RU2399158C2 - Method and device for interrupted reception of connected terminal in mobile communication system - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: for packet transmission service, uninterrupted reception operation ensures set up duration of the active period in accordance with traffic requirements during reception. Also user equipment enters standby mode after confirmation of successful reception of packets, including retransmission packets, and sending the ACK RLC signal for packets.

EFFECT: uninterrupted reception (UR) of connected user equipment (UE) in mobile communication system.

22 cl, 10 dwg

Description

1. FIELD OF THE INVENTION

The present invention generally relates to a continuous reception (DRX) operation in a mobile communication system. More specifically, the present invention relates to a method and apparatus for performing a DRX operation using a variable active period in a connected terminal.

2. DESCRIPTION OF THE PRIOR ART

The wireless communication system has been largely developed because the communication device does not have access to a fixed wired network. Such wireless communication systems include mobile communication systems, wireless local area network (WLAN), wireless broadband (WiBro) and specially designed mobile communication systems.

In particular, mobile communication systems in comparison with other wireless communication systems are based on user mobility. Ultimately, they aim to deliver communication services to mobile terminals, such as a portable telephone and alphanumeric radio receivers (pagers), regardless of time and location.

Mobile communication systems operate synchronously or asynchronously. In particular, the universal mobile communication system (USMS, UMTS) is a 3rd generation (3G) asynchronous mobile communication system operating in wideband code division multiple access (WCDMA) based on European mobile communication systems, global mobile communication system (GSM) ) and general packet radio service (GPRS). The 3rd Generation Communications Systems Partnership (3GPP) project, working to standardize the Universal Mobile Communications System (UMTS), is currently discussing the next generation UMTS system, called “Long Term Evolution” (LTE) technology.

LTE is a high-speed communication technology with packet transmission with a transmission speed of 100 Mbit / s or higher, which will be commercially available by approximately 2010. To do this, many schemes are being investigated, for example, a method of reducing the number (types) of nodes existing in a communication channel by simplifying the configuration networks or a method for as close as possible the approximation of wireless communication protocols to radio channels. Ultimately, the LTE system will change from an existing 4-node architecture to a 3-node or 2-node architecture.

1 illustrates the configuration of an LTE system to which the present invention is applied.

Referring to FIG. 1, an LTE system can be simplified to a 2-node architecture with LTE-enabled Advanced Node B (Evolved Node B, ENB) 100a-100e and Advanced GPRS Gateway Support Nodes (Evolved GGSN, EGGSN) 102a and 102b.

Nodes ENB 100a-100e, which are equivalent to the existing Nodes B (base stations), are connected to the user equipment (software, UE) 104 through a radio channel. Compared to conventional Node B, ENB 100a-100e nodes provide more sophisticated functionality.

This implies that all user traffic, including a real-time service, such as voice traffic over IP networks (VoIP), is served on shared (public) channels and, accordingly, a device is required in the LTE system to accumulate state information regarding a specific UE 104 and other UEs and their maintenance planning. ENB 100a-100e nodes are responsible for planning.

To achieve data rates of up to 100 Mbps, the LTE system is expected to use a wireless access technology called orthogonal frequency division multiplexing (OFDM) in the 20 MHz band. For UE 104, adaptive modulation and coding (AMC) will be applied according to the state of its channel. That is, for UE 104, the modulation scheme and the channel coding rate are selected adaptively (adaptively) in accordance with the channel state.

Like the High Speed Downlink Packet Access (HSDPA) or the uplink dedicated dedicated channel (E-DCH), the LTE system between the UE 104 and the ENB 100a-100e will use a hybrid automatic retransmission request ( HARQ). HARQ is a scheme to increase the share of successful reception by “soft” (software) combining the original transmission data with the retransmission data without deleting the old data. Thus, UE 104 intends to provide packet reception performance through AMC and HARQ schemes.

Traditionally, the UE starts up (“wakes up”) at a predetermined time, monitors a predetermined channel for a predetermined period of time, and then re-enters standby mode in an inactive state. This is called a continuous reception operation (DRX), which is a method of extending the latency for a UE in an idle state.

Figure 2 illustrates a timing diagram of a DRX operation in a conventional mobile communication system.

As for FIG. 2, the UE and the Node B are consistent with respect to the DRX configuration, the idle period, and the alternating (variable) active period in accordance with the DRX configuration. The waiting period is a period of time during which the UE turns off its receiver, thus minimizing power consumption. An active period is a period of time during which a UE performs a normal receive operation with its switched-on receiver. The active period is also called the launch period (“awakening”) and thus the terms “active period” and “launch period” are used interchangeably in the document in the same sense.

The DRX structure is typically composed of the following elements.

1. Duration 210 or 220 DRX cycles: the time interval between a certain active period and the next active period. By using the DRX cycle time, the standby mode is extended and the power consumption of the UE is reduced. In addition, the increased DRX cycle length increases the paging delay of the UE. The network signals the duration of the DRX cycle.

2. The starting position of the active period 205, 215 or 225: the starting position of the active period is derived from the identifier (ID, ID) of the UE and the duration of the DRX cycle. For example, the starting position of the active period is calculated according to a modulo operation with respect to the UE ID and DRX cycle duration.

3. Duration 235 active period: the period of time delay (cycle) of the timer, during which the UE remains active in one active period. Typically, the duration of the active period is preset. For example, the active period is 10 ms in the UMTS communication system.

The UE calculates the start position 230 of the active period using the UE ID and the duration 210 or 220 of the DRX cycle, and receives the downlink channel during the active period counted from the start position 230. In the absence of the required information on the downlink channel, the UE turns off its receiver and included in the duty period.

Illustrated in FIG. 2, a typical DRX operation of starting at each predetermined time interval and monitoring the downlink channel for a predetermined period of time is not feasible for the connected UE in the new LTE system.

When the UE is connected, this means that a specific service is currently running for the UE, and user data associated with the service is present between the network and the UE. The radio control network (RRL) maintains a service context for the UE (subscriber). UEs in this state are called connected UEs.

Accordingly, there is a need to determine a DRX operation for a connected UE in an LTE system with respect to a conventional DRX operation for a UE in an inactive state.

SUMMARY OF THE INVENTION

An aspect of embodiments of the present invention is to direct efforts at least to the aforementioned problems and / or disadvantages and to provide at least the advantages described below. Accordingly, an aspect of embodiments of the present invention is to provide a method and apparatus for a connected UE in a mobile communication system for performing a DRX operation.

Another aspect of embodiments of the present invention provides a method and apparatus for setting a variable DRX cycle, taking into account the amount of packet data in a UE, in a future generation mobile communication system.

An additional aspect of the exemplary embodiments of the present invention provides a method and apparatus for setting an active period for a UE according to a type of service in a mobile communication system.

In accordance with one aspect of embodiments of the present invention, a method for performing a DRX operation for a connected UE in a mobile communication system is provided. In the DRX (execution) method, the UE receives information on the DRX cycle duration from the Node B, retrieving information to obtain the starting position of the active period and information on the minimum duration of the active period, obtains the starting position of the active period using the extracted information, and activates the first timer set for the duration of the DRX cycle, and a second timer set to the minimum duration of the active period, in the initial position of the active period. The UE monitors the presence of a downlink packet for a minimum active period. If there is no downlink packet during the minimum active period, the UE goes into sleep mode. If there is a downlink packet, the UE receives the downlink packet, determines if there is information indicating the end of the packet, stops receiving the packet when there is indicative information, and enters standby mode. When the first timer expires, the UE switches from the standby mode to the active mode.

In accordance with another aspect of embodiments of the present invention, a method for performing a DRX operation in a connected UE in a mobile communication system is provided. In the DRX method, the UE receives the DRX cycle duration from the Node B, extracts information intended to obtain an active period starting position, a minimum active period duration and an active period ending interval, obtains an active period starting position using the extracted information, and activates a first timer set for the duration of the DRX cycle, and a second timer set to the minimum duration of the active period, in the initial position of the active period. The UE monitors the presence of a downlink packet for a minimum active period. If there is no downlink packet for a minimum active period, the UE goes into sleep mode. If there is a downlink packet, the UE receives the downlink packet in accordance with a predetermined HARQ scheme, activates a third timer set to a finite interval of the active period. After the time of the third timer, the UE goes into standby mode. When the first timer expires, the UE switches from the standby mode to the active mode.

In accordance with a further aspect of embodiments of the present invention, there is provided an apparatus for performing a DRX operation in a connected UE in a mobile communication system in which a DRX controller obtains an active period starting position using DRX cycle length information, extracts information to obtain an active period starting position, and information about the minimum active period duration received from Node B, activates the first timer set to the DRX cycle duration, and the second timer sets When the active period is shortened to the minimum position, it monitors the presence of a downlink packet during the minimum active period, turns off the transceiver when there is no downlink packet for a minimum active period, and turns on the transceiver if there is a downlink packet , receives indicative information indicating the end of packet reception, and controls the transceiver in accordance with the pointer No information the demultiplexer determines whether the packet has indicative information, and provides an indication of the indicative information to the DRX controller, and the transceiver is turned on or off under control of the DRX controller.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of some embodiments of the present invention will be more apparent from the following detailed description, taken in conjunction with the accompanying drawings, in which:

Figure 1 is an illustration of a configuration of an LTE system to which the present invention is applied;

Figure 2 is an illustration of a timing diagram of a DRX operation in a conventional mobile communication system;

Figure 3 is an illustration of a DRX operation with a variable active period in accordance with the present invention;

4 is a block diagram of the operation of the UE in the case of in-band signaling the end of the active period in accordance with the present invention;

5 is a flowchart of a UE in case of out-of-band signaling of the end of an active period in accordance with the present invention;

6 is a flowchart of a UE when a mobile station (MS, MS) determines the end of an active period, taking into account downlink activity, in accordance with the present invention;

7 is a block diagram of a receiver of a UE in accordance with the present invention;

Fig. 8 is an illustration of a timing diagram of a DRX operation taking into account an ACKnowledgement (ACK) signal (acknowledgment) of a radio link control layer (RLC) in accordance with the present invention;

FIG. 9 is a flowchart of a DRX operation taking into account an RK level ACK signal in a UE in accordance with the present invention; FIG.

10 is a block diagram of a receiver of a UE in accordance with the present invention.

Throughout the drawings, the same numeric reference numbers in the drawings will be understood to refer to the same elements, features and structures.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The information defined in the description, such as detailed constructions and elements, is presented to help a comprehensive understanding of the invention. Accordingly, those of ordinary skill in the art will recognize that various changes and modifications to the embodiments described herein may be made without departing from the scope and spirit of the invention. In addition, descriptions of known functions and constructions are omitted for clarity and conciseness.

Although embodiments of the present invention are described in the context of an LTE system, it should be understood that they are applicable without modification to other mobile communication systems using DRX.

Embodiments of the present invention define a DRX operation for a connected UE in a future generation mobile communication system. Preferably, but not necessarily, the DRX structure for the connected UE is determined taking into account the characteristics of the services. Depending on the type of service for the connected UE, a different amount of data may be generated in each DRX period (DRX_cycle). In other words, it is required that the duration during which the UE monitors the downlink channel varies in each DRX period in accordance with the amount of data that will be sent during the DRX cycle.

For example, when a UE accepts a file download service over a network using the Transmission Control Protocol (TCP), due to the nature of TCP, initially one packet is sent on the downlink, two packets are sent from the UE in response to the TCP ACK, and then four packets are sent from The UE is in response to the TCP ACK for these two packets. The TCP file download service differs in that the downlink data increases depending on some time intervals between transmissions. Given this trend, it is preferable to gradually increase the active period for the UE during the service.

In addition to the file network download service, unpredictability and heterogeneity in data generation are characteristics of packet transmission services. Thus, a packet service may encounter a different traffic shaping state in each DRX cycle. Accordingly, exemplary embodiments of the present invention are intended to provide a method for setting (duration) a DRX clock, which varies according to the amount of packet data in the UE.

As for FIG. 3, the Node B signals the duration 310 of the DRX cycle, information intended to obtain the starting position 305 of the active period 350 (indicated below by the information on obtaining the starting position), and the minimum duration 340a or 340b of the active period.

The UE starts at each of the initial positions 305, 320, and 325 of the active periods 350, 360, and 370. If there is no data to receive, the UE is held for the minimum duration of the active period and enters standby mode. If there is data to receive, the UE maintains an active period until it has completely received the data, and then enters standby mode.

The UE calculates the starting position 305 of the active period 350 in a predetermined manner, for example, by a modulo operation with respect to the UE ID and DRX cycle duration. When an active period begins at time 305, the UE is activated.

Durations of active periods 350, 360, and 370 vary from a minimum duration of 340a or 340b to a duration of 310 or 380 DRX cycles. At the starting position 305 of the active period 350, the UE receives a packet on the downlink channel. Numeric numerals 340a and 340b denote the identical minimum duration of the active period.

With respect to the active period 360, packets are sequentially received for a minimum duration 340a of the active period. The UE may terminate the active period 360 as determined by a predetermined method whether each received packet is the last.

Receiving a packet may be performed in a predetermined manner depending on the communication system. For example, in an LTE system, the UE monitors the downlink control channel to determine where the packet to receive is located, and if there is a packet to receive, the UE receives the packet.

With respect to the active period 370, the UE starts at time 325 and detects that there is no packet to receive for a predetermined minimum duration of the active period 340b. Thus, the UE ends the active period 370 and goes into sleep mode until the next active period.

On the other hand, when the UE starts at time 320 and determines if there is a packet to receive before the minimum duration of 360 active period has elapsed, it starts to receive packets from Node B.

The end positions of active periods 350, 360 and 370 are signaled by in-band information included in the packet or by a control channel. Or the UE can autonomously determine the end positions of the active periods 350, 360 and 370 in accordance with a predetermined rule.

1. In the case where the end of the active period is notified by in-band information, Node B sets the 1-bit flag of the last packet to YES (yes) in the last packet during the active period. By accepting a packet with the flag of the last packet set to YES, the UE maintains an active period until the packets stored in the HARQ processor are fully processed while the UE detects that the packet is the last and when processing ends, the UE enters standby mode .

2. When the end of the active period is notified via the control channel, the UE maintains the active period until packets that are processed in the HARQ processor are received at the time when the end of the active period is announced and when the reception ends, the UE goes into standby mode.

3. If packets are not received within a predetermined period of time, the UE may go into standby mode, assuming that the active period has been completed.

As described above, in the absence of any packet for admission, the active period is maintained for a minimum duration of the active period. If there is any packet to receive, the end of the active period is signaled by in-band information or out-of-band signal in the control channel, or the end of the active period is determined autonomously by the UE. Thus, when necessary, the active period is set in accordance with a variable duration, thereby ensuring the effective operation of DRX.

Option 1 implementation

As for FIG. 4, when the end of the active period is notified by the flag of the last packet, the UE acts as follows.

At step 405, the UE receives information about the duration of the DRX cycle, information about obtaining the initial position and the minimum duration of the active period during the establishment of the call. Then, the UE prepares for the DRX operation.

At step 410, the UE obtains the start position of the active period based on the extracted start position information, for example, the ID for the UE and the DRX cycle time, and determines whether the start position of the active period has arrived.

If the active period has not yet begun, the UE in step 435 is held in the duty interval until the start position of the active period. The UE is aware that the active period starts the DRX cycle duration after the start position of the previous active period.

When the active period begins, at step 415, the UE activates the timer T (DRX_CYCLE_LENGTH) (DRX cycle time) and the timer T (MINIMUM_ACTIVE) (minimum active period duration). Timer T (DRX_CYCLE_LENGTH) is a timer set to DRX T cycle duration (DRX_CYCLE_LENGTH), and timer T (MINIMUM_ACTIVE) is a timer set to minimum active duration T (MINIMUM_ACTIVE).

At 420, the UE monitors the shared control channel to determine if there is a packet to receive. If there are no packets to receive before the timer T expires (MINIMUM_ACTIVE), at step 435, the UE is put into sleep mode until the next active period begins. The next active period begins after the timer T expires (DRX_CYCLE_LENGTH).

Conversely, if at step 420 there is any packet to receive before the timer T expires (MNIMUM_ACTIVE), at step 425, the UE receives the packet in accordance with the HARQ operation. If the packet is successfully received, at step 430, the UE checks the flag of the last packet of the received packet.

If the flag of the last packet is set to YES, the UE proceeds to step 440. If the flag of the last packet is set to NO, the UE returns to step 425 to continue receiving packets.

At step 440, the UE ends processing HARQ packets stored in the HARQ processor if it detects that the received packet is the last. Then, the UE enters standby mode until the next active period begins. The next active period begins after the timer T expires (DRX_CYCLE_LENGTH).

The completion of the HARQ packet processing means that the packet stored in the HARQ processor is normally received by the HARQ operation, and thus a HARQ ACK confirmation is sent for the packet, or, despite errors in the packet, a new packet is received in the HARQ process, and thus in this way, packet reception is ultimately unsuccessful in the HARQ operation.

That is, when a packet stored in the HARQ processor is received successfully, or the UE determines that successful reception of the packet is not possible, it is considered that the packet is fully processed.

Option 2 implementation

As for FIG. 5, the UE acts in the same manner as in the first embodiment of the present invention, except for the way in which the UE determines the end of the active period. Therefore, the following description is made with respect to steps different from those illustrated in FIG. 4. That is, steps 505-520 of FIG. 5 will not be described since they are performed in the same manner as steps 405-420 of FIG. 4.

At step 525, the UE receives a packet from the Node B in accordance with a predetermined HARQ protocol.

Since the UE continues to receive the downlink control channel, the UE in step 530 monitors the reception of a signal indicating the end of the active period on the downlink control channel.

Upon receiving the signal, the UE proceeds to step 540, and otherwise, the UE returns to step 525 to continue receiving packets.

At step 540, the UE ends processing the HARQ packets present in the HARQ processor at this time if it receives a signal indicating the end of the active period, and enters into standby mode at step 535 until the next active period begins. The next active period begins after the timer T (DRX_CYCLE_LENGTH), activated at step 515, has elapsed.

Option 3 implementation

Referring to FIG. 6, in step 605, the UE receives information about the DRX cycle length, start position information, minimum active period duration and end interval of the active period during call setup. Then, the UE prepares for the DRX operation. The minimum active period may be at the end of the active period interval. In this case, only one of both can be signaled. Then, the UE prepares for the DRX operation.

At step 610, the UE obtains the start position of the active period based on the extracted start position information, for example, the ID for the UE and the DRX cycle duration, and determines whether the start position of the active period has arrived.

If the active period has not yet begun, at step 635, the UE is held in the duty interval until the start position of the active period. The starting position of the active period is derived from the extracted information of the starting position, and the next active period starts the DRX cycle duration after the starting position of the previous active period.

When the active period begins, the UE in step 615 activates the timer T (DRX_CYCLE_LENGTH) and another timer T (MINIMUM_ACTIVE). A timer T (DRX_CYCLE_LENGTH) is a timer set to a duration T (DRX_CYCLE_LENGTH) of a DRX cycle, and a timer T (MINIMUM_ACTIVE) is a timer set to a minimum duration T (MINIMUM_ACTIVE) of the active period.

At step 620, the UE monitors the shared control channel to determine if there is a packet to receive. If packets for reception are not present before the timer T expires (MTNIMUM_ACTIVE), the UE is put into standby mode at step 635 until the next active period begins. The next active period begins when timer T expires (DRX_CYCLE_LENGTH).

Conversely, if at step 620 there is any packet to receive before the timer T expires (MTNIMUM_ACTIVE), the UE at step 625 receives the packet in accordance with the HARQ protocol.

At step 627, the UE starts (or re-starts) the timer T (active_period_end) (end of active period) set to the end interval of the active period T (active_period_end). The timer T (active_period_end) is used to complete the active period if a packet is not received within the time T (active_period_end). The UE starts the timer T (active_period_end), having received the initial packet, and re-starts it whenever the UE receives a subsequent packet.

The subsequent packet may be (1) a new packet or (2) either a new packet or a retransmission packet.

That is, the UE can restart the timer T (active_period_end) only when the next packet is a new packet or when the next packet is either a new packet or a retransmission packet. For the sake of convenience, the first case is called method 1, and the last is method 2.

At step 630, the UE determines whether the timer T (active_period_end) has expired, that is, if a packet was not received within the time T (active_period_end). If the timer T (active_period_end) has expired, the UE proceeds to block 640. If the timer T (active_period_end) is still running, the UE repeats steps 625 and 627.

At step 640, the UE operates in various ways depending on method 1 or method 2.

In method 1, in step 640, the UE ends processing the HARQ packets stored in the HARQ processor after the time has elapsed and enters into standby mode until the next active period begins. The next active period begins after the timer T expires (DRX_CYCLE_LENGTH).

In method 2, the UE enters standby mode without waiting for HARQ packet processing to complete, since the end of the active period interval is set with respect to the reception of any downlink packet, regardless of the new packet or retransmission packet. If the Node B does not retransmit a specific packet within the end of the active period interval, the UE switches to standby mode. Therefore, the Node B and the UE must send and receive a corresponding retransmission version of the packet during the final interval of the active period.

In other words, if the retransmission packet does not arrive at the UE within the end of the active period interval, this means that the Node B refused to transmit the packet, and thus it is not possible for the UE to receive the packet successfully. Therefore, the UE deletes packets stored in the HARQ processor for which retransmission versions were not received, and immediately enters standby mode.

As for FIG. 7, the UE receiver 700 includes a demultiplexer (DEMUX) 705, a HARQ processor 715, a control channel processor 720, a DRX controller 725, and a receiver 730.

The receiver 730 turns on or off under the control of the controller 725 DRX.

The 725 DRX controller turns off the receiver in standby mode and turns it on in the active period. The HARQ processor 715 processes the HARQ packet received from the receiver 730 in accordance with a predetermined HARQ operation and delivers an error-free HARQ packet to the DEMUX 705.

DEMUX 705 checks the flag of the last packet of the received HARQ packet.

If the flag of the last packet is set to YES, the DEMUX 705 reports this to the 725 DRX controller, and also delivers the received packet to a higher level.

After detecting the receipt of a packet with the flag of the last packet set to YES, the DRX controller 725 monitors the state of the HARQ processor 715. If the processing of the HARQ processor 715 is completed, the DRX controller 725 enters standby mode, that is, turns off the receiver 730.

A control channel processor 720 processes information received on a downlink shared control channel. If the end of the active period is signaled by the downlink shared control channel, as in the case of the second embodiment of the present invention described with reference to FIG. 5, the control channel processor 720 provides a report to the DRX controller 725 about the end of the active period.

Then, the controller 725 DRX monitors the state of the processor 715 HARQ.

If the processing of the HARQ processor 715 is completed, the DRX controller 725 enters standby mode, that is, turns off the receiver 730.

When the UE receiver 700 receives the last packet, as in the first embodiment of the present invention, it is preferable, but not necessary, that it enters the standby mode after sending the RLC level ACK signal (RLC ACK signal, for short), rather than immediately entering the standby mode .

This is because in the packet service, the UE operates in RLC with acknowledgment (RLC-AM) using an automatic retransmission request (ARQ) other than HARQ in order to increase the reliability of transmission / reception.

In the ARQ operation, the transmitter inserts the sequence number into the packet before transmission, and the receiver determines if there is any failed packet by checking the sequence number. For a failed packet, the receiver requests a retransmission of the failed packet by sending a negative ACK (NACK) signal to the transmitter. For a successfully received packet, the receiver sends an ACK signal to the transmitter. The ACK signal and the NACK signal are carried in a control message called an RLC level status report.

If a service requiring DRX is provided in the AM RLC, then, having received the last packet, the UE should send an RCL ACK signal for the last packet. Therefore, the UE preferably enters the standby mode after sending the RK ACK signal than immediately enters the standby mode.

Thus, a description will be made of the method of entering the standby mode after sending the RLC ACK signal for the last packet, carried out after receiving the packet with the pointer of the last packet embedded in the packet, in comparison with the first embodiment of the present invention.

The UE in the active period without the presence of packets for receiving acts in the same manner as in the first embodiment of the present invention, and thus, the description of the action of the UE in the active period without packets for receiving is not presented in the document.

As for FIG. 8, the Node B signals the DRX cycle time 810, information for acquiring the starting position 805 of the active period 850 and the minimum active period 840a or 840b.

The UE starts at each of the initial positions 805, 820 and 825 of the active periods 850, 860 and 870. If there is no data to receive, the UE is held for the minimum duration of the active period and enters standby mode. When there is data to receive, the UE maintains an active period until it receives the data completely, and then enters standby mode.

The UE calculates the starting position 805 of the active period 850 in accordance with a predetermined method, for example, according to a modulo operation with respect to the UE ID and DRX cycle duration. When an active interval begins at time 305, the UE is activated.

The durations of active periods 850, 860 and 870 vary from a minimum duration of 840a or 840b to a duration of 810 or 880 DRX cycles. At the initial position 805 of the active period 850, the UE receives a packet on the downlink channel. Numeric numerals 840a and 840b indicate a physically identical minimum active period duration.

As for the active period 860, packets are received sequentially for a minimum duration of the active period 840a. The UE may complete the active period 860 by determining whether each received packet is the last.

For example, the UE starts at the initial position of the active period and monitors the downlink control channel. That is, the downlink control channel and the downlink packets are sent to the UE before the minimum active period duration 840a has ended. The UE receives downlink packets until it receives packet 880 with the nested pointer of the last packet. The pointer of the last packet may be in the form of an RLC level control signal.

The UE in the active period with the presence of packets for receiving acts in different ways in the first and fourth embodiments of the present invention, as set forth below.

When the UE fully receives the packet with the last packet nested flag set to YES, in the first embodiment of the present invention, the UE ends the active period and goes into sleep mode.

In the fourth embodiment of the present invention, when the UE receives the packet with the nested pointer of the last packet and finishes successfully receiving all packets with sequence numbers lower than that of the last packet, the UE sends ACK signals for packets with lower sequence numbers, ends the active period and then enters standby mode.

Although packet numbers are denoted from x to x + n, the RLC module 945 configured for each application in the UE determines whether any RLC level PDUs have been received by checking the sequence numbers of the protocol exchange units (PDUs) of the RLC level. Having received the packet with the last packet indicator, the UE sends an RLC status report 885 on the uplink channel along with the reception status information about the RLC PDUs.

If all RLC PDUs from the [x] RLC PDUs to the [x + n] RLC PDUs have been received, the RLC status report 885 carries ACK signals for RLC level PDU units. After sending the RLC status report 885, the UE ends the active period.

On the other hand, if the PDU [x + m] RLC among the PDUs from the PDU [x] RLC to the RLC [x + n] PDUs has not been received, the UE includes in the RLC status report 885 a NACK signal for the failed RLC PDU. The UE then maintains an active period until the failed RLC PDU is completely retransmitted from the Node B.

As for FIG. 9, in step 905, the UE receives information about the duration of the DRX cycle, information about obtaining the initial position, and the minimum duration of the active period during call setup. Then, the UE prepares for the DRX operation.

At step 910, the UE obtains the starting position of the active period based on the information for obtaining the starting position, for example, the ID for the UE and the duration of the DRX cycle, and determines whether the starting position of the active period has arrived.

If the active period has not yet begun, the UE in step 935 is held in the waiting interval until the start position of the active period. The next active period begins with the DRX cycle duration after the starting position of the active period.

When the active period begins, the UE in step 915 activates the timer T (DRX_CYCLE_LENGTH) and another timer T (MINIMUM_ACTIVE). Timer T (DRX_CYCLE_LENGTH) is a timer set to DRX T cycle duration (DRX_CYCLE_LENGTH), and timer T (MINIMUM_ACTIVE) is a timer set to minimum active duration T (MINIMUM_ACTIVE).

At step 920, the UE monitors the shared control channel to determine if there is a packet to receive. If packets for reception are not present before the timer T (MINIMUM_ACTIVE) has expired, the UE is put into standby mode at step 935 until the next active period begins. The next active period begins when timer T expires (DRX_CYCLE_LENGTH).

Conversely, if at step 920 there is any packet to receive before the timer T (MINIMUM_ACTIVE) expires, the UE at step 925 receives the packet in accordance with the HARQ operation.

If the packet is successfully received, the UE determines whether the received packet is the last, for example, by checking at 1030 the control information embedded in the packet. When sending the last RLC PDU, the RLC transmitter includes in the RLC PDU control information indicating the last RLC PDU. Thus, at 1030, the UE determines the presence or absence of control information indicating the last unit of the RLC PDUs in the received RLC PDU.

If the received packet is not the last, the UE at step 925 continues to receive packets until a packet is received with the presence of control information indicating the last packet.

If the received packet is the last one, the UE, at 940, generates an RLC layer status report representing reception states for the RLC PDUs received so far. The RLC status report contains RLC sequence numbers for failed packets and RLC sequence numbers of received packets. As indicated earlier, of these, the first RLC sequence numbers are called NACK, and the last RLC sequence numbers are called ACK. Therefore, the RLC status report includes NACK and ACK numbers. NACK is the sequence number set of failed packets, and the ACK is the sequence number set of received packets.

If there is no NACK in the RLC status report, the UE checks at step 945 whether the RLC status report includes ACKs for the last RLC PDUs and ACKs for all other RLCs with sequence numbers lower than those for the last RLC PDUs. If the result of the check is YES, the UE proceeds to step 950. If the result of the check is NO, which means there is a packet requiring retransmission, the UE proceeds to step 955.

At step 950, the UE sends an RLC status report and enters into standby mode at step 935 until the next active period begins. The next active period begins when timer T expires (DRX_CYCLE_LENGTH).

At step 955, the UE sends an RLC status report and waits until retransmissions of RLC packets requesting a retransmission in the RLC status report are completed. Then, the UE sends an RLC status report with an ACK for all RLC PDUs with sequence numbers lower than that of the last RLC PDU. At step 935, the UE enters standby mode until the next active period begins.

Referring to FIG. 10, a UE receiver may have a plurality of RLC modules 1035, 1040, and 1045 configured for respective applications. Some of them can be configured to work in DRX mode. For example, RLC module 1045 operates in DRX mode.

When all of the following conditions are met, the RLC module 1045 queries the DRX controller 1025 to complete the active period.

Condition 1: An RLC PDU with a nested pointer of the last packet is received.

Condition 2: all packets received during the active period are successfully received.

Condition 3: An RLC status report with ACKs for all packets received during the active period is sent in full.

Also, the RLC layer module 1045 determines whether there is any failed packet by checking the sequence numbers of the RLC PDUs and generates an RLC status report in accordance with the determination result.

Having received a signal indicating the end of the active period from the RLC module 1045 operating in DRX mode, the DRX controller 1025 terminates the active period and maintains a standby mode until the next active period begins.

A demultiplexer / multiplexer (DEMUX / MUX) 1005 multiplexes RLC PDU units received from the RLC layer, i.e., RLC modules 1035, 1040 and 1045, into media access control layer (MAC) PDU units or demultiplexes the MAC layer PDU received from the HARQ processor 1015, to RLC level PDU units before transmitting to RLC level modules 1035, 1040, and 1045.

The HARQ processor 1015 processes the HARQ packet received from the transceiver 1030 in accordance with a predetermined HARQ operation and delivers an error-free HARQ packet to the DEMUX / MUX 1005. The demultiplexer as part of the DEMUX / MUX 1005 delivers the received HARQ packet to the RLC levels 1035, 1040, and 1045.

Also, the HARQ processor 1015 supplies the MAC layer PDU received from the DEMUX DEMUX / MUX 1005 to the transceiver in accordance with the HARQ operation, and the transceiver 1030 sends the MAC PDU to the Node B.

A control channel processor 1020 processes the received information from the downlink shared control channel. If the information indicates the presence of a packet destined for the UE, the control channel processor 1020 provides a report on the presence of a packet for reception to the DRX controller 1025.

DRX controller 1025 calculates the starting position of the active period and turns on the receiver at the starting position. If the DRX controller 1025 does not receive a report from the control channel processor 1020 indicating the presence of a packet to receive before the minimum active period has elapsed, it ends the active period.

On the other hand, after receiving a report indicating the presence of a packet for reception, the DRX controller 1025 maintains an active period until it receives a signal from the RLC module 1045 indicating the end of the active period.

As is apparent from the above description, the present invention increases the latency for the UE according to the definition of the DRX operation for the connected UE, taking into account the characteristics of services in a future generation mobile communication system. Therefore, the power consumption of the UE is minimized.

For a packet service in which the state of the formation of traffic may change every DRX cycle, setting the duration of the active period in accordance with the requirements of the traffic during reception provides the DRX operation.

Also, the UE enters standby mode after acknowledging successful reception of packets, including retransmission packets, and sending an RLC ACK signal for packets. Therefore, the performance of packet reception is improved.

Although the invention has been shown and described with reference to some examples of the implementation of such, specialists in the art will understand that it can be made various changes in form and detail without going beyond the essence and scope of the present invention defined hereinafter in accordance with the attached the claims and its equivalents.

Claims (22)

1. A method of performing a continuous reception (DRX) operation in a user equipment (UE) in a mobile communication system, comprising the steps of:
receiving information from the Node B about the duration of the DRX cycle, information for obtaining the initial position of the active period, and information about the minimum duration of the active period;
obtaining the starting position of the active period using at least one of the information received and activating the first timer set to the DRX cycle duration and the second timer set to the minimum active period in the starting position of the active period;
monitoring the presence of a downlink packet for a minimum active period;
the transition to standby mode in the absence of a packet downlink for the minimum duration of the active period;
receiving a downlink packet in the presence of a downlink packet, determining whether there is information indicating the end of the reception of the packet, the completion of receiving the packet when there is indicative information, and transition to standby mode; and
the transition from standby to active mode after the expiration of the first timer. 2. The method of claim 1, wherein the indicative information is a flag of the last packet included in the received packet, the flag of the last packet indicating that the packet is the last packet. 3. The method according to claim 1, in which the indicative information is transferred on the control channel downlink. 4. A method for performing a continuous reception (DRX) operation in a user equipment (UE) in a mobile communication system, comprising the steps of:
receiving information from the Node B about the duration of the DRX cycle, information for obtaining the initial position of the active period, information about the minimum duration of the active period and information about the final interval of the active period;
obtaining the starting position of the active period using at least one of the information received and activating the first timer set to the DRX cycle duration and the second timer set to the minimum active period in the starting position of the active period;
monitoring the presence of a downlink packet for a minimum active period;
the transition to standby mode in the absence of a packet downlink for the minimum duration of the active period;
receiving a downlink packet in the presence of a downlink packet, activating a third timer set to a finite interval of the active period;
the transition to standby after the time of the third timer; and
the transition from standby to active mode after the expiration of the first timer. 5. The method according to claim 4, in which the monitoring step comprises the step of monitoring a common control channel for a minimum duration of an active period in order to determine the presence or absence of a downlink packet. 6. The method according to claim 5, further comprising, prior to entering the standby mode, the step of processing downlink packets in accordance with a predetermined HARQ scheme after the time of the third timer. 7. The method according to claim 5, in which the downlink packet is a protocol unit of exchange (PDU) radio link control layer (RLC), further comprising the step of creating a status report of the RLC level for the received packet and sending the status report RLC to the Node B. 8. The method according to claim 7, in which the RLC status report includes a response signal to the automatic retransmission request (ARQ) for the received packet, the method further comprising the step of entering standby mode after transmitting the RLC status report. 9. The method of claim 8, further comprising, prior to entering the standby mode, the step of sending to the Node B a response signal for the retransmission packet. 10. The method according to claim 7, in which the indicative information is RLC control information included in the RLC layer PDU, wherein the RLC control information indicates that the received packet is the last packet. 11. The method according to claim 7, in which the RLC status report includes negative acknowledgment (NACK) for failed packets and ACK acknowledgment for successfully received packets, the negative NACK acknowledgment being a set of sequence numbers of failed packets and ACK acknowledgment are a set of sequence numbers of successfully received packets. 12. A device for performing a continuous reception (DRX) operation in a user equipment (UE) in a mobile communication system, comprising:
DRX controller, in order to: obtain the starting position of the active period using at least one information from information on the DRX cycle duration, information for obtaining the starting position of the active period, and information on the minimum active period received from Node B, activate the first timer set for the duration of the DRX cycle, and the second timer, set to the minimum duration of the active period, in the initial position of the active period, monitor the presence of a downlink packet for the minimum duration of the active period, turn off the transceiver in the absence of a downlink packet for a minimum duration of the active period, and turn on the transceiver in the presence of a downlink packet, receive indicative information indicating the end of packet reception and control the transceiver in accordance with the indicative information ;
a demultiplexer (DEMUX) to determine if the packet has indicative information and report the indicative information to the DRX controller; and
transceiver to turn on or off under the control of the DRX controller. 13. The device according to item 12, in which the indicative information is the flag of the last packet included in the received packet, and the flag of the last packet indicates that the packet is the last packet. 14. The apparatus of claim 12, further comprising a control channel processor for monitoring reception of indicative information on the downlink control channel. 15. The device according to item 12, in which the DRX controller activates a third timer, set at the end of the interval of the active period, signaled from the Node B. 16. The device according to clause 15, further comprising a hybrid automatic retransmission request (HARQ) processor to: monitor the presence of a downlink packet for a minimum active period under the control of a DRX controller, enter standby mode when there is no downlink packet receiving a downlink packet for a finite interval of an active period. 17. The device according to clause 16, in which the DRX controller completes the reception of the HARQ packet after the time of the third timer and simultaneously turns off the transceiver. 18. The device according to item 12, further comprising a plurality of radio link control modules (RLC) corresponding to service applications to generate an RLC status report for the received packet and send an RLC status report to Node B. 19. The apparatus of claim 18, wherein the RLC status report includes an automatic retransmission request (ARQ) response for the received packet, the DRX controller controls one module from a plurality of RLC modules to send an RLC status report to Node B, and turns off the transceiver. 20. The device according to claim 19, in which before turning off the transceiver, the DRX controller controls one of the plurality of RLC modules to send an RLC status report to the UE for the retransmission packet received from the Node B. 21. The apparatus of claim 18, wherein one of the plurality of RLC modules determines whether the received packet is the last packet by checking the RLC control information included in the received packet. 22. The apparatus of claim 18, wherein the RLC status report includes negative acknowledgment (NACK) for failed packets and ACK acknowledgment for successfully received packets, NACK messages are a set of sequence numbers of failed packets, and ACK acknowledgments are a set sequence numbers of successfully received packets.

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