KR20150124693A - A method and an apparatus for sleep operation and wake-up operation of an user equipment providing Multimedia Broadcast Multicast Service - Google Patents

Abstract

Embodiments of the present invention provide a method and device for performing sleep and wake-up operation of a terminal providing a multimedia broadcast multicast service (MBMS). According to an embodiment of the present invention, a method for performing slip and not-sleep operation of a terminal providing an MBMS comprises the steps of: calculating a sleep possible time value corresponding to an interval between time for determining sleep and non-sleep, and wake-up time, according to a sleep mode request in a discontinuous reception (DRX) cycle; comparing the calculated sleep possible time value with a critical time value ensuring minimum sleep according to the characteristics of a terminal; and operating a sleep mode when the calculated sleep possible time value is greater than the critical time value.

Description

[0001] The present invention relates to a method and apparatus for sleep and wake-up operations of a terminal providing a Multimedia Broadcast Multicast Service (MBMS) Service}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a terminal that provides MBMS (Multimedia Broadcast Multicast Service), and more particularly to a technique for operating in a multiple sleep mode when a DRX cycle is interrupted by MBSFN sub- .

Wireless communication systems are widely deployed throughout the world to provide various communication services. Demand for mobile broadband services such as mobile television channels is increasing rapidly. A new technology called MBSFN / eMBMS, with the primary goal of providing wireless broadband services, including mobile television channel access, has been integrated into LTE systems. The prior art is specified in the LTE standard for specifying MBSFN / eMBMS (evolved Multimedia Broadcast and Multicast Service) operation.

In the LTE e-MBMS structure, constituent entities of an EPC (Evolved Packet Core) network are divided into e-BMSCs providing interfaces with e-MBMS content servers and e-MBMS service data To the other e-NBs.

The time synchronization transmission from the various eNBs provides reliable reception of the broadcast data to the terminal and via public coupling. With the use of a single frequency for this transmission, this scheme is called MBSFN. Therefore, this method provides broadcasting of data switching in only one direction. Therefore, the terminals in the service area called in the MBSFN area can receive the same data use broadcast service as the radio resources.

In the LTE system, the channel access time is divided into radio frames of 10 [ms], and the radio frame is divided into 10 subframes of 1 [ms] period. The subframes to be used for broadcast / multicast purposes are called MBSFN subframes. Non-broadcast / multicast purpose subframes (for example, for use in unicast data transmission for point-to-point mode between network and terminal) are referred to as non-MBSFN subframes. However, not all subframes in the system may be used as MBSFN subframes. Here we will define only a few subframes that can be used for broadcast / multicast data transmission.

Now, for the MBSFN, it is possible to configure the network to use only a subset of some of these possible subframes. Therefore, information about the actual subframes for MBSFN use and what is not is dynamic. Information about the subframes and the radio frames designated for the MBSFN is conveyed via "SystemInformationBlockType2", specifically called MBSFN "Subframe Config List".

The two logical channels (MCCH for delivery of control information and MTCH for delivery of eMBMS data packets) are defined in LTE for MBSFN activity. These logical channels are all mapped to a single transport channel, which means multicast / broadcast traffic MCH. The MCH is mapped to an MBSFN specific physical channel called a PMCH.

The terminal needs additional information to know the presence of the MCCH and the settings required to obtain the same. This information is provided to the terminal in a separate system information block, which is made exclusively for eMBMS " SIB-13 ". The SIB-13 transmits all information about the MBSFN area set in the base station (eNB). In the request from the upper layer, the RRC requests the SIB-13 and judges the presence or absence of the requested MBSFN area information. If the information is present, the terminal will further attempt to obtain MCCH information of such MBSFN area.

The MCCH transmits a single message or " MBSFN Area Configuration " message indicating the radio resource configuration and ongoing eMBMS sessions. The eMBMS control information MCCH is periodically transmitted. Similar to the system information messages, the MCCH is associated with a repetition period, a change period, and a change notification period.

User services, including streaming and download application services, are mapped to MTCH logical channels. The scheduling of these services is controlled by the network and dynamically notified to the terminals. For this purpose, the assignment of MBSFN subframes of a PMCH channel to other services (MTCHs) in a defined time period called MCH Scheduling Period (MSP) is informed by a control PDU called MCH Scheduling Information (MSI). The MSI is always received in the first subframe of the MSP.

Each MTCH channel of the MSI PDU is identified by the logical channel ID provided in the MSI PDU itself. Therefore, with the MSI PDU reception state, the UE can know the start and end of the sub-frames of the MTCH channels scheduled for a given PMCH. Because decoding is performed at the PHY, the MAC needs to decode, analyze, decouple, and forward the scheduling information associated with the appropriate MTCH channels to the PHY. The scheduling information is immediately applied after receiving the MSI PDU. That is, the first MTCH channel data can be initially scheduled from the same subframe in which the MSI PDU was received. In particular, MBSFN services can receive both idle and connected modes.

For power saving purposes, LTE systems use DRX operation. The DRX operation differs somewhat in the idle mode and the connected mode.

In the standby mode, the terminal periodically sets the cycle of the wakeup period and the sleep period based on the paging cycle broadcasted by the system information terminal. During wakeup, the terminal checks the paging messages and finds out what messages are intended for it. If such a message is displayed, it handles the required processing operation. Otherwise, the terminal returns to the sleep mode. This method provides optimum power savings during sleep mode in which the RF circuitry and processing are terminated.

In the connected mode, the DRX operation is performed during the waiting period. For this purpose, the terminal may use some timers (e.g., inactivity timer, on-duration timer, RTT (Round Trip Time) timer) and some triggers The DRX command of the DRM command). The network also maintains synchronization with the terminal connection mode DRX period.

Broadcast MBSFN service data is available at any point in time. Along with the original broadcast of the data, it has no consideration for the DRX cycle of the terminal. Therefore, the DRX operation is subjected to a severe collision. Besides,

Since the MBSFN is a multi-transmission scheme in a unidirectional point, the network has no way of knowing which eMBMS service data is received by the terminal and when the terminal wakes up for this purpose. This is also true in connected mode. This is especially because it does not support uplink transmission for MBSFN operation.

The prior art does not provide a technique for power saving in terms of MBSFN operation. In addition, MBSFN interactions including the DRX procedure are completely intact. Under this situation, the terminal needs to fully wake up for the MBSFN operation, or if the terminal applies a generic DRX scheme, it has to bear the MBSFN data loss.

Disclosure of Invention Technical Problem [8] The present invention provides a method and apparatus for sleep and non-sleep operations of a terminal that provides an MBMS service for reducing power consumption by efficiently performing operations by DRX in a terminal providing an MBMS service will be.

According to an aspect of the present invention, there is provided a method of sleeping and waking up a terminal that provides a multimedia broadcast multicast service (MBMS) Calculating a sleep time value corresponding to a time between a sleep and a wake-up time for a sleep and a non-sleep decision according to a sleep mode request in a cycle; Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic; And operating in a sleep mode if the calculated sleepable time value is greater than the threshold time value.

According to another aspect of the present invention, there is provided a method of sleeping and waking up a terminal providing an MBMS service, the method comprising: receiving a sleep mode request in a DRX (Discontinuous Reception) Calculating a sleep time value corresponding to a time between a sleep and a sleep-up time and a wake-up time according to the sleep time; Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic; If the calculated sleepable time value is greater than the threshold time value, scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes is confirmed and a time value of a start frame and a last frame of the MBSFN subframes And operating in the sleep mode or the non-sleep mode through comparison of the threshold time value with the threshold time value.

According to another aspect of the present invention, there is provided a method of sleeping and waking up a terminal providing an MBMS service, the method comprising: receiving a sleep mode request in a DRX (Discontinuous Reception) Calculating a sleep time value corresponding to a time between a sleep and a sleep-up time and a wake-up time according to the sleep time; Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic; If the calculated sleepable time value is greater than the threshold time value, confirming scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes and comparing the time values for each of the scheduled MBSFN subframes with the time- And operating in the sleep mode or the non-sleep mode through comparison of time values.

According to another aspect of the present invention, there is provided an apparatus for providing a sleep and wake-up operation of an MBMS service terminal, the apparatus comprising: A first time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a sleep-up time and a wake-up time according to the sleep time; A first time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics; And a first sleep operation controller for controlling operation in a sleep mode if the calculated sleep time value is greater than the threshold time value.

According to another aspect of the present invention, there is provided an apparatus for providing a sleep and wake-up operation of an MBMS service terminal, the apparatus comprising: A second time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a sleep-up time and a wake-up time according to the sleep time; A second time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring a minimum sleep according to the terminal characteristics; And checking the scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes, if the calculated sleepable time value is greater than the threshold time value, determining a time of a start frame and a last frame of the MBSFN subframes And a second sleep operation controller for controlling the sleep mode or the non-sleep mode to be performed by comparing the values with the threshold time value.

According to another aspect of the present invention, there is provided an apparatus for providing a sleep and wake-up operation of an MBMS service terminal, the apparatus comprising: A third time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a sleep-up time and a wake-up time according to the sleep time; A third time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics; And scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes, if the calculated sleepable time value is greater than the threshold time value, and comparing the time values for each of the scheduled MBSFN subframes with And a third sleep operation controller for controlling operation in the sleep mode or the non-sleep mode through comparison of the threshold time values.

According to the present invention, in a terminal providing an MBMS service, power loss can be effectively implemented in a terminal by minimizing data loss of an MBSFN subframe due to MBMS service provision and streamlining operations by DRX.

BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, wherein like reference numerals designate identical parts.
FIG. 1 is a block diagram illustrating a structure of a terminal providing an MBMS service.
Figure 2 is an exemplary illustration of a first method for determining slip and non-slip decisions.
3 is a flowchart of one embodiment for explaining a first method for slip and non-slip decisions.
Figure 4 is an example of a reference diagram for illustrating a second method for slip and non-slip decisions.
5 is a flowchart of an embodiment for explaining a second method for slip and non-sleep determination.
Figure 6 is an example diagram of a third method for determining slip and non-slip decisions.
7 is a flowchart of an embodiment for explaining a third method for slip and non-slip determination.
FIG. 8 is a flowchart illustrating a method of operating a sleep and a wake-up operation of a terminal providing an MBMS service according to an embodiment of the present invention.
FIG. 9 is a flowchart of another embodiment of a sleep and wake-up operation method of a terminal providing MBMS according to the present invention.
FIG. 10 is a flowchart of another embodiment of a sleep and non-sleep operation method of a terminal providing MBMS according to the present invention.
11 is a block diagram of an embodiment for explaining a sleep and wake-up operation device of a terminal providing MBMS according to the present invention.
12 is a block diagram of another embodiment for explaining a sleep and wake-up operation device of a terminal providing MBMS according to the present invention.
FIG. 13 is a block diagram of another embodiment for explaining a sleep and wake-up operation device of a terminal providing MBMS according to the present invention.

1 to 13, which are used to describe the principles of the present invention in this patent specification, are for illustrative purposes only and are not to be construed as limiting the scope of the invention. Those skilled in the art will appreciate that the principles of the present invention may be implemented in any wireless communication system in which it is properly arranged.

The present invention aims at a method and apparatus for applying DRX sleep patterns considering MBSFN receiving subframes by presenting a plan for DRX operation in a connected mode and a standby mode. The present invention provides a new scheme for performing the DRX operation of the MBSFN available in the UE.

FIG. 1 is a block diagram illustrating a structure of a terminal providing an MBMS service. As shown in Fig. 1, a module called " MBSFN controller " for controlling the setting and operation of the MBSFN receiving function and a module called " DRX controller " for controlling the DRX operation in the terminal are considered. The DRX controller interacts between the PHY and the RF module to determine sleep and wakeup operations. 1 illustrates a structure for an LTE terminal supporting an MBSFN / eMBMS, the arrangement of modules and functions is merely intended to illustrate the purpose and is not limited to the specific example shown.

The MBSFN controller interacts with the DRX controller to manipulate the DRX interval by identifying the location of MBSFN subframes between the two paging occasions. The presence of MBSFN subframes located within the DRX period is determined based on various inputs received from other modules.

In receiving the MSI PDU information, the " MBSFN Scheduler " block sends information corresponding to the location of the MBSFN subframes located between the two MCH scheduling periods to the MBSFN controller. The next MSI specifies the location of the scheduled subframes.

The MBSFN controller uses this information with the MCCH modulation period, change notification period. The available MCCH reception period information from the system information is stored in the MBSFN controller in order to recognize all the subframes lying between paging. This information is also known to the DRX controller. Before going to the sleep operation, the DRX controller must consider these subframes and calculate and determine this during the sleep period.

The present invention provides several approaches for operation when the DRX cycle is ignored by MBSFN subframes. This also takes into account the "minimum threshold sleep duration" indicated by "Tx", which is based on a hardware constraint requirement for switching operation between sleep and wakeup by RF and other circuitry.

In the discussion below, the phrase " Decision to sleep / No-sleep " refers to the point at which the DRX controller module determines the sleep. In idle mode, the decisions are made by all paging cycles after the scheduled search / measurement operation is completed. In Connected mode operation, this is activated when all active DRX timers (on-duration timer, RRT timer, inactivity timer) have expired.

Decision to sleep / No-sleep The first method for this is as follows. Figure 2 is an exemplary illustration of a first method for determining slip and non-slip decisions.

As shown in FIG. 2, when at least one MBSFN subframe conforming to the active eMBMS service or the control information suitable for the terminal is found between the general sleep and wakeup periods, the terminal DRX operation is stopped and the wakeup state itself Avoid slip by maintaining. MBSFN reception is performed in the scheduled subframes. When this confirmation fails, the terminal performs a normal DRX operation. This choice provides an overly simplified execution approach. The flowchart of FIG. 6 shows a better method plan.

3 is a flowchart of one embodiment for explaining a first method for slip and non-slip decisions.

Upon receipt of the sleep request, the DRX module calculates the possible sleep time 'Ts'. To this end, the UE calculates a DRX end-SFN and a TTI, and determines Ts corresponding to a period between the current SFN and the TTI and the calculated DRX end-SFN and TTI. In normal operation, if 'Ts' is greater than the minimum sleep period 'Tx' based on hardware constraints, a sleep command occurs. However, if MBSFN is set, it is checked whether there is an MBSFN subframe (frame in which user service or related control information exists) between the DRX end-SFN & TTI and the current SFN & TTI at which the sleep command is generated. If this acknowledgment is affirmative, the UE remains awake for this calculated DRX Sleep Time (Ts) and the UE will avoid sleeping to receive MBSFN content. This method applies to all DRX cycles.

Decision to sleep / No-sleep The second method for this is as follows. Figure 4 is an example of a reference diagram for illustrating a second method for slip and non-slip decisions.

As shown in FIG. 4, in the Tx based on the minimum hardware limit, the UE takes a sleep state for a period until the first related MBSFN subframe is not observed. Thereafter, the UE remains in the wake up state until the last MBSFN subframe. Thereafter, the terminal again determines again whether to go to sleep after reading the last MBSFN subframe depending on the sleep time probability and Tx. The advantage of this processing method depends on the periodicity of the MBSFN subframes. Frequent repetition of RF toggling is avoided and significant power savings are achieved by DRX operation.

5 is a flowchart of an embodiment for explaining a second method for slip and non-sleep determination.

Upon receipt of the sleep request, the DRX module calculates a sleep time 'Ts' based on the DRX end-SFN & TTI. In normal operation, if 'Ts' is greater than 'Tx', a sleep command is generated. However, if MBSFN is set, the UE checks whether there is any MBSFN subframe (a frame in which the user's service or related control information is placed) between the DRX end SFN & TTI and the SFN & TTI when a sleep command is generated . If it exists, the terminal calculates the position of the first MBSFN subframe and the last MBSFN subframe. If the time period after the first MBSFN subframe T1 occurs is greater than Tx, the UE enters the sleep mode and then switches to the wakeup mode before receiving the first MBSFN subframe. The UE will keep waking up until the last MBSFN sub-frame T2 is read. The MBSFN reception is performed in the scheduled subframes. Thereafter, it is checked whether the time period for generation of the DRX end-SFN & TTI is sufficient for the sleep operation, and if the remaining time is allowed, the terminal performs the sleep operation again.

Decision to sleep / No-sleep The third method for this is as follows. Figure 6 is an example diagram of a third method for determining slip and non-slip decisions.

As shown in FIG. 6, the UE can spoof multiple times between scheduled MBSFN subframes for the UE. Slip or non-slip crystals take into account the minimum slip duration criterion. In two MBSFN subframes placed between DRX sleep periods, if the time difference is greater than the " minimum DRX sleep period ", the UE performs a sleep operation between two MBSFN subframes. In the opposite case, the UE skips the sleep and continues normal operation (e.g., PDCCH (Physical Downlink Control Channel) monitoring). By carefully setting the "minimum DRX sleep period", this scheme provides optimal power saving benefits.

7 is a flowchart of an embodiment for explaining a third method for slip and non-slip determination. The terminal determines the time period for generation of the first MBSFN sub-frame from the DRX start-SFN & TTI and compares it with Tx. If this period is greater than Tx, slip is performed. Repeatedly, this is done for each set of consecutive MBSFN subframes scheduled for the terminal. Finally, the time interval between the DRX end-SFN and the TTI and the occurrence of the last MBSFN subframe are compared to Tx, and a sleep decision is made accordingly. The UE receives the MBSFN data in the scheduled subframes.

As an improvement of the third method, the set of consecutive MBSFNs scheduled for the terminal corresponds to the start and end MTCH subframes of the active services of the terminal. This start and end MTCH subframe information is determined from the MSI PDU information received in the network. This approach leads to efficient computation and optimization because each service is like having continuous MBSFN subframes allocated to MBSFN subframe data.

The above three methods can be applied according to the number of active services of the terminal system. The three methods can be dynamically determined in each DRX cycle. When there is no scheduled active service, the terminal takes the third method to receive control information with notification information and only multiple interrupts. However, when there is one active service for the terminal, it takes a second method of providing a single interruption in the DRX cycle. There are four or fewer active services with the terminal and if the active services are scheduled with consecutive local identities (LC Ids) (and therefore scheduled on a continuous basis), the second method . However, if the scheduled local identities (LC Ids) are not contiguous (time scheduling is not contiguous), the terminal performs the third method. On the other hand, if the number of scheduled active services is greater than four, the first method is executed so as not to have a sleep in the DRX cycle.

In another aspect, the present invention provides a method for performing DRX operation in a connected mode. If DRX operation is specified in connection mode by DSP (Digital Signal Proc- cessing) / DRX, the MBSFN controller considers occurrences of MBSFN subframes in a specified short or long DRX cycle, which modifies the sleep operation accordingly.

In particular, the MSBFN controller does not interrupt DRX operation in the connection mode, but slightly interrupts the DRX period within the MBSFN receiving subframes. Short or long DRX cycles and DRX timer operation are not affected. As a result, the sleep operation or power savings do not have a drastic effect on the proposed processing method. This processing method can be similar to the discussion in previous methods of non-slip. Along with the sleep period in the connected mode, the single interruption and the multiple interrupts of the sleep period for the standby mode are applied as a short or long DRX cycle.

In another aspect, when the UE is in the connection mode and is receiving the MBSFN service, and in the reception state of the MAC CE for DRX, the UE discards the DRX command message if the MBSFN service reception state is active.

In yet another aspect, the present invention provides a method for a terminal in a connected mode to inform a network of a control message using a unicast uplink channel, when an event occurs or periodically, for an MBSFN reception state. For example, this message may be placed as a reserved bit in a new MAC Control Element (CE) or MAC PDU. This information provides the network status of the ON / OFF period of MBSFN reception of the terminal, and this information also establishes a network of synchronization of the terminal's connection mode DRX periods. As a result, the network avoids the DRX command to the terminal when the MBSFN reception is turned on, and sends a DRX command to the terminal when the MBSFN reception is turned off. As an alternative approach, this allows the network to be aware of the MBSFN capabilities and reception status of the terminal and to provide better scheduling considering this factor.

FIG. 8 is a flowchart illustrating a method of operating a sleep and a wake-up operation of a terminal providing an MBMS service according to an embodiment of the present invention.

It is determined whether there is a request for a sleep mode in a DRX (Discontinuous Reception) cycle (S100).

In step S100, if there is a request for the sleep mode, a sleep time value Ts corresponding to a time between sleep and non-sleep determination and a wake-up time is calculated (S102). For example, as shown in FIG. 2, a time between a decision to sleep / no sleep time and a normal wakeup time corresponds to a sleep enable time value Ts .

After step S102, the calculated sleep time value Ts is compared with a threshold time value Tx for guaranteeing minimum sleep according to the terminal characteristics (S104). The threshold time value Tx for guaranteeing the minimum sleep is a minimum time value for allowing the terminal to operate in the sleep mode only when the time when the MBSFN (Multicast Broadcast Single Frequency Network) subframe is not received exceeds the threshold time value it means. The threshold time value Tx is set in advance and can be changed as needed.

If it is determined in step S104 that the calculated sleepable time value Ts is greater than the threshold time value Tx, the sleep mode is operated (S106). The sleepable time value Ts is greater than the threshold time value Tx when the terminal does not receive the MBSFN subframe for a time equal to or greater than the threshold time value and thus determines to switch to the sleep mode, .

After step S106, scheduling of the MBSFN sub-frame between the start time of the sleep mode and the wake-up time is confirmed (S108). For example, as shown in FIG. 2, when the MBSFN subframe exists between the sleep and non-sleep decision time corresponding to the start time of the sleep mode and a wake-up time, It is judged whether or not there is a scheduling for

In step S108, if there is no MBSFN sub-frame scheduled between the start time of the sleep mode and the wake-up time, it is determined whether a wake-up time of the DRX cycle has arrived (S110). The sleep mode is maintained without switching to the non-sleep mode due to the absence of the scheduled MBSFN sub-frame between the start time of the sleep mode and the wake-up time, thereby reducing the power consumption of the UE , The state of this sleep mode continues until the wake-up time of the DRX cycle arrives. Therefore, if the wake-up time of the DRX cycle has not come, the process goes back to step S106 to repeat the above-described process. If the wake-up time of the DRX cycle comes, the above-described process is terminated.

However, if the MBSFN subframe scheduled between the start time of the sleep mode and the wakeup time exists, the non-sleep mode operates in step S108. The existence of the MBSFN subframe scheduled between the start time of the sleep mode and the wakeup time means that the UE should no longer operate in the sleep mode. Therefore, the UE determines the non-sleep mode, . According to the operation in the non-sleep mode, a scheduled MBSFN subframe is received.

On the other hand, if it is determined in step S104 that the calculated sleep time value is not greater than the threshold time value, the process proceeds to step S112 and operates in a non-sleep mode. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, Quot; < / RTI > Therefore, at this time, the non-sleep mode is decided rather than the iterative switching to the sleep mode and the non-sleep mode, so that the mobile station can maintain the active state in which the mobile station can continuously receive the MBSFN subframe.

After step < RTI ID = 0.0 > S112, < / RTI > the process proceeds to step S110 to determine whether the wake-up time of the DRX cycle has arrived. Therefore, if the wake-up time of the DRX cycle has not come, the process goes back to step S106 to repeat the above-described process. If the wake-up time of the DRX cycle comes, the above-described process is terminated.

FIG. 9 is a flowchart of another embodiment of a sleep and wake-up operation method of a terminal providing MBMS according to the present invention.

It is determined whether there is a request for a sleep mode in a DRX (Discontinuous Reception) cycle (S200).

In step S200, if there is a request for the sleep mode, a sleep time value Ts corresponding to a time between a sleep and a sleep-up time and a wake-up time is calculated (S202). For example, as shown in FIG. 4, the time between the decision to sleep / no sleep time and the normal wakeup time corresponds to the sleep enable time value Ts .

After step S202, the calculated sleep time value Ts is compared with a threshold time value Tx for guaranteeing minimum sleep according to the terminal characteristics (S204). The threshold time value Tx is set in advance and can be changed as needed.

If the calculated sleepable time value Ts is greater than the threshold time value Tx in step S204, the start time value of the start frame of the scheduled MBSFN subframe and the last time value of the last frame are calculated (S206). For example, as shown in FIG. 4, a start time value T1 corresponding to the start frame of the MBSFN subframe and a last time value T2 corresponding to the last frame are calculated.

After step S206, it is determined whether the start time value is greater than the threshold time value (S208). For example, as shown in FIG. 4, a start time value T1 corresponding to a start frame of an MBSFN subframe is compared with a threshold time value Tx.

In step S208, if the start time value is greater than the threshold time value, the mobile terminal operates in the sleep mode by the start time value (S210). For example, as shown in FIG. 4, the fact that the start time value T1 corresponding to the start frame of the MBSFN subframe is larger than the threshold time value Tx means that the first MBSFN sub- The reception time of the frame is larger than the threshold time value. Therefore, in order to reduce the power consumption of the UE, the UE operates in the sleep mode by the time value T1 corresponding to the start frame of the MBSFN subframe.

After the operation of the sleep mode corresponding to the start time value corresponding to the start frame of the MBSFN sub-frame is performed after step S210, the non-sleep mode is operated by the time value obtained by subtracting the start time value from the last time value S212). For example, as shown in FIG. 4, a time obtained by subtracting the start time value (T1) from the last time value (T2) corresponding to the last frame of the MBSFN subframe is operated in the non-sleep mode. That is, in step S212, the terminal is operated in the non-sleep mode until the last frame of the MBSFN subframe is received.

If it is determined in step S208 that the start time value of the BSFN subframe is not greater than the threshold time value, a decision to sleep / no-sleep decision time (T2) may be made at the last time value T2 corresponding to the last frame of the MBSFN subframe sleep mode by a time obtained by subtracting the time value corresponding to the sleep time. The value of the start time value of the MBSFN subframe is not greater than the threshold time value means a state in which the UE must transition to the non-sleep mode again after a short period of transition to the sleep mode. Therefore, in this case, rather than repeatedly switching from the sleep mode to the non-sleep mode, the state of the non-sleep mode in which the MBSFN subframe can be continuously received after the decision to sleep / no sleep time .

After the step S212, a comparison is made as to whether the time value obtained by subtracting the last time value from the slip time value is larger than the threshold time value (S214). 4, the time value Ts-T2 obtained by subtracting the last time value T2 corresponding to the last frame of the MBSFN subframe from the sleepable time value Ts is smaller than the threshold time value Tx, for example, .

If the time value obtained by subtracting the last time value from the sleepable time value is greater than the threshold time value in step S214, the sleep mode is operated in the sleep mode by a time value obtained by subtracting the last time value from the sleepable time value (S216). 4, the time value Ts-T2 obtained by subtracting the last time value T2 corresponding to the last frame of the MBSFN subframe from the sleepable time value Ts is smaller than the threshold time value Tx, for example, Is greater than a minimum time value for reducing power consumption of the UE. The sleep mode operation is performed from the time corresponding to the last frame of the MBSFN sub-frame to the wake-up time.

After step S216, it is determined whether a wake-up time of the DRX cycle has come (S218). The state of the sleep mode in step S216 is continued until the wake-up time of the DRX cycle comes. Therefore, if the wake-up time of the DRX cycle has not come, the process goes back to the step S2166 to repeat the above-mentioned process. If the wake-up time of the DRX cycle comes, the above-described process is terminated.

However, if the time value obtained by subtracting the last time value from the slip enable time value is not greater than the threshold time value in step S214, the non-sleep mode operation is performed (S220). For example, if the time value Ts-T2 obtained by subtracting the last time value T2 corresponding to the last frame of the MBSFN sub-frame from the sleepable time value Ts is not greater than the threshold time value Tx, It means that the system must be switched to the non-sleep mode again in a short time. Therefore, at this time, the non-sleep mode operation is performed rather than the iterative switching to the sleep mode and the non-sleep mode.

On the other hand, if it is determined in step S204 that the calculated sleep time value is not greater than the threshold time value, the flow advances to step S220 to operate in the non-sleep mode. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, And therefore, the non-sleep mode operation is performed.

After step S220, the flow advances to step S218 to determine whether the wake-up time of the DRX cycle has come. If the wake-up time of the DRX cycle has come, the above-described process is terminated.

FIG. 10 is a flowchart of another embodiment of a sleep and wake-up operation method of a terminal providing an MBMS according to the present invention.

It is determined whether there is a request for a sleep mode in a DRX (Discontinuous Reception) cycle (S300).

In step S300, if there is a request for the sleep mode, a sleep time value Ts corresponding to a time between a sleep and a sleep-up time and a wake-up time is calculated (S302). For example, as shown in FIG. 6, the time between the decision to sleep / no sleep time and the normal wakeup time corresponds to the sleep enable time value Ts .

After step S302, the calculated sleep time value Ts is compared with a threshold time value Tx for guaranteeing minimum sleep according to the terminal characteristics (S304). The threshold time value Tx is set in advance and can be changed as needed.

If the calculated sleepable time value Ts is greater than the threshold time value Tx in step S304, the time value for the sleep and non-sleep determination time is set to zero Time value and a time value of the wakeup time is a time value of an (n + 1) th (where n is a positive integer greater than 1) time value of the wakeup time, the first to n < th > Time values are calculated (S306). For example, as shown in FIG. 6, when a 0th time value is Ta and an n + 1 time value is Tb, a first time value T1 as time values for each of the MBSFN subframes, To the n-th time value Tn.

After step S306, it is determined whether the difference between the i-th time value (where i is a positive integer equal to or smaller than n + 1) and the i-1 time value is greater than the threshold time value (S308). For example, when i = 1, it is determined whether the difference between the first time value and the 0th time value, that is, the value of T1-Ta is larger than the threshold time value Tx. Also, when i = 2, it is determined whether the difference between the second time value and the first time value, that is, the value of T2-T1 is greater than the threshold time value Tx. Also, when i = n, it is determined whether the difference between the n-th time value and the (n-1) -th time value, that is, the value of Tn-Tn-1 is larger than the threshold time value Tx.

If the difference between the i-th time value and the i-1 time value is greater than the threshold time value in step S308, the controller operates in a sleep mode by a time value corresponding to a difference between the i-th time value and the i- (S310). The fact that the difference between the i-th time value and the i-1 time value is larger than the threshold time value (Tx) means that the reception time of the MBSFN subframe in the DRX cycle is greater than the threshold time value. Therefore, in order to reduce the power consumption of the UE, the sleep mode operation is performed for a time corresponding to the difference between the i-th time value and the i-1 time value. For example, when i = 1, a sleep mode operation is performed for a time value of T1-Ta, and when i = 2, a sleep mode operation is performed for a time value of T2-T1 do. Also, when i = n, the sleep mode operation is performed for the time value of Tn - Tn-1.

After step S310, the non-sleep mode is operated during a period of the MBSFN subframe corresponding to the i-th time value (S312). For example, as shown in FIG. 6, the non-sleep mode operation is performed during a period of the MBSFN subframe 1 corresponding to the first time value T1, and the non-sleep mode operation is performed during the MBSFN subframe 1 corresponding to the second time value T2. 2, and performs a non-sleep mode operation during the interval of the MBSFN sub-frame n corresponding to the n-th time value Tn.

If the difference between the i-th time value and the i-1 time value is not greater than the threshold time value in step S308, the time corresponding to the difference between the i-th time value and the i- Mode. The difference between the i-th time value and the (i-1) th time value is not greater than the threshold time value means a state in which the terminal must be switched to the non-sleep mode again in a short time even if the terminal is switched to the sleep mode. Therefore, at this time, it is possible to maintain the state of the non-sleep mode rather than the repeated switching to the sleep mode and the non-sleep mode.

After step S312, it is determined whether the i-th time value corresponds to the (n + 1) th time value at step S314. If the i-th time value does not correspond to the (n + 1) -th time value, the process proceeds to step S308 and repeats the above-described process.

If the i-th time value corresponds to the (n + 1) th time value in step S314, it is determined whether the difference between the (n + 1) th time value and the nth time value is greater than the threshold time value in step S316. For example, as shown in FIG. 6, when the n + 1 time value is Tb and the nth time value is Tn, it is judged whether or not the value of Tb-Tn is larger than Tx corresponding to the threshold time value do.

If the difference between the (n + 1) -th time value and the n-th time value is greater than the threshold time value in step S316, the apparatus operates in a sleep mode by a time value corresponding to a difference between the (n + (S318). If the difference between the n + 1 time value and the nth time value is greater than the threshold time value (Tx), in order to reduce the power consumption of the UE, a time corresponding to the difference between the (n + 1) The sleep mode operation is performed.

After step S318, it is determined whether the wake-up time of the DRX cycle has come (S320). The state of the sleep mode in step S318 is continued until the wake-up time of the DRX cycle comes. Therefore, if the wake-up time of the DRX cycle has not come, the process goes back to step S318 to repeat the above-mentioned process. If the wake-up time of the DRX cycle comes, the above-described process is terminated.

However, if the difference between the (n + 1) -th time value and the n-th time value is not greater than the threshold time value in step S316, the non-sleep mode operation is performed in step S322. For example, the time value Tb-Tn obtained by subtracting the Tn corresponding to the n-th time value from the Tb corresponding to the (n + 1) -th time value is not larger than the threshold time value Tx means that even if the terminal is switched to the sleep mode It means a state in which the non-sleep mode should be switched again. Therefore, at this time, the non-sleep mode operation is performed rather than the iterative switching to the sleep mode and the non-sleep mode.

On the other hand, if it is determined in step S304 that the calculated sleep time value is not greater than the threshold time value, the flow advances to step S322 to operate in the non-sleep mode. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, And therefore, the non-sleep mode operation is performed.

After step S322, the flow advances to step S320 to determine whether or not the wake-up time of the DRX cycle has arrived. If the wake-up time of the DRX cycle has come, the above-described process is terminated.

11 is a block diagram of an apparatus 400 for explaining a sleep and wake-up operation apparatus of a terminal providing MBMS according to an embodiment of the present invention. The apparatus includes a first time value calculator 410 A first time value comparator 420 and a first sleep operation controller 430.

The first time value calculator 410 calculates a first time value between a time for a sleep and a sleep-up decision and a wake-up time according to a sleep mode request in a DRX (Discontinuous Reception) And transmits the calculated result to the first time value comparator 420 and the first sleep operation controller 430. The first time value comparator 420 and the first sleep operation controller 430 calculate the sleep time value.

The first time value comparator 420 compares the calculated sleep time value with a threshold time value for guaranteeing minimum sleep according to the terminal characteristics and transmits the comparison result to the first sleep operation controller 430. The threshold time value Tx for guaranteeing the minimum sleep is a minimum time value for allowing the terminal to operate in the sleep mode only when the time when the MBSFN (Multicast Broadcast Single Frequency Network) subframe is not received exceeds the threshold time value it means. The first time value comparator 420 stores the threshold time value Tx in a predetermined memory space.

The first sleep operation control unit 430 controls the sleep mode to operate in the sleep mode if the calculated sleep time value is greater than the threshold time value. The sleep time value Ts is greater than the threshold time value Tx when the UE does not receive the MBSFN subframe for a time equal to or greater than the threshold time value. And performs a sleep mode operation.

The first sleep operation control unit 430 confirms the scheduling of the MBSFN (Multicast Broadcast Single Frequency Network) subframe between the start time of the sleep mode and the wake-up time, And if the MBSFN subframe scheduled between the wakeup time and the wakeup time exists, controls to operate in the non-sleep mode.

The first sleep operation control unit 430 may perform scheduling for the MBSFN subframe between the sleep and non-sleep decision times corresponding to the start time of the sleep mode and a wake-up time It is judged whether or not it exists. The first sleep operation control unit 430 may reduce the power consumption of the UE if the MBSFN subframe scheduled between the start time of the sleep mode and the wakeup time does not exist, And continues until the wake-up time of the DRX cycle arrives. If the wake-up time of the DRX cycle has come, the first sleep operation control unit 430 ends the above-described process.

Also, the first sleep operation control unit 430 controls the non-sleep mode operation if the MBSFN subframe scheduled between the start time of the sleep mode and the wakeup time exists. The presence of the MBSFN sub-frame scheduled between the start time of the sleep mode and the wake-up time indicates that the UE should no longer operate in the sleep mode. Therefore, the first sleep operation control unit 430 sets the non- And performs non-sleep mode operation. According to the operation in the non-sleep mode, a scheduled MBSFN subframe can be received.

Also, the first sleep operation control unit 430 controls the non-sleep mode to operate if the calculated sleep time value is not greater than the threshold time value. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, Quot; < / RTI > Therefore, the first sleep operation control unit 430 determines the non-sleep mode rather than the iterative switching to the sleep mode and the non-sleep mode, and maintains the non-sleep mode state in which the UE continuously receives the MBSFN sub-frame .

FIG. 12 is a block diagram of another embodiment 500 for explaining a sleep and wake-up operation apparatus of a terminal providing MBMS according to the present invention. The second time value calculation unit 510, a second time value comparator 520, and a second sleep operation controller 530.

The second time value calculator 510 calculates a sleep time corresponding to a time between the sleep and non-sleep determination and the wake-up time according to the sleep mode request in the DRX cycle And transmits the calculated result to the second time value comparator 520 and the second sleep operation controller 530. [

Also, the second time value calculator 510 calculates the start time value of the start frame of the MBSFN sub-frame and the last time value of the last frame of the scheduled MBSFN sub-frame. For example, as shown in FIG. 4, the second time value calculator 510 may calculate a start time value T1 corresponding to the start frame of the MBSFN subframe, a last time value T2 corresponding to the last frame, To the second time value comparator 520 and the second sleep operation controller 530. [

The second time value comparator 520 compares the calculated sleep time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics and transmits the comparison result to the second sleep operation controller 530. [ The second time value comparator 520 stores the threshold time value Tx in a predetermined memory space.

Also, the second time value comparator 520 compares the start time value with the threshold time value. For example, as shown in FIG. 4, the second time value comparator 520 compares the start time value T1 and the threshold time value Tx corresponding to the start frame of the MBSFN subframe.

The second time value comparator 520 compares the time value obtained by subtracting the last time value from the slip time value with the threshold time value. For example, as shown in FIG. 4, the second time value comparator 520 compares a time value obtained by subtracting a last time value (T2) corresponding to the last frame of the MBSFN subframe from the sleepable time value Ts It is determined whether Ts-T2 is larger than the threshold time value Tx.

If the calculated sleep time value is greater than the threshold time value, the second sleep operation control unit 530 confirms the scheduling of one or more MBSFN subframes and notifies the scheduling of the start frame and the last frame of the scheduled MBSFN subframes And controls to operate in the sleep mode or the non-sleep mode by comparing the time values with the threshold time value.

If the start time value is greater than the sleep time value, the second sleep operation control unit 530 controls the sleep mode to operate in the sleep mode by the start time value. After the elapse of the start time value, If the time value obtained by subtracting the last time value from the sleepable time value is greater than the threshold time value, the control unit controls the sleep time value In the sleep mode by a time value obtained by subtracting the last time value.

For example, as shown in FIG. 4, the fact that the start time value T1 corresponding to the start frame of the MBSFN subframe is larger than the threshold time value Tx means that the first MBSFN sub- The reception time of the frame is larger than the threshold time value. Accordingly, the second sleep operation control unit 530 controls the sleep mode to operate at a time value (T1) corresponding to the start frame of the MBSFN subframe in order to reduce power consumption of the UE.

After the operation of the sleep mode corresponding to the start time value corresponding to the start frame of the MBSFN subframe is performed, the second sleep operation control unit 530 controls the non-sleep mode . For example, as shown in FIG. 4, the second sleep operation control unit 530 sets a time corresponding to a time obtained by subtracting the start time value (T1) from the last time value (T2) corresponding to the last frame of the MBSFN sub- Operate in the sleep mode.

If the start time value of the MBSFN subframe is not greater than the threshold time value, the second sleep operation control unit 530 determines a sleep and non-sleep determination time (T2) from the last time value T2 corresponding to the last frame of the MBSFN subframe decision-to-sleep / no-sleep time) is subtracted from the non-sleep mode.

If the time value obtained by subtracting the last time value from the slip enable time value is greater than the threshold time value, the second sleep operation control unit 530 may calculate a time value obtained by subtracting the last time value from the slip enable time value To operate in the sleep mode. 4, the time value Ts-T2 obtained by subtracting the last time value T2 corresponding to the last frame of the MBSFN subframe from the sleepable time value Ts is smaller than the threshold time value Tx, for example, The second sleep operation control unit 530 performs a sleep mode operation from the time corresponding to the last frame of the MBSFN sub-frame to the wake-up time. do. The state of the sleep mode continues until the wake-up time of the DRX cycle arrives. Thereafter, the second sleep operation control unit 530 determines whether or not the wake-up time of the DRX cycle has arrived, and ends the above-mentioned process if the wake-up time of the DRX cycle comes.

Also, the second sleep operation control unit 530 controls the non-sleep mode to operate if the time value obtained by subtracting the last time value from the sleepable time value is not greater than the threshold time value. 4, the time value Ts-T2 obtained by subtracting the last time value T2 corresponding to the last frame of the MBSFN subframe from the sleepable time value Ts is smaller than the threshold time value Tx, for example, If it is not larger, it indicates that the terminal must be switched to the non-sleep mode again after a short time even if the terminal is switched to the sleep mode. Accordingly, the second sleep operation control unit 530 performs the non-sleep mode operation rather than the repeated switching to the sleep mode and the non-sleep mode.

Also, the second sleep operation control unit 530 controls the non-sleep mode to operate when the calculated sleep time value is not greater than the threshold time value. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, And therefore, the non-sleep mode operation is performed. Thereafter, the second sleep operation control unit 530 determines whether or not the wake-up time of the DRX cycle has arrived, and ends the above-mentioned process if the wake-up time of the DRX cycle comes.

FIG. 13 is a block diagram of a sleep and wake-up operation apparatus of a terminal providing MBMS according to another embodiment of the present invention. Referring to FIG. 13, a third time value calculator 610, a third time value comparator 620, and a third sleep operation controller 630.

The third time value calculator 610 calculates a sleep time corresponding to the time between the sleep and non-sleep determination and the wake-up time according to the sleep mode request in the DRX cycle And transmits the calculated result to the third time value comparator 620 and the third sleep operation controller 630. [

Wherein a time value for a time for the sleep and non-sleep determination is referred to as a zeroth time value, and a time value of the wakeup time is set to an n + 1, where n is a positive Time), the third time value calculator 610 calculates first through n-th time values as time values for each of the MBSFN subframes. For example, as shown in FIG. 6, when the 0th time value is Ta and the n + 1 time value is Tb, the third time value calculator 610 calculates a time value for each of MBSFN subframes The first time value T1 through the nth time value Tn are calculated as time values.

The third time value comparator 620 compares the calculated sleep time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics and transmits the comparison result to the third sleep operation controller 630. [ The third time value comparator 620 stores the threshold time value Tx in a predetermined memory space.

The third time value comparator 620 compares the difference between the ith time value (where i is a positive integer equal to or less than n + 1) and the (i-1) th time value greater than the threshold time value. For example, when i = 1, the third time value comparator 620 determines whether the difference between the first time value and the 0th time value, that is, the value of T1-Ta, is greater than the threshold time value Tx do. Also, when i = 2, the third time value comparator 620 determines whether the difference between the second time value and the first time value, that is, the value of T2-T1 is greater than the threshold time value Tx. Also, when i = n, the third time value comparator 620 compares the difference between the n-th time value and the (n-1) -th time value, that is, the value of Tn-Tn-1 is greater than the threshold time value Tx .

The third sleep operation control unit 630 confirms the scheduling of one or more MBSFN (Multicast Broadcast Single Frequency Network) subframes if the calculated sleep time value is greater than the threshold time value, And controls to operate in the sleep mode or the non-sleep mode through comparison of the time values with respect to each other and the threshold time value.

If the difference between the i-th time value and the i-1 time value is greater than the threshold time value, the third sleep operation control unit 630 determines a time value corresponding to a difference between the i-th time value and the i- And controls the base station to operate in a non-sleep mode during a period of the MBSFN subframe corresponding to the i-th time value, and when the i-th time value corresponds to the (n + 1) -th time value .

If the difference between the i-th time value and the (i-1) -th time value is greater than the threshold time value, the third sleep operation control unit 630 stores the time value corresponding to the difference between the i- So as to operate in the sleep mode. The fact that the difference between the i-th time value and the i-1 time value is larger than the threshold time value (Tx) means that the reception time of the MBSFN subframe in the DRX cycle is greater than the threshold time value. Accordingly, at this time, the third sleep operation controller 630 performs the sleep mode operation for a time corresponding to the difference between the i-th time value and the i-1 time value to reduce the power consumption of the terminal. For example, when i = 1, the third sleep operation control unit 630 performs the sleep mode operation for the time value of T1-Ta, and when i = 2, The controller 630 performs a sleep mode operation for a time value of T2-T1. Also, when i = n, the third sleep operation control unit 630 performs the sleep mode operation as much as the time value of Tn - Tn-1.

Also, the third sleep operation control unit 630 controls the non-sleep mode to operate during the interval of the MBSFN subframe corresponding to the i-th time value. For example, as shown in FIG. 6, the third sleep operation control unit 630 performs a non-sleep mode operation during the interval of the MBSFN subframe 1 corresponding to the first time value T1, Performs a non-sleep mode operation during a period of the MBSFN subframe 2 corresponding to the second time T2 and performs a non-sleep mode operation during a period of the MBSFN subframe n corresponding to the nth time value Tn.

If the difference between the i-th time value and the (i-1) -th time value is not greater than the threshold time value, the third sleep operation control unit 630 determines that the i- Time mode to operate in the non-sleep mode. The difference between the i-th time value and the (i-1) th time value is not greater than the threshold time value means a state in which the terminal must be switched to the non-sleep mode again in a short time even if the terminal is switched to the sleep mode. Therefore, the third sleep operation controller 630 can maintain the non-sleep mode rather than repeatedly switching to the sleep mode and the non-sleep mode.

The third sleep operation control unit 630 determines whether the i-th time value corresponds to the (n + 1) -th time value, and if the i-th time value does not correspond to the (n + Repeat the process.

If the difference between the (n + 1) th time value and the (n) th time value is greater than the threshold time value, the third sleep operation control unit 630 determines that the So as to operate in the sleep mode by the time value. If the difference between the (n + 1) -th time value and the n-th time value is greater than the threshold time value Tx, the third sleep operation control unit 630 sets the The sleep mode operation is performed for a time corresponding to the difference between the values. The state of the sleep mode continues until the wake-up time of the DRX cycle arrives. Then, the third sleep operation control unit 630 determines whether or not the wake-up time of the DRX cycle has arrived. If the wake-up time of the DRX cycle has come, the third sleep operation control unit 630 ends the above-described process.

If the difference between the n + 1 time value and the nth time value is not greater than the threshold time value, the third sleep operation control unit 630 controls to operate in the non-sleep mode. For example, the time value Tb-Tn obtained by subtracting the Tn corresponding to the n-th time value from the Tb corresponding to the (n + 1) -th time value is not larger than the threshold time value Tx means that even if the terminal is switched to the sleep mode It means a state in which the non-sleep mode should be switched again. Therefore, the third sleep operation control unit 630 performs the non-sleep mode operation rather than the repeated switching to the sleep mode and the non-sleep mode.

Also, the third sleep operation control unit 630 controls the non-sleep mode to operate when the calculated sleep time value is not greater than the threshold time value. The calculated sleep-time value is not greater than the threshold time value means that the time when the subscriber station does not receive the MBSFN subframe is less than the threshold time value. Even if the sleep mode is switched to the sleep mode, And therefore, the non-sleep mode operation is performed. Then, the third sleep operation control unit 630 determines whether or not the wake-up time of the DRX cycle has arrived. If the wake-up time of the DRX cycle has come, the third sleep operation control unit 630 ends the above-described process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Do.

Methods according to embodiments of the invention described in the claims and / or in the specification may be implemented in hardware, software, or a combination of hardware and software. When implemented in software, a computer-readable storage medium storing one or more programs (software modules) may be provided. One or more programs stored on a computer-readable storage medium are configured for execution by one or more processors in an electronic device. The one or more programs include instructions that cause the electronic device to perform the methods in accordance with the embodiments of the invention and / or the claims of the present invention.

Such programs (software modules, software) may be stored in a computer readable medium such as a random access memory, a non-volatile memory including a flash memory, a ROM (Read Only Memory), an electrically erasable programmable ROM (EEPROM), a magnetic disc storage device, a compact disc-ROM (CD-ROM), a digital versatile disc (DVDs) An optical storage device, or a magnetic cassette. Or a combination of some or all of these. In addition, a plurality of constituent memories may be included.

The electronic device may also be connected to a communication network, such as the Internet, an Intranet, a LAN (Local Area Network), a WLAN (Wide Area Network), or a communication network such as a SAN (Storage Area Network) And can be stored in an attachable storage device that can be accessed. Such a storage device may be connected to the electronic device through an external port. Further, a separate storage device on the communication network may be connected to the portable electronic device.

410: first time value calculation unit
420: first time value comparison unit
430: a first sleep operation control section
510: second time value calculation unit
520: second time value comparison unit
530: second sleep operation control section
610: a third time value calculation unit
620: third time value comparison unit
630: a third sleep operation control section

Claims (22)

1. A sleep and wake-up operation method of a terminal providing a multimedia broadcast multicast service (MBMS)
A process of calculating a sleep-time value corresponding to a time for wake-up and a time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) ;
Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic; And
And operating in a sleep mode if the calculated sleepable time value is greater than the threshold time value.
2. The method of claim 1, wherein the sleep and non-sleep modes of operation of the terminal include:
Confirming scheduling of a MBSFN (Multicast Broadcast Single Frequency Network) subframe between the start time of the sleep mode and the wake-up time after operating in the sleep mode; And
Further comprising the step of operating in a non-sleep mode if the MBSFN subframe scheduled between the start time of the sleep mode and the wakeup time exists.
2. The method of claim 1, wherein the sleep and non-sleep modes of operation of the terminal include:
And operating in a non-sleep mode if the calculated sleepable time value is not greater than the threshold time value.
1. A method of operating a sleep and a wake-up operation of a terminal providing a Multimedia Broadcast Multicast Service (MBMS)
A process of calculating a sleep-time value corresponding to a time for wake-up and a time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) ;
Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic;
If the calculated sleepable time value is greater than the threshold time value, scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes is confirmed and a time value of a start frame and a last frame of the MBSFN subframes And operating in the sleep mode or the non-sleep mode through comparison of the threshold time value with the threshold time value.
5. The method of claim 4, wherein the sleep mode or the non-sleep mode comprises:
Calculating a start time value of the start frame and a last time value of the last frame of the scheduled MBSFN subframe;
Comparing the start time value with the threshold time value;
Operating in the sleep mode by the start time value if the start time value is greater than the threshold time value;
Operating in the non-sleep mode by a time value obtained by subtracting the start time value from the last time value after a lapse of the start time value;
Comparing the time value obtained by subtracting the last time value from the sleepable time value to determine whether the time value is greater than the threshold time value; And
If the time value obtained by subtracting the last time value from the sleepable time value is greater than the threshold time value, operating in the sleep mode by a time value obtained by subtracting the last time value from the sleepable time value ≪ / RTI >
6. The method of claim 5, wherein the sleep mode or the non-sleep mode comprises:
And operating in the non-sleep mode if the time value obtained by subtracting the last time value from the slip enable time value is not greater than the threshold time value.
5. The method of claim 4, wherein the sleep and non-sleep modes of the terminal
And operating in a non-sleep mode if the calculated sleepable time value is not greater than the threshold time value.
1. A method of operating a sleep and a wake-up operation of a terminal providing a Multimedia Broadcast Multicast Service (MBMS)
A process of calculating a sleep-time value corresponding to a time for wake-up and a time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) ;
Comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to a terminal characteristic;
If the calculated sleepable time value is greater than the threshold time value, confirming scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes and comparing the time values for each of the scheduled MBSFN subframes with the time- And operating in the sleep mode or the non-sleep mode through comparison of time values.
The method of claim 8, wherein the sleep mode or the non-sleep mode comprises:
Wherein a time value for a time for the sleep and non-sleep determination is referred to as a zeroth time value, and a time value of the wakeup time is set to an n + 1, where n is a positive Calculating first to n-th time values as time values for the MBSFN sub-frames, respectively,
Comparing a difference between a time value of i (where i is a positive integer equal to or smaller than n + 1) and an i-1 time value to be greater than the threshold time value;
Operating in a sleep mode by a time value corresponding to a difference between the i-th time value and an i-1 time value, if the difference between the i-th time value and the i-1 time value is greater than the threshold time value;
And operating in a non-sleep mode during a period of the MBSFN subframe corresponding to the i < th > time value,
And repeating the above process until the i-th time value corresponds to the (n + 1) -th time value.
The method as claimed in claim 9, wherein the operation in the sleep mode or the non-sleep mode comprises:
And operating in a non-sleep mode if the difference between the n + 1 time value and the nth time value is not greater than the threshold time value.
9. The method of claim 8, wherein the sleep and non-sleep modes of operation
And operating in a non-sleep mode if the calculated sleepable time value is not greater than the threshold time value.
1. A sleep and wake-up operation apparatus of a terminal providing a Multimedia Broadcast Multicast Service (MBMS)
And a sleep time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a wake-up time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) 1 time value calculation unit;
A first time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics; And
And a first sleep operation controller for controlling operation in a sleep mode if the calculated sleep time value is greater than the threshold time value.
13. The apparatus of claim 12, wherein the first sleep operation control unit
(MBSFN) subframe between the start time of the sleep mode and the wake-up time, and the scheduling of the MBSFN (Multicast Broadcast Single Frequency Network) subframe between the start time of the sleep mode and the wake- And to operate in a non-sleep mode if the MBSFN subframe exists.
13. The apparatus of claim 12, wherein the first sleep operation control unit
And to operate in a non-sleep mode if the calculated sleep-time value is not greater than the threshold time value.
1. A sleep and wake-up operation apparatus of a terminal providing a Multimedia Broadcast Multicast Service (MBMS)
And a sleep time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a wake-up time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) 2 time value calculation unit;
A second time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring a minimum sleep according to the terminal characteristics; And
If the calculated sleepable time value is greater than the threshold time value, scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes is confirmed and a time value of a start frame and a last frame of the MBSFN subframes And a second sleep operation control unit for controlling the sleep mode or the non-sleep mode to operate in the sleep mode or the non-sleep mode by comparing the threshold time value with the threshold time value.
16. The method of claim 15,
Wherein the second time value calculator calculates a start time value of the start frame and a last time value of the last frame of the scheduled MBSFN subframe,
Wherein the second time value comparator compares whether the start time value is greater than the threshold time value and whether the time value obtained by subtracting the last time value from the sleep time value is greater than the threshold time value,
Wherein the second sleep operation control unit controls the sleep mode to operate in the sleep mode by the start time value if the start time value is greater than the sleep time value, Wherein the control unit controls to operate in the non-sleep mode by a time value obtained by subtracting the last time value from the sleepable time value, And to operate in the sleep mode by a time value obtained by subtracting a time value.
17. The apparatus of claim 16, wherein the second sleep operation control unit
And to operate in the non-sleep mode if the time value obtained by subtracting the last time value from the slip enable time value is not greater than the threshold time value.
16. The apparatus of claim 15, wherein the second sleep operation control section
And to operate in a non-sleep mode if the calculated sleep-time value is not greater than the threshold time value.
1. A sleep and wake-up operation apparatus of a terminal providing a Multimedia Broadcast Multicast Service (MBMS)
And a sleep time value calculation unit for calculating a sleep time value corresponding to a time between a sleep and a wake-up time for determining a sleep and a non-sleep according to a sleep mode request in a DRX (Discontinuous Reception) A 3-time value calculator;
A third time value comparing unit for comparing the calculated sleepable time value with a threshold time value for ensuring minimum sleep according to the terminal characteristics; And
If the calculated sleepable time value is greater than the threshold time value, confirming scheduling of at least one MBSFN (Multicast Broadcast Single Frequency Network) subframes and comparing the time values for each of the scheduled MBSFN subframes with the time- And a third sleep operation control unit for controlling the sleep mode or the non-sleep mode to operate in the sleep mode or the non-sleep mode through comparison of time values.
20. The method of claim 19,
Wherein the third time value calculator calculates a time value for the sleep and non-sleep decisions as a zeroth time value and a time value of the wakeup time as an n + n is a positive integer greater than 1) time value, the first to n-th time values are calculated as time values for each of the MBSFN subframes,
The third time value comparator compares whether the difference between the i-th time value (where i is a positive integer equal to or less than n + 1) and the i-1 time value is greater than the threshold time value,
If the difference between the i-th time value and the (i-1) -th time value is greater than the threshold time value, the third sleep operation control unit determines that the sleep time is equal to the time value corresponding to the difference between the i- Mode and controls to operate in a non-sleep mode during a period of the MBSFN subframe corresponding to the i-th time value, and repeats the operation until the i-th time value corresponds to the (n + 1) -th time value Lt; / RTI >
21. The apparatus of claim 20, wherein the third sleep operation control section
And controls to operate in a non-sleep mode if the difference between the n + 1 time value and the nth time value is not greater than the threshold time value.
20. The apparatus of claim 19, wherein the third sleep operation control unit
And to operate in a non-sleep mode if the calculated sleep-time value is not greater than the threshold time value.

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