JP5564585B2 - Discontinuous reception method and apparatus for connected terminal in mobile communication system - Google Patents

Description

  The present invention relates to a discontinuous reception (DRX) operation in a mobile communication system, and more particularly, to a method and apparatus for a discontinuous reception operation of a connected terminal with a variable activation period.

  In general, a wireless communication system is a system developed for a case where a communication device cannot be used by connecting a fixed wired network. As a typical system of such a wireless communication system, mobile communication is used. System, wireless LAN (WLAN), Wibro, Mobile Ad Hoc, etc. are mentioned.

  In particular, unlike other wireless communication systems, the mobile communication system is a system that assumes user mobility, and the target is that of mobile phones and wireless pagers regardless of location and time. A communication service is provided to such a mobile terminal.

  Such a mobile communication system operates roughly according to a synchronous method and an asynchronous method. In particular, the UMTS (Universal Mobile Telecommunication Service) system is based on the European mobile communication system GSM (registered trademark) (Global System for Mobile Communications) and GPRS (General Packet Radio Services). It is a third generation asynchronous mobile communication system using multiple access (Code Division Multiple Access; hereinafter referred to as 'CDMA'). Currently, the 3rd Generation Partnership Project (3GPP), which is in charge of UMTS standardization, is debating on LTE (Long Term Evolution) as the next generation mobile communication system of the UMTS system.

  The LTE system is a technology that realizes high-speed packet-based communication of about 100 Mbps with 2010 as the goal of commercialization. For this reason, various methods have been discussed. For example, there are a method for reducing the number of nodes located on the communication path by simplifying the network structure and a method for bringing the wireless protocol as close as possible to the wireless channel. . As a result, the structure of the LTE system is seen to be changed from the existing 4-node structure to a 2-node or 3-node structure.

  FIG. 1 is a diagram showing a structure of an LTE system to which the present invention is applied.

  Referring to FIG. 1, the LTE system can be simplified to two node structures of ENB (Evolved Node B) 100a, 100b, 100c, 100d, 100e and EGGSN (Evolved Gateway GPRS Serving Node) 102a, 102b.

  ENBs 100a, 100b, 100c, 100d, and 100e are nodes corresponding to the existing Node B, and are connected to UE (User Equipment) 104 by a radio channel. Unlike the existing Node B, the ENB performs a more complex role.

  In the LTE system, all user traffic including a real-time service such as VoIP is serviced through a shared channel, and thus scheduling information of a specific UE 104 and multiple UEs is combined. It means that a device to do is necessary. The ENBs 100a, 100b, 100c, 100d, and 100e are in charge of the scheduling.

  In order to realize a transfer rate of up to 100 Mbps, the LTE system is expected to be used for OFDM (Orthogonal Frequency Division Multiplexing) wireless connection technology with a 20 MHz bandwidth. An adaptive modulation and coding (hereinafter referred to as “AMC”) scheme that determines a modulation scheme and a channel coding rate in accordance with the channel state of each UE 104 is applied. Is done.

  In addition, a mobile communication system using a high speed downlink packet access (hereinafter referred to as “HSDPA”) system, an enhanced uplink dedicated channel (hereinafter referred to as “E-DCH”). The LTE system uses hybrid automatic retransmission (Hybrid ARQ; hereinafter referred to as 'HARQ') between the ENB 100a, 100b, 100c, 100d, 100e and the UE 104. To do. Here, HARQ is a technique for improving the reception success rate by soft combining the data that is initially transferred together with the retransmitted data without discarding the previously received data. As described above, the UE 104 attempts to guarantee reception performance for packets through AMC and HARQ techniques.

  In the conventional mobile communication system, an idle terminal wakes up at a predetermined time (Wake up), monitors a predetermined channel for a predetermined period, and then repeats the operation of entering a sleep mode. This is called discontinuous reception (hereinafter referred to as 'DRX'), which is mainly used as a method for increasing the waiting time of an idle terminal.

  In relation to this, FIG. 2 is a diagram illustrating DRX operation in a conventional mobile communication system.

  Referring to FIG. 2, the terminal and the base station agree on a DRX configuration and repeat the sleep period and the activation period accordingly. The sleep period means a period in which the terminal turns off the receiver to minimize power consumption, and the activation period means a period in which the terminal attaches the receiver and performs a normal reception operation. The activation period is also called a wake-up period, and throughout this specification, “activation period” is used as a synonym for “wake-up period”.

  First, a DRX configuration generally includes the following elements.

  1. DRX cycle length 210, 220: An interval between any activation period and the next activation period. The longer the DRX cycle length, the longer the sleep period. Power consumption is also reduced. However, if the DRX cycle length is long, there is a disadvantage that the call delay for the terminal increases. The DRX cycle length is signaled by the network.

  2. Activation period start time 205, 215, 225: Generally derived from the terminal's unique identifier and DRX cycle length. For example, a value obtained by calculating a modulo operation between the terminal identifier (ID) and the DRX cycle length may be used at the start of the activation period.

  3. Length of activation period (235): This means the length of the period during which the terminal wakes up during one activation period, and generally a predetermined value is used. For example, the length of the activation period in the UMTS communication system is 10 msec.

  The terminal calculates an activation period start time 230 using its identifier (ID) and DRX cycle lengths 210 and 220, and then, during the activation period counted from the start of the activation period, Receive the forward channel. If there is no desired information in the received forward channel, the terminal turns off the receiver and enters a sleep period.

  Therefore, as described in FIG. 2, the classic DRX operation of awakening at a certain period according to the conventional mobile communication system and monitoring a predetermined forward channel for a certain period of time is a newly proposed LTE system. Not suitable for connected terminals.

  Here, the connected state terminal means a terminal in which a specific service is driven and user data related to the service exists between the network and the terminal. At this time, the network is in a state where radio link control (RRC) is actually possible in a state where a service context for the terminal is provided. This is called a connected state terminal.

  As described above, in connection with the DRX operation of the idle terminal defined in the conventional mobile communication system, the DRX operation for the connected terminal in the newly proposed LTE system needs to be specifically defined.

JP 2005-130436 A

  An object of the present invention devised to solve the problems of the prior art that operates as described above is to provide a discontinuous reception operation method and apparatus for connected terminals in a mobile communication system.

  Another object of the present invention is to provide a method and apparatus in which a terminal variably sets a DRX cycle in consideration of the amount of packet data in a next generation mobile communication system.

  Still another object of the present invention is to provide an apparatus and method for adjusting the length of a terminal activation period according to the type of service in a mobile communication system.

  In the method in which the connected mobile terminals in the mobile communication system according to the present invention perform discontinuous reception, the mobile station is capable of guiding the starting point of the activation period and the minimum active period length. ), And receive the discontinuous reception cycle length (DRX cycle length) from the base station, and use the retrieved information to derive the activation period start time and the induced activation At the start of the period, the first timer set to the discontinuous reception cycle length (DRX cycle length) and the second timer set to the minimum active period length are activated. During the minimum activation period, the terminal monitors the presence of forward packets. If the forward packet does not exist during the minimum activation period, the terminal shifts to a sleep mode. If the forward packet exists, the terminal receives the packet, determines whether there is information indicating the end of packet reception, and if there is the instruction information, ends the packet reception, and then sleep mode. Migrate to When the first timer expires, the terminal shifts from the sleep mode to an activated state.

  In a method for a discontinuous reception by a connected mobile terminal in a mobile communication system according to the present invention, the terminal receives a discontinuous reception cycle length (DRX cycle length) from a base station, and starts an activation period ( Search for information that can guide the starting point, information for the minimum activation period (minimum active period length), and information for the activation period end interval, and use the retrieved information to derive the start point of the activation period The first timer set to the discontinuous reception cycle length (DRX cycle length) at the start of the activation period and the second timer set to the minimum active period length Activate. The terminal monitors the presence of a forward packet during the minimum activation period. If the forward packet does not exist during the minimum activation period, the terminal shifts to a sleep mode. If the forward packet exists, the terminal receives the forward packet according to a predetermined HARQ scheme and activates the third timer set in the activation period end interval. When the third timer expires, the terminal shifts to a sleep mode. When the first timer expires, the terminal shifts from the sleep mode to an activated state.

  The connected mobile terminal device performing discontinuous reception in the mobile communication system according to the present invention uses the information for the discontinuous reception cycle length (DRX cycle length) to derive an activation period starting point (Starting point), Information on a minimum activation period (minimum active period length) received from the base station and information capable of deriving an activation period start time are searched, and the discontinuous reception cycle length is determined at the start of the induced activation period. The first timer set in (DRX cycle length) and the second timer set in the minimum active period (minimum active period length) are activated, and during the minimum activation period, forward packet If the forward packet is not present, the transmission / reception unit is turned off. If the forward packet is present, the transmission / reception unit is turned on. Receiving the instruction information indicating the end of communication, determining whether or not the instruction information exists in the packet, and a DRX control unit for controlling the transmission / reception unit on or off according to the instruction information. Including a demultiplexer that reports to the DRX controller, and the transceiver that operates on or off according to the DRX controller.

  According to the present invention, a DRX operation of a connected terminal considering service characteristics in a next-generation mobile communication system is proposed to improve the standby time of the terminal. Therefore, the power consumption of the terminal is minimized.

  Further, by supporting a packet service in which a traffic generation state can be changed every discontinuous reception period, an effect of providing a DRX operation by adjusting the length of the activation period according to the traffic requirement at the time of reception. Is obtained.

  In addition, after the terminal confirms the successful reception of the packet including the retransmitted packet, the terminal receives the RLC ACK signal for the corresponding packet and enters the sleep mode, thereby improving the packet reception performance.

It is a figure which shows the structure of the LTE system to which this invention is applied. It is the figure explaining DRX operation | movement of the conventional mobile communication system. FIG. 6 illustrates a DRX operation with a variable activation period length according to the present invention. 7 is an operation flowchart of a terminal when an end of an activation period is signaled in an in-band form according to the first embodiment of the present invention. 7 is a flowchart illustrating a terminal operation when an end of an activation period is signaled in an out-band form according to the second embodiment of the present invention. FIG. 10 is an operation flowchart of the terminal when the mobile station determines the end of the activation period in consideration of the forward activation state according to the third embodiment of the present invention. 4 is a terminal reception device according to the first to third embodiments of the present invention. It is the figure explaining DRX operation | movement which considered the RLC recognition (ACK) signal according to 4th Embodiment of this invention. 10 is a signal flowchart of a terminal performing a DRX operation considering an RLC recognition signal according to a fourth embodiment of the present invention. It is a terminal receiver according to a fourth embodiment of the present invention.

  The above and other aspects, features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

  It will be appreciated that the same reference numerals in the accompanying drawings represent the same elements, features and structures.

  Hereinafter, an operation principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is recognized that a specific description of a related known technique or configuration may obscure the gist of the present invention, the detailed description is omitted. . Furthermore, the terms described later are terms defined in consideration of the functions in the present invention, and these may vary depending on the user, the intention of the operator, the custom, or the like. Therefore, these terms should be defined based on the entire contents of this specification.

  Although the present invention has been described with reference to an LTE system, the present invention can be applied to other mobile communication systems that use discontinuous reception operation without any other changes.

  The present invention defines a DRX operation of a connected terminal in a next-generation mobile communication system. In particular, the DRX of the connected terminal is preferably configured in consideration of service characteristics. That is, the connected terminal may have a different amount of data generated every DRX cycle depending on the type of service. In other words, the period for monitoring the forward channel of the terminal every DRX cycle needs to be changed according to the amount of data to be transferred during the corresponding DRX cycle.

  For example, in the case of a terminal receiving a file down node service using TCP, due to the characteristics of TCP, when one packet is initially transferred in the forward direction and the terminal transmits a TCP ACK corresponding thereto, the terminal responds to the TCP ACK. Then, two more packets are transferred, and four more packets are transferred in response to the TCP ACK for the two packets. For example, the amount of forward data increases with a certain time difference. In consideration of such a tendency, it is preferable to continuously increase the activation period of the terminal in service.

  Even if it is not the file down node service, the inability to measure data generation and discontinuity are general characteristics of the packet service. Therefore, in this packet service, the traffic generation state may change every DRX cycle. Therefore, the present invention intends to provide a method in which the terminal variably sets the DRX cycle in consideration of the amount of packet data.

  Referring to FIG. 3, in the present invention, a DRX cycle length 310 from the base station to the terminal, information that can guide the start point 305 of the activation period 350 (hereinafter referred to as start point guide information), a minimum activation period (minimum active period) period length) 340a and 340b are signaled.

  The terminal wakes up every start time 305, 320, 325 of each activation period 350, 360, 370, and if there is no data to receive, after maintaining the minimum activation period, the terminal enters sleep mode, and the received data In some cases, the sleep period is entered again after maintaining the activation period until the data is received.

  At this time, the terminal derives the start time 305 of the activation period 350 using a predetermined method, for example, a value obtained by calculating a modulo operation of the DRX cycle length and the terminal identifier. After that, at the start time 305 of the activation period, the activation state is entered.

  The activation period length 350, 360, 370 can have a variable length from the minimum activation period 340a, 340b to the DRX cycle length 310, 380, and the terminal is at the activation period start time 305. Receive the packet via the forward channel. In FIG. 3, reference numbers 340a and 340b indicate the same minimum activation period length.

  In particular, referring to the activation period 360 in FIG. 3, it can be seen that packets are continuously received within the minimum activation period 340a. At this time, the terminal can determine whether the received packet is the last packet by a predetermined method, and can end the activation period 360.

  In FIG. 3, the reception of the packet can proceed by a predetermined method according to the communication system. For example, in the LTE system, the terminal determines whether there is a packet to be transferred to itself via the forward control channel. Monitors and receives the packet if there is a packet transferred to itself.

  In FIG. 3, when the activation period with the reference number 370 is seen, the terminal that wakes up at the point with the reference number 325 has no packet transferred to itself during the predetermined minimum activation period 340 b. Therefore, the corresponding activation period 370 is terminated, and the sleep mode is entered until the next activation period starts.

  On the other hand, as described above, when the terminal awakened at the reference number 320 point recognizes the packet transferred to itself before the expiration of the minimum activation period 360, the terminal starts receiving the packet from the base station. In fact, the end of the activation periods 350, 360, and 370 in which packets are transmitted to and received from the terminal can be reported through in-band information included in the packets or a control channel. Alternatively, the terminal can autonomously detect the end of the activation period according to a predetermined rule.

  First, when the end of the activation period is reported with in-band information, the base station sets a last packet flag of 1 bit of the last packet of the corresponding activation period. Set to 'YES'. Therefore, when the terminal receives a packet with the last packet flag set to 'YES', the terminal maintains an activation period until the processing for the packet stored in the HARQ processor at the corresponding time is completed, and then the terminal When the process is completed, a sleep mode 390 is entered.

  Second, if the end of the activation period is reported via the control channel, the terminal remains active until reception of the packet being processed by the HARQ processor is completed when the end of the activation period is declared. When the reception of the packet is completed after maintaining the conversion period, the sleep mode is entered.

  Finally, if a packet is not received for a predetermined length of time, the terminal determines that the activation period has ended and can enter sleep mode.

  As described above, when there is no packet reception, the length of the activation period is maintained at the minimum activation period, and when there is packet reception, the end point of the activation period is set to in-band (in signal is transmitted in the form of a band), or is signaled in the form of an out-band signal via a control channel, or the terminal makes an autonomous determination. According to this method, the activation period is adjusted to a variable length as required, thereby attempting to guarantee the efficiency of the DRX operation.

(First embodiment)
Referring to FIG. 4, when the end of the activation period is reported using the last packet flag, the operation of the terminal is as follows.

  In step 405, the terminal receives a DRX cycle length, information that can guide an activation period start position, and a minimum active period length during call setup. The terminal that has received the information prepares for DRX operation.

  In step 410, the terminal uses information that can guide the start time of the activation period, and as an example, the terminal uses its own unique identifier and the DRX cycle period to guide the start time of the activation period, It is determined whether or not the current time is the start time of the activation period.

  If it is not the start time of the activation period, the process proceeds to step 435, and the terminal maintains the sleep period until the start time of the activation period. The terminal recognizes that a point separated from the start point of the previous activation period by the DRX cycle length is the start point of the activation period.

  When the activation period starts, the terminal activates timer T (DRX_CYCLE_LENGTH) and timer T (MINIMUM_ACTIVE) in step 415. The timer T (DRX_CYCLE_LENGTH) is a timer in which the DRX cycle length recognized in step 405 is set, and the timer T (MINIMUM_ACTIVE) is a timer in which the minimum activation period recognized in step 405 is set.

  In step 420, the terminal determines whether there is a packet to be received through the common control channel or the like. If no packet is transferred to the timer T (MINIMUM_ACTIVE) at step 420, the process branches to step 435 to enter sleep mode and then the next activation period starts. Maintain sleep. The next activation period starts when the timer T (DRX_CYCLE_LENGTH) driven in step 415 expires.

  On the other hand, if it is determined in step 420 that there is a packet to be transferred to the terminal before the timer T (MINIMUM_ACTIVE) expires, the terminal proceeds to step 425 and receives the packet according to the HARQ operation. If the packet is successfully received in step 425, the terminal checks the last packet flag of the received packet in step 430.

  As a result of the inspection in step 430, if the last packet flag is set to 'YES', the process proceeds to step 440. If the last packet flag is set to 'NO', the process returns to step 425 and the packet Continue receiving.

  If it is found in step 440 that the received packet is over, the terminal completes processing of the HARQ packet stored in the HARQ processor and enters sleep mode until the next activation period begins. The next activation period starts when timer T (DRX_CYCLE_LENGTH) expires.

  In step 440, completing the processing of the HARQ packet means that the packet stored in the HARQ processor is normally received by the HARQ operation, and the HARQ ACK for the corresponding packet is transferred or there is an error in the corresponding packet. Nevertheless, there is a case where a new packet is received by the same HARQ process, and the packet cannot be successfully received after all.

  In other words, when the packet stored in the HARQ processor is successfully received or when the terminal recognizes that there is no possibility of receiving the stored packet successfully, the stored packet is processed. Can be said to be completed.

(Second Embodiment)
Referring to FIG. 5, the terminal operation of the second embodiment of the present invention is the same as that of the first embodiment mentioned above except for the operation of the terminal excluding the operation of the terminal that determines the end of the activation period. In the following second embodiment, only a portion where a different operation is performed will be described. That is, Steps 505 to 520 in FIG. 5 are the same as Steps 405 to 420 in the first embodiment, and thus description thereof is omitted.

  In step 525, the terminal receives a packet from the base station according to a predetermined HARQ operation.

  At this time, the terminal monitors reception of a signal indicating the end of the activation period via the forward control channel in step 530 while continuously receiving the forward control channel.

  If a signal indicating the end of the activation period is received, the terminal proceeds to step 540, otherwise returns to step 525 to continue packet reception.

  In step 540, the terminal completes the processing of the HARQ packet present in the HARQ processor at the time of receiving the signal indicating the end of the activation period, and proceeds to step 535 to enter the sleep mode until the next activation period starts. enter. The next activation period starts when the timer T (DRX_CYCLE_LENGTH) activated in step 515 expires.

(Third embodiment)
Referring to FIG. 6, in step 605, the UE determines the DRX cycle length, information that can guide the start time of the activation period, the minimum activation period, the activation period, from the base station during call setup. After receiving the end period (active period end interval), the DRX operation is prepared. The same value can be used for the minimum activation period and the activation period end interval, in which case only one of the two values can be signaled. The terminal that has received the information prepares for DRX operation.

  In step 610, the terminal uses information that can guide the start time of the activation period, and as an example, the terminal uses its own unique identifier and the DRX cycle period to guide the start time of the activation period, It is determined whether the activation period has started.

  If the activation period has not started, the process proceeds to step 635 and the sleep mode is maintained until the activation period starts. The start time of the activation period is derived through information that can derive the start time of the activation period, and the start time of the next activation period is a value obtained by adding the DRX cycle length to the start time of the previous activation period. It is.

  When the activation period starts, the terminal proceeds to step 615 to activate timer T (DRX_CYCLE_LENGTH) and timer T (MINIMUM_ACTIVE). Timer T (DRX_CYCLE_LENGTH) is a timer in which the DRX cycle length is set, and timer T (MINIMUM_ACTIVE) is a timer in which the minimum activation period is set.

  In step 620, the terminal determines whether there is a packet to be received through the common control channel. If no packet is transferred to the timer T (MINIMUM_ACTIVE) before the timer T (MINIMUM_ACTIVE) expires, the process branches to step 635 to enter the sleep mode until the next activation period starts. The next activation period starts when the timer T (DRX_CYCLE_LENGTH) expires.

  On the other hand, if there is a packet transferred to itself before the minimum activation period ends in step 620, the terminal proceeds to step 625 and receives the packet according to the HARQ operation.

  The terminal that has received the packet proceeds to Step 627 and drives (or re-drives) the timer T (active_period_end) set in the activation period end interval T (active_period_end). The timer T (active_period_end) is used for the purpose of ending the activation period when no packet is received during the T (active_period_end) time. When receiving a packet for the first time, the terminal drives the timer T (active_period_end), and then redrives the timer T (active_period_end) every time the next packet is received.

  The next packet may be (1) a new packet, or (2) a retransmit packet for a new packet or a conventional packet.

  That is, the timer T (active_period_end) can be re-driven only when the next packet is a new packet, and the timer T (active_period_end) can also be used when the next packet is a new packet or a retransmission packet for a conventional packet. ) Can be re-driven. In the following, for convenience of explanation, the first scheme is that the timer T (active_period_end) is redriven only when a new packet is received, and the timer T (active_period_end) receives all packets including retransmitted packets. The scheme that is sometimes redriven is referred to as the second scheme.

  In step 630, the terminal determines whether the timer T (active_period_end) has expired. Since the timer T (active_period_end) has expired means that no packet has been received during the activation period end interval, the process proceeds to step 640. If the timer T (active_period_end) is still operating, the terminal repeats step 625 and step 627.

  In step 640, the operation of the terminal varies depending on whether the timer T (active_period_end) operates according to the first scheme or the second scheme.

  If operating according to the first scheme, in step 640, when the terminal times out, it completes processing of the HARQ packet stored in the HARQ processor and enters sleep mode until the next activation period begins. The next activation period starts when timer T (DRX_CYCLE_LENGTH) expires.

  When operating according to the second plan, the terminal does not wait for the processing of the HARQ packet being processed by the HARQ processor to be completed, and immediately enters the sleep mode. This is because in the second proposal, the activation period end interval is set based on the reception of the forward packet, regardless of whether it is a retransmitted packet or a new packet. In the second plan, if the base station does not retransmit a specific packet during the activation period end interval, the terminal switches to the sleep mode. Packets must be sent and received.

  In other words, if a retransmit packet does not arrive during the activation period end interval, it means that the base station has abandoned the transfer for the corresponding packet, so the packet may be successfully received. Means that there will be no more. Therefore, the terminal discards the packet stored in the HARQ processor for which the retransmit packet has not arrived during the activation period end interval, and immediately enters the sleep mode.

  Referring to FIG. 7, a terminal receiving apparatus 700 includes a demultiplexing apparatus 705, a HARQ processor 715, a control channel processing unit 720, a DRX control unit 725, and a receiving unit 730.

  The receiving unit 730 of the terminal is turned on or off under the control of the DRX control unit 725. The DRX control unit 725 turns off the reception unit 730 in the sleep mode and turns on the reception unit 730 in the activation period. The HARQ processor 715 processes the HARQ packet received by the receiving unit 730 by a predetermined HARQ operation, and transmits the HARQ packet having no error to the demultiplexer 705.

  The demultiplexer 705 checks the last packet flag (Last Packet Flag) of the received HARQ packet, and reports this to the DRX control unit 725 if the last packet flag is set to 'YES'. . Also, the demultiplexer 705 transmits the received packet to the upper layer.

  When the DRX control unit 725 recognizes that the packet with the last packet flag of “YES” has been received, the DRX control unit 725 monitors the state of the HARQ processor 715 and enters the sleep mode when the operation of the HARQ processor 715 is completed. That is, the receiving unit 730 is turned off.

  The control channel processing unit 720 processes information received through the forward common control channel. As in the second embodiment described with reference to FIG. 5, when the end of the activation period is signaled through the forward common control channel, the control channel processing unit 720 determines the end of the activation period as the DRX control unit. Report to 725.

  When receiving the report from the control channel processing unit 720 that the activation period has ended, the DRX control unit 725 monitors the state of the HARQ processor 715 and enters the sleep mode when the operation of the HARQ processor 715 is completed. That is, the receiving unit 730 is turned off.

  Here, as in the first embodiment of the present invention, when the terminal device 700 receives the last packet, the corresponding activation period ends and the sleep mode is immediately entered, so that positive recognition at the RLC level is achieved. It is preferable to enter sleep mode after transferring the signal (simply RLC ACK signal).

  This is because, in the case of packet service, the terminal performs radio link control (RLC) recognition to perform automatic retransmission request (ARQ) operation, which is different from HARQ, in order to increase the reliability of transmission and reception. Operates in Acknowledged Mode.

  In the ARQ operation, a serial number is inserted and transferred to a packet on the transmission side, and the reception side determines the presence or absence of a packet that has failed to be received through inspection of the serial number of the received packet. For a packet that has failed to be received, the receiving side forwards a negative acknowledgment signal (NACK) to the transmitting side to request retransmission of the corresponding packet, and for a packet that has been successfully received, affirmative An acknowledgment signal (ACK) is transmitted to the transmitting side. The negative recognition signal and the positive recognition signal are transferred in a control message called an RLC status report.

  If a service that requires discontinuous reception operates in the RLC awareness mode, the terminal must transmit an RLC level positive acknowledgment signal when receiving the last packet. Therefore, it is preferable to enter the sleep mode after transferring the positive recognition signal of the RLC level, rather than immediately entering the sleep mode.

  Therefore, in the following, unlike the above-described first embodiment, when the terminal apparatus receives the last packet indicator, a method for entering the sleep mode after transferring the RLC recognition signal for the last packet is described below in the fourth embodiment. This will be described in the embodiment.

  In the following fourth embodiment of the present invention, the operation of the terminal is the same as that in the first embodiment in the activation period during which packets cannot be received, and thus the description thereof is omitted.

(Fourth embodiment)
Referring to FIG. 8, in the fourth embodiment, the base station signals to the terminal the DRX cycle length 810, information that can guide the start time 805 of the activation period 850, and the minimum activation periods 840a and 840b.

  If there is no data to wake up and receive every start time 805, 820, 825 of each activation period 850, 860, 870, the terminal enters the sleep mode after maintaining the minimum activation period, and the received data is In some cases, the sleep period is entered again after maintaining the activation period until the data is received.

  In FIG. 8, as an example of a predetermined method determined in advance, the terminal derives the start time 805 of the activation period 850 using a value obtained by calculating a modulo operation of the DRX cycle length and the terminal identifier. After that, at the start time 805 of the activation period, the activation period is activated.

  The length of the activation period 850, 860, 870 may have a variable length from the minimum activation period 840a, 840b to the DRX cycle length (810 or 880), and the terminal At 805, the packet is received via the forward channel. In FIG. 8, reference numbers 840a and 840b representing the length of the minimum activation period represent physically the same time.

  In FIG. 8, when the activation period having the reference number 860 is seen, it can be seen that packets are continuously received within the minimum activation period 840a. Therefore, the terminal ends the activation period 860 by determining whether or not the received packet is the last packet.

  As an example, the terminal wakes up at the start of a predetermined activation period and monitors the forward control channel. That is, before the minimum activation period 840a ends, the forward control channel and the forward packet start to be transferred to the terminal, and the terminal stores the packet 880 stored with the 'Last packet indicator'. Until the packet is received in the forward direction. The 'last packet indicator' may be implemented with an RLC control signal.

  In the fourth embodiment of the present invention and the first embodiment of the present invention, the terminal operates with different activation periods as follows for received packets.

  In the first embodiment, when the reception of the packet in which the information of the last packet is stored (piggyback) is completed, the corresponding activation period ends, and the sleep mode is entered.

  In the fourth embodiment, when information on the last packet is stored and a packet is received and all packets having a sequence number lower than the last packet are successfully received, all packets having a sequence number lower than the last packet are received. After transmitting the positive acknowledgment signal (ACK) for the packets of, the activation period ends and sleep mode is entered.

  In the fourth embodiment, when the RLC sequence number of the packet is changed from x to x + n, the sequence number of the RLC PDU (Packet Data Unit) received by the RLC entity (Entity) 945 of the terminal configured for each application is inspected. Thus, it is determined whether there is an RLC PDU that has not been received. Then, when receiving the packet in which the “last packet indicator” is stored, the terminal transfers the RLC status report 885 including the reception status information of the RLC PDU through the reverse channel.

  If the terminal receives all RLC PDU [x] to RLC PDU [x + n], the RLC status report 885 is loaded with a positive acknowledgment (ACK) signal for the RLC PDU. When the terminal completes the transfer of the RLC status report 885 that positively recognizes all the packets received during the corresponding activation period, the terminal ends the activation period.

  If the terminal cannot receive any RLC PDU [x + m] among RLC PDU [x] to RLC PDU [x + n], the terminal denies the RLC PDU that could not be received in the RLC status report. Include a cognitive (NACK) signal. As described above, when a negative acknowledgment signal is included in the status report, the UE maintains the activation period until the retransmission of the RLC PDU that has failed to be received is completed.

  Referring to FIG. 9, in step 905, the UE sets a DRX cycle length, information that can guide a starting position of the activation period, and a minimum activation period (minimum active period) during call setup. period length). The terminal that has received the information prepares for DRX operation.

  In step 910, the terminal uses the information that can guide the start time of the activation period, as an example, uses the unique identifier and the DRX cycle period to guide the start time of the activation period, and the current time is activated. It is determined whether it is the start point of the period.

  If the result of determination in step 910 is not the current activation period start point, in step 935, the terminal maintains the sleep period until the activation period start point is reached. The next activation period begins at a point separated by the DRX cycle length from the start of the activation period.

  When the activation period starts, the terminal activates timer T (DRX_CYCLE_LENGTH) and timer T (MINIMUM_ACTIVE) in step 915. Timer T (DRX_CYCLE_LENGTH) is a timer in which the DRX cycle length is set, and timer T (MINIMUM_ACTIVE) is a timer in which the minimum activation period is set.

  Then, the terminal proceeds to step 920 and determines whether there is a packet to be received through the common control channel or the like. If there is no packet to be transferred to the terminal until the timer T (MINIMUM_ACTIVE) expires, that is, until the minimum activation period ends, the terminal branches to step 935 and enters the sleep mode. The sleep period is maintained until the activation period begins. The next activation period starts when the timer T (DRX_CYCLE_LENGTH) expires.

  On the other hand, if it is determined in step 920 that there is a packet transferred to the mobile terminal before the minimum activation period ends, the terminal proceeds to step 925 and receives the packet according to the HARQ operation.

  When the packet is successfully received in step 925, it is checked whether or not the packet received in step 930 is the last packet. Whether or not it is the last packet can be confirmed through control information stored (Piggyback) in the received RLC PDU, for example. While transmitting the last RLC PDU, the RLC transmission side includes the last RLC PDU including control information indicating that the RLC PDU is the last RLC PDU. Therefore, in step 930, the terminal checks whether the RLC PDU received by the RLC receiver includes control information indicating that it is the last RLC PDU.

  If the received packet is not the last packet in step 930, the terminal proceeds to step 925 and performs a packet reception process until a packet including control information representing the last packet is received.

  On the other hand, if the received packet is the last packet in step 930, the terminal proceeds to step 940 and forms an RLC status report including RLC PDU reception status information up to the corresponding time. The RLC status report includes the RLC sequence number of the unreceived packet and the RLC sequence number of the received packet. As described above, the RLC sequence number of the unreceived packet is called NACK and is received. The RLC sequence number of the packet is called ACK. That is, the RLC status report includes NACK and ACK, where NACK is a set of serial numbers of packets not received, and ACK is a set of serial numbers of received packets.

  If the NLC is not included in the RLC status report of Step 940, the UE receives an ACK for the last RLC PDU and an ACK for all RLC PDUs having a lower sequence number than the last RLC PDU in the RLC status report in Step 945. Check if it is included. If the result of the inspection is 'YES', it means that there is no packet to be retransmitted and the process proceeds to step 950. If the result of the check is “NO”, it means that there is a packet that needs to be retransmitted, and the process proceeds to step 955.

  In step 950, after the terminal transmits the RLC status report, the UE proceeds to step 935 and enters a sleep mode until the next activation period starts. The next activation period starts when timer T (DRX_CYCLE_LENGTH) expires.

  In step 955, after transmitting the RLC status report, the UE waits until the retransmission for the RLC packet requested to be retransmitted by the RLC status report is completed. Then, after transferring the RLC status report including the ACK signal for all RLC PDUs having a lower sequence number than the last RLC PDU, the process proceeds to step 935 to enter sleep mode until the next activation period begins.

  Referring to FIG. 10, the terminal may include a number of RLC entities 1035, 1040, and 1045 configured for each application, and a specific RLC entity among them may operate in DRX mode. It can also be configured. For example, the RLC entity having the reference number 1045 is set as an RLC entity operating in the DRX mode.

  The RLC entity 1045 operating in the DRX mode requests the DRX control unit 1025 to end the activation period when all of the following conditions are satisfied.

1. 1. Receive RLC PDU with last packet indicator stored 2. Successful reception of all packets received during the corresponding activation period. Completion of transfer of RLC status report including positive acknowledge signal for all packets received during corresponding activation period

  In addition, the RLC entity 1045 checks whether there is an unreceived packet by checking the serial number of the RLC PDU, and performs an operation such as configuring an RLC status report according to the check.

  When the DRX controller 1025 receives a signal indicating that the activation period has ended from the RLC entity 1045 operating in the discontinuous mode, the DRX controller 1025 ends the activation period and maintains the sleep mode until the next activation period starts.

  The terminal demultiplexer / multiplexer 1005 multiplexes RLC PDUs transmitted from the RLC layer, that is, RLC entities 1035, 1040, and 1045, into MAC PDUs, and MAC PDUs transmitted from HARQ processor 1015 to RLC PDUs. And demultiplexing to RLC entities 1035, 1040, and 1045.

  The HARQ processor 1015 processes the HARQ packet received by the transmission / reception unit 1030 through a predetermined HARQ operation, transmits the HARQ packet having no error to the demultiplexing / multiplexing apparatus 1005, and receives the HARQ packet. The demultiplexing block of the multiplexing apparatus 1005 transfers the HARQ packet to the RLC layers 1035, 1040, and 1045.

  Also, the HARQ processor 1015 transfers the MAC PDU received from the multiplexed block of the demultiplexing / multiplexing apparatus 1005 to the transmitting / receiving unit 1030 through a predetermined HARQ operation, and the transmitting / receiving unit 1030 transfers the MAC PDU to the base station. To do.

  The control channel processing unit 1020 processes information received through the forward common control channel, and if there is a packet transferred to the corresponding terminal, reports it to the DRX control unit 1025.

  The DRX control unit 1025 recognizes the start time of the activation period, and turns on the receiver at the start time. If the control channel processing unit 1020 does not receive a report indicating that there is a packet to be transferred to the terminal before the minimum activation period expires, the activation period ends.

  On the other hand, upon receiving a report from the control channel processing unit 1020 that there is a packet to be transferred to the terminal, the activation period is maintained until a signal indicating that the activation period has ended is received from the RLC entity 1045.

  A person having ordinary knowledge in the technical field to which the present invention pertains can implement the present invention in various forms without departing from the spirit and scope of the present invention defined in the claims. I can see that

100a, 100b, 100c, 100d, 100e ENB
102a, 102b EGGSN
104 UE
205, 215, 225 Activation period start time 210, 220 DRX cycle length 230 Activation period start point 235 Activation period length 305, 320, 325 Activation period start time 310, 380 DRX cycle length 330 packet 340a, 340b Minimum activation period 350, 360, 370 Activation period 700 Receiver 705 Demultiplexer 715 HARQ processor 720 Control channel processor 725 DRX controller 730 Receiver 805, 820, 825 Start of activation period Time 810, 880 DRX cycle length 840a, 840b Minimum activation period 850, 860, 870 Activation period 885 RLC status report 945 RLC entity 1005 Demultiplexer / multiplexer 1015 HARQ processor 1020 Control channel Le processor 1025 DRX controller 1030 transceiver 1035,1040,1045 RLC entity

Claims (22)

A method for controlling an activation period during discontinuous reception (DRX) operation by a terminal in a mobile communication system,
Starting a first timer to monitor whether control data associated with new user data has been received over the shared control channel during the activation period;
Extending the activation period when the control data indicating new user data transmission is received through a shared control channel instead of retransmitted data during the activation period; and
When a control signal indicating the end of the activation period is received from a base station, the process of ending the activation period,
The process of extending the activation period starts a second timer or activates the second timer when the control data indicating new user data transmission is received through a shared control channel instead of retransmitted data. The second timer is restarted when the control data indicating new user data transmission instead of retransmitted data is received through the shared control channel .   The method of claim 1, further comprising suspending at least one of the first timer and the second timer when a control signal indicating the end of the activation period is received.   The method of claim 1, wherein the duration value of the first timer and the duration value of the second timer are received from a base station.   The method of claim 1, further comprising receiving start information from the base station to determine a start time of the first timer.   The method of claim 1, further comprising monitoring the control data through the shared control channel during operation of at least one of the first timer and the second timer.   The method of claim 1, wherein the shared control channel includes a reverse physical control channel (Physical Downlink control channel PDCCH). An apparatus for controlling an activation period during discontinuous reception (DRX) operation of a terminal in a mobile communication system,
During the activation period, a first timer is started to monitor whether control data associated with new user data has been received through the shared control channel, and during the activation period, a new user, not retransmitted data, is started. When the control data instructing data transmission is received through a shared control channel, the activation period is extended, and when a control signal indicating the end of the activation period is received from a base station, the activation period is Including a DRX controller to terminate,
Extending the activation period starts a second timer or activates the second timer when the control data indicating new user data transmission is received through a shared control channel instead of retransmitted data. The second timer is restarted when the control data indicating new user data transmission is received through the shared control channel instead of retransmitted data . The DRX controller is
8. The apparatus of claim 7, wherein when a control signal indicating the end of the activation period is received, at least one of the first timer and the second timer is interrupted. The DRX controller is
The apparatus of claim 7, wherein the duration value of the first timer and the duration value of the second timer are received from a base station. The DRX controller is
8. The apparatus according to claim 7, wherein start information for determining a start time of the first timer is received from a base station. The DRX controller is
The apparatus of claim 7, wherein the control data is monitored through the shared control channel during operation of at least one of the first timer and the second timer.   The apparatus according to claim 7, wherein the shared control channel includes a reverse physical control channel (Physical Downlink control channel PDCCH). A method in which a terminal in a mobile communication system transfers configuration information in a base station to control an activation period during discontinuous reception (DRX) operation,
The base station transfers configuration information including information on the discontinuous reception cycle length, information that can guide the start position of the activation period, information about the minimum activation period, and information about the activation period end interval to the terminal. Including the process,
The terminal
During the activation period, a first timer is started to monitor whether control data associated with new user data rather than retransmitted data is received through the shared control channel;
If the control data indicating new user data transmission is received through a shared control channel instead of re-transfer data during the activation period, the activation period is extended,
When a control signal indicating the end of the activation period is received from a base station, the activation period ends,
The process of extending the activation period starts a second timer or activates the second timer when the control data indicating new user data transmission is received through a shared control channel instead of retransmitted data. The second timer is restarted when the control data indicating new user data transmission instead of retransmitted data is received through the shared control channel .   The method of claim 13, further comprising interrupting at least one of the first timer and the second timer when a control signal indicating the end of the activation period is received.   The method of claim 13, further comprising monitoring the control data through the shared control channel during operation of at least one of the first timer and the second timer.   The method of claim 13, wherein the shared control channel includes a reverse physical control channel (Physical Downlink control channel PDCCH).   The method of claim 13, wherein the period of the second timer is determined based on information about the activation period end interval. An apparatus for transferring configuration information in a base station to control an activation period during discontinuous reception (DRX) operation by a terminal in a mobile communication system,
The base station transfers configuration information including information on the discontinuous reception cycle length, information that can guide the start position of the activation period, information about the minimum activation period, and information about the activation period end interval to the terminal. Including the transmitter,
The terminal
During the activation period, a first timer is started to monitor whether control data associated with new user data rather than retransmitted data is received through the shared control channel;
If the control data indicating new user data transmission is received through a shared control channel instead of re-transfer data during the activation period, the activation period is extended,
When a control signal indicating the end of the activation period is received from a base station, the activation period ends,
Extending the activation period starts a second timer or activates the second timer when the control data indicating new user data transmission is received through a shared control channel instead of retransmitted data. The second timer is restarted when the control data indicating new user data transmission is received through the shared control channel instead of retransmitted data . The terminal
The apparatus of claim 18, wherein when a control signal indicating the end of the activation period is received, at least one of the first timer and the second timer is interrupted. The terminal
The apparatus of claim 18, wherein the control data is monitored through the shared control channel during operation of at least one of the first timer and the second timer.   19. The apparatus of claim 18, wherein the shared control channel includes a reverse physical control channel (Physical Downlink control channel PDCCH).   The apparatus of claim 18, wherein the period of the second timer is determined based on information on the activation period end interval.

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