a next round trip time measurement request is
prevented according to the round trip time measurement prohibit interval and transmission

WO 2006/104341 PCT/KR2006/001139
45
of a next round trip time measurement request is initiated according to the round trip time
measurement transmission interval.
27. The apparatus of claim 21, wherein the processing unit is further adapted to
include the transmission time of the round trip time measurement request in the round trip
time measurement request.
28. The apparatus of claim 21, wherein the processing 'unit is further adapted to
determine the round trip time hy calculating a difference between a transmission time in the
round trip time measurement response and the reception time of the round trip time
measurement response.
29. The apparatus of claim 21, wherein the processing unit is further adapted to
include the round trip time measurement request in one of a status PDU and a piggybacked
status PDU and to extract the round trip time measurement response from one of a status
PDU and a piggybacked status PDU.
30. The apparatus of claim 21, wherein the processing unit is further adapted to
determine the round trip time by computing an average of a plurality of round trip times
determined based on the transmission times of a plurality of round trip time measurement
requests and the reception times of a plurality of round trip time measurement responses.

WO 2006/104341 PCT/KR2006/001139
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31. The apparatus of claim 21, wherein the processing unit is further adapted to
control the transmitting unit to transmit a plurality of round trip time measurement requests
consecutively, each of the plurality of round trip time measurement requests having the
same first identifier.
32. The apparatus of claim 21, wherein the processing unit is further adapted to
process a plurality of consecutively received round trip time measurement responses, each
of the plurality of round trip time measurement responses having the same second identifier.
33. The apparatus of claim 21, wherein the wireless communication system
supports a data receipt acknowledgement from the receiving device.
34. A method of controlling data "block transmission in a wireless
communication system, the method comprising:
receiving a round trip time measurement request from a transmitting device, the
round trip time measurement request comprising a first identifier; and
transmitting a round trip time measurement response to the receiving device in
response to the round trip time measurement request, the round trip time measurement
response comprising a second identifier.
35. The method of claim 34, wherein the data block comprises an
acknowledgement mode radio link control protocol data unit.

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36. The method of claim 34, wherein the first identifier is the same as the
second identifier.
37. The method of claim 34, wherein the first and second identifiers are
sequence numbers.
38. The method of claim 34, wherein the round trip time measurement request
further comprises the transmission time of the round trip time measurement request.
39. The method of claim 38, wherein the transmission time of the round trip
time measurement request comprises at least one of a system frame number and a
connection frame number.
40. The method of claim 34, further comprising including the transmission time
of the round trip time measurement response in the round trip time measurement response.
41. The method of claim 34, wherein the round trip time measurement request is
included in one of a status PDU and a piggybacked status PDU and further comprising
including the round trip time measurement response in one of a status PDU and a
piggybacked status PDU.

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42. The method of claim 34, wherein receiving the round trip time measurement
request comprises receiving a plurality of round trip rime measurement requests
consecutively, each of the plurality of round trip time measurement requests having the
same first identifier.
43. The method of claim 34, wherein transmitting the round tip time
measurement response comprises transmitting a plurality of round trip time measurement
responses consecutively, each of the plurality of round trip time measurement responses
having the same second identifier.
44. The method of claim 34, wherein the wireless communication system
supports a data receipt acknowledgement from the receiving device.
45. A communication apparatus for controlling data block transmission in a
wireless communication system, the apparatus comprising:
a receiving unit adapted to receive RF signals comprising a round trip time
measurement request from a transmitting device, the round trip time measurement request
comprising a first identifier; and
a transmitting unit adapted to transmit RF signals comprising a round trip time
measurement response to the transmitting device in response to the round trip time
measurement request, the round trip time measurement response comprising a second
identifier.

WO 2006/104341 PCT/KR2006/001139
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46. The apparatus of claim 45, wherein the processing unit is further adapted to
control the transmitting unit to periodically transmit a data block retransmission request
until receipt of a data block is acknowledged such that the time between successive data
"block retransmission requests is as least as great as a determined round trip time.
47. The apparatus of claim 45, wherein the processing unit is further adapted to
set the second identifier as a sequence number.
48. The apparatus of claim 45, wherein the processing unit is further adapted to
include the transmission time of the round trip time measurement response in the round trip
time measurement response.
49. The apparatus of claim 45, wherein the processing unit is further adapted to
extract the round trip time measurement request from one of a status PDU and a
piggybacked status PDU and to include the round trip time measurement response in one of
a status PDU and a piggybacked status PDU.
50. The apparatus of claim 45, wherein the processing unit is further adapted to
control the transmitting unit to transmit a plurality of round trip tune measurement
responses consecutively, each of the plurality of round trip time measurement responses
having the same second identifier.

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50
51. The apparatus of claim 45, wherein the processing unit is further adapted to
process a plurality of consecutively received round trip time measurement requests, each of
the plurality of round trip time measurement requests having the same first identifier,
52. The apparatus of claim 45, wherein the wireless communication system
supports a data receipt acknowledgement from the receiving device.

A method and apparatus for
controlling a transmission of data blocks is
provided by which data block transmission can
be controlled more efficiently by measuring
the RTT and setting a control timer value
according to the measured RTT

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=O/PKA9NkSlzGz9F8VU+zUA==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

271493

Indian Patent Application Number

3587/KOLNP/2007

PG Journal Number

09/2016

Publication Date

26-Feb-2016

Grant Date

23-Feb-2016

Date of Filing

24-Sep-2007

Name of Patentee

LG ELECTRONICS INC

Applicant Address

20, YOIDO-DONG YOUNGDUNGPO-GU SEOUL

Inventors:

#	Inventor's Name	Inventor's Address
1	LEE YOUNG DAE	370-43, DEOKPUNG 2-DONG, HANAM-SI, GYEONGGI-DO 465-012
2	CHUN SUNG DUCK	601-1007, SAETBYEOL HANYANG APT., DARAN-DONG, DONGAN-GU, ANYANG-SI, GYEONGGI-DO 431-719
3	JUNG MYUNG CHEUL	2/2, 358-36, SANGDO 2-DONG, DONGJAK-GU, SEOUL 156-032

PCT International Classification Number

H04L 12/26,H04L 1/08

PCT International Application Number

PCT/KR2006/001139

PCT International Filing date

2006-03-29

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10-2005-0026230	2005-03-29	Republic of Korea